by: University
"Neovascular age-related macular degeneration (nvAMD) is a chronic, progressive disease of the central retina, and its prevalence is expected to rise with the aging population. Using a bottom-up approach based on retrospective data, this cross-sectional study estimated average annual direct costs of nvAMD to be A 4,047 pound, and average annual indirect costs to be A 449 pound," scientists in Bristol, the United Kingdom report.
"An attempt to measure intangible costs through willingness-to-pay yielded a lower response rate and estimated intangible costs to be 11.5% of monthly income. Direct costs were significantly higher for male participants, for those who have mild or moderate visual impairment in both eyes, and for those who have been diagnosed for a shorter time," wrote K.M. Ke and colleagues, University of Bristol.
The researchers concluded: "The findings of this study suggest that the availability of early diagnosis, effective treatment, support services, and sustained research into the management of nvAMD may reduce the burden of visual impairment caused by nvAMD to affected individuals and the state."
Ke and colleagues published their study in European Journal of Health Economics (The direct, indirect and intangible costs of visual impairment caused by neovascular age-related macular degeneration. European Journal of Health Economics, 2010;11(6):525-531).
For additional information, contact K.M. Ke, University of Bristol, Bristol Dental School, Dept. of Oral & Dental Science, Lower Maudlin St., Bristol BS1 2LY, Avon, UK.
The publisher's contact information for the European Journal of Health Economics is: Springer, 233 Spring St., New York, NY 10013, USA.
Keywords: City:Bristol, Country:United Kingdom, Age-Related Macular Degeneration, Retinal Degeneration, Retinal Diseases
Monday, December 27, 2010
Monday, December 20, 2010
Genetic Testing for AMD is here Today
by:Diana Shechtman OD FAAO & Steven Ferrucci OD FAAO
Age-Related macular degeneration (AMD) is a progressive disease and the leading cause of vision loss among the elderly, affecting central vision required for daily activities such as driving and reading. There are a number of factors affecting AMD, such as advanced age, smoking, UV exposure, overall health (that contribute to high blood pressure, obesity, diet) and family history. Many factors may be modified and yet others like genetics cannot. Although AMD may seem to be hereditary in some families and not others, genetics have been shown to contribute significantly to the disease. Multiple twin and sibling studies have collaborated to the familial nature of the disease. First-degree relatives of patients with AMD are at a significantly increased risk for the disease. Furthermore, large epidemiological studies have suggested a strong genetic risk factor for AMD. In fact, the risk of developing AMD increases 4 fold among patients with a positive family history. In 2005 a breakthrough occurred in the area of genetic research and AMD; Klein and associates discovered a strong link between AMD and certain genetic variants. Similarly, numerous other genes have been implicated in AMD, which may increase the risk of AMD up to 70%.
Until recently there was no test to help determined patient’s inherited risk for AMD. Today, Macula Risk (ArcticDX, Toronto, Ontario) is a genetic test specifically designed to determine genetic predisposition to AMD and vision loss attributed to the more advanced stage of the disease.
Macula Risk genetic test separates individuals into one of 5 macula risk (MR) categories, with MR 3 through 5 representing an increased risk for the more advance stage of the disease. This accounts for approximately 20% of the general population. MR1 has less than a 5% risk of the advanced stage of the disease, while MR 5 carries greater than 55% risk. These results can aid the doctor in devising a specific management plan and follow-up protocol in order to reassure early intervention to prevent vision loss.
The test only requires a simple in-office cheek swab, which is sent directly to the genetic lab. The report includes test results and written genetic support information (including access to genetic counseling). Macula Risk genetic testing is covered by most insurance providers, including Medicare, as long as the specific diagnosis (ICD-9) are identified by the doctor. The prognostic genetic test is intended for patients who have a diagnosis of early or intermediate AMD. Thus, the “at risk patient,” would have to pay a fee for the test.
Despite our best efforts and new treatment options available today, many people are still losing vision from AMD. New advancements in the area of AMD are becoming an integral part in preventing future visual deterioration. AMD is affected by both environmental and genetic factors that interact with one another to determine prevalence and progression of the disease. Furthermore, at this time we do not know all of the genes linked to AMD. Hence, genetic testing in the area of AMD is only a risk indicator and cannot predict “without a shadow of a doubt,” which patients will and which will not develop the disease. However, this test provides a genetic profile screening to help identify those at risk as well as aids in tailoring a distinct management approach for those with the disease. With various researches devoted to treatment options for AMD, genetic testing in the area of AMD is at the frontier of providing crucial information.
REFERENCES
1. Swaroop, Branham KE, Chen W, Abecasis G. Genetic susceptibility to age-related macular degeneration: a paradigm for dissecting complex disease traits. Hum Mol Genet 2007; 16: 174-82.
2. Klein ML, Mauldin WM, Stoumbos VD. Heredity and age-related macular degeneration. Observations in monozygotic twins. Arch Ophthalmol. 1994; 112: 932-7.
3. Meyers SM, Greene T, Gutman FA. A twin study of age-related macular degeneration. Am J Ophthalmol. 1995; 120: 757-66.
4. Heiba IM, Elston RC, Klein BE, et al. Sibling correlations and segregation analysis of age-related maculopathy: The Beaver Dam Eye Study. Genet Epidemiol. 1994; 11: 51-67.
5. Klaver CC, Wolfs RC, Assink JJ, et al. Genetic risk of age-related maculopathy. Population-based familial aggregation study. Arch Ophthalmol. 1998; 116: 1646-51.
6. Seddon JM, Ajani UA, Mitchell BD. Familial aggregation of age-related maculopathy. Am J Ophthalmol. 1997; 123: 199-206.
7. Klein RJ, Zeiss C, Chew EY, et al. Complement Factor H Polymorphism in Age-Related Macular Degeneration. Science 2005; 308: 385-389.
8. Seddon JM, Reynolds R, Maller J, Fagerness JA, Daly MJ, Rosner B. Prediction model for prevalence and incidence of advanced age-related macular degeneration based on genetic, demographic, and environmental variables. Invest Ophthalmol Vis Sci 2009; 50 (65): 2044-53.
9. www.macularisk.com/en/physicians/order.html (accessed Dec. 14th , 2010)
Age-Related macular degeneration (AMD) is a progressive disease and the leading cause of vision loss among the elderly, affecting central vision required for daily activities such as driving and reading. There are a number of factors affecting AMD, such as advanced age, smoking, UV exposure, overall health (that contribute to high blood pressure, obesity, diet) and family history. Many factors may be modified and yet others like genetics cannot. Although AMD may seem to be hereditary in some families and not others, genetics have been shown to contribute significantly to the disease. Multiple twin and sibling studies have collaborated to the familial nature of the disease. First-degree relatives of patients with AMD are at a significantly increased risk for the disease. Furthermore, large epidemiological studies have suggested a strong genetic risk factor for AMD. In fact, the risk of developing AMD increases 4 fold among patients with a positive family history. In 2005 a breakthrough occurred in the area of genetic research and AMD; Klein and associates discovered a strong link between AMD and certain genetic variants. Similarly, numerous other genes have been implicated in AMD, which may increase the risk of AMD up to 70%.
Until recently there was no test to help determined patient’s inherited risk for AMD. Today, Macula Risk (ArcticDX, Toronto, Ontario) is a genetic test specifically designed to determine genetic predisposition to AMD and vision loss attributed to the more advanced stage of the disease.
Macula Risk genetic test separates individuals into one of 5 macula risk (MR) categories, with MR 3 through 5 representing an increased risk for the more advance stage of the disease. This accounts for approximately 20% of the general population. MR1 has less than a 5% risk of the advanced stage of the disease, while MR 5 carries greater than 55% risk. These results can aid the doctor in devising a specific management plan and follow-up protocol in order to reassure early intervention to prevent vision loss.
The test only requires a simple in-office cheek swab, which is sent directly to the genetic lab. The report includes test results and written genetic support information (including access to genetic counseling). Macula Risk genetic testing is covered by most insurance providers, including Medicare, as long as the specific diagnosis (ICD-9) are identified by the doctor. The prognostic genetic test is intended for patients who have a diagnosis of early or intermediate AMD. Thus, the “at risk patient,” would have to pay a fee for the test.
Despite our best efforts and new treatment options available today, many people are still losing vision from AMD. New advancements in the area of AMD are becoming an integral part in preventing future visual deterioration. AMD is affected by both environmental and genetic factors that interact with one another to determine prevalence and progression of the disease. Furthermore, at this time we do not know all of the genes linked to AMD. Hence, genetic testing in the area of AMD is only a risk indicator and cannot predict “without a shadow of a doubt,” which patients will and which will not develop the disease. However, this test provides a genetic profile screening to help identify those at risk as well as aids in tailoring a distinct management approach for those with the disease. With various researches devoted to treatment options for AMD, genetic testing in the area of AMD is at the frontier of providing crucial information.
REFERENCES
1. Swaroop, Branham KE, Chen W, Abecasis G. Genetic susceptibility to age-related macular degeneration: a paradigm for dissecting complex disease traits. Hum Mol Genet 2007; 16: 174-82.
2. Klein ML, Mauldin WM, Stoumbos VD. Heredity and age-related macular degeneration. Observations in monozygotic twins. Arch Ophthalmol. 1994; 112: 932-7.
3. Meyers SM, Greene T, Gutman FA. A twin study of age-related macular degeneration. Am J Ophthalmol. 1995; 120: 757-66.
4. Heiba IM, Elston RC, Klein BE, et al. Sibling correlations and segregation analysis of age-related maculopathy: The Beaver Dam Eye Study. Genet Epidemiol. 1994; 11: 51-67.
5. Klaver CC, Wolfs RC, Assink JJ, et al. Genetic risk of age-related maculopathy. Population-based familial aggregation study. Arch Ophthalmol. 1998; 116: 1646-51.
6. Seddon JM, Ajani UA, Mitchell BD. Familial aggregation of age-related maculopathy. Am J Ophthalmol. 1997; 123: 199-206.
7. Klein RJ, Zeiss C, Chew EY, et al. Complement Factor H Polymorphism in Age-Related Macular Degeneration. Science 2005; 308: 385-389.
8. Seddon JM, Reynolds R, Maller J, Fagerness JA, Daly MJ, Rosner B. Prediction model for prevalence and incidence of advanced age-related macular degeneration based on genetic, demographic, and environmental variables. Invest Ophthalmol Vis Sci 2009; 50 (65): 2044-53.
9. www.macularisk.com/en/physicians/order.html (accessed Dec. 14th , 2010)
Saturday, December 11, 2010
The link Between Age-Related Macular Degeneration and Cardiovascular Disease
by:Johns Hopkins Health Alert
Several studies have found that people with age-related macular degeneration (AMD) are more likely to have heart disease than those without age-related macular degeneration. A U.S. Medicare study, for example, found that elderly people with age-related macular degeneration were 20% more likely to have a heart attack than their counterparts who didn't have age-related macular degeneration. And a large Australian study, reported in the British Journal of Ophthalmology, suggests that age-related macular degeneration increases the risk of dying from coronary heart disease or stroke.
The researchers used data from nearly 3,000 participants, age 49 and older, in the Blue Mountains Eye Study -- none with a history of coronary heart disease or stroke at enrollment. They found that people younger than age 75 who had early signs of age-related macular degeneration at the study's start were twice as likely to die of coronary heart disease as their counterparts who did not have early signs. However, there was no increased risk of dying of a stroke in this group.
People with late age-related macular degeneration at the beginning of the study who were under age 75 had five times the risk of dying of coronary heart disease and 10 times the risk of dying of a stroke. The link between late age-related macular degeneration and risk of death from cardiovascular disease should be interpreted cautiously, warn the researchers, because there were so few people with late age-related macular degeneration at study entry.
Surprisingly, the researchers found no increased risk of death from cardiovascular disease among people over age 75 with age-related macular degeneration. They speculate that past 75, patients died of other serious health conditions that overshadowed the connection.
Take-away message: What's behind the link between age-related macular degeneration and cardiovascular disease? Some researchers suspect that age-related macular degeneration and cardiovascular diseases may share a common genesis: for instance, atherosclerosis, inflammation, and oxidative stress (the cell damage caused by free radicals) are known to affect both conditions. Another alternative: age-related macular degeneration may simply be a disease of aging.
Medical Disclaimer: This information is not intended to be substituted for the advice of a physician. Johns Hopkins Health Alerts
Several studies have found that people with age-related macular degeneration (AMD) are more likely to have heart disease than those without age-related macular degeneration. A U.S. Medicare study, for example, found that elderly people with age-related macular degeneration were 20% more likely to have a heart attack than their counterparts who didn't have age-related macular degeneration. And a large Australian study, reported in the British Journal of Ophthalmology, suggests that age-related macular degeneration increases the risk of dying from coronary heart disease or stroke.
The researchers used data from nearly 3,000 participants, age 49 and older, in the Blue Mountains Eye Study -- none with a history of coronary heart disease or stroke at enrollment. They found that people younger than age 75 who had early signs of age-related macular degeneration at the study's start were twice as likely to die of coronary heart disease as their counterparts who did not have early signs. However, there was no increased risk of dying of a stroke in this group.
People with late age-related macular degeneration at the beginning of the study who were under age 75 had five times the risk of dying of coronary heart disease and 10 times the risk of dying of a stroke. The link between late age-related macular degeneration and risk of death from cardiovascular disease should be interpreted cautiously, warn the researchers, because there were so few people with late age-related macular degeneration at study entry.
Surprisingly, the researchers found no increased risk of death from cardiovascular disease among people over age 75 with age-related macular degeneration. They speculate that past 75, patients died of other serious health conditions that overshadowed the connection.
Take-away message: What's behind the link between age-related macular degeneration and cardiovascular disease? Some researchers suspect that age-related macular degeneration and cardiovascular diseases may share a common genesis: for instance, atherosclerosis, inflammation, and oxidative stress (the cell damage caused by free radicals) are known to affect both conditions. Another alternative: age-related macular degeneration may simply be a disease of aging.
Medical Disclaimer: This information is not intended to be substituted for the advice of a physician. Johns Hopkins Health Alerts
Tuesday, December 7, 2010
SiemCells, Inc. Expands SC Proven(R) Product Portfolio With launch of Proprietary Human Cell Detection Antibodies
Posted by: StemCells,Inc.
StemCells, Inc. (Nasdaq: STEM | PowerRating) announced today the launch of STEM101(TM), STEM121(TM) and STEM123(TM), three new antibody reagents that significantly improve the visualization of human cells, including human stem cells and their progeny. These high potency antibodies are the latest additions to the Company's growing SC Proven(R) portfolio of research products, and provide powerful, cost-effective tools for the detection, tracking and characterization of human cells both in vitro and when transplanted into animal models of human diseases.
"The commercial launch of these proprietary antibodies demonstrates our ongoing commitment to broaden our portfolio of innovative research products and to take advantage of the growing market for research-grade cells, media and reagents," said Stewart Craig, Senior Vice President, Development and Operations at StemCells, Inc. "Their utility has been proven by our scientists and by independent academic collaborators in the conduct of their research and development activities. These antibodies have also become the cornerstone of our extensive preclinical studies, which have allowed us to successfully advance our stem cell therapeutic candidates into multiple clinical trials. There is considerable demand for these reagents, so we are pleased to now make them available to the scientific community at large."
STEM101, STEM121 and STEM123 are human-specific mouse monoclonal antibodies that have been extensively used to detect the engraftment, migration and differentiation of human neural stem cells and human liver engrafting cells (hLEC(TM)) transplanted into rodents.1,2,3,4,5 These antibodies can be used for immunohistochemistry and immunofluorescence applications such as:
-- Quantifying the location and number of engrafted cells
-- Tracking the migration pattern of engrafted cells
-- Determining the nature of engrafted cells
-- Identifying specific differentiated human-derived cells such as
astrocytes
STEM101 recognizes the Ku80 protein found in human nuclei, STEM121 recognizes a cytoplasmic protein of human cells, and STEM123 recognizes human glial fibrillary acidic protein (GFAP).
About SC Proven Products
The SC Proven product portfolio comprises a range of specialty cell culture products that enable the standardized and reproducible production and propagation of highly purified stem cells and their differentiated progeny, as well as reagents for cell detection, isolation and characterization.
References
-- Kelly S, et al. Transplanted human fetal neural stem cells survive,
migrate, and differentiate in ischemic rat cerebral cortex. PNAS (2004)
101:11839-11844
-- Cummings B.J., et al. Human neural stem cells differentiate and promote
locomotor recovery in spinal cord-injured mice. PNAS (2005) 102:
14069-14074
-- Tamaki S.J., et al., Neuroprotection of Host Cells by Human Central
Nervous System Stem Cells in a Mouse Model of Infantile Neuronal Ceroid
Lipofuscinosis. Cell Stem Cell (2009) 5:310-319
-- Kallur T., et al. Human Fetal Cortical and Striatal Neural Stem Cells
Generate Region-Specific Neurons In Vitro and Differentiate Extensively
to Neurons After Intrastriatal Transplantation in Neonatal Rats. J
Neurosci Res. (2006) 84:1630-1644
-- Salazar D.L., et al., Human Neural Stem Cells Differentiate and Promote
Locomotor Recovery in an Early Chronic Spinal Cord Injury NOD-scid Mouse
Model. PLoS ONE (2010) 5: e12272
About StemCells, Inc.
StemCells, Inc. is engaged in the research, development, and commercialization of cell-based therapeutics and tools for use in stem cell-based research and drug discovery. In its therapeutic product development programs, StemCells is targeting disorders of the central nervous system and the liver. StemCells' lead product candidate, HuCNS-SC(R) cells (purified human neural stem cells), is currently in clinical development for the treatment of two fatal neurodegenerative disorders in children, and in preclinical development for spinal cord injury and retinal disorders such as age-related macular degeneration. StemCells also markets research products, including media and reagents, under the SC Proven(R)brand, and is developing stem cell-based assay platforms for use in pharmaceutical research, drug discovery and drug development. Further information about StemCells is available at www.stemcellsinc.com.
The StemCells, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=7014
Apart from statements of historical fact, the text of this press release constitutes forward-looking statements within the meaning of the U.S. securities laws, and is subject to the safe harbors created therein. These statements include, but are not limited to, statements regarding the ability of STEM101, STEM121 and STEM123 to enable and improve the visualization, detection, tracking and characterization of human cells both in vitro and when transplanted into animal models of human diseases; the clinical development of the Company's HuCNS-SC cells; the prospects for the Company to pursue non-therapeutic applications of its cell-based technologies; and the future business operations of the Company. These forward-looking statements speak only as of the date of this news release. The Company does not undertake to update any of these forward-looking statements to reflect events or circumstances that occur after the date hereof. Such statements reflect management's current views and are based on certain assumptions that may or may not ultimately prove valid. The Company's actual results may vary materially from those contemplated in such forward-looking statements due to risks and uncertainties to which the Company is subject, including those described under the heading "Risk Factors" in the Company's Annual Report
on Form 10-K for the year ended December 31, 2009, and in its subsequent reports on Form 10-Q and Form 8-K.
StemCells, Inc. (Nasdaq: STEM | PowerRating) announced today the launch of STEM101(TM), STEM121(TM) and STEM123(TM), three new antibody reagents that significantly improve the visualization of human cells, including human stem cells and their progeny. These high potency antibodies are the latest additions to the Company's growing SC Proven(R) portfolio of research products, and provide powerful, cost-effective tools for the detection, tracking and characterization of human cells both in vitro and when transplanted into animal models of human diseases.
"The commercial launch of these proprietary antibodies demonstrates our ongoing commitment to broaden our portfolio of innovative research products and to take advantage of the growing market for research-grade cells, media and reagents," said Stewart Craig, Senior Vice President, Development and Operations at StemCells, Inc. "Their utility has been proven by our scientists and by independent academic collaborators in the conduct of their research and development activities. These antibodies have also become the cornerstone of our extensive preclinical studies, which have allowed us to successfully advance our stem cell therapeutic candidates into multiple clinical trials. There is considerable demand for these reagents, so we are pleased to now make them available to the scientific community at large."
STEM101, STEM121 and STEM123 are human-specific mouse monoclonal antibodies that have been extensively used to detect the engraftment, migration and differentiation of human neural stem cells and human liver engrafting cells (hLEC(TM)) transplanted into rodents.1,2,3,4,5 These antibodies can be used for immunohistochemistry and immunofluorescence applications such as:
-- Quantifying the location and number of engrafted cells
-- Tracking the migration pattern of engrafted cells
-- Determining the nature of engrafted cells
-- Identifying specific differentiated human-derived cells such as
astrocytes
STEM101 recognizes the Ku80 protein found in human nuclei, STEM121 recognizes a cytoplasmic protein of human cells, and STEM123 recognizes human glial fibrillary acidic protein (GFAP).
About SC Proven Products
The SC Proven product portfolio comprises a range of specialty cell culture products that enable the standardized and reproducible production and propagation of highly purified stem cells and their differentiated progeny, as well as reagents for cell detection, isolation and characterization.
References
-- Kelly S, et al. Transplanted human fetal neural stem cells survive,
migrate, and differentiate in ischemic rat cerebral cortex. PNAS (2004)
101:11839-11844
-- Cummings B.J., et al. Human neural stem cells differentiate and promote
locomotor recovery in spinal cord-injured mice. PNAS (2005) 102:
14069-14074
-- Tamaki S.J., et al., Neuroprotection of Host Cells by Human Central
Nervous System Stem Cells in a Mouse Model of Infantile Neuronal Ceroid
Lipofuscinosis. Cell Stem Cell (2009) 5:310-319
-- Kallur T., et al. Human Fetal Cortical and Striatal Neural Stem Cells
Generate Region-Specific Neurons In Vitro and Differentiate Extensively
to Neurons After Intrastriatal Transplantation in Neonatal Rats. J
Neurosci Res. (2006) 84:1630-1644
-- Salazar D.L., et al., Human Neural Stem Cells Differentiate and Promote
Locomotor Recovery in an Early Chronic Spinal Cord Injury NOD-scid Mouse
Model. PLoS ONE (2010) 5: e12272
About StemCells, Inc.
StemCells, Inc. is engaged in the research, development, and commercialization of cell-based therapeutics and tools for use in stem cell-based research and drug discovery. In its therapeutic product development programs, StemCells is targeting disorders of the central nervous system and the liver. StemCells' lead product candidate, HuCNS-SC(R) cells (purified human neural stem cells), is currently in clinical development for the treatment of two fatal neurodegenerative disorders in children, and in preclinical development for spinal cord injury and retinal disorders such as age-related macular degeneration. StemCells also markets research products, including media and reagents, under the SC Proven(R)brand, and is developing stem cell-based assay platforms for use in pharmaceutical research, drug discovery and drug development. Further information about StemCells is available at www.stemcellsinc.com.
The StemCells, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=7014
Apart from statements of historical fact, the text of this press release constitutes forward-looking statements within the meaning of the U.S. securities laws, and is subject to the safe harbors created therein. These statements include, but are not limited to, statements regarding the ability of STEM101, STEM121 and STEM123 to enable and improve the visualization, detection, tracking and characterization of human cells both in vitro and when transplanted into animal models of human diseases; the clinical development of the Company's HuCNS-SC cells; the prospects for the Company to pursue non-therapeutic applications of its cell-based technologies; and the future business operations of the Company. These forward-looking statements speak only as of the date of this news release. The Company does not undertake to update any of these forward-looking statements to reflect events or circumstances that occur after the date hereof. Such statements reflect management's current views and are based on certain assumptions that may or may not ultimately prove valid. The Company's actual results may vary materially from those contemplated in such forward-looking statements due to risks and uncertainties to which the Company is subject, including those described under the heading "Risk Factors" in the Company's Annual Report
on Form 10-K for the year ended December 31, 2009, and in its subsequent reports on Form 10-Q and Form 8-K.
Sunday, November 28, 2010
DeGette Hails Approval of Second Embryonic Stem Cell Human Trial
by:PoliticalNews
Congresswoman Diana DeGette (CO-01) hailed the approval of the second human treatment trial using human embryonic stem cells. The test, just approved by the FDA, will be conducted by Advanced Cell Technology (ACT) and will focus on Stagart disease. Medical professionals believe a successful human trial will open the doors to the treatment of other, more common eye diseases such as macular degeneration. DeGette has been the leading Congressional advocate for federal funding of ethical embryonic stem cell research, as these investments drive breakthrough trials like the one announced this week.
“Embryonic stem cell research holds enormous promise for countless diseases,” said DeGette, “and the approval of this test is yet another step towards the breakthroughs it can bring for millions of Americans. I am excited to see the results of this, and other trials, and encourage my colleagues to recognize the enormous benefits of ethical embryonic stem cell research.”
Stagart’s disease affects central vision – e.g., reading and facial recognition – and can cause its victims to lose peripheral vision, only be able to see various levels of light, or ultimately go blind. This test will treat Stagart’s patients with healthy cells, created from embryonic stem cells, to replace the “scavenger cells” that deteriorate their vision.
The test is the second trial using embryonic stem cells to be approved in the United States. Last month, the Geron Corporation was permitted to conduct a trial involving embryonic stem cells to treat spinal cord injuries. Preliminary testing is still ongoing in that trial. Like the Geron trial, this latest trial will focus primarily on the safety and viability of embryonic stem cell use in the treatment of this condition. The Stagart’s trial will likely start early next year and 12 subjects will be treated.
“The approval of these two tests in such close order demonstrates how the investment by the federal government in ethical stem cell research is beginning to bear fruit for the millions of Americans facing debilitating diseases and conditions,” said DeGette. “The breakthroughs of these discoveries underscore the critical importance of finally codifying ethical stem cell research regulations, so our scientists and their critical work can no longer be subject to political whims.”
Congresswoman Diana DeGette (CO-01) hailed the approval of the second human treatment trial using human embryonic stem cells. The test, just approved by the FDA, will be conducted by Advanced Cell Technology (ACT) and will focus on Stagart disease. Medical professionals believe a successful human trial will open the doors to the treatment of other, more common eye diseases such as macular degeneration. DeGette has been the leading Congressional advocate for federal funding of ethical embryonic stem cell research, as these investments drive breakthrough trials like the one announced this week.
“Embryonic stem cell research holds enormous promise for countless diseases,” said DeGette, “and the approval of this test is yet another step towards the breakthroughs it can bring for millions of Americans. I am excited to see the results of this, and other trials, and encourage my colleagues to recognize the enormous benefits of ethical embryonic stem cell research.”
Stagart’s disease affects central vision – e.g., reading and facial recognition – and can cause its victims to lose peripheral vision, only be able to see various levels of light, or ultimately go blind. This test will treat Stagart’s patients with healthy cells, created from embryonic stem cells, to replace the “scavenger cells” that deteriorate their vision.
The test is the second trial using embryonic stem cells to be approved in the United States. Last month, the Geron Corporation was permitted to conduct a trial involving embryonic stem cells to treat spinal cord injuries. Preliminary testing is still ongoing in that trial. Like the Geron trial, this latest trial will focus primarily on the safety and viability of embryonic stem cell use in the treatment of this condition. The Stagart’s trial will likely start early next year and 12 subjects will be treated.
“The approval of these two tests in such close order demonstrates how the investment by the federal government in ethical stem cell research is beginning to bear fruit for the millions of Americans facing debilitating diseases and conditions,” said DeGette. “The breakthroughs of these discoveries underscore the critical importance of finally codifying ethical stem cell research regulations, so our scientists and their critical work can no longer be subject to political whims.”
Monday, November 22, 2010
Chardan Capital Market Initiates Research Coverage of Stemcells
by GlobeNewswire
PALO ALTO, Calif., - StemCells, Inc. /quotes/comstock/15*!stem/quotes/nls/stem (STEM 1.12, -0.02, -1.75%) announced today that Chardan Capital Markets (Chardan) initiated independent equity research coverage on the Company with a "Buy" recommendation and a 12-month price target of $1.45 per share. The new report, issued yesterday, was authored by Keay Nakae, Senior Analyst at Chardan.
Chardan is the second firm to initiate independent equity research coverage of StemCells, Inc. this year. Headquartered in New York, Chardan is an investment banking and institutional brokerage firm with a focus on micro, small, and mid-cap markets. More information about Chardan is available at www.chardancm.com. StemCells does not endorse or adopt the reports, projections or statements of any analyst.
About StemCells, Inc.
StemCells, Inc. is engaged in the research, development, and commercialization of cell-based therapeutics and tools for use in stem cell-based research and drug discovery. In its therapeutic product development programs, StemCells is targeting disorders of the central nervous system and the liver. StemCells' lead product candidate, HuCNS-SC(R) cells (purified human neural stem cells), is currently in clinical development for the treatment of two fatal neurodegenerative disorders in children, and in preclinical development for spinal cord injury and retinal disorders such as age-related macular degeneration. StemCells also markets stem cell research products, including media and reagents, under the SC Proven(R) brand, and is developing stem cell-based assay platforms for use in pharmaceutical research, drug discovery and drug development. Further information about StemCells is available at www.stemcellsinc.com.
PALO ALTO, Calif., - StemCells, Inc. /quotes/comstock/15*!stem/quotes/nls/stem (STEM 1.12, -0.02, -1.75%) announced today that Chardan Capital Markets (Chardan) initiated independent equity research coverage on the Company with a "Buy" recommendation and a 12-month price target of $1.45 per share. The new report, issued yesterday, was authored by Keay Nakae, Senior Analyst at Chardan.
Chardan is the second firm to initiate independent equity research coverage of StemCells, Inc. this year. Headquartered in New York, Chardan is an investment banking and institutional brokerage firm with a focus on micro, small, and mid-cap markets. More information about Chardan is available at www.chardancm.com. StemCells does not endorse or adopt the reports, projections or statements of any analyst.
About StemCells, Inc.
StemCells, Inc. is engaged in the research, development, and commercialization of cell-based therapeutics and tools for use in stem cell-based research and drug discovery. In its therapeutic product development programs, StemCells is targeting disorders of the central nervous system and the liver. StemCells' lead product candidate, HuCNS-SC(R) cells (purified human neural stem cells), is currently in clinical development for the treatment of two fatal neurodegenerative disorders in children, and in preclinical development for spinal cord injury and retinal disorders such as age-related macular degeneration. StemCells also markets stem cell research products, including media and reagents, under the SC Proven(R) brand, and is developing stem cell-based assay platforms for use in pharmaceutical research, drug discovery and drug development. Further information about StemCells is available at www.stemcellsinc.com.
Monday, November 15, 2010
UC Santa Barbara Part of International Research Collaboration Focusing on Age-Related Macular degeneration Cure
By AScribe Newswire
SANTA BARBARA, Calif., Nov. 15 - An international collaboration between UC Santa Barbara, the Keck School of Medicine of the University of Southern California (USC), and several other research institutions, is bringing together leaders in the fields of stem cell biology, basic science, and ophthalmology to develop a treatment for blindness caused by age-related macular degeneration.
The California Project to Cure Blindness (CPCB) was formed with a $16 million California Institute for Regenerative Medicine (CIRM) "disease team" grant awarded in late 2009 to fund development of a stem cell-based treatment for age-related macular degeneration. As part of the CIRM Disease Team partnership program, an additional $4.1 million from Britain's Medical Research Council funds collaborative work at University College of London.
"UCSB scientists in the Center for Stem Cell Biology and Engineering and the Center for the Study of Macular Degeneration are excited to provide the basic research that will allow translation of stem cell research to the clinic," said Dennis Clegg, professor in UCSB's Department of Molecular, Cellular, and Developmental Biology, and co-director of the UCSB Center for Stem Cell Biology and Engineering. Both centers are part of UCSB's Neuroscience Research Institute. Grant funds totaling $2.5 million for this work were assigned to UCSB through USC.
The overall grant was awarded to principal investigator Mark Humayun, professor of ophthalmology, cell and neurobiology and biomedical engineering at the Keck School, and David R. Hinton, professor of pathology and ophthalmology at the Keck School. Co-investigator is Martin Pera, director of the Eli and Edythe Broad CIRM Center for Regenerative Medicine and Stem Cell Research at USC.
"With this collaboration, we hope to accelerate research on a stem cell-based therapy for age-related macular degeneration," said Humayun. "Age-related macular degeneration is the leading cause of irreversible vision loss, affecting one in three people age 75 or older. The CIRM grant enables us to work with numerous researchers and experts who are dedicated to finding the cure to this devastating medical condition."
The cause of blindness in age-related macular degeneration is the death of retinal pigment epithelial cells, which provide critical support of photoreceptor function and health. The project objective is to replace damaged retinal epithelium with healthy tissue derived from human embryonic stem cells to prevent loss of vision.
Stem cell therapy offers the possibility of a wider range of options for age-related macular degeneration patients, said Keck School Dean Carmen A. Puliafito. "While exciting new pharmaceuticals to treat age-related macular degeneration are now available, these are effective only in a select group of patients, and can be used only during a narrow time window," said Puliafito, an ophthalmologist whose academic focus is macular degeneration. "In contrast, stem cell therapy promises to be broadly applicable. The potential is tremendous."
CIRM President Alan Trounson noted that the disease team approach exemplified by the California Project to Cure Blindness could transform the direction of future research.
"Scientists have talked for years about the need to find ways to speed the pace of discovery," said Trounson. "CIRM, through the Disease Team Award Program, has encouraged applicants to form teams composed of the best researchers from around the world. The partnership between the California Project to Cure Blindness and Britain's Medical Research Council is a great example of CIRM's vision of a new standard for funding translational research."
SANTA BARBARA, Calif., Nov. 15 - An international collaboration between UC Santa Barbara, the Keck School of Medicine of the University of Southern California (USC), and several other research institutions, is bringing together leaders in the fields of stem cell biology, basic science, and ophthalmology to develop a treatment for blindness caused by age-related macular degeneration.
The California Project to Cure Blindness (CPCB) was formed with a $16 million California Institute for Regenerative Medicine (CIRM) "disease team" grant awarded in late 2009 to fund development of a stem cell-based treatment for age-related macular degeneration. As part of the CIRM Disease Team partnership program, an additional $4.1 million from Britain's Medical Research Council funds collaborative work at University College of London.
"UCSB scientists in the Center for Stem Cell Biology and Engineering and the Center for the Study of Macular Degeneration are excited to provide the basic research that will allow translation of stem cell research to the clinic," said Dennis Clegg, professor in UCSB's Department of Molecular, Cellular, and Developmental Biology, and co-director of the UCSB Center for Stem Cell Biology and Engineering. Both centers are part of UCSB's Neuroscience Research Institute. Grant funds totaling $2.5 million for this work were assigned to UCSB through USC.
The overall grant was awarded to principal investigator Mark Humayun, professor of ophthalmology, cell and neurobiology and biomedical engineering at the Keck School, and David R. Hinton, professor of pathology and ophthalmology at the Keck School. Co-investigator is Martin Pera, director of the Eli and Edythe Broad CIRM Center for Regenerative Medicine and Stem Cell Research at USC.
"With this collaboration, we hope to accelerate research on a stem cell-based therapy for age-related macular degeneration," said Humayun. "Age-related macular degeneration is the leading cause of irreversible vision loss, affecting one in three people age 75 or older. The CIRM grant enables us to work with numerous researchers and experts who are dedicated to finding the cure to this devastating medical condition."
The cause of blindness in age-related macular degeneration is the death of retinal pigment epithelial cells, which provide critical support of photoreceptor function and health. The project objective is to replace damaged retinal epithelium with healthy tissue derived from human embryonic stem cells to prevent loss of vision.
Stem cell therapy offers the possibility of a wider range of options for age-related macular degeneration patients, said Keck School Dean Carmen A. Puliafito. "While exciting new pharmaceuticals to treat age-related macular degeneration are now available, these are effective only in a select group of patients, and can be used only during a narrow time window," said Puliafito, an ophthalmologist whose academic focus is macular degeneration. "In contrast, stem cell therapy promises to be broadly applicable. The potential is tremendous."
CIRM President Alan Trounson noted that the disease team approach exemplified by the California Project to Cure Blindness could transform the direction of future research.
"Scientists have talked for years about the need to find ways to speed the pace of discovery," said Trounson. "CIRM, through the Disease Team Award Program, has encouraged applicants to form teams composed of the best researchers from around the world. The partnership between the California Project to Cure Blindness and Britain's Medical Research Council is a great example of CIRM's vision of a new standard for funding translational research."
Thursday, November 4, 2010
Miracle Eye Implant Restores sight to Blind
by Victoria Fletcher
A MAN who was totally blind can now read letters of the alphabet and the time on a clock face with a microchip implanted in his eye, it was revealed yesterday.
Experts said hopes of such a leap forward had previously existed “only in the realm of science fiction”.
But now researchers have shown it is possible to restore vision lost to disease with an electronic eye.
The study, by a team in Germany, will offer hope to the 25,000 Britons who are told they will go blind due to an inherited condition known as retinitis pigmentosa.
But it could also eventually treat the 300,000 who have macular degeneration which also leads to blindness.
The microchip, smaller than the tip of a pen and containing 1,500 tiny light sensors, fits into a natural space beneath the retina.
When an image comes through the lens of the eye it hits the sensors which send an electrical pulse to nerve cells at the back of the eye. These transmit the message to the brain.
Miikka can now tell an apple from a banana and right Professor Robert Maclaren
The device is powered by a thin cable that runs from the eye, out of the side of the skull and is attached to a battery behind the ear.
The new study reveals that three patients have been able to see grainy images of objects and recognise shapes after having the device fitted.
Finn Miikka Terho, 46, was able to walk around a room with ease, read his own name and even tell researchers they had spelt it wrongly.
He could recognise shades of grey, read the time from a clock and pick up an apple and a banana from the table in front of him.
Before the implant he was totally blind apart from being able to detect changes between light and dark.
The pilot study, published in the Proceedings of the Royal Society B Journal, means the technology behind the device works, is safe and is ready to be tested on a larger number of patients in a proper clinical trial.
Although it does not mean patients will ever be able to see normally, it does raise the prospect that the blind will be helped to see enough to regain some independence.
Prof Robert Maclaren, Professor of Ophthalmology at Oxford University, will conduct the next trial.
He said: “This is a big breakthrough, no two ways about it. To take someone who is blind and help them see again is pretty incredible.”
He added: “The successful testing of this electronic implant in Germany is without doubt a truly significant advance.
“One previously blind patient was able to read his own name with the implant switched on. Until now, this concept would have been considered only in the realms of science fiction.”
In recent years, scientists have helped to restore vision using a small camera mounted on spectacles.
This allowed a rough interpretation of an image beamed through a wire into the brain.
But the new device, developed by German scientist Prof Eberhart Zrenner, shows that the damaged light receptor cells in the eye can simply be replaced by a microchip.
The rest of the image is obtained by the natural eye. Prof Zrenner has now set up the technology firm Retinal Implant AG to develop the device.
Around one in 3,000 Britons have retinitis pigmentosa, which destroys light cells in the eye.The condition, triggered by a range of genes, is incurable and untreatable.
More than 10 times as many people have macular degeneration.
It usually affects older adults and leads to a loss of central vision, making it difficult or impossible to read or recognise faces although enough some peripheral vision remains.
Prof Maclaren said he was thrilled he could now tell patients with retinitis pigmentosa that there was hope ahead after years of having to tell them they would be left completely blind. And he said that although the device did not offer an amazing quality of vision, it would be significant for people who had previously been unable to see anything.
David Head, chief executive of the British Retinitis Pigmentosa Society, welcomed the news, calling it “a very significant advance”. But he said he wanted patients to realise that even this breakthrough would not restore their vision.
He added: “The technology is exciting and hopefully this will advance in the next few years but we have to temper it with reality.”
Up to 12 patients are expected to take part in the British study, due to start early next year at King’s College Hospital, London, and the Oxford Eye Hospital.It is hoped that when the device can be left in place for years instead of months, the brain may learn to interpret the grey and white images into far more accurate pictures of what the eye is really seeing.
A MAN who was totally blind can now read letters of the alphabet and the time on a clock face with a microchip implanted in his eye, it was revealed yesterday.
Experts said hopes of such a leap forward had previously existed “only in the realm of science fiction”.
But now researchers have shown it is possible to restore vision lost to disease with an electronic eye.
The study, by a team in Germany, will offer hope to the 25,000 Britons who are told they will go blind due to an inherited condition known as retinitis pigmentosa.
But it could also eventually treat the 300,000 who have macular degeneration which also leads to blindness.
The microchip, smaller than the tip of a pen and containing 1,500 tiny light sensors, fits into a natural space beneath the retina.
When an image comes through the lens of the eye it hits the sensors which send an electrical pulse to nerve cells at the back of the eye. These transmit the message to the brain.
Miikka can now tell an apple from a banana and right Professor Robert Maclaren
The device is powered by a thin cable that runs from the eye, out of the side of the skull and is attached to a battery behind the ear.
The new study reveals that three patients have been able to see grainy images of objects and recognise shapes after having the device fitted.
Finn Miikka Terho, 46, was able to walk around a room with ease, read his own name and even tell researchers they had spelt it wrongly.
He could recognise shades of grey, read the time from a clock and pick up an apple and a banana from the table in front of him.
Before the implant he was totally blind apart from being able to detect changes between light and dark.
The pilot study, published in the Proceedings of the Royal Society B Journal, means the technology behind the device works, is safe and is ready to be tested on a larger number of patients in a proper clinical trial.
Although it does not mean patients will ever be able to see normally, it does raise the prospect that the blind will be helped to see enough to regain some independence.
Prof Robert Maclaren, Professor of Ophthalmology at Oxford University, will conduct the next trial.
He said: “This is a big breakthrough, no two ways about it. To take someone who is blind and help them see again is pretty incredible.”
He added: “The successful testing of this electronic implant in Germany is without doubt a truly significant advance.
“One previously blind patient was able to read his own name with the implant switched on. Until now, this concept would have been considered only in the realms of science fiction.”
In recent years, scientists have helped to restore vision using a small camera mounted on spectacles.
This allowed a rough interpretation of an image beamed through a wire into the brain.
But the new device, developed by German scientist Prof Eberhart Zrenner, shows that the damaged light receptor cells in the eye can simply be replaced by a microchip.
The rest of the image is obtained by the natural eye. Prof Zrenner has now set up the technology firm Retinal Implant AG to develop the device.
Around one in 3,000 Britons have retinitis pigmentosa, which destroys light cells in the eye.The condition, triggered by a range of genes, is incurable and untreatable.
More than 10 times as many people have macular degeneration.
It usually affects older adults and leads to a loss of central vision, making it difficult or impossible to read or recognise faces although enough some peripheral vision remains.
Prof Maclaren said he was thrilled he could now tell patients with retinitis pigmentosa that there was hope ahead after years of having to tell them they would be left completely blind. And he said that although the device did not offer an amazing quality of vision, it would be significant for people who had previously been unable to see anything.
David Head, chief executive of the British Retinitis Pigmentosa Society, welcomed the news, calling it “a very significant advance”. But he said he wanted patients to realise that even this breakthrough would not restore their vision.
He added: “The technology is exciting and hopefully this will advance in the next few years but we have to temper it with reality.”
Up to 12 patients are expected to take part in the British study, due to start early next year at King’s College Hospital, London, and the Oxford Eye Hospital.It is hoped that when the device can be left in place for years instead of months, the brain may learn to interpret the grey and white images into far more accurate pictures of what the eye is really seeing.
Tuesday, November 2, 2010
OGI invests in personalized medicine for age-related macular degeneration
by administrator
Established in 2007 and based in Toronto, ArcticDx has developed a test, Macula Risk®, the first of its kind and specifically designed to determine one's inherited risk for age-related macular degeneration (AMD), the most common form of acquired blindness in the developed world, affecting over 10% of individuals. ArcticDx will use the PBDF investment to undertake studies in support of a planned filing for Food and Drug Administration (FDA) approval for Macula Risk.
Macula Risk detects variations in genetic markers known to predict the progression of early asymptomatic AMD to blindness using a cheek swab sample. The eyesight of individuals who are genetically predisposed to blindness can be saved through enhanced surveillance and early treatment. Macula Risk helps target effective care to those who need it most and relieves others who would otherwise live with uncertainty.
"The investment from OGI will support our filing for FDA approval for Macula Risk," commented Mr. Gregory Hines, CEO of ArcticDx. "We think this approval is an important departure from the growing trend of direct to consumer marketing of genetic tests that have only a weak link to science and are often of no clinical value. Macula Risk stands as the best example of a validated test for a multi-genetic common human disease. Achieving FDA approval will position Macula Risk for wide spread adoption."
The Macula Risk test will be marketed to eye care professionals who manage most cases of AMD in North America. These doctors will offer the test to individuals with the dry form of the disease who have not yet lost vision.
In the industrialized world, AMD is the major cause of uncorrectable vision loss in the elderly, affecting over 2.5 million people in Canada and over 25 million people in the USA. Age?related macular degeneration is generally a disease of the elderly with the worldwide incidence of the disease growing from one in ten people over the age of 60 to more than 1 in 4 people over the age of 75. Macular degeneration is more common than Parkinson's disease, Alzheimer's disease, breast cancer and prostate cancer combined.
"Application of genomics technologies is opening the door to an era of personalized medicine in our approach to preventing, detecting and treating human disease," commented Dr. Christian Burks, President and CEO, OGI. "We are particularly pleased to be investing in a company that grew out of applied research funded by Genome Canada through OGI."
The funded work will focus on a cohort of patient samples who had early stage AMD in the Age-Related Eye Disease Study (AREDS), a large eye survey carried out by the American National Eye Institute. These patients were followed over a five-year period to determine progression of the disease. The ArcticDx team will undertake a prospective study on this cohort to evaluate use of Macula Risk in predicting which patients will progress to wet AMD (the late form of AMD) and which will not.
OGI's PBDF program invests in opportunities ? based in genomics, proteomics or associated technologies ? that fall in the proof-of-principle (validation) phase of research and that have the short-term potential to secure a significant next step towards the marketplace. Previous recipients have included Ontario universities, research institutes and companies.
Established in 2007 and based in Toronto, ArcticDx has developed a test, Macula Risk®, the first of its kind and specifically designed to determine one's inherited risk for age-related macular degeneration (AMD), the most common form of acquired blindness in the developed world, affecting over 10% of individuals. ArcticDx will use the PBDF investment to undertake studies in support of a planned filing for Food and Drug Administration (FDA) approval for Macula Risk.
Macula Risk detects variations in genetic markers known to predict the progression of early asymptomatic AMD to blindness using a cheek swab sample. The eyesight of individuals who are genetically predisposed to blindness can be saved through enhanced surveillance and early treatment. Macula Risk helps target effective care to those who need it most and relieves others who would otherwise live with uncertainty.
"The investment from OGI will support our filing for FDA approval for Macula Risk," commented Mr. Gregory Hines, CEO of ArcticDx. "We think this approval is an important departure from the growing trend of direct to consumer marketing of genetic tests that have only a weak link to science and are often of no clinical value. Macula Risk stands as the best example of a validated test for a multi-genetic common human disease. Achieving FDA approval will position Macula Risk for wide spread adoption."
The Macula Risk test will be marketed to eye care professionals who manage most cases of AMD in North America. These doctors will offer the test to individuals with the dry form of the disease who have not yet lost vision.
In the industrialized world, AMD is the major cause of uncorrectable vision loss in the elderly, affecting over 2.5 million people in Canada and over 25 million people in the USA. Age?related macular degeneration is generally a disease of the elderly with the worldwide incidence of the disease growing from one in ten people over the age of 60 to more than 1 in 4 people over the age of 75. Macular degeneration is more common than Parkinson's disease, Alzheimer's disease, breast cancer and prostate cancer combined.
"Application of genomics technologies is opening the door to an era of personalized medicine in our approach to preventing, detecting and treating human disease," commented Dr. Christian Burks, President and CEO, OGI. "We are particularly pleased to be investing in a company that grew out of applied research funded by Genome Canada through OGI."
The funded work will focus on a cohort of patient samples who had early stage AMD in the Age-Related Eye Disease Study (AREDS), a large eye survey carried out by the American National Eye Institute. These patients were followed over a five-year period to determine progression of the disease. The ArcticDx team will undertake a prospective study on this cohort to evaluate use of Macula Risk in predicting which patients will progress to wet AMD (the late form of AMD) and which will not.
OGI's PBDF program invests in opportunities ? based in genomics, proteomics or associated technologies ? that fall in the proof-of-principle (validation) phase of research and that have the short-term potential to secure a significant next step towards the marketplace. Previous recipients have included Ontario universities, research institutes and companies.
Saturday, October 23, 2010
CIRM to dole Out $72M to Advance Research and Recruit Stem Cell Scientist
The California Institute for Regenerative Medicine (CIRM) approved funding for 19 awards worth $67 million under the Early Translation II Awards program. The 29-member governing board also voted to approve the second Research Leadership Award of $4.8 million, given to aid in recruiting Peter Coffey, D.Phil., from the University College London to the University of California, Santa Barbara.
The Early Translation II Awards are the second of what CIRM expects to be a 12- to 18-month award cycle for translational research grants. The funded projects are expected to either result in a candidate drug or cell therapy or make significant strides toward such a candidate.
“We are looking for ways to complement our leading edge of stem cell-based treatments for patients, and these projects will load our frontline portfolio with promising studies on autism, muscular dystrophy, Canavan disease, and liver disease,” says Alan Trounson, CIRM president.
The awards went to one for-profit and 11 not-for-profit institutions. The for-profit company iPierian will take its award in the form of a loan. Three of the awards include collaborators in Germany. The portion of the projects carried out by these collaborators will be supported by the Federal Ministry of Education and Research, the science financing agency in Germany, which will fund up to $15 million for this round of awards.
The $4.8 million grant under the Research Leadership Award program will be spread over six years and will back Dr. Coffey’s research on maturing embryonic stem cells into retinal pigment epithelial cells to treat macular degeneration and other forms of vision loss such as diabetic retinopathy and retinitis pigmentosa. Dr. Coffey is part of a team working toward a therapy for macular degeneration led by Mark Humayun, M.D., Ph.D., at the University of Southern California.
“Recruiting internationally renowned stem cell experts such as Dr. Coffey builds a critical mass of stem cell leadership in California to drive the creation of innovative therapies for patients suffering from chronic disease or injury,” notes Robert Klein, chair of the CIRM governing board.
The Early Translation II Awards are the second of what CIRM expects to be a 12- to 18-month award cycle for translational research grants. The funded projects are expected to either result in a candidate drug or cell therapy or make significant strides toward such a candidate.
“We are looking for ways to complement our leading edge of stem cell-based treatments for patients, and these projects will load our frontline portfolio with promising studies on autism, muscular dystrophy, Canavan disease, and liver disease,” says Alan Trounson, CIRM president.
The awards went to one for-profit and 11 not-for-profit institutions. The for-profit company iPierian will take its award in the form of a loan. Three of the awards include collaborators in Germany. The portion of the projects carried out by these collaborators will be supported by the Federal Ministry of Education and Research, the science financing agency in Germany, which will fund up to $15 million for this round of awards.
The $4.8 million grant under the Research Leadership Award program will be spread over six years and will back Dr. Coffey’s research on maturing embryonic stem cells into retinal pigment epithelial cells to treat macular degeneration and other forms of vision loss such as diabetic retinopathy and retinitis pigmentosa. Dr. Coffey is part of a team working toward a therapy for macular degeneration led by Mark Humayun, M.D., Ph.D., at the University of Southern California.
“Recruiting internationally renowned stem cell experts such as Dr. Coffey builds a critical mass of stem cell leadership in California to drive the creation of innovative therapies for patients suffering from chronic disease or injury,” notes Robert Klein, chair of the CIRM governing board.
Monday, October 18, 2010
Vitamin A pill could save sight
By Fiona Macrae
A drug based on vitamin A could prevent millions from going blind as they get older, doctors believe.
The treatment was able to stop the most common cause of blindness in old age during trials.
Researchers behind the drug, fenretinide, found it halted the advance of age-related macular degeneration, for which there is currently no cure.
They targeted the most prevalent form of the condition, known as ‘dry’ AMD, which is caused by the deterioration and death of cells in the macula – the part of the retina used to see straight ahead.
The disease robs sufferers of their sight by creating a blackspot in the centre of their vision.
It can make it impossible to carry out everyday tasks such as reading, driving and watching television.
While the less common ‘wet’ form can be treated, nothing can be done to help the bulk of patients.
The U.S. research studied fenretinide, which is derived from vitamin A, the vitamin found in carrots, and which was originally designed to tackle arthritis.
Almost 250 men and women with dry AMD took a fenretinide pill a day or a placebo.
In the highest dose, the drug halted visual deterioration after a year. This suggests that while it was unable to do anything to stop cells that were already damaged from dying, it protected healthy cells. Although the research is still preliminary, it offers promise of a treatment for the disease.
More...
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It affects millions across the world and 300,000 Britons. The number of UK sufferers could more than treble to one million within 25 years as the population ages.
Dr Jason Slakter, of New York University School of Medicine, said: ‘There are currently no effective treatments for dry AMD and the need for finding one is grave.
‘Our study wasn’t designed to give a final answer.
‘It was designed to see if there was a biological effect and if the drug was working in the way we’d expect and to find out if it was well tolerated by patents.
‘I think we answered all of these points favourably. The bottom line is that I am excited about doing more studies.’
Further, larger trials are planned for the end of next year.
If the drug lives up to its initial promise, it could be in widespread use for dry AMD by 2015.
The treatment works because in normal circumstances the eye needs vitamin A to help it see. The retina naturally uses the vitamin and is helped to do so by a compound called retinol binding protein, or RBP.
However in some patients, the vitamin can produce poisons that kill the delicate cells, leading to loss of vision.
Fenretinide acts as a decoy, attaching itself to the RBP and stopping vitamin A from causing harm, the American Academy of Ophthalmology’s annual conference heard.
Wet AMD, in which tiny blood vessels bleed into the retina, is less common, but progresses more rapidly, with central vision being lost within months of diagnosis.
Caught early enough, wet AMD can be stopped in its tracks by a technique called photodynamic therapy, which uses a light-activated dye to destroy abnormal blood vessels. Drug treatments are also available.
Fenretinide also halved the odds of the patients, who already had dry AMD, going on to develop wet AMD.
A spokesman for the research team said: ‘Years of use of fenretinide to treat cancers, rheumatoid arthritis have shown it to be safe and well-tolerated.’
A drug based on vitamin A could prevent millions from going blind as they get older, doctors believe.
The treatment was able to stop the most common cause of blindness in old age during trials.
Researchers behind the drug, fenretinide, found it halted the advance of age-related macular degeneration, for which there is currently no cure.
They targeted the most prevalent form of the condition, known as ‘dry’ AMD, which is caused by the deterioration and death of cells in the macula – the part of the retina used to see straight ahead.
The disease robs sufferers of their sight by creating a blackspot in the centre of their vision.
It can make it impossible to carry out everyday tasks such as reading, driving and watching television.
While the less common ‘wet’ form can be treated, nothing can be done to help the bulk of patients.
The U.S. research studied fenretinide, which is derived from vitamin A, the vitamin found in carrots, and which was originally designed to tackle arthritis.
Almost 250 men and women with dry AMD took a fenretinide pill a day or a placebo.
In the highest dose, the drug halted visual deterioration after a year. This suggests that while it was unable to do anything to stop cells that were already damaged from dying, it protected healthy cells. Although the research is still preliminary, it offers promise of a treatment for the disease.
More...
* The age of the pensionista: Why most women are totally unprepared for retirement
* The rise of the silver surfer: How half of women over 55 log on to Facebook
It affects millions across the world and 300,000 Britons. The number of UK sufferers could more than treble to one million within 25 years as the population ages.
Dr Jason Slakter, of New York University School of Medicine, said: ‘There are currently no effective treatments for dry AMD and the need for finding one is grave.
‘Our study wasn’t designed to give a final answer.
‘It was designed to see if there was a biological effect and if the drug was working in the way we’d expect and to find out if it was well tolerated by patents.
‘I think we answered all of these points favourably. The bottom line is that I am excited about doing more studies.’
Further, larger trials are planned for the end of next year.
If the drug lives up to its initial promise, it could be in widespread use for dry AMD by 2015.
The treatment works because in normal circumstances the eye needs vitamin A to help it see. The retina naturally uses the vitamin and is helped to do so by a compound called retinol binding protein, or RBP.
However in some patients, the vitamin can produce poisons that kill the delicate cells, leading to loss of vision.
Fenretinide acts as a decoy, attaching itself to the RBP and stopping vitamin A from causing harm, the American Academy of Ophthalmology’s annual conference heard.
Wet AMD, in which tiny blood vessels bleed into the retina, is less common, but progresses more rapidly, with central vision being lost within months of diagnosis.
Caught early enough, wet AMD can be stopped in its tracks by a technique called photodynamic therapy, which uses a light-activated dye to destroy abnormal blood vessels. Drug treatments are also available.
Fenretinide also halved the odds of the patients, who already had dry AMD, going on to develop wet AMD.
A spokesman for the research team said: ‘Years of use of fenretinide to treat cancers, rheumatoid arthritis have shown it to be safe and well-tolerated.’
Sunday, October 10, 2010
Prizes Honor Studies in Vision Loss
Posted by admin
NEW YORK – Three scientists have won prestigious medical prizes — one for devising a treatment for a major cause of vision loss and two for laying the groundwork for an explosion in obesity research.
The Lasker Awards, worth $250,000 apiece, will be presented Oct. 1 by the Albert and Mary Lasker Foundation. A fourth scientist is being honored for decades of statesmanship in biomedical sciences.
The clinical research award goes to Dr. Napoleone Ferrara, 54, of the biotech company Genentech in South San Francisco, Calif. He is honored for discovering a protein called VEGF in 1989 and using it to develop a treatment that significantly improves sight for people with a devastating type of age-related macular degeneration.
More than a million people worldwide have been treated based on Ferrara’s research, the Lasker foundation says. The type of age-related macular degeneration his research addressed — “wet” as opposed to the more common “dry” form — accounts for a tenth or more of the 25 million to 30 million cases of AMD worldwide.
Two drugs based on Ferrara’s VEGF research, Lucentis and the cancer medicine Avastin, are used for wet AMD, attacking it by discouraging the formation of an abnormal growth of blood vessels behind the retina.
The Lasker prize for basic research is shared by Douglas Coleman, 78, of the Jackson Laboratory in Bar Harbor, Maine, and Jeffrey Friedman, 56, of Rockefeller University in New York. They are honored for the discovery of the hormone leptin, which helps regulate appetite and body weight.
In the 1970s, Coleman showed that mice have some sort of appetite-suppressing substance in the blood. Friedman identified the substance in 1994 and named it leptin. People have leptin too, and the research opened new avenues for exploring the biological basis of human obesity, the foundation said.
A Lasker award for special achievement in medical research goes to Dr. David Weatherall, 77, of Oxford University. He is honored for 50 years of “international statesmanship in biomedical science,” including his research on an inherited anemia called thalassemia.
The Lasker foundation was established in 1942. Albert Lasker was an advertising executive who died in 1952. His wife Mary was a longtime champion of medical research before her death in 1994.
NEW YORK – Three scientists have won prestigious medical prizes — one for devising a treatment for a major cause of vision loss and two for laying the groundwork for an explosion in obesity research.
The Lasker Awards, worth $250,000 apiece, will be presented Oct. 1 by the Albert and Mary Lasker Foundation. A fourth scientist is being honored for decades of statesmanship in biomedical sciences.
The clinical research award goes to Dr. Napoleone Ferrara, 54, of the biotech company Genentech in South San Francisco, Calif. He is honored for discovering a protein called VEGF in 1989 and using it to develop a treatment that significantly improves sight for people with a devastating type of age-related macular degeneration.
More than a million people worldwide have been treated based on Ferrara’s research, the Lasker foundation says. The type of age-related macular degeneration his research addressed — “wet” as opposed to the more common “dry” form — accounts for a tenth or more of the 25 million to 30 million cases of AMD worldwide.
Two drugs based on Ferrara’s VEGF research, Lucentis and the cancer medicine Avastin, are used for wet AMD, attacking it by discouraging the formation of an abnormal growth of blood vessels behind the retina.
The Lasker prize for basic research is shared by Douglas Coleman, 78, of the Jackson Laboratory in Bar Harbor, Maine, and Jeffrey Friedman, 56, of Rockefeller University in New York. They are honored for the discovery of the hormone leptin, which helps regulate appetite and body weight.
In the 1970s, Coleman showed that mice have some sort of appetite-suppressing substance in the blood. Friedman identified the substance in 1994 and named it leptin. People have leptin too, and the research opened new avenues for exploring the biological basis of human obesity, the foundation said.
A Lasker award for special achievement in medical research goes to Dr. David Weatherall, 77, of Oxford University. He is honored for 50 years of “international statesmanship in biomedical science,” including his research on an inherited anemia called thalassemia.
The Lasker foundation was established in 1942. Albert Lasker was an advertising executive who died in 1952. His wife Mary was a longtime champion of medical research before her death in 1994.
Monday, October 4, 2010
Portable Macular Degeneration (AMD) Early Detection & Screening Device
Health Research Sciences has developed a new portable device allowing early detection of the leading cause of blindness in the US; Age-Related Macular Degeneration (AMD) and Diabetic Maculopathy. This inexpensive and portable device will be an integral part during the next few years in the fight to reduce AMD in the US.
Lighthouse Point, Florida September 30, 2010. Health Research Sciences introduces a new approach for testing macular function with the purpose of early detection of Age-Related Macular Degeneration (AMD), Diabetic Maculopathy and other retinal pathologies. The MDD-2 Macular Degeneration Detection & Screening Device has a unique, hand-held design that measures photostress recovery and solves the problem of inconsistent macular function testing.
The MDD-2 provides reproducible measurements of macular function (precise photostress recovery times) which are documented in a concise format for health professional interpretation. The MDD-2 also permits monitoring of central retinal health over time and can warn of deterioration in function at an early stage. Over 10 million Americans suffer from vision loss due to Macular Degeneration and approximately 4 million Americans are at risk for vision loss from Diabetes and further that these vision disorders cost all Americans over $1 billion annually.
The MDD-2 enables Ophthalmologists, Optometrists, Primary Care Physicians and Endocrinologists to easily and efficiently measure macular function for the purpose of early detection of AMD, Diabetic Retinopathy and other central retinal diseases. The test may be administered by a trained technician/assistant and takes approximately 4 minutes to complete. Results are available immediately and easily interpreted by the physician.
“As Professor of Ophthalmology and Pathology, Johns Hopkins University, School of Medicine, I am very concerned about the need for early detection of Age Related Macular Degeneration (AMD) and Diabetic Retinopathy in the United States. I believe that dark adaptation and photostress recovery measurement are both effective tests for evaluating the function of the macula, detecting macular degeneration and diabetic retinopathy at an early stage.”
Mark O.M. Tso, M.D., D. Sc.
Lighthouse Point, Florida September 30, 2010. Health Research Sciences introduces a new approach for testing macular function with the purpose of early detection of Age-Related Macular Degeneration (AMD), Diabetic Maculopathy and other retinal pathologies. The MDD-2 Macular Degeneration Detection & Screening Device has a unique, hand-held design that measures photostress recovery and solves the problem of inconsistent macular function testing.
The MDD-2 provides reproducible measurements of macular function (precise photostress recovery times) which are documented in a concise format for health professional interpretation. The MDD-2 also permits monitoring of central retinal health over time and can warn of deterioration in function at an early stage. Over 10 million Americans suffer from vision loss due to Macular Degeneration and approximately 4 million Americans are at risk for vision loss from Diabetes and further that these vision disorders cost all Americans over $1 billion annually.
The MDD-2 enables Ophthalmologists, Optometrists, Primary Care Physicians and Endocrinologists to easily and efficiently measure macular function for the purpose of early detection of AMD, Diabetic Retinopathy and other central retinal diseases. The test may be administered by a trained technician/assistant and takes approximately 4 minutes to complete. Results are available immediately and easily interpreted by the physician.
“As Professor of Ophthalmology and Pathology, Johns Hopkins University, School of Medicine, I am very concerned about the need for early detection of Age Related Macular Degeneration (AMD) and Diabetic Retinopathy in the United States. I believe that dark adaptation and photostress recovery measurement are both effective tests for evaluating the function of the macula, detecting macular degeneration and diabetic retinopathy at an early stage.”
Mark O.M. Tso, M.D., D. Sc.
Saturday, September 18, 2010
Shark Liver Oil and Cartilage could provide Rescue
By Debbie Nicholson
Sharks are labeled with a bad persona. Mainly due to movies like "Jaws" where they go around and chomp down for a nightly feast on any human or animal they can find. There are one million slaughters going on each year on this creature. However, these creatures of the sea have the ability to aide in certain medical conditions such as anemia, brain bleeding and cancer.
Scientists for decades have been studying the shark, well at least his cartilage. They believe this creature has something that can offer the medical community especially in the treatment of cancer. It is a known fact that sharks hardly ever get cancer. There must be something in their bodies that aide in protection from this disease.
The theory of the shark cartilage and cancer among most of the scientific community is having to do specifically with the composition of the cartilage. For one thing cartilage cannot grow cancer due to the fact it has no blood vessels. The theory is that the cartilage manufactures elements that barricade the growing of new blood vessels that would feed on the tumor. So by using the cartilage to treat the tumor the blood vessels then should be stopped from developing on the tumor.
A study was performed to scientifically prove or disprove the theory of shark cartilage. Nine patients had participated in this study. When the study had been completed the evidence indicated that seven of the nine patients who had advanced cancer there was an 87% positive response from the treatment. It is important to note that no other treatment was applied during this study.
The evidence laid out had shown the following results (in brief form here after seven weeks of treatment and all patients were diagnosed as terminal)
A few results:
Female patient stage three uterine cancer going into bladder. Radiation had no effects on the tumor. After seven weeks of the cartilage the tumor reduced in size by 80% and after eleven weeks the tumor had gone and so did her pain. The only remaining factor was scar tissue.
Female with vaginal hemangioma in size of 5"x 5" after hysterectomy and partial vaginectomy along with radiation. Heavy bleeding was life threatening complication. At seven weeks tumor reduced by 60% and bleeding had stopped. At eleven weeks tumor size was 3"x 3" with further treatment it was stated tumor would appear to decrease.
Male stage three cancer on back of right thigh. After nine weeks of cartilage therapy surgery was done. It was noticed that 60% of the tumor was dead and surgically removed.
The summary of this research had indicated that further research was still required but shark cartilage treatments had displayed promise.
Studies on shark cartilage are still being conducted however, these studies are extremely expensive. At the same time environmentalists are advocating for the shark and making the fact known that the shark population has decreased significantly in the prior fifteen years due to over fishing and the ever on going demand for shark products.
The compounds of the shark cartilage are being tested by a few pharmaceutical companies. If developed it would only be able to be available by prescription and it is stated the cartilage is coming from those sharks who have been slaughtered for meat.
Shark cartilage in research has shown it can help alleviate arthritis symptoms. In all reality scientists had determined it is one of the main components in the shark cartilage which is chondroitin sulfate that is the magic behind the alleviation. To make a note the supplements which are sold in health food stores usually come from cows and that of sharks.
Shark cartilage has demonstrated benefits in patients with arthritis. It decrease joint pain and inflammation which enabled patients to use less pain relievers. Good news is a lot of persons who use it in small doses have no major problems. Some can have side effects which include nausea, vomiting, cramping, can lower blood pressure and raise sugar levels. Pregnant women, children and those recovering from surgery are advised against using the product. It has been validated for use in osteoporosis.
Shark cartilage has also been noted to be used for psoriasis, healing wounds, retina damage due to diabetes and inflammation of the intestines. The FDA has given the cartilage "Orphan Drug Status"for renal cell carcinoma. This law allows drug pharmaceuticals special incentives to study drugs for rare conditions.
Currently there has been no reported cases for drug interactions of this product. Doses are dependent on a variety of factors such as age, health and other conditions. There is no current information for proper dosage of this product. Follow directions on label and consult health practitioner before using this product.
Shark liver oil is also being used to treat health conditions. The liver oil is either brown or yellow in appearance. Fisherman for a very long time have used the oil for health treatments. The oil is an abundant source alkyiglycerols which just possibly contain anti-cancer elements. There are currently two other chemicals in the oil which are being studied for cancer they are squalene and squalamine.
Shark liver oil is vastly used in northern Europe as one of the conventional cancer treatments. However, in the United States it is sold as a dietary supplement. Current research is aiming at the components of the oil alkyiglycerols, squalene and squalamone. Past scientific studies have demonstrated the oil possibly has anti-cancer reactions on tumors in animals. Clinical trails based on if it works in humans are currently being studied.
We do know that shark liver oil aides in heightening the immune system, fighting infections, in cancer treatments (northern Europe) and decreases side effects of conventional cancer treatments.
The theory of the alkyiglycerols provide benefits in several different ways. It has been proposed that when fighting cancer they kill off the tumor cells indirectly. Advocates allege they stimulate the immune system by activation of immune cells (macrophages) that eat germs that are trying to penetrate along with damaged cells. The other way is that they have the ability to lessen side effects from chemotherapy and radiation therapy. This is due to the fact they can guard the cell membrane.
Due to the ability to heighten the immune system, there are claims that they provide protection against colds, flu, chronic infections, asthma, arthritis and AIDS.
Previous studies have demonstrated that squalamine can slow down the growing of tumor blood vessels. Advocates lay claim that it just possibly could treat cancer either independently or with chemotherapy. It is currently in studies for macular degeneration, eye condition in which ends in vision loss. Squalene is advocated to having cell protection ability which in turn could possibly lessen side effects that occur from chemotherapy.
All claims to shark liver oil are currently being researched.
Based on how the oil is prepared for commercial use it possibly can be loaded with omega 3 fatty acids and Vitamin A. The oil has been used in already in some moisturizing skin creams and lotions. Just to note some cosmetic companies have removed the ingredient over concern for the decline in the shark population.
The shark liver oil is being sold in capsules and liquid forms. You can purchase it at many of the health food stores and over the internet.
To clarify a few points in the shark liver oil. There is no current evidence that the supplement are effective to treat cancer. There have been a couple of studies that did present some benefit to women who were having radiation therapy for cervical cancer. There has been no other confirmed research in this area since 1980.
Recent studies have demonstrated squalamine has lessened the amounts of lung metastases, tumors in which spread to lungs from a primary cancer which is elsewhere in the body and this was found in animals. Studies conducted early in humans did show it can be used safely with chemotherapy. It is still not determined if it does shrink the tumor or prolongs survival of patients. It is undergoing studies with other treatments for lung and prostate cancers.
Some side effects include nausea and upset stomachs have been noted. In animal studies it had shown it could raise blood pressure. If you are allergic to seafood you could have a reaction.
The dosage for shark liver oil is also undetermined at this time so it is advisable to talk with your practitioner first.
Please do not use this product on its own current merit solely. It is used to aide in other treatments and best used with the advice of your health care practitioner.
Sharks are labeled with a bad persona. Mainly due to movies like "Jaws" where they go around and chomp down for a nightly feast on any human or animal they can find. There are one million slaughters going on each year on this creature. However, these creatures of the sea have the ability to aide in certain medical conditions such as anemia, brain bleeding and cancer.
Scientists for decades have been studying the shark, well at least his cartilage. They believe this creature has something that can offer the medical community especially in the treatment of cancer. It is a known fact that sharks hardly ever get cancer. There must be something in their bodies that aide in protection from this disease.
The theory of the shark cartilage and cancer among most of the scientific community is having to do specifically with the composition of the cartilage. For one thing cartilage cannot grow cancer due to the fact it has no blood vessels. The theory is that the cartilage manufactures elements that barricade the growing of new blood vessels that would feed on the tumor. So by using the cartilage to treat the tumor the blood vessels then should be stopped from developing on the tumor.
A study was performed to scientifically prove or disprove the theory of shark cartilage. Nine patients had participated in this study. When the study had been completed the evidence indicated that seven of the nine patients who had advanced cancer there was an 87% positive response from the treatment. It is important to note that no other treatment was applied during this study.
The evidence laid out had shown the following results (in brief form here after seven weeks of treatment and all patients were diagnosed as terminal)
A few results:
Female patient stage three uterine cancer going into bladder. Radiation had no effects on the tumor. After seven weeks of the cartilage the tumor reduced in size by 80% and after eleven weeks the tumor had gone and so did her pain. The only remaining factor was scar tissue.
Female with vaginal hemangioma in size of 5"x 5" after hysterectomy and partial vaginectomy along with radiation. Heavy bleeding was life threatening complication. At seven weeks tumor reduced by 60% and bleeding had stopped. At eleven weeks tumor size was 3"x 3" with further treatment it was stated tumor would appear to decrease.
Male stage three cancer on back of right thigh. After nine weeks of cartilage therapy surgery was done. It was noticed that 60% of the tumor was dead and surgically removed.
The summary of this research had indicated that further research was still required but shark cartilage treatments had displayed promise.
Studies on shark cartilage are still being conducted however, these studies are extremely expensive. At the same time environmentalists are advocating for the shark and making the fact known that the shark population has decreased significantly in the prior fifteen years due to over fishing and the ever on going demand for shark products.
The compounds of the shark cartilage are being tested by a few pharmaceutical companies. If developed it would only be able to be available by prescription and it is stated the cartilage is coming from those sharks who have been slaughtered for meat.
Shark cartilage in research has shown it can help alleviate arthritis symptoms. In all reality scientists had determined it is one of the main components in the shark cartilage which is chondroitin sulfate that is the magic behind the alleviation. To make a note the supplements which are sold in health food stores usually come from cows and that of sharks.
Shark cartilage has demonstrated benefits in patients with arthritis. It decrease joint pain and inflammation which enabled patients to use less pain relievers. Good news is a lot of persons who use it in small doses have no major problems. Some can have side effects which include nausea, vomiting, cramping, can lower blood pressure and raise sugar levels. Pregnant women, children and those recovering from surgery are advised against using the product. It has been validated for use in osteoporosis.
Shark cartilage has also been noted to be used for psoriasis, healing wounds, retina damage due to diabetes and inflammation of the intestines. The FDA has given the cartilage "Orphan Drug Status"for renal cell carcinoma. This law allows drug pharmaceuticals special incentives to study drugs for rare conditions.
Currently there has been no reported cases for drug interactions of this product. Doses are dependent on a variety of factors such as age, health and other conditions. There is no current information for proper dosage of this product. Follow directions on label and consult health practitioner before using this product.
Shark liver oil is also being used to treat health conditions. The liver oil is either brown or yellow in appearance. Fisherman for a very long time have used the oil for health treatments. The oil is an abundant source alkyiglycerols which just possibly contain anti-cancer elements. There are currently two other chemicals in the oil which are being studied for cancer they are squalene and squalamine.
Shark liver oil is vastly used in northern Europe as one of the conventional cancer treatments. However, in the United States it is sold as a dietary supplement. Current research is aiming at the components of the oil alkyiglycerols, squalene and squalamone. Past scientific studies have demonstrated the oil possibly has anti-cancer reactions on tumors in animals. Clinical trails based on if it works in humans are currently being studied.
We do know that shark liver oil aides in heightening the immune system, fighting infections, in cancer treatments (northern Europe) and decreases side effects of conventional cancer treatments.
The theory of the alkyiglycerols provide benefits in several different ways. It has been proposed that when fighting cancer they kill off the tumor cells indirectly. Advocates allege they stimulate the immune system by activation of immune cells (macrophages) that eat germs that are trying to penetrate along with damaged cells. The other way is that they have the ability to lessen side effects from chemotherapy and radiation therapy. This is due to the fact they can guard the cell membrane.
Due to the ability to heighten the immune system, there are claims that they provide protection against colds, flu, chronic infections, asthma, arthritis and AIDS.
Previous studies have demonstrated that squalamine can slow down the growing of tumor blood vessels. Advocates lay claim that it just possibly could treat cancer either independently or with chemotherapy. It is currently in studies for macular degeneration, eye condition in which ends in vision loss. Squalene is advocated to having cell protection ability which in turn could possibly lessen side effects that occur from chemotherapy.
All claims to shark liver oil are currently being researched.
Based on how the oil is prepared for commercial use it possibly can be loaded with omega 3 fatty acids and Vitamin A. The oil has been used in already in some moisturizing skin creams and lotions. Just to note some cosmetic companies have removed the ingredient over concern for the decline in the shark population.
The shark liver oil is being sold in capsules and liquid forms. You can purchase it at many of the health food stores and over the internet.
To clarify a few points in the shark liver oil. There is no current evidence that the supplement are effective to treat cancer. There have been a couple of studies that did present some benefit to women who were having radiation therapy for cervical cancer. There has been no other confirmed research in this area since 1980.
Recent studies have demonstrated squalamine has lessened the amounts of lung metastases, tumors in which spread to lungs from a primary cancer which is elsewhere in the body and this was found in animals. Studies conducted early in humans did show it can be used safely with chemotherapy. It is still not determined if it does shrink the tumor or prolongs survival of patients. It is undergoing studies with other treatments for lung and prostate cancers.
Some side effects include nausea and upset stomachs have been noted. In animal studies it had shown it could raise blood pressure. If you are allergic to seafood you could have a reaction.
The dosage for shark liver oil is also undetermined at this time so it is advisable to talk with your practitioner first.
Please do not use this product on its own current merit solely. It is used to aide in other treatments and best used with the advice of your health care practitioner.
Monday, September 13, 2010
AstraZeneca joins UCL to find stem cell cure for diabetic blindness
* Julia Kollewe
12 September 2010
AstraZeneca and University College London (UCL) will announce a research partnership tomorrow to develop medicines that use stem cells to repair damaged eyesight in people with diabetes.
Under the three-year deal funded by the drugmaker, researchers from AstraZeneca will team up with scientists at the UCL Institute of Ophthalmology to work on new medicines that use the regenerative capacity of stem cells. They hope to come up with a compound in three to five years, which could then undergo clinical development and possibly be on the market in 10 years' time.
Dr Marcus Fruttiger of the UCL Institute of Ophthalmology, who is leading the project, said: "These tools could be used either to manufacture transplantable material or to directly stimulate new cell growth in the eye to help restore or improve the vision of those with diabetic retinopathy [DR]."
DR is now the most common cause of vision impairment or blindness among western people of working age. The majority of patients with type-1 diabetes, which occurs when the body produces no insulin and often develops during the teenage years, will suffer eyesight problems and about 20%-30% will become blind. Moreover, at least 50% of patients with type-2 diabetes – the far more common type of diabetes, which occurs when the body produces too little insulin or when cells in the body do not react properly to insulin – will also develop retinopathy over time.
With the rapid spread of type-2 diabetes, which is linked to obesity, the need for a retinopathy treatment will grow as more than 438 million people are expected to suffer from diabetes by 2030. A study published this year by Oxford University predicted that eight out of 10 men and almost seven in 10 women will be overweight or obese by 2020. It forecast a 98% rise in obesity-related diabetes by 2050.
Alan Lamont, director of sciences and technology alliances at AstraZeneca. said: "We're getting very keen on the whole area of regenerative medicines and they will be part of our research development over the next few years." He said the collaboration aimed to come up with a treatment that could be administered to the back of the eye to repair damage locally.
AstraZeneca's US rival Pfizer also has a partnership with Professor Pete Coffey of the UCL Institute of Ophthalmology, for another eye condition, macular degeneration. Coffey said: "It's great that 'Big Pharma' is considering regenerative medicines as a serious possibility." He added: "This is British science being developed into a commercial entity with the pharmaceutical industry. It's a good example why the government shouldn't cut funding for biomedical research."
While this is the first time that AstraZeneca has worked on medicine for retinopathy, diabetes has been an area of focus. The company has a new diabetes treatment on the market called Onglyza, which was developed with Bristol-Myers Squibb, and the companies are developing a second diabetes drug that could be submitted to regulators for approval later this year.
12 September 2010
AstraZeneca and University College London (UCL) will announce a research partnership tomorrow to develop medicines that use stem cells to repair damaged eyesight in people with diabetes.
Under the three-year deal funded by the drugmaker, researchers from AstraZeneca will team up with scientists at the UCL Institute of Ophthalmology to work on new medicines that use the regenerative capacity of stem cells. They hope to come up with a compound in three to five years, which could then undergo clinical development and possibly be on the market in 10 years' time.
Dr Marcus Fruttiger of the UCL Institute of Ophthalmology, who is leading the project, said: "These tools could be used either to manufacture transplantable material or to directly stimulate new cell growth in the eye to help restore or improve the vision of those with diabetic retinopathy [DR]."
DR is now the most common cause of vision impairment or blindness among western people of working age. The majority of patients with type-1 diabetes, which occurs when the body produces no insulin and often develops during the teenage years, will suffer eyesight problems and about 20%-30% will become blind. Moreover, at least 50% of patients with type-2 diabetes – the far more common type of diabetes, which occurs when the body produces too little insulin or when cells in the body do not react properly to insulin – will also develop retinopathy over time.
With the rapid spread of type-2 diabetes, which is linked to obesity, the need for a retinopathy treatment will grow as more than 438 million people are expected to suffer from diabetes by 2030. A study published this year by Oxford University predicted that eight out of 10 men and almost seven in 10 women will be overweight or obese by 2020. It forecast a 98% rise in obesity-related diabetes by 2050.
Alan Lamont, director of sciences and technology alliances at AstraZeneca. said: "We're getting very keen on the whole area of regenerative medicines and they will be part of our research development over the next few years." He said the collaboration aimed to come up with a treatment that could be administered to the back of the eye to repair damage locally.
AstraZeneca's US rival Pfizer also has a partnership with Professor Pete Coffey of the UCL Institute of Ophthalmology, for another eye condition, macular degeneration. Coffey said: "It's great that 'Big Pharma' is considering regenerative medicines as a serious possibility." He added: "This is British science being developed into a commercial entity with the pharmaceutical industry. It's a good example why the government shouldn't cut funding for biomedical research."
While this is the first time that AstraZeneca has worked on medicine for retinopathy, diabetes has been an area of focus. The company has a new diabetes treatment on the market called Onglyza, which was developed with Bristol-Myers Squibb, and the companies are developing a second diabetes drug that could be submitted to regulators for approval later this year.
Saturday, September 4, 2010
Federal stem cell ruling blocks Yale scientists
By Rachel Gilmore
For two decades, Lawrence Rizzolo, the director of medical studies at the Yale School of Medicine, has been working toward a project that aims to transplant young, healthy retinal cells to replace diseased tissues in the eyes of patients who are going blind.
But now Rizzolo fears he may have to delay, or even stop, his research because of last week’s ruling by a federal judge that prevents federal funding for studies involving embryonic stem cells, the building blocks for human organs and tissues that Rizzolo needs for his project.
Rizzolo had applied for a grant from the National Institutes of Health to replace his funding from the nonprofit International Retinal Research Foundation, which ends in December. Rizzolo also has a three-year state grant from Rocky Hill, Conn.-based state holding company Connecticut Innovations, but he says he cannot continue his research without the federal funding.
Rizzolo’s laboratory is one of about a dozen facilities on campus that use stem cells. Haifan Lin, director of the Yale Stem Cell Center, said he did not yet know how the moratorium will affect Yale researchers.
“We’re all waiting for clarification on the implications of the judge’s ruling,” University President Richard Levin said.
But frozen funding could lead scientists to lose their jobs. Rizzolo said that although a fourth researcher will join his laboratory in October, he may soon have to fire his workers because the grants and not the University pay for his researchers’ salaries.
Although the U.S. Department of Justice has filed a motion seeking to delay the federal judge’s ban on funding, the relief would only be temporary, NIH spokesman Don Ralbovsky said. The Justice Department declined to comment Thursday.
Opponents of embryonic stem cell research have hailed the ruling.
“The American people should not be forced to pay for experiments — prohibited by federal law — that destroy human life,” said Steven Aden, the legal counsel for the Alliance Defense Fund, which advised the party that brought the lawsuit to court.
Most labs at Yale’s Stem Cell Center are supported primarily by state funds, which are not affected by the ruling, said Diane Krause, the center’s assistant director. But, she explained, those state grants were meant to be a springboard for acquiring federal funding.
“Discontinuation of NIH funding of work with human embryonic stem cells could be a disaster,” she said.
School of Medicine Dean Robert Alpern agreed, saying that halting the stem cell research would be a “loss to society.”
Krause and other Yale researchers met Aug. 26 with Connecticut attorney general and U.S. Senate candidate Richard Blumenthal LAW ’73, who told the News this week that he plans to file a brief in support of the appeal.
“It is incredibly important for our scientific and legislative leaders to come together and solve this issue quickly,” Blumenthal said in a statement. “We have already lost so many years of work to backwards-looking and bureaucratic federal policy.”
Linda McMahon, his Republican challenger for Chris Dodd’s Senate seat, also supports stem cell research, according to her website. The McMahon campaign did not respond to multiple phone requests for comment this week.
Even if the Justice Department successfully delays the ruling, NIH has not said whether it would accept new applications. That would be a problem for Yibing Qyang, an assistant professor of cardiology at the School of Medicine who currently has a $95,499 federal grant and had planned on applying for another in October.
“I cannot live without federal funding,” said Qyang, who is priming stem cells to become healthy heart cells in patients with heart disease.
Yale has received at least $17 million in state funding from a $100 million stem cell research pot funded in part by tobacco taxes. It also received $4.9 million in NIH stem cell research grants in 2009 and 2010. NIH gave $123 million to researchers in fiscal year 2010 for embryonic stem cell research, Ralbovsky said.
Rizzolo studies eye tissues called retinal pigment epithelia. Many eye diseases — including macular degeneration, from which more than 10 million Americans suffer — affect these tissues, which function as a support for the retina, the part of the eye responsible for sight. Doctors have tried to transplant retinal and epithelial cells to combat these diseases. But most of the transplants fail because they are risky and the patients who choose to undergo them are usually almost blind. Patients in the early stages of macular degeneration are unlikely to attempt a transplant; Rizzolo said he hopes that his research with stem cells, which he started to use about a year ago, would lead to other, less risky, treatments for the disease.
Rizzolo added that, in the past year, two Yale colleagues had entirely shut down their stem-cell research labs because of funding shortages.
“It’s pretty frustrating when you work so hard to see something go unfunded for political reasons,” he said.
The Yale Stem Cell Center, established in 2006, brings together more than 30 faculty members across the University.
For two decades, Lawrence Rizzolo, the director of medical studies at the Yale School of Medicine, has been working toward a project that aims to transplant young, healthy retinal cells to replace diseased tissues in the eyes of patients who are going blind.
But now Rizzolo fears he may have to delay, or even stop, his research because of last week’s ruling by a federal judge that prevents federal funding for studies involving embryonic stem cells, the building blocks for human organs and tissues that Rizzolo needs for his project.
Rizzolo had applied for a grant from the National Institutes of Health to replace his funding from the nonprofit International Retinal Research Foundation, which ends in December. Rizzolo also has a three-year state grant from Rocky Hill, Conn.-based state holding company Connecticut Innovations, but he says he cannot continue his research without the federal funding.
Rizzolo’s laboratory is one of about a dozen facilities on campus that use stem cells. Haifan Lin, director of the Yale Stem Cell Center, said he did not yet know how the moratorium will affect Yale researchers.
“We’re all waiting for clarification on the implications of the judge’s ruling,” University President Richard Levin said.
But frozen funding could lead scientists to lose their jobs. Rizzolo said that although a fourth researcher will join his laboratory in October, he may soon have to fire his workers because the grants and not the University pay for his researchers’ salaries.
Although the U.S. Department of Justice has filed a motion seeking to delay the federal judge’s ban on funding, the relief would only be temporary, NIH spokesman Don Ralbovsky said. The Justice Department declined to comment Thursday.
Opponents of embryonic stem cell research have hailed the ruling.
“The American people should not be forced to pay for experiments — prohibited by federal law — that destroy human life,” said Steven Aden, the legal counsel for the Alliance Defense Fund, which advised the party that brought the lawsuit to court.
Most labs at Yale’s Stem Cell Center are supported primarily by state funds, which are not affected by the ruling, said Diane Krause, the center’s assistant director. But, she explained, those state grants were meant to be a springboard for acquiring federal funding.
“Discontinuation of NIH funding of work with human embryonic stem cells could be a disaster,” she said.
School of Medicine Dean Robert Alpern agreed, saying that halting the stem cell research would be a “loss to society.”
Krause and other Yale researchers met Aug. 26 with Connecticut attorney general and U.S. Senate candidate Richard Blumenthal LAW ’73, who told the News this week that he plans to file a brief in support of the appeal.
“It is incredibly important for our scientific and legislative leaders to come together and solve this issue quickly,” Blumenthal said in a statement. “We have already lost so many years of work to backwards-looking and bureaucratic federal policy.”
Linda McMahon, his Republican challenger for Chris Dodd’s Senate seat, also supports stem cell research, according to her website. The McMahon campaign did not respond to multiple phone requests for comment this week.
Even if the Justice Department successfully delays the ruling, NIH has not said whether it would accept new applications. That would be a problem for Yibing Qyang, an assistant professor of cardiology at the School of Medicine who currently has a $95,499 federal grant and had planned on applying for another in October.
“I cannot live without federal funding,” said Qyang, who is priming stem cells to become healthy heart cells in patients with heart disease.
Yale has received at least $17 million in state funding from a $100 million stem cell research pot funded in part by tobacco taxes. It also received $4.9 million in NIH stem cell research grants in 2009 and 2010. NIH gave $123 million to researchers in fiscal year 2010 for embryonic stem cell research, Ralbovsky said.
Rizzolo studies eye tissues called retinal pigment epithelia. Many eye diseases — including macular degeneration, from which more than 10 million Americans suffer — affect these tissues, which function as a support for the retina, the part of the eye responsible for sight. Doctors have tried to transplant retinal and epithelial cells to combat these diseases. But most of the transplants fail because they are risky and the patients who choose to undergo them are usually almost blind. Patients in the early stages of macular degeneration are unlikely to attempt a transplant; Rizzolo said he hopes that his research with stem cells, which he started to use about a year ago, would lead to other, less risky, treatments for the disease.
Rizzolo added that, in the past year, two Yale colleagues had entirely shut down their stem-cell research labs because of funding shortages.
“It’s pretty frustrating when you work so hard to see something go unfunded for political reasons,” he said.
The Yale Stem Cell Center, established in 2006, brings together more than 30 faculty members across the University.
Sunday, August 29, 2010
Gene involved in Fuchs Corneal dystrophy is found
A 13-member research team led by University of Oregon scientist Dr. Albert O. Edwards has found a gene likely responsible for Fuchs corneal dystrophy, an inheritable genetic disorder and leading cause of corneal transplant operations.
Edwards performed a genome-wide analysis comparing patients with and without typical age-related Fuchs, finding an alteration in the transcription-factor-4 gene (TCF4). Fuchs -- pronounced FEWKS or FOOKS -- generally emerges in middle-aged, roughly age 40, and older people.
The discovery appears online Wednesday, Aug. 25, ahead of regular publication in the Sept. 9 issue of the New England Journal of Medicine.
Fuchs emerges slowly with blurred or cloudy vision, tiny bumps known as guttae (GOO-tay) on the cornea's surface and, in severe stages, painful blisters on the corneal surface. The disease affects the endothelium, a thin layer of cells that line the back part of the cornea where changes result in swelling of the cornea and thickening and clouding of the cornea. Guttae are found in the corneas of an estimated 5 percent of people in the United States.
Of those diagnosed with Fuchs, only a small percentage go on to require corneal transplants, said lead author Dr. Keith H. Baratz of the Mayo Clinic ophthalmology department in Rochester, Minn. There are about 40,000 corneal transplants -- about 10,000 linked to Fuchs -- performed annually in the United States, according to the Eye Bank Association of America. It is more common in women than in men, according to the Fuchs Corneal Dystrophy Association.
The discovery won't immediately translate into clinical benefits, but "this is the first step in identifying the pathophysiology of the disease," Baratz said. "Right now, we don't have a treatment for Fuchs dystrophy other than transplant surgery when a patient is at the end stages of the disease. The ultimate goal is to find out how the disease occurs and find a treatment to prevent or slow its progression."
Having the TCF4 gene variation has a huge impact on the risk of Fuchs disease, said Edwards, a senior research associate in the University of Oregon's Institute of Molecular Biology. "It vastly exceeds the risk found previously for the complement-factor-H gene in macular degeneration," he said. "If a person has risk variants involving TCF4, that individual is anywhere from several to a couple of hundred times more likely to have Fuchs disease."
Edwards, in 2005, when at the University of Texas Southwestern Medical Center, was lead author of a study published in the journal Science that identified complement factor H in macular degeneration. That gene discovery tied complement factor H to a five-fold increase of risk to developing macular degeneration, accounting possibly for at least 50 percent of the risk of being affected. The risk impact of TCF4 on Fuchs is much stronger, Edwards said.
While the TCF4 gene has been identified, exactly what occurs to cause a defect is not understood. The researchers found evidence that at least one transcription protein, E2-2, needs more scrutiny. "E2-2 is a transcription factor. It controls gene expression," Edwards said. "The pathway probably contains E2-2 and the protein ZEB1, but we don't really know that yet. We do find variation of expression across this region, so it has something to do with the expression of the gene."
E2-2, important in cellular growth and differentiation, has been implicated in other disease states, including activity that promotes or suppresses cancer. It is expressed in the corneal endothelium. ZEB1, which may be regulated by E2-2, already is thought to contribute to Fuchs.
The study involved the genotyping of 280 Fuchs patients recruited in clinical settings in Minnesota and Michigan. These patients had at least Stage 1 signs of Fuchs or had received corneal replacements as a result of the disease. Their genomes were compared with 410 control patients.
"The real impact of what we've done is to determine the biological underpinnings of the disease," Edwards said. "We've identified a protein that is probably involved, and that will allow us to, hopefully, identify a method to prevent people from losing their vision."
Three other genes previously had been linked to very rare subtypes of Fuchs. In addition, early onset Fuchs has been linked to mutations in yet another gene, COL8A2, but Edwards and colleagues suggest in their paper that this may be a different disease with a different cause.
"This discovery demonstrates the value of excellent clinical phenotyping and a large-scale genetic database of genome-wide association studies (GWAS) to uncover genetic risk factors for many vision-related disorders," said co-author Anand Swaroop, chief of the National Eye Institute (NEI) Neurobiology-Neurodegeneration and Repair Laboratory. "The genetic data used in this study was obtained for GWAS of age-related macular degeneration through a scientific collaboration supported by the NEI."
Edwards performed a genome-wide analysis comparing patients with and without typical age-related Fuchs, finding an alteration in the transcription-factor-4 gene (TCF4). Fuchs -- pronounced FEWKS or FOOKS -- generally emerges in middle-aged, roughly age 40, and older people.
The discovery appears online Wednesday, Aug. 25, ahead of regular publication in the Sept. 9 issue of the New England Journal of Medicine.
Fuchs emerges slowly with blurred or cloudy vision, tiny bumps known as guttae (GOO-tay) on the cornea's surface and, in severe stages, painful blisters on the corneal surface. The disease affects the endothelium, a thin layer of cells that line the back part of the cornea where changes result in swelling of the cornea and thickening and clouding of the cornea. Guttae are found in the corneas of an estimated 5 percent of people in the United States.
Of those diagnosed with Fuchs, only a small percentage go on to require corneal transplants, said lead author Dr. Keith H. Baratz of the Mayo Clinic ophthalmology department in Rochester, Minn. There are about 40,000 corneal transplants -- about 10,000 linked to Fuchs -- performed annually in the United States, according to the Eye Bank Association of America. It is more common in women than in men, according to the Fuchs Corneal Dystrophy Association.
The discovery won't immediately translate into clinical benefits, but "this is the first step in identifying the pathophysiology of the disease," Baratz said. "Right now, we don't have a treatment for Fuchs dystrophy other than transplant surgery when a patient is at the end stages of the disease. The ultimate goal is to find out how the disease occurs and find a treatment to prevent or slow its progression."
Having the TCF4 gene variation has a huge impact on the risk of Fuchs disease, said Edwards, a senior research associate in the University of Oregon's Institute of Molecular Biology. "It vastly exceeds the risk found previously for the complement-factor-H gene in macular degeneration," he said. "If a person has risk variants involving TCF4, that individual is anywhere from several to a couple of hundred times more likely to have Fuchs disease."
Edwards, in 2005, when at the University of Texas Southwestern Medical Center, was lead author of a study published in the journal Science that identified complement factor H in macular degeneration. That gene discovery tied complement factor H to a five-fold increase of risk to developing macular degeneration, accounting possibly for at least 50 percent of the risk of being affected. The risk impact of TCF4 on Fuchs is much stronger, Edwards said.
While the TCF4 gene has been identified, exactly what occurs to cause a defect is not understood. The researchers found evidence that at least one transcription protein, E2-2, needs more scrutiny. "E2-2 is a transcription factor. It controls gene expression," Edwards said. "The pathway probably contains E2-2 and the protein ZEB1, but we don't really know that yet. We do find variation of expression across this region, so it has something to do with the expression of the gene."
E2-2, important in cellular growth and differentiation, has been implicated in other disease states, including activity that promotes or suppresses cancer. It is expressed in the corneal endothelium. ZEB1, which may be regulated by E2-2, already is thought to contribute to Fuchs.
The study involved the genotyping of 280 Fuchs patients recruited in clinical settings in Minnesota and Michigan. These patients had at least Stage 1 signs of Fuchs or had received corneal replacements as a result of the disease. Their genomes were compared with 410 control patients.
"The real impact of what we've done is to determine the biological underpinnings of the disease," Edwards said. "We've identified a protein that is probably involved, and that will allow us to, hopefully, identify a method to prevent people from losing their vision."
Three other genes previously had been linked to very rare subtypes of Fuchs. In addition, early onset Fuchs has been linked to mutations in yet another gene, COL8A2, but Edwards and colleagues suggest in their paper that this may be a different disease with a different cause.
"This discovery demonstrates the value of excellent clinical phenotyping and a large-scale genetic database of genome-wide association studies (GWAS) to uncover genetic risk factors for many vision-related disorders," said co-author Anand Swaroop, chief of the National Eye Institute (NEI) Neurobiology-Neurodegeneration and Repair Laboratory. "The genetic data used in this study was obtained for GWAS of age-related macular degeneration through a scientific collaboration supported by the NEI."
Monday, August 23, 2010
International Stem Cell Corporation Formalizes Stem Cell- Based Eye Care Programs Into Cyovis
Article Date: 22 Aug 2010
International Stem Cell Corporation (OTCBB:ISCO), announced that its stem cell therapeutic programs focused on protective, transparent corneas (CytoCor™) in the front of the eye and the light-sensitive retinal tissue (CytoRet™) in the back of the eye will be formalized into a new business unit, Cytovis™. Together these programs will leverage external and internal development, regulatory and commercial expertise in cellular ophthalmology to form a focused portfolio of complementary product candidates designed to address high unmet medical needs with apparent pharmacoeconomic and quality of life benefits.
CytoCor is the brand name for ISCO's corneal tissue that can be derived from the company's proprietary parthenogenetic stem cells or commonly used embryonic stem cells. Research and development with partners Absorption Systems in the US, Sankara Nethralaya in India and Automation Partnership in the UK continues for the purpose of optimizing the tissue for transplantation in the 10 million people worldwide suffering from corneal vision impairment and as an alternative to the use of live animals and animal eyes in the $500+M market for safety testing of drugs, chemicals and consumer products. ISCO's goal in the coming months is to establish funding and infrastructure in India for accelerated development of CytoCor for the therapeutic application and to advance and implement the chemical testing application with partners in the US and Europe.
CytoRet is the brand name for ISCO's stem cell-derived retinal tissue. ISCO is using its parthenogenetic stem cells to develop individual retinal pigmented epithelial ("RPE") cells and layered retinal structures internally and in collaboration with the laboratory of Dr. Hans Keirstead, Professor of Anatomy and Neurobiology at the University of California, Irvine. ISCO recently commenced a new research collaboration with UC Irvine to launch the next phase of its retinal studies with that institution, including preclinical trials. Potential therapeutic applications include retinitis pigmentosa, an untreatable inherited disease affecting about 100,000 Americans, and the dry form of age-related macular degeneration, a major cause of blindness in the elderly of the Western world. ISCO's goal is to establish functional proof of concept for RPE cellular therapy in models of human disease in the next twelve-eighteen months.
Jointly referred to as Cytovis ("cyto" for cellular, "vis" for vision), these two cellular ophthalmology programs share a number of features and benefits. First, with the aging of the population worldwide and the growing number of work-related eye injuries in India, China and other major countries, the market opportunity is growing steadily. Second, there are strong pharmacoeconomic and quality-of-life rationales for full or partial vision restoration or delay of vision impairment diseases. Third, delivery of cells and tissues to the confined anatomy of the eye inherently provides for better safety and efficacy than, for example, the systemic circulation or the central nervous system. This will likely result in lower regulatory barriers and shorter and less costly development paths compared to that of anatomically deeper and more widespread diseases. Fourth, a number of eye diseases cannot be treated with surgery or traditional small molecule or protein therapeutics, yet cell and tissue therapy is proven to work but currently limited by availability of safe and sufficient cells and tissue from human donors. Finally, eye care development programs like CytoCor and CytoRet share a number of regulatory, development and commercial aspects that make it feasible for a relatively small team to produce substantial clinical outcomes and achieve competitive presence in the marketplace alone or in collaboration with dedicated partners.
Brian Lundstrom, ISCO's President, says: "ISCO's proprietary parthenogenetic stem cell technology continues to form the foundation for the company's long term regenerative medicine therapy programs. In the nearer term, CytoCor and CytoRet's unique benefits in the field of cellular ophthalmology offer the potential for partnering and funding at a relatively early stage. Combined with the current and future revenue of Lifeline Cell Technology and the revenue potential of Lifeline Skin Care, scheduled for launch in the 4th quarter, Cytovis adds significantly to ISCO's diversity and value creation potential for its investor base in a cost-efficient fashion."
Source:
International Stem Cell Corporation
International Stem Cell Corporation (OTCBB:ISCO), announced that its stem cell therapeutic programs focused on protective, transparent corneas (CytoCor™) in the front of the eye and the light-sensitive retinal tissue (CytoRet™) in the back of the eye will be formalized into a new business unit, Cytovis™. Together these programs will leverage external and internal development, regulatory and commercial expertise in cellular ophthalmology to form a focused portfolio of complementary product candidates designed to address high unmet medical needs with apparent pharmacoeconomic and quality of life benefits.
CytoCor is the brand name for ISCO's corneal tissue that can be derived from the company's proprietary parthenogenetic stem cells or commonly used embryonic stem cells. Research and development with partners Absorption Systems in the US, Sankara Nethralaya in India and Automation Partnership in the UK continues for the purpose of optimizing the tissue for transplantation in the 10 million people worldwide suffering from corneal vision impairment and as an alternative to the use of live animals and animal eyes in the $500+M market for safety testing of drugs, chemicals and consumer products. ISCO's goal in the coming months is to establish funding and infrastructure in India for accelerated development of CytoCor for the therapeutic application and to advance and implement the chemical testing application with partners in the US and Europe.
CytoRet is the brand name for ISCO's stem cell-derived retinal tissue. ISCO is using its parthenogenetic stem cells to develop individual retinal pigmented epithelial ("RPE") cells and layered retinal structures internally and in collaboration with the laboratory of Dr. Hans Keirstead, Professor of Anatomy and Neurobiology at the University of California, Irvine. ISCO recently commenced a new research collaboration with UC Irvine to launch the next phase of its retinal studies with that institution, including preclinical trials. Potential therapeutic applications include retinitis pigmentosa, an untreatable inherited disease affecting about 100,000 Americans, and the dry form of age-related macular degeneration, a major cause of blindness in the elderly of the Western world. ISCO's goal is to establish functional proof of concept for RPE cellular therapy in models of human disease in the next twelve-eighteen months.
Jointly referred to as Cytovis ("cyto" for cellular, "vis" for vision), these two cellular ophthalmology programs share a number of features and benefits. First, with the aging of the population worldwide and the growing number of work-related eye injuries in India, China and other major countries, the market opportunity is growing steadily. Second, there are strong pharmacoeconomic and quality-of-life rationales for full or partial vision restoration or delay of vision impairment diseases. Third, delivery of cells and tissues to the confined anatomy of the eye inherently provides for better safety and efficacy than, for example, the systemic circulation or the central nervous system. This will likely result in lower regulatory barriers and shorter and less costly development paths compared to that of anatomically deeper and more widespread diseases. Fourth, a number of eye diseases cannot be treated with surgery or traditional small molecule or protein therapeutics, yet cell and tissue therapy is proven to work but currently limited by availability of safe and sufficient cells and tissue from human donors. Finally, eye care development programs like CytoCor and CytoRet share a number of regulatory, development and commercial aspects that make it feasible for a relatively small team to produce substantial clinical outcomes and achieve competitive presence in the marketplace alone or in collaboration with dedicated partners.
Brian Lundstrom, ISCO's President, says: "ISCO's proprietary parthenogenetic stem cell technology continues to form the foundation for the company's long term regenerative medicine therapy programs. In the nearer term, CytoCor and CytoRet's unique benefits in the field of cellular ophthalmology offer the potential for partnering and funding at a relatively early stage. Combined with the current and future revenue of Lifeline Cell Technology and the revenue potential of Lifeline Skin Care, scheduled for launch in the 4th quarter, Cytovis adds significantly to ISCO's diversity and value creation potential for its investor base in a cost-efficient fashion."
Source:
International Stem Cell Corporation
Wednesday, August 18, 2010
Macular Degeneration and Heavy Metals
By Jannette Barrett
What Is Macular Degeneration?
Macular Degeneration is a condition that affects the macula part of the retina of the eye resulting in a disturbance to central vision. Although the exact etiology of the disease is unknown, it is believed that deterioration of the retina leads to a breakdown in the transmission of signals to the brain from the nerves and receptors of the eye. When the signals are unclear, the brain cannot correctly interpret the information it receives and there is a loss of the detail that allows us to read, recognise people, perform manual work or manage fine tasks such as threading a needle. A person with macular degeneration may experience blurred or decreased central vision, blind spots, wavy lines instead of straight and size distortion.
There are two types of macular degeneration, wet and dry.
The onset of wet macular degeneration occurs when abnormal blood vessels, which have grown under the centre of the retina, bleed or leak and scar the retina. Macula damage may occur rapidly. It is not uncommon for wet macular degeneration to start in one eye and effect the other at a later time.
Dry macular degeneration, which is the most common form, results from a gradual breakdown of cells in the macula leading to blurring of central vision. The onset of dry macular degeneration can be detected early by an optometrist because of the presence of small, yellowish spots, called drusen, at the back of the eye. However, people who have drusen, may not have visual impairment or related symptoms. When dry macular degeneration advances due to damage to the retina and nerves, vision loss will occur.
Macular degeneration is treated by laser surgery, photodynamic therapy where a drug is injected that destroys newly formed, abnormal blood vessels or injections, however, none of these treatments can restore the vision that has already been lost.
Risk factors
There are a number of identified risk factors associated with AMD. Family history and age are thought to be the most common risk factors. People with outdoor occupations and continuous exposure to sunlight may also be at risk, particularly if their skin is lightly pigmented. Women seem to be at a greater risk than men. There are also environmental and behavioural factors such as smoking and obesity. Research cited below shows that a build up of toxic heavy metals can damage eye health.
Research
The National Institute of Health and the National Eye Institute in the US, published the results of a random study of people with moderate and advanced AMD in the Archives of Opthalmology in 2001, entitled the Age-Related Eye Disease Study. The study reported that a significant slowing of disease progression and preservation of sight could be achieved by taking dietary supplements containing high-dose antioxidants and zinc.
Research published by Erie et al in 2005 in the American Journal of Opthalmology, measured the concentration of toxic heavy metals in the fluids and tissues of human eyes. Concentrations of lead, cadmium, mercury, and thallium in ocular tissues, ocular fluids, and blood were found in the autopsy of 30 eyes from 16 subjects. The study concluded the presence of lead and cadmium which had accumulated in the tissues and retinal pigment epithelium and choroid. Further study into the toxicity of these heavy metals and their possible role in eye disease was recommended.
What Can We Do?
In addition to the medical treatments mentioned above, there are a number of common sense things we can do to help prevent the onset of macular degeneration.
In order for high-dose antioxidants and zinc to be effectively absorbed into the body and to protect the eyes from heavy metals, it is firstly essential to detoxify the body. Published clinical trials have shown that when removing heavy metals and toxins, including pesticides and herbicides from the body safely and effectively, supplements will be more readily absorbed, the immune system may function more efficiently and normal blood pressure may be more easily maintained. Eating a healthy diet, including green leafy vegetables and fish, is also essential to good eye health. A healthy diet will help with weight control as will some regular exercise. Giving up smoking is critical for eye health.
Some people also believe in the benefit of eye exercises to increase eye health. Firstly move the eye slowly from side to side, then from top to bottom a few times. Move the eyes in a circular motion, then reverse a few times. Finally, raise your finger level with your nose and focus there for a time, then focus on something in the distance.
Remember the most important step, to take a daily detoxifying shower on the inside to give your eyes the maximum chance for sustained health. Your body will love you!
Author Resource:- Jannette has researched health and well being issues for the past 20 years and holds a Bachelor of Applied Science in Health Promotion. Healthy eating, regular meditation, moderation in everything and taking the correct supplements can make an enormous improvement to the quality of our lives.
What Is Macular Degeneration?
Macular Degeneration is a condition that affects the macula part of the retina of the eye resulting in a disturbance to central vision. Although the exact etiology of the disease is unknown, it is believed that deterioration of the retina leads to a breakdown in the transmission of signals to the brain from the nerves and receptors of the eye. When the signals are unclear, the brain cannot correctly interpret the information it receives and there is a loss of the detail that allows us to read, recognise people, perform manual work or manage fine tasks such as threading a needle. A person with macular degeneration may experience blurred or decreased central vision, blind spots, wavy lines instead of straight and size distortion.
There are two types of macular degeneration, wet and dry.
The onset of wet macular degeneration occurs when abnormal blood vessels, which have grown under the centre of the retina, bleed or leak and scar the retina. Macula damage may occur rapidly. It is not uncommon for wet macular degeneration to start in one eye and effect the other at a later time.
Dry macular degeneration, which is the most common form, results from a gradual breakdown of cells in the macula leading to blurring of central vision. The onset of dry macular degeneration can be detected early by an optometrist because of the presence of small, yellowish spots, called drusen, at the back of the eye. However, people who have drusen, may not have visual impairment or related symptoms. When dry macular degeneration advances due to damage to the retina and nerves, vision loss will occur.
Macular degeneration is treated by laser surgery, photodynamic therapy where a drug is injected that destroys newly formed, abnormal blood vessels or injections, however, none of these treatments can restore the vision that has already been lost.
Risk factors
There are a number of identified risk factors associated with AMD. Family history and age are thought to be the most common risk factors. People with outdoor occupations and continuous exposure to sunlight may also be at risk, particularly if their skin is lightly pigmented. Women seem to be at a greater risk than men. There are also environmental and behavioural factors such as smoking and obesity. Research cited below shows that a build up of toxic heavy metals can damage eye health.
Research
The National Institute of Health and the National Eye Institute in the US, published the results of a random study of people with moderate and advanced AMD in the Archives of Opthalmology in 2001, entitled the Age-Related Eye Disease Study. The study reported that a significant slowing of disease progression and preservation of sight could be achieved by taking dietary supplements containing high-dose antioxidants and zinc.
Research published by Erie et al in 2005 in the American Journal of Opthalmology, measured the concentration of toxic heavy metals in the fluids and tissues of human eyes. Concentrations of lead, cadmium, mercury, and thallium in ocular tissues, ocular fluids, and blood were found in the autopsy of 30 eyes from 16 subjects. The study concluded the presence of lead and cadmium which had accumulated in the tissues and retinal pigment epithelium and choroid. Further study into the toxicity of these heavy metals and their possible role in eye disease was recommended.
What Can We Do?
In addition to the medical treatments mentioned above, there are a number of common sense things we can do to help prevent the onset of macular degeneration.
In order for high-dose antioxidants and zinc to be effectively absorbed into the body and to protect the eyes from heavy metals, it is firstly essential to detoxify the body. Published clinical trials have shown that when removing heavy metals and toxins, including pesticides and herbicides from the body safely and effectively, supplements will be more readily absorbed, the immune system may function more efficiently and normal blood pressure may be more easily maintained. Eating a healthy diet, including green leafy vegetables and fish, is also essential to good eye health. A healthy diet will help with weight control as will some regular exercise. Giving up smoking is critical for eye health.
Some people also believe in the benefit of eye exercises to increase eye health. Firstly move the eye slowly from side to side, then from top to bottom a few times. Move the eyes in a circular motion, then reverse a few times. Finally, raise your finger level with your nose and focus there for a time, then focus on something in the distance.
Remember the most important step, to take a daily detoxifying shower on the inside to give your eyes the maximum chance for sustained health. Your body will love you!
Author Resource:- Jannette has researched health and well being issues for the past 20 years and holds a Bachelor of Applied Science in Health Promotion. Healthy eating, regular meditation, moderation in everything and taking the correct supplements can make an enormous improvement to the quality of our lives.
Monday, August 9, 2010
The Best 9 Omega-Fish Oil Benefits
“A huge amount of studies show that, not only are the benefits of fish oil numerous, many of them are really very amazing! It seems sometimes like new research is being produced all the time, as researchers and physicians learn even more about how and why it is indeed effective. The omega-3 fatty acids found in fish oil are “good fats” that are vital to health. They are crucial for our health but our bodies can’t produce them – you have to get them through diet.
Here are some proven fish oil health benefits that should convince you to eat more oily, wild-caught fish and begin taking a highly refined fish oil supplement in the event you’re not at present!
Reduces Pain & Inflammation
Omega-3s possess a great anti-inflammatory impact. Research trials suggest that diets rich in omega-3s (and low in the pro-inflammatory omega-6s) may benefit people with inflammatory conditions — anything that ends in -itis!. Omega-3 additionally has been used to effectively treat neck, back and menstrual pain, allowing study patients to cut down their particular consumption of NSAID medication.
Promotes Heart Wellness & Protects Against Heart Attack and Strokes
Fish oil continues to grow in research reputation as a key promoter of heart health. According to the American Heart Association, fish oil is effective in lessening the incidence of heart disease and aids in reducing risk factors such as high cholesterol and high blood pressure. Research studies of heart attack survivors have discovered that daily fish oil capsules drastically minimize the risk of death, additional heart attacks and stroke. Omega-3s also reduce blood triglycerides, help correct irregular heartbeats, and can help prevent and treat atherosclerosis by preventing the formation of plaque and blood clots, which typically clog arteries.
Ensures Healthy Joints and Reduces Arthritis Symptoms
The omega-3 fatty acids in fish oil reduce tenderness in joints, pain intensity and morning stiffness caused by rheumatoid arthritis. In fact, several test tube studies have shown that omega-3s actually lessen the action of enzymes that break down cartilage. More than 13 published research trials have shown that fish oil supplements are very effective at treating rheumatoid arthritis. Fish oil has helped those suffering from RA to reduce their need for pain medicine.
Supports Happy Mood & Emotional Wellness
In nations where fish makes up a significant part of the diet, nationwide rates of depression are lower. So, it’s not surprising that studies have shown that fish oil capsules can alleviate the symptoms of depression, bipolar disorder and psychosis. Numerous clinical trials have found that participants that took omega-3s in addition to prescribed anti-depressants had a larger improvement in symptoms than those who only took antidepressants, with subjects experiencing a stabilizing effect and less mood swings. Studies have also demonstrated that, when prisoners were administered omega three fatty acids, there was a significant drop in hostile behavior. Omega-3s also appear to lower the risk ofpostpartum depression.
Enhances Mental Focus & Long-Term Cognitive Functioning
Did you know that omega-3s, especially DHA, are highly concentrated in our brains? They’re important for optimal cognitive (brain memory and performance) and behavioral function, as well as normal growth and development. Studies demonstrate that omega-3s may help in maintaining adequate cognitive functioning and possibly in avoiding or delaying the onset of Alzheimer’s disease. We also now know it’s incredibly necessary that pregnant women get adequate DHA, which is required by the developing fetus — during the third trimester of being pregnant, the brain of the fetus grows at a rate of a quarter million new neurons every 60 seconds! Children are also aided by omega-3 intake, as many studies show that omega-3s enhance learning, concentration, reading and vocabulary skills. Countless studies have even shown benefits in treating ADD.
Promotes Vision Wellness
Studies show that people with a greater omega-3 consumption appear to have a decreased risk of Dry-Eye Syndrome and developing AMD, or age-related macular degeneration. Early research also shows that fish oil supplements aid in lessening dry eye symptoms, may help to slow macular degeneration for those already developing it and improves ocular health in general.
Pregnancy, Infant Brain/Vision Development & Reduced Incidence of Childhood Disorders
DHA makes up 15-20% of the cerebral cortex and approximately 30-60% of the retina, so it’s absolutely necessary for normal growth and development of the fetus and baby. Prenatal DHA availability also seems to reduce the chances of childhood allergies and have an effect on motor skill quality, cognitive development and hyperactivity/behavior later in the child’s life. Omega-3s also assist in reducing the risk of low birth weight and premature birth.
Enhances Metabolism of Fat and Weight Loss
According to the National Institute of Health, omega-3s transmit “I’m full” signals to the brain and help quash hunger signals. Research has also shown that omega-3 fish oil improves the effectiveness of exercise in reducing weight. Volunteers who were alloted fish oil with their diet showed greater weight loss as compared to those who didn’t consume fish oil. Exercise along with fish oil had a positive effect on the body shape and body composition of the volunteers. Reduces Risk of Prostate, Breast & Colorectal Cancers Though more research in this area is certainly needed, we now know that the omega 3’s that appear in fish oil assist in the prevention and treatment of testicular, prostate, breast and ovarian cancers. Preliminary studies suggest that taking fish oil everyday can help inhibit the progression of colon cancer in people with early stages of the disease and may even have the capacity to cause apoptosis (cellular death) of cancer cells.
More can be written with regards to the many fish oil benefits. And, as the scientific community and doctors continue to examine omega-3s, you can bet that fish oil will keep making headlines as the ideal source of these essential fatty acids that are so essential to our bodies. Even if you’re currently in great health, a quality fish oil supplement is the fastest, safest way to realize and maintain optimal health!”
Here are some proven fish oil health benefits that should convince you to eat more oily, wild-caught fish and begin taking a highly refined fish oil supplement in the event you’re not at present!
Reduces Pain & Inflammation
Omega-3s possess a great anti-inflammatory impact. Research trials suggest that diets rich in omega-3s (and low in the pro-inflammatory omega-6s) may benefit people with inflammatory conditions — anything that ends in -itis!. Omega-3 additionally has been used to effectively treat neck, back and menstrual pain, allowing study patients to cut down their particular consumption of NSAID medication.
Promotes Heart Wellness & Protects Against Heart Attack and Strokes
Fish oil continues to grow in research reputation as a key promoter of heart health. According to the American Heart Association, fish oil is effective in lessening the incidence of heart disease and aids in reducing risk factors such as high cholesterol and high blood pressure. Research studies of heart attack survivors have discovered that daily fish oil capsules drastically minimize the risk of death, additional heart attacks and stroke. Omega-3s also reduce blood triglycerides, help correct irregular heartbeats, and can help prevent and treat atherosclerosis by preventing the formation of plaque and blood clots, which typically clog arteries.
Ensures Healthy Joints and Reduces Arthritis Symptoms
The omega-3 fatty acids in fish oil reduce tenderness in joints, pain intensity and morning stiffness caused by rheumatoid arthritis. In fact, several test tube studies have shown that omega-3s actually lessen the action of enzymes that break down cartilage. More than 13 published research trials have shown that fish oil supplements are very effective at treating rheumatoid arthritis. Fish oil has helped those suffering from RA to reduce their need for pain medicine.
Supports Happy Mood & Emotional Wellness
In nations where fish makes up a significant part of the diet, nationwide rates of depression are lower. So, it’s not surprising that studies have shown that fish oil capsules can alleviate the symptoms of depression, bipolar disorder and psychosis. Numerous clinical trials have found that participants that took omega-3s in addition to prescribed anti-depressants had a larger improvement in symptoms than those who only took antidepressants, with subjects experiencing a stabilizing effect and less mood swings. Studies have also demonstrated that, when prisoners were administered omega three fatty acids, there was a significant drop in hostile behavior. Omega-3s also appear to lower the risk ofpostpartum depression.
Enhances Mental Focus & Long-Term Cognitive Functioning
Did you know that omega-3s, especially DHA, are highly concentrated in our brains? They’re important for optimal cognitive (brain memory and performance) and behavioral function, as well as normal growth and development. Studies demonstrate that omega-3s may help in maintaining adequate cognitive functioning and possibly in avoiding or delaying the onset of Alzheimer’s disease. We also now know it’s incredibly necessary that pregnant women get adequate DHA, which is required by the developing fetus — during the third trimester of being pregnant, the brain of the fetus grows at a rate of a quarter million new neurons every 60 seconds! Children are also aided by omega-3 intake, as many studies show that omega-3s enhance learning, concentration, reading and vocabulary skills. Countless studies have even shown benefits in treating ADD.
Promotes Vision Wellness
Studies show that people with a greater omega-3 consumption appear to have a decreased risk of Dry-Eye Syndrome and developing AMD, or age-related macular degeneration. Early research also shows that fish oil supplements aid in lessening dry eye symptoms, may help to slow macular degeneration for those already developing it and improves ocular health in general.
Pregnancy, Infant Brain/Vision Development & Reduced Incidence of Childhood Disorders
DHA makes up 15-20% of the cerebral cortex and approximately 30-60% of the retina, so it’s absolutely necessary for normal growth and development of the fetus and baby. Prenatal DHA availability also seems to reduce the chances of childhood allergies and have an effect on motor skill quality, cognitive development and hyperactivity/behavior later in the child’s life. Omega-3s also assist in reducing the risk of low birth weight and premature birth.
Enhances Metabolism of Fat and Weight Loss
According to the National Institute of Health, omega-3s transmit “I’m full” signals to the brain and help quash hunger signals. Research has also shown that omega-3 fish oil improves the effectiveness of exercise in reducing weight. Volunteers who were alloted fish oil with their diet showed greater weight loss as compared to those who didn’t consume fish oil. Exercise along with fish oil had a positive effect on the body shape and body composition of the volunteers. Reduces Risk of Prostate, Breast & Colorectal Cancers Though more research in this area is certainly needed, we now know that the omega 3’s that appear in fish oil assist in the prevention and treatment of testicular, prostate, breast and ovarian cancers. Preliminary studies suggest that taking fish oil everyday can help inhibit the progression of colon cancer in people with early stages of the disease and may even have the capacity to cause apoptosis (cellular death) of cancer cells.
More can be written with regards to the many fish oil benefits. And, as the scientific community and doctors continue to examine omega-3s, you can bet that fish oil will keep making headlines as the ideal source of these essential fatty acids that are so essential to our bodies. Even if you’re currently in great health, a quality fish oil supplement is the fastest, safest way to realize and maintain optimal health!”
Wednesday, August 4, 2010
Avastin/Lucentis Update 39: And the Controversy Continues
By Alicia Mundy
Medicare could save more than $500 million annually by using a cheaper Genentech drug to save vision, according to a draft study by federal officials and a University of Miami eye doctor.
The study shows that the cheaper drug, Avastin, is already used in about 65% of Medicare patients with wet age-related macular degeneration and accounts for nearly 60% of their eye injections, compared with about 40% for a more expensive drug called Lucentis. However, Medicare paid $537 million for Lucentis in 2008 and only $20 million for Avastin, according to the unpublished study, which was reviewed by The Wall Street Journal.
The numbers point to a delicate problem for the federal program for the elderly, whose rising costs are often cited as among the biggest long-term factors in the federal budget deficit. Both drugs are made by Genentech, but only Lucentis is approved by the Food and Drug Administration to treat the disease, the leading cause of irreversible blindness among older people.
Clinical trials suggest that Avastin, approved by the FDA to treat some forms of cancer, is also effective in treating the eye disease. Doctors have been "voting for Avastin with their feet," said Philip Rosenfeld, a retina specialist at the University of Miami's Bascom Palmer Eye Institute and one of the study's authors. Some pharmacies take supplies of Avastin and divide it into tiny doses suitable for injection in the eye.
The study, based on data from more than 200,000 Medicare patients, found that Medicare paid on average $42 a dose for Avastin in the eye, compared with $1,593 a dose for Lucentis.
Medicare could save more than $500 million annually by using a cheaper Genentech drug to save vision, according to a draft study by federal officials and a University of Miami eye doctor.
The study shows that the cheaper drug, Avastin, is already used in about 65% of Medicare patients with wet age-related macular degeneration and accounts for nearly 60% of their eye injections, compared with about 40% for a more expensive drug called Lucentis. However, Medicare paid $537 million for Lucentis in 2008 and only $20 million for Avastin, according to the unpublished study, which was reviewed by The Wall Street Journal.
The numbers point to a delicate problem for the federal program for the elderly, whose rising costs are often cited as among the biggest long-term factors in the federal budget deficit. Both drugs are made by Genentech, but only Lucentis is approved by the Food and Drug Administration to treat the disease, the leading cause of irreversible blindness among older people.
Clinical trials suggest that Avastin, approved by the FDA to treat some forms of cancer, is also effective in treating the eye disease. Doctors have been "voting for Avastin with their feet," said Philip Rosenfeld, a retina specialist at the University of Miami's Bascom Palmer Eye Institute and one of the study's authors. Some pharmacies take supplies of Avastin and divide it into tiny doses suitable for injection in the eye.
The study, based on data from more than 200,000 Medicare patients, found that Medicare paid on average $42 a dose for Avastin in the eye, compared with $1,593 a dose for Lucentis.
Monday, July 26, 2010
Leading brands under threat
Ophthalmology encompasses some lucrative markets, but the future of leading brands in AMD is under threat, and while established markets like glaucoma and conjunctivitis have many therapeutic options, diabetic retinopathy remains largely untapped. Key opinion leaders agree there is unmet need in terms of drug delivery methods and dose frequency across ophthalmology diseases.
Highlights
The future of leading brands Lucentis (ranibizumab) and Xalatan (latanoprost) is at risk. Lucentis dominates AMD with 91% market share but the use of currently off-label Avastin (bevacizumab, Roche) is a threat. Xalatan, the gold standard in glaucoma achieved $1.5 billion in 2008 but the drug faces generic erosion after patent expiry in 2011
Diabetic retinopathy and AMD markets show high growth potential. Both diseases are highly prevalent, with 11.5 million cases of diabetic retinopathy, and 7.5 million in AMD, in the seven major markets in 2010. There are few drug treatments for AMD, while no approved drugs for diabetic retinopathy mean this market is untapped.
Key opinion leaders report high unmet need for reduced dosing regimens of existing therapies and an improvement in drug delivery methods. However, any new formulations of existing drugs will have to compete with cheap generics and need to show significant additional benefits.
Reasons to Purchase
*Validate the market potential of particular ophthalmology indications based on prevalence numbers in each of the seven major markets
*Understand the commercial potential of ophthalmic diseases with Datamonitor’s assessment of market and brand dynamics
*Assess the key unmet needs and possible new approaches in the treatment of eye diseases as noted by opinion leaders
Ophthalmology market attractiveness
ophthalmology market definition
Therapeutic sales for ophthalmology disorders exceeded $12 billion in 2008
High growth potential observed in diabetic retinopathy and age-related macular degeneration markets
Age-related macular degeneration shows a high growth rate, and seemingly unsaturated market
Middle Eastern, North African (MENA) and Brazil, Russia, India and China (BRIC) ophthalmology markets are growing rapidly
High pipeline potential in age-related macular degeneration (AMD)
to greater patient compliance
Preservative-free formulations
Therapies with better side-effect profiles
Pipeline analysis of glaucoma treatments
Chapter 3. Age-related macular degeneration
Key findings 70
Definition and classification of age-related macular degeneration (AMD)
Dry (nonexudative) age-related macular degeneration
Wet (exudative/neovascular) age-related macular degeneration
Epidemiology of age-related macular degeneration (AMD)
Over 7.5 million sufferers of age-related macular degeneration in the seven major markets in 2010
estimates over 2.7 million cases of age-related macular degeneration in the US in 2010
Japanese males have higher prevalence of age-related macular degeneration
estimates over 4.3 million cases of age-related macular degeneration across the five major EU markets in 2010
Age-related macular degeneration prevalence is high in India
Age-related macular degeneration prevalence varies in racial groups
Current treatment options in age-related macular degeneration (AMD)
Overview of treatments in age-related macular degeneration (AMD)
Anti-vascular endothelial growth factor (VEGF) therapy
Off-label use of Avastin in age-related macular degeneration
Laser photocoagulation and photodynamic therapy
Other surgical treatments for AMD
Vitamins and lifestyle change are the main treatment options in dry AMD
Age-related macular degeneration (AMD) treatment guidelines Diagnosis of AMD
Treatment guidelines on the management of AMD
Sales analysis of brands in age-related macular degeneration (AMD)
Lucentis drives rapid growth in AMD market between 2004 and 2008
Major brands in AMD therapy
Lucentis (ranibizumab, Roche/Novartis/Alcon)
Macugen (pegaptanib, Eyetech/Pfizer)
Visudyne (verteporfin, QLT /Novartis)
Avastin (bevacizumab, Roche)
Highlights
The future of leading brands Lucentis (ranibizumab) and Xalatan (latanoprost) is at risk. Lucentis dominates AMD with 91% market share but the use of currently off-label Avastin (bevacizumab, Roche) is a threat. Xalatan, the gold standard in glaucoma achieved $1.5 billion in 2008 but the drug faces generic erosion after patent expiry in 2011
Diabetic retinopathy and AMD markets show high growth potential. Both diseases are highly prevalent, with 11.5 million cases of diabetic retinopathy, and 7.5 million in AMD, in the seven major markets in 2010. There are few drug treatments for AMD, while no approved drugs for diabetic retinopathy mean this market is untapped.
Key opinion leaders report high unmet need for reduced dosing regimens of existing therapies and an improvement in drug delivery methods. However, any new formulations of existing drugs will have to compete with cheap generics and need to show significant additional benefits.
Reasons to Purchase
*Validate the market potential of particular ophthalmology indications based on prevalence numbers in each of the seven major markets
*Understand the commercial potential of ophthalmic diseases with Datamonitor’s assessment of market and brand dynamics
*Assess the key unmet needs and possible new approaches in the treatment of eye diseases as noted by opinion leaders
Ophthalmology market attractiveness
ophthalmology market definition
Therapeutic sales for ophthalmology disorders exceeded $12 billion in 2008
High growth potential observed in diabetic retinopathy and age-related macular degeneration markets
Age-related macular degeneration shows a high growth rate, and seemingly unsaturated market
Middle Eastern, North African (MENA) and Brazil, Russia, India and China (BRIC) ophthalmology markets are growing rapidly
High pipeline potential in age-related macular degeneration (AMD)
to greater patient compliance
Preservative-free formulations
Therapies with better side-effect profiles
Pipeline analysis of glaucoma treatments
Chapter 3. Age-related macular degeneration
Key findings 70
Definition and classification of age-related macular degeneration (AMD)
Dry (nonexudative) age-related macular degeneration
Wet (exudative/neovascular) age-related macular degeneration
Epidemiology of age-related macular degeneration (AMD)
Over 7.5 million sufferers of age-related macular degeneration in the seven major markets in 2010
estimates over 2.7 million cases of age-related macular degeneration in the US in 2010
Japanese males have higher prevalence of age-related macular degeneration
estimates over 4.3 million cases of age-related macular degeneration across the five major EU markets in 2010
Age-related macular degeneration prevalence is high in India
Age-related macular degeneration prevalence varies in racial groups
Current treatment options in age-related macular degeneration (AMD)
Overview of treatments in age-related macular degeneration (AMD)
Anti-vascular endothelial growth factor (VEGF) therapy
Off-label use of Avastin in age-related macular degeneration
Laser photocoagulation and photodynamic therapy
Other surgical treatments for AMD
Vitamins and lifestyle change are the main treatment options in dry AMD
Age-related macular degeneration (AMD) treatment guidelines Diagnosis of AMD
Treatment guidelines on the management of AMD
Sales analysis of brands in age-related macular degeneration (AMD)
Lucentis drives rapid growth in AMD market between 2004 and 2008
Major brands in AMD therapy
Lucentis (ranibizumab, Roche/Novartis/Alcon)
Macugen (pegaptanib, Eyetech/Pfizer)
Visudyne (verteporfin, QLT /Novartis)
Avastin (bevacizumab, Roche)
Tuesday, July 20, 2010
Alcon Terminates the Development of Anecortave Acetate in Age-Related Macular Degeneration
HUENENBERG, Switzerland -- Alcon, Inc. (NYSE:ACL) announced today it has terminated the development program designed to evaluate the benefit of anecortave acetate treatment on the risk for developing sight-threatening choroidal neovascularization secondary to age-related macular degeneration. The decision followed a planned interim analysis of studies C-02-60 A and B that was performed after 2,546 patients had completed the 24 month time point. In this analysis, anecortave acetate showed no effect on the primary or secondary endpoints. In addition to terminating studies C-02-60 A and B, the company also terminated two smaller studies with an identical design that were being conducted in Asia, C-04-30 and C-05-34.
The company continues to study anecortave acetate administered as an anterior juxtascleral depot to reduce intraocular pressure in patients with open-angle glaucoma.
About Alcon
Alcon, Inc. is the world's leading eye care company, with sales of approximately $5.6 billion in 2007. Alcon, which has been dedicated to the ophthalmic industry for more than 60 years, researches, develops, manufactures and markets pharmaceuticals, surgical equipment and devices, contact lens care solutions and other vision care products that treat diseases, disorders and other conditions of the eye. Alcon's majority shareholder is Nestle, S.A., the world's largest food company. For more information on Alcon Inc., visit the company's Web site at www.alcon.com.
The company continues to study anecortave acetate administered as an anterior juxtascleral depot to reduce intraocular pressure in patients with open-angle glaucoma.
About Alcon
Alcon, Inc. is the world's leading eye care company, with sales of approximately $5.6 billion in 2007. Alcon, which has been dedicated to the ophthalmic industry for more than 60 years, researches, develops, manufactures and markets pharmaceuticals, surgical equipment and devices, contact lens care solutions and other vision care products that treat diseases, disorders and other conditions of the eye. Alcon's majority shareholder is Nestle, S.A., the world's largest food company. For more information on Alcon Inc., visit the company's Web site at www.alcon.com.
Monday, July 12, 2010
Artificial Retina offers new Hope
TUCSON - There is new hope for millions of people losing their vision. Many are going blind because of age-related macular degeneration and other conditions. But a new device called Artificial Retina has people seeing and believing.
Dean Lloyd is one of 14 people in the United States seeing through an Artifical Retina. He lost his vision in 1974. Lloyd says, "I almost lost all my vision in six months." Then in 2007, after a three hour operation, his sight, though limited, returned. "The beauty of the human brain is when you've had sight at one time, the brain seems to save the images," he said.
The camera on Dean's glasses captures an image and sends it wirelessly to an implant in his eye that stimulates his optic nerve to create an image in his brain. The next generation for Dean's implant is one that could help him see details and faces.
Satinderpall Pannu heads the Artificial Retina project at Lawrence Livermore labs in California. Starting with a silicon wafer and a thin coating of polymer, the disk is processed, electrodes are added and the implant is encased in titanium and gold, "It's a very rewarding feeling. It's amazing to me that technology that we've developed here at the lab can actually restore someone's sight," Pannu said.
Pannu says in 10 years, 50 million people in the world will suffer from blindness that these implants could reverse, "We really would like to take this tech to have a digital camera embedded in your retina and be able to restore your vision completely."
The only clinical trials for the artificial retina in the U.S. are run through a California Company "Second Sight."
Project leaders at Lawrence Livermore say they only have funding through next year. Right now, they're trying to lobby congress to extend the project's 8-million dollar a year budget, to improve the implant.
Dean Lloyd is one of 14 people in the United States seeing through an Artifical Retina. He lost his vision in 1974. Lloyd says, "I almost lost all my vision in six months." Then in 2007, after a three hour operation, his sight, though limited, returned. "The beauty of the human brain is when you've had sight at one time, the brain seems to save the images," he said.
The camera on Dean's glasses captures an image and sends it wirelessly to an implant in his eye that stimulates his optic nerve to create an image in his brain. The next generation for Dean's implant is one that could help him see details and faces.
Satinderpall Pannu heads the Artificial Retina project at Lawrence Livermore labs in California. Starting with a silicon wafer and a thin coating of polymer, the disk is processed, electrodes are added and the implant is encased in titanium and gold, "It's a very rewarding feeling. It's amazing to me that technology that we've developed here at the lab can actually restore someone's sight," Pannu said.
Pannu says in 10 years, 50 million people in the world will suffer from blindness that these implants could reverse, "We really would like to take this tech to have a digital camera embedded in your retina and be able to restore your vision completely."
The only clinical trials for the artificial retina in the U.S. are run through a California Company "Second Sight."
Project leaders at Lawrence Livermore say they only have funding through next year. Right now, they're trying to lobby congress to extend the project's 8-million dollar a year budget, to improve the implant.
Wednesday, July 7, 2010
Miniature Telescope for Eye Approved for Macular Degeneration
TUESDAY, July 6 (HealthDay News) -- A tiny telescope that's implanted in an eye affected by advanced age-related macular degeneration (AMD) has been approved by the U.S. Food and Drug Administration.
The Implantable Miniature Telescope replaces the natural lens and magnifies an image more than two times, the FDA said in a news release.
The device is meant for people aged 75 and older who have blind spots associated with end-stage AMD. Candidates will be trained with an external telescopic device to see if they may benefit from the implanted product, the agency said.
AMD damages the eye's macula, causing vision loss in the center of the visual field. The condition affects mostly older people, often making it impossible to recognize faces or perform tasks such as watching television, the FDA said. Some 8 million Americans have been diagnosed with the condition, and about 25 percent of those are significantly visually impaired.
The FDA said it's requiring the labeling to warn that the device puts users at greater risk of injury to the eye's cornea.
As a condition of approval, California-based VisionCare Ophthalmic Technologies will conduct two follow-up studies of the device, the agency said.
More information
To learn more about AMD, visit the U.S. National Eye Institute.
Copyright © 2010 ScoutNews, LLC. All rights reserved.
HealthDayNews articles are derived from various sources and do not reflect federal policy. healthfinder.gov does not endorse opinions, products, or services that may appear in news stories. For more information on health topics in the news, visit Health News on healthfinder.gov.
The Implantable Miniature Telescope replaces the natural lens and magnifies an image more than two times, the FDA said in a news release.
The device is meant for people aged 75 and older who have blind spots associated with end-stage AMD. Candidates will be trained with an external telescopic device to see if they may benefit from the implanted product, the agency said.
AMD damages the eye's macula, causing vision loss in the center of the visual field. The condition affects mostly older people, often making it impossible to recognize faces or perform tasks such as watching television, the FDA said. Some 8 million Americans have been diagnosed with the condition, and about 25 percent of those are significantly visually impaired.
The FDA said it's requiring the labeling to warn that the device puts users at greater risk of injury to the eye's cornea.
As a condition of approval, California-based VisionCare Ophthalmic Technologies will conduct two follow-up studies of the device, the agency said.
More information
To learn more about AMD, visit the U.S. National Eye Institute.
Copyright © 2010 ScoutNews, LLC. All rights reserved.
HealthDayNews articles are derived from various sources and do not reflect federal policy. healthfinder.gov does not endorse opinions, products, or services that may appear in news stories. For more information on health topics in the news, visit Health News on healthfinder.gov.
Wednesday, June 30, 2010
Alimera seek NDA for diabetic macular degeneration drug/device combo
June 29, 2010 by MassDevice staffpSivida Corp. and Alimera Sciences file a new drug application with the Food & Drug Administration for Iluvien, a drug/device combination aimed at treating diabetic macular degeneration.
pSivida Corp. (NSDQ:PSDV) and Alimera Sciences (NSDQ:ALIM) are seeking a green light from the Food & Drug Administration for a drug/device combination to treat diabetic macular degeneration.
Watertown, Mass.-based pSivida said Alimera, which licenses the Iluvien technology from pSivida, submitted a new drug application to the FDA. The technology is designed to deliver sustained, low doses of flucocinolone acetonide to the retina at the rear of the eyeball.
Alimera asked the federal watchdog for priority review, an expedited process that could bring an FDA response during the fourth quarter, according to a press release.
There are no approved drugs to treat DME, according to pSivida president and CEO Paul Ashton, adding that Iluvien is the company's third product aimed at back-of-the-eye diseases. The first two won FDA approval and are on the market, Ashton said: Retisert, for the treatment of posterior uveitis, and Vitrasert for the treatment of AIDS-related cytomegalovirus retinitis. Both are licensed to Bausch & Lomb Inc.
The company is also working on a treatment for retinitis pigmentosa, which involves the gradual deterioration of the rods and cones that make up the retina. In April Ashton told MassDevice that its Durasert device also uses flucocinolone acetonide, a steroid, to treat the disease.
"What we've done is use a very small insertable drug delivery device to release a steroid directly into the eye that will just provide some protection and slow down the rates of vision loss," he said. "With a condition that takes 20 years to make you blind, if you slow it down by a factor of two, that's pretty good."
The partnership with Alimera has already paid dividends, namely a $15.3 million payment triggered by Alimera's April 21 initial public offering. At the time Ashton told us pSivida planned to use the cash to further develop its product pipeline. If the FDA gives the nod to Iluvien, it would trigger another, $25 million milestone payment from Alimera, plus 20 percent royalties on net profits from sales of the treatment.
For more information go to www.maculardegenerationassociation.org
pSivida Corp. (NSDQ:PSDV) and Alimera Sciences (NSDQ:ALIM) are seeking a green light from the Food & Drug Administration for a drug/device combination to treat diabetic macular degeneration.
Watertown, Mass.-based pSivida said Alimera, which licenses the Iluvien technology from pSivida, submitted a new drug application to the FDA. The technology is designed to deliver sustained, low doses of flucocinolone acetonide to the retina at the rear of the eyeball.
Alimera asked the federal watchdog for priority review, an expedited process that could bring an FDA response during the fourth quarter, according to a press release.
There are no approved drugs to treat DME, according to pSivida president and CEO Paul Ashton, adding that Iluvien is the company's third product aimed at back-of-the-eye diseases. The first two won FDA approval and are on the market, Ashton said: Retisert, for the treatment of posterior uveitis, and Vitrasert for the treatment of AIDS-related cytomegalovirus retinitis. Both are licensed to Bausch & Lomb Inc.
The company is also working on a treatment for retinitis pigmentosa, which involves the gradual deterioration of the rods and cones that make up the retina. In April Ashton told MassDevice that its Durasert device also uses flucocinolone acetonide, a steroid, to treat the disease.
"What we've done is use a very small insertable drug delivery device to release a steroid directly into the eye that will just provide some protection and slow down the rates of vision loss," he said. "With a condition that takes 20 years to make you blind, if you slow it down by a factor of two, that's pretty good."
The partnership with Alimera has already paid dividends, namely a $15.3 million payment triggered by Alimera's April 21 initial public offering. At the time Ashton told us pSivida planned to use the cash to further develop its product pipeline. If the FDA gives the nod to Iluvien, it would trigger another, $25 million milestone payment from Alimera, plus 20 percent royalties on net profits from sales of the treatment.
For more information go to www.maculardegenerationassociation.org
Thursday, June 10, 2010
Researchers create retina from embryonic cells
By Adrian Galbreth
Researchers in the US have successfully created a retina from human embryonic stem cells, which offers hope to millions with degenerative eye disorders.
Experts at the University of California Irvine created an eight-layer, early stage retina from human embryonic stem cells, which is the first ever three-dimensional tissue structure to be made from stem cells.
Study leader Hans Keirstead of the Reeve-Irvine Research Center and the Sue and Bill Gross Stem Cell Research Center at the facility, said the process also marks the first step towards the development of transplant-ready retinas to treat conditions such as retinitis pigmentosa and macular degeneration, a leading cause of blindness.
"We made a complex structure consisting of many cell types. This is a major advance in our quest to treat retinal disease," he explained.
Recently, German research centre Fraunhofer-Gesellschaft claimed that a new implant made of plastic could soon offer patients the chance to see again without having to wait for cornea transplants.ADNFCR-1853-ID-19804594-ADNFCR
Researchers in the US have successfully created a retina from human embryonic stem cells, which offers hope to millions with degenerative eye disorders.
Experts at the University of California Irvine created an eight-layer, early stage retina from human embryonic stem cells, which is the first ever three-dimensional tissue structure to be made from stem cells.
Study leader Hans Keirstead of the Reeve-Irvine Research Center and the Sue and Bill Gross Stem Cell Research Center at the facility, said the process also marks the first step towards the development of transplant-ready retinas to treat conditions such as retinitis pigmentosa and macular degeneration, a leading cause of blindness.
"We made a complex structure consisting of many cell types. This is a major advance in our quest to treat retinal disease," he explained.
Recently, German research centre Fraunhofer-Gesellschaft claimed that a new implant made of plastic could soon offer patients the chance to see again without having to wait for cornea transplants.ADNFCR-1853-ID-19804594-ADNFCR
Wednesday, June 2, 2010
New Drugs for Macular Degeneration
By Emily Singer
Two genetic studies of people with age-related macular degeneration (AMD)--the most common cause of blindness in people older than 65--made a surprising discovery. Research showed that defects in a gene that is an important regulator of parts of the immune system significantly increased risk of the disease. Scientists have since identified variants in several related genes that also boost risk, and which collectively account for about 50 to 60 percent of the heritability of the disorder.
At the same time that researchers identified the harmful variation linked to AMD, Gregory Hageman, now at the University of Utah, identified a protective variant found in about 20 percent of the population. "That form is so incredibly protective that people with two copies are almost guaranteed not to develop the disease," he says. Hageman founded Optherion, a startup based in New Haven, CT, and investigated how to translate the findings into new treatments. Optherion is now producing large quantities of an engineered version of the protein and doing preclinical safety and effectiveness testing--for example, examining whether the treatment can reduce ocular deposits in mice that lack the protein, says Colin Foster, Optherion's president. He declined to estimate when the company will begin clinical trials of the drug.
Scientists hope that these developments will prove to be an example of the benefits that can arise from a type of genetic study called genome-wide association. The genome-wide studies of macular degeneration were among the first and perhaps the biggest success for the approach, which employs specially designed chips dotted with markers to cheaply detect hundreds of thousands of the most common variations in the human genome. While these chips have allowed scientists to cheaply scan the genomes of many patients and healthy controls, the approach has come under increasing scrutiny in the last couple of years. Even huge studies of thousands of people have failed to identify the majority of the heritability of common diseases, such as type 2 diabetes or Alzheimer's disease.
Two genetic studies of people with age-related macular degeneration (AMD)--the most common cause of blindness in people older than 65--made a surprising discovery. Research showed that defects in a gene that is an important regulator of parts of the immune system significantly increased risk of the disease. Scientists have since identified variants in several related genes that also boost risk, and which collectively account for about 50 to 60 percent of the heritability of the disorder.
At the same time that researchers identified the harmful variation linked to AMD, Gregory Hageman, now at the University of Utah, identified a protective variant found in about 20 percent of the population. "That form is so incredibly protective that people with two copies are almost guaranteed not to develop the disease," he says. Hageman founded Optherion, a startup based in New Haven, CT, and investigated how to translate the findings into new treatments. Optherion is now producing large quantities of an engineered version of the protein and doing preclinical safety and effectiveness testing--for example, examining whether the treatment can reduce ocular deposits in mice that lack the protein, says Colin Foster, Optherion's president. He declined to estimate when the company will begin clinical trials of the drug.
Scientists hope that these developments will prove to be an example of the benefits that can arise from a type of genetic study called genome-wide association. The genome-wide studies of macular degeneration were among the first and perhaps the biggest success for the approach, which employs specially designed chips dotted with markers to cheaply detect hundreds of thousands of the most common variations in the human genome. While these chips have allowed scientists to cheaply scan the genomes of many patients and healthy controls, the approach has come under increasing scrutiny in the last couple of years. Even huge studies of thousands of people have failed to identify the majority of the heritability of common diseases, such as type 2 diabetes or Alzheimer's disease.
Thursday, May 27, 2010
Decreased antioxidant levels increase risk of age-related macular degeneration with exposure to sunlight
The journal Archives of Ophthalmology recently reported that having reduced plasma antioxidant levels and increased exposure to sunlight increases the risk of neovascular, or advanced age-related macular degeneration (AMD).
In a recent study (titled the European Eye Study), over 4,400 participants over age 65 were analyzed for the presence of macular degeneration. Their blood plasma was evaluated for vitamins C and E, the carotenoids lutein and zeaxanthin, and the mineral zinc. Each individual also completed a questionnaire regarding their typical exposure to sunlight. This was used to estimate blue light exposure from visible light, which is known to contribute to the development of macular degeneration.
Early stage macular degeneration was detected in 2,182 participants, and 101 had the advanced form of the disease. The research found no association between blue light exposure and early macular degeneration. However, among participants in the lowest quartile (25 percent) of serum vitamin C, zeaxanthin, vitamin E and zinc, exposure to blue light significantly increased the risk of advanced macular degeneration.
In a recent study (titled the European Eye Study), over 4,400 participants over age 65 were analyzed for the presence of macular degeneration. Their blood plasma was evaluated for vitamins C and E, the carotenoids lutein and zeaxanthin, and the mineral zinc. Each individual also completed a questionnaire regarding their typical exposure to sunlight. This was used to estimate blue light exposure from visible light, which is known to contribute to the development of macular degeneration.
Early stage macular degeneration was detected in 2,182 participants, and 101 had the advanced form of the disease. The research found no association between blue light exposure and early macular degeneration. However, among participants in the lowest quartile (25 percent) of serum vitamin C, zeaxanthin, vitamin E and zinc, exposure to blue light significantly increased the risk of advanced macular degeneration.
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