by:Elias Reichel
KAANAPALI, Hawaii — Sustained-release corticosteroids will play a significant role in retinal vascular disease, but the current implants still need improvements, one presenter here said.
"It is important to realize [steroids] will have a continued role in our treatment of diseases. They may also serve for adjunctive [therapies] like stem cell treatments and [instances] where transplantation or immunoreactions may occur," Elias Reichel, MD, who discussed outcomes using Ozurdex (dexamethasone intravitreal implant, Allergan) and Iluvien (fluocinolone acetonide intravitreal implant, Alimera), said at Retina 2011. "So, having a better delivery system for corticosteroids is very useful for many of the diseases we are seeing in our offices."
Challenges include needing to achieve and maintain clinically effective concentrations in the vitreous over time while maximizing efficacy and minimizing adverse effects, Dr. Reichel said.
As part of a 6-month study, the dexamethasone implant demonstrated 2- to 3-month peak efficacy, had a low incidence of IOP issues and conferred a cataract progression of approximately 5%. Additionally, 45% of the patients gained three lines of visual acuity, Dr. Reichel said.
The U.S. Food and Drug Administration has approved the device for all retinal venous obstructive disease.
The fluocinolone implant is now part of a 36-month study and has demonstrated efficacy to at least 30 months. Between 30% and 40% of patients gained at least three lines of visual acuity. However, the device has a moderately higher risk of IOP issues and a cataract progression rate of 50%, according to Dr. Reichel.
The device has received a complete response letter from the FDA.
"Current formulations that we have are good but can be better," Dr. Reichel said. "We really have to look at longer duration and this reduced risk trade-off."
* Disclosure: Dr. Reichel is a consultant to Alimera and Allergan.
Showing posts with label eyes. Show all posts
Showing posts with label eyes. Show all posts
Sunday, January 23, 2011
Saturday, January 15, 2011
Stem cell therapy for macular degeneration
By Jill U. Adams, Special to the Los Angeles Times
The FDA has approved a new study aimed at fighting dry age-related macular degeneration.
About 10 million Americans suffer some degree of vision loss caused by age-related macular degeneration, and that figure is expected to grow as more baby boomers become senior citizens. There is no cure for the disease, but last week the U.S. Food and Drug Administration gave a green light to an unusual clinical trial that seeks to restore patients' sight by employing human embryonic stem cells.
None of the stem cells will be injected into patients; instead, they are grown into another kind of cell that will be delivered to the back of the eye, where the retina is damaged by the disease. The hope is that the cells will help repair the damaged retinal tissue.
The company behind the trial, Santa Monica-based Advanced Cell Technology Inc., developed the therapy to treat Stargardt's macular dystrophy, a rare childhood version of macular degeneration that affects about 1 in 10,000 kids. The FDA gave the company permission to test the therapy in Stargardt's patients in November. However, if they work, the cells would have a much bigger effect as a treatment for age-related macular degeneration.
Here's a closer look at the disease and the new therapy.
What is age-related macular degeneration?
Age-related macular degeneration is the leading cause of vision impairment and blindness among people who are 65 and older, says Dr. Jose Pulido, an ophthalmologist at the Mayo Clinic in Rochester, Minn. The dry version of the disease begins with tiny deposits of fat and protein — called drusen — that appear in the center of the retina, called the macula. As the deposits grow in number and size over the course of years, things begin to look blurry in the center of a person's field of vision. As the disease worsens, the blurriness may progress to a blind spot.
What causes it?
The main problem is that light-sensing cells in the macula, called photoreceptors, slowly break down. This is thought to be caused by the loss of another population of cells, called retinal pigment epithelial (RPE) cells, which support the photoreceptors in a number of ways.
Among other things, the RPE cells release growth factors important for photoreceptors to thrive. "The RPE are also the garbage trucks of the retina," removing toxic byproducts that the retina makes as it performs its light-sensing function, says Stephen Rose, chief research officer for the Foundation Fighting Blindness, a fundraising organization based in Columbia, Md.
Dry age-related macular degeneration can also progress into wet age-related macular degeneration, in which blood vessels grow abnormally and leak fluid into the macula. It's a much more aggressive form of the disease, but it's also more treatable.
How can human embryonic stem cells help?
The stem cells are grown into healthy replacement RPE cells and injected into the retina, says Gary Rabin, Advanced Cell Technology's chief executive. The company hopes the lab-grown cells will replace the dying RPE cells and keep vision intact — or even restore it to some degree.
"We've had incredible success with this in animal studies," Rabin says. A study published in the journal Stem Cells found that the RPE cells restored eye function in sick mice and rats to "near-normal levels," and another study in Cloning and Stem Cells reported that the treatment improved vision in affected rats until it was 70% as good as that of healthy animals.
Of course, success in animal studies doesn't always translate to humans. In addition, the eyes of people in their 50s and 60s likely present "a very different milieu for the RPE cells to try to hook onto," Pulido says.
Rose adds that the treatment, if it works, wouldn't amount to a cure because it doesn't address the reason why RPE cells deteriorate in the first place. But it would buy time for patients, delaying vision loss for perhaps years. "That's huge," he says.
What will the new trial assess?
The FDA granted permission to conduct a Phase I/II clinical trial, which is essentially a safety trial, that will involve a dozen patients. The first patients will get a very low "dose" of cells — 50,000 — and will be monitored for any untoward effects.
"If there are no safety issues after three-ish months, we will increase the dose [to a level where we] hope to see efficacy," Rabin says. "We anticipate that the photoreceptor cells will awaken and that there will be a gradual increase in visual acuity over time." For now, the protocol calls for a one-time treatment of up to 200,000 cells.
Aren't there ethical concerns about using human embryonic stem cells?
Generally speaking, many people are troubled by research involving human embryonic stem cells because they are typically made by dismantling — and thus destroying — embryos that are a few days old.
Advanced Cell Technology uses a proprietary technique to extract a single cell from a young embryo, allowing the rest to remain intact and develop normally, Rabin says. A similar method is routinely used to biopsy embryos for pre-implantation genetic diagnosis, in which embryos created through in vitro fertilization are scanned for genetic disorders before being transferred to a uterus.
The FDA has approved a new study aimed at fighting dry age-related macular degeneration.
About 10 million Americans suffer some degree of vision loss caused by age-related macular degeneration, and that figure is expected to grow as more baby boomers become senior citizens. There is no cure for the disease, but last week the U.S. Food and Drug Administration gave a green light to an unusual clinical trial that seeks to restore patients' sight by employing human embryonic stem cells.
None of the stem cells will be injected into patients; instead, they are grown into another kind of cell that will be delivered to the back of the eye, where the retina is damaged by the disease. The hope is that the cells will help repair the damaged retinal tissue.
The company behind the trial, Santa Monica-based Advanced Cell Technology Inc., developed the therapy to treat Stargardt's macular dystrophy, a rare childhood version of macular degeneration that affects about 1 in 10,000 kids. The FDA gave the company permission to test the therapy in Stargardt's patients in November. However, if they work, the cells would have a much bigger effect as a treatment for age-related macular degeneration.
Here's a closer look at the disease and the new therapy.
What is age-related macular degeneration?
Age-related macular degeneration is the leading cause of vision impairment and blindness among people who are 65 and older, says Dr. Jose Pulido, an ophthalmologist at the Mayo Clinic in Rochester, Minn. The dry version of the disease begins with tiny deposits of fat and protein — called drusen — that appear in the center of the retina, called the macula. As the deposits grow in number and size over the course of years, things begin to look blurry in the center of a person's field of vision. As the disease worsens, the blurriness may progress to a blind spot.
What causes it?
The main problem is that light-sensing cells in the macula, called photoreceptors, slowly break down. This is thought to be caused by the loss of another population of cells, called retinal pigment epithelial (RPE) cells, which support the photoreceptors in a number of ways.
Among other things, the RPE cells release growth factors important for photoreceptors to thrive. "The RPE are also the garbage trucks of the retina," removing toxic byproducts that the retina makes as it performs its light-sensing function, says Stephen Rose, chief research officer for the Foundation Fighting Blindness, a fundraising organization based in Columbia, Md.
Dry age-related macular degeneration can also progress into wet age-related macular degeneration, in which blood vessels grow abnormally and leak fluid into the macula. It's a much more aggressive form of the disease, but it's also more treatable.
How can human embryonic stem cells help?
The stem cells are grown into healthy replacement RPE cells and injected into the retina, says Gary Rabin, Advanced Cell Technology's chief executive. The company hopes the lab-grown cells will replace the dying RPE cells and keep vision intact — or even restore it to some degree.
"We've had incredible success with this in animal studies," Rabin says. A study published in the journal Stem Cells found that the RPE cells restored eye function in sick mice and rats to "near-normal levels," and another study in Cloning and Stem Cells reported that the treatment improved vision in affected rats until it was 70% as good as that of healthy animals.
Of course, success in animal studies doesn't always translate to humans. In addition, the eyes of people in their 50s and 60s likely present "a very different milieu for the RPE cells to try to hook onto," Pulido says.
Rose adds that the treatment, if it works, wouldn't amount to a cure because it doesn't address the reason why RPE cells deteriorate in the first place. But it would buy time for patients, delaying vision loss for perhaps years. "That's huge," he says.
What will the new trial assess?
The FDA granted permission to conduct a Phase I/II clinical trial, which is essentially a safety trial, that will involve a dozen patients. The first patients will get a very low "dose" of cells — 50,000 — and will be monitored for any untoward effects.
"If there are no safety issues after three-ish months, we will increase the dose [to a level where we] hope to see efficacy," Rabin says. "We anticipate that the photoreceptor cells will awaken and that there will be a gradual increase in visual acuity over time." For now, the protocol calls for a one-time treatment of up to 200,000 cells.
Aren't there ethical concerns about using human embryonic stem cells?
Generally speaking, many people are troubled by research involving human embryonic stem cells because they are typically made by dismantling — and thus destroying — embryos that are a few days old.
Advanced Cell Technology uses a proprietary technique to extract a single cell from a young embryo, allowing the rest to remain intact and develop normally, Rabin says. A similar method is routinely used to biopsy embryos for pre-implantation genetic diagnosis, in which embryos created through in vitro fertilization are scanned for genetic disorders before being transferred to a uterus.
Sunday, January 9, 2011
FDA approves embryonic stem cells to reverse macular degeneration
by:Admin
Sacramento is now the hub of stem-cell research focusing on regenerative medicine. See the article, UC Davis: Stem Cell Research. After receiving $62 million for stem cell research last year, the new UC Davis Institute for Regenerative Cures opened. And the center already is testing dozens of therapies in the laboratory. The center will bring 200 scientists and laboratory personnel together under one roof. Check out the UC Davis Stem Cell Institute. See UC Davis Stem Cell Program. And check out the site, UCDMC Stem Cell Research News.
Now that the FDA has approved embryonic stem cells today, to help reverse certain types of macular degeneration, consumers should know that the stem cell taken from an embryo does not destroy the embryo. Just a single stem cell is taken from the embryo. Then the embryo continues to thrive and is not destroyed.
California sites currently under consideration for the trials include the Jules Stein Eye Institute at UCLA and the Ophthalmology Department at Stanford University. Check out the government site listing clinical trials, Clinical Trials.gov.
Also, in the Sacramento and Davis regional area, did you know that the University of California is recruiting for or has completed at least 193 clinical trials on various types of health studies ranging from the health benefits of ground flax seeds to stem cell research? Also see the January 4, 2011 news article, Read: Vitamin Drug Could Stop Dry Macular Degeneration.
Concerning studies at another university on macular degeneration and stem cell research, if you're interested in stem cell research for macular degeneration, the breaking news is that the FDA has just approved the use of stem cells to treat certain types of macular degeneration. According to a January 4, 2011 news article, "FDA Approves Stem Cell Treatment Trial for AMD-Related Vision Loss," the US Food and Drug Administration (FDA) has approved a clinical trial of human embryonic stem-cell treatments on patients who have suffered vision loss related to dry age-related macular degeneration (AMD).
Advanced Cell Technology of Massachusetts will begin a Phase I/II open-label study on twelve patients at multiple clinical sites to determine the safety and tolerability of the treatment. The dry version of macular degeneration is a leading cause of blindness in older adults. Dry age-related macular degeneration is one of two forms of an eye disease that breaks down retinal pigment epithelial (RPE) cells in the macula of the retina, a layer of light-sensitive tissue at the back of the eye. Progressive loss of RPE cells and the accompanying loss of photoreceptors can cause severe vision loss. There are no current treatments available for AMD.
Dry AMD is the leading cause of blindness in individuals over the age of 55, afflicting approximately 10 million people in the US. And as the population ages, according to the article, "FDA Approves Stem Cell Treatment Trial for AMD-Related Vision Loss."
In the clinical trials and approved experiments, patients will receive 50,000 to 2,000,000 RPE cells derived from human embryonic stem cells to replace those lost due to AMD. While human embryonic stem cell use is controversial, ACT maintains that their cells are derived from a single-cell extraction technology that “does not destroy the embryo.” Also read the article, Read: Smoking Raises Risk of Macular Degeneration.
Sacramento is now the hub of stem-cell research focusing on regenerative medicine. See the article, UC Davis: Stem Cell Research. After receiving $62 million for stem cell research last year, the new UC Davis Institute for Regenerative Cures opened. And the center already is testing dozens of therapies in the laboratory. The center will bring 200 scientists and laboratory personnel together under one roof. Check out the UC Davis Stem Cell Institute. See UC Davis Stem Cell Program. And check out the site, UCDMC Stem Cell Research News.
Now that the FDA has approved embryonic stem cells today, to help reverse certain types of macular degeneration, consumers should know that the stem cell taken from an embryo does not destroy the embryo. Just a single stem cell is taken from the embryo. Then the embryo continues to thrive and is not destroyed.
California sites currently under consideration for the trials include the Jules Stein Eye Institute at UCLA and the Ophthalmology Department at Stanford University. Check out the government site listing clinical trials, Clinical Trials.gov.
Also, in the Sacramento and Davis regional area, did you know that the University of California is recruiting for or has completed at least 193 clinical trials on various types of health studies ranging from the health benefits of ground flax seeds to stem cell research? Also see the January 4, 2011 news article, Read: Vitamin Drug Could Stop Dry Macular Degeneration.
Concerning studies at another university on macular degeneration and stem cell research, if you're interested in stem cell research for macular degeneration, the breaking news is that the FDA has just approved the use of stem cells to treat certain types of macular degeneration. According to a January 4, 2011 news article, "FDA Approves Stem Cell Treatment Trial for AMD-Related Vision Loss," the US Food and Drug Administration (FDA) has approved a clinical trial of human embryonic stem-cell treatments on patients who have suffered vision loss related to dry age-related macular degeneration (AMD).
Advanced Cell Technology of Massachusetts will begin a Phase I/II open-label study on twelve patients at multiple clinical sites to determine the safety and tolerability of the treatment. The dry version of macular degeneration is a leading cause of blindness in older adults. Dry age-related macular degeneration is one of two forms of an eye disease that breaks down retinal pigment epithelial (RPE) cells in the macula of the retina, a layer of light-sensitive tissue at the back of the eye. Progressive loss of RPE cells and the accompanying loss of photoreceptors can cause severe vision loss. There are no current treatments available for AMD.
Dry AMD is the leading cause of blindness in individuals over the age of 55, afflicting approximately 10 million people in the US. And as the population ages, according to the article, "FDA Approves Stem Cell Treatment Trial for AMD-Related Vision Loss."
In the clinical trials and approved experiments, patients will receive 50,000 to 2,000,000 RPE cells derived from human embryonic stem cells to replace those lost due to AMD. While human embryonic stem cell use is controversial, ACT maintains that their cells are derived from a single-cell extraction technology that “does not destroy the embryo.” Also read the article, Read: Smoking Raises Risk of Macular Degeneration.
Monday, December 20, 2010
New Investment to Boost Gene Therapy Development
National Neurovision Research Institute (NNRI), the Foundation Fighting Blindness’ clinical trial support organization, announced today that one of its key partners, biopharmaceutical company Oxford BioMedica, has established a collaboration with sanofi-aventis, a major international pharmaceutical company, to develop and commercialize gene therapy treatments for vision-robbing retinal degenerative diseases that affect tens of millions of people around the world.
The collaboration will significantly bolster the development of the following gene therapy products: StarGen™ for the treatment of Stargardt disease, a form of early-onset macular degeneration; UshStat™ for the treatment of Usher syndrome, the leading cause of deaf-blindness; and RetinoStat® for the treatment of age-related macular degeneration, the leading cause vision loss in people 55 and older in developed countries.
The development of treatments for these and other retinal degenerative diseases is a key goal of the National Neurovision Research Institute and is the basis for its partnership with Oxford BioMedica. In 2006, Paul and Diane Manning, with the National Neurovision Research Institute, established a partnership with Oxford BioMedica to advance gene therapies for these and other related retinal degenerative diseases.
“The investment from sanofi-aventis is a wonderful boost for the development of Oxford BioMedica’s gene therapy products and will greatly enhance our ability to move these emerging treatments into and through the clinical trial process,” says Stephen Rose, Ph.D., chief research officer, Foundation Fighting Blindness. “This collaboration affirms the great potential for gene therapy to treat and cure a number of retinal degenerative diseases including Stargardt disease and Usher syndrome that, as rare diseases, often do not receive the attention or investment necessary to bring about promising treatments.”
“An important goal of the Foundation, through NNRI, is to attract investment from large pharmaceutical companies for the development and production of treatments for inherited retinal disease,” says Morton Goldberg, M.D., chairman of the board of NNRI. “The NNRI-Oxford partnership is an excellent model of how NNRI collaborations can accelerate the translation of laboratory-based research into clinical trials, ultimately getting successful treatments for rare diseases like inherited retinal degenerations to the market and out to the people who need them.”
Based on the agreement, Oxford BioMedica will receive an upfront payment of $26 million and a further $24 million from sanofi-aventis over a three-year period.
The treatments will utilize Oxford BioMedica’s LentiVector® gene delivery technology to deliver healthy vision-saving genes to the retina. For more information on this technology, visit www.oxfordbiomedica.co.uk/
The collaboration will significantly bolster the development of the following gene therapy products: StarGen™ for the treatment of Stargardt disease, a form of early-onset macular degeneration; UshStat™ for the treatment of Usher syndrome, the leading cause of deaf-blindness; and RetinoStat® for the treatment of age-related macular degeneration, the leading cause vision loss in people 55 and older in developed countries.
The development of treatments for these and other retinal degenerative diseases is a key goal of the National Neurovision Research Institute and is the basis for its partnership with Oxford BioMedica. In 2006, Paul and Diane Manning, with the National Neurovision Research Institute, established a partnership with Oxford BioMedica to advance gene therapies for these and other related retinal degenerative diseases.
“The investment from sanofi-aventis is a wonderful boost for the development of Oxford BioMedica’s gene therapy products and will greatly enhance our ability to move these emerging treatments into and through the clinical trial process,” says Stephen Rose, Ph.D., chief research officer, Foundation Fighting Blindness. “This collaboration affirms the great potential for gene therapy to treat and cure a number of retinal degenerative diseases including Stargardt disease and Usher syndrome that, as rare diseases, often do not receive the attention or investment necessary to bring about promising treatments.”
“An important goal of the Foundation, through NNRI, is to attract investment from large pharmaceutical companies for the development and production of treatments for inherited retinal disease,” says Morton Goldberg, M.D., chairman of the board of NNRI. “The NNRI-Oxford partnership is an excellent model of how NNRI collaborations can accelerate the translation of laboratory-based research into clinical trials, ultimately getting successful treatments for rare diseases like inherited retinal degenerations to the market and out to the people who need them.”
Based on the agreement, Oxford BioMedica will receive an upfront payment of $26 million and a further $24 million from sanofi-aventis over a three-year period.
The treatments will utilize Oxford BioMedica’s LentiVector® gene delivery technology to deliver healthy vision-saving genes to the retina. For more information on this technology, visit www.oxfordbiomedica.co.uk/
Monday, December 6, 2010
Drug Therapy To Cure Macular Degeneration
By Administration
Lucentis-is a drug therapy based on the cancer drug Avastin for wet macular degeneration. The treatment involves periodic injection of the drug directly into the eye. A higher percentage of those treated with Lucentis have shown improved vision than with any other treatment. Macugen-is another drug therapy for macular degeneration. It also involves periodic injections directly into the eye. It employs a molecule that attacks a protein involved with the growth of macular degeneration related blood vessels. macular degeneration treatment Vitamins and Minerals-are a treatment that is being used to treat dry macular degeneration. There is evidence to suggest that vitamins and minerals that have antioxidant properties will slow the progression of intermediate dry macular degeneration to the advanced form. The treatment typically involves large doses of Vitamin C, Vitamin E, Beta Carotene and Zinc Oxide.
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Lucentis-is a drug therapy based on the cancer drug Avastin for wet macular degeneration. The treatment involves periodic injection of the drug directly into the eye. A higher percentage of those treated with Lucentis have shown improved vision than with any other treatment. Macugen-is another drug therapy for macular degeneration. It also involves periodic injections directly into the eye. It employs a molecule that attacks a protein involved with the growth of macular degeneration related blood vessels. macular degeneration treatment Vitamins and Minerals-are a treatment that is being used to treat dry macular degeneration. There is evidence to suggest that vitamins and minerals that have antioxidant properties will slow the progression of intermediate dry macular degeneration to the advanced form. The treatment typically involves large doses of Vitamin C, Vitamin E, Beta Carotene and Zinc Oxide.
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Monday, November 15, 2010
Macular Degeneration Treatments/Therapies Breakthroughs
by Isobel Washington
Macular degeneration is an eye condition characterized by the deterioration of the macula, which is the central "lens-like" part of the eye's retina responsible for sharp central vision. Affecting central vision and often leading to vision loss, macular degeneration has had limited treatment options. Recently, there have been some breakthroughs to help patients retain vision.
Significance
Macular degeneration is the leading cause of vision loss and blindness among Americans age 65 and older. Vision loss from this condition is a growing problem, since this age demographic represents an increasingly larger percentage of the U. S. population.
Function
Treatments for macular degeneration work to preserve vision ability at the time of treatment, and slow the progression of the disease (it's a progressive disease that affects vision over time). Treatment cannot restore vision that is already lost through the disease. There is no cure or treatment to stop the progression of macular degeneration, there are ways to preserve and prolong current vision.
Eye Injections
Lucentis and Macugen are FDA-approved ocular injection treatments, and are highly effective for preserving vision and inhibiting macular degeneration symptoms, according to AllAboutVision.com. A 2005 study on Lucentis demonstrated success rate of 95 percent for improving and sustaining vision in macular degeneration patients.
Laser Treatment
Laser technology is now used to destroy the abnormal, leaky blood vessels that cause vision loss in macular degeneration patients. The National Eye Institute points out, however, that while this treatment may be effective for preventing vision loss, it is also comes with the risk of destroying healthy tissue that surrounds the treatment area.
Photodynamic Therapy
This method uses special light treatment to activate an injected drug, verteporfin, in the blood vessels, so that it destroys the new, abnormal blood vessels being hyper-produced in the eye (those that cause vision impairment or loss). The National Eye Institute reports that this light-activation method slows vision loss, but doesn't stop it.
Investigational Treatments
Investigational treatments for macular degeneration, in various stages of research and FDA clinical studies, include Avastin, a cancer treatment drug. As of 2009, the National Eye Institute reports that no available treatment provides a cure for macular degeneration, and that vision loss may result, despite treatment.
About the Author
Isobel Washington has been a freelance journalist since 2007. Washington's work first surfaced in Europe, where she served as a restaurant critic and journalist for "LifeStyles" magazine. Her love of travel and culture inspired her first novel, which is currently underway. Washington has a 10-year career in marketing communication and holds a Bachelor of Science degree.
Macular degeneration is an eye condition characterized by the deterioration of the macula, which is the central "lens-like" part of the eye's retina responsible for sharp central vision. Affecting central vision and often leading to vision loss, macular degeneration has had limited treatment options. Recently, there have been some breakthroughs to help patients retain vision.
Significance
Macular degeneration is the leading cause of vision loss and blindness among Americans age 65 and older. Vision loss from this condition is a growing problem, since this age demographic represents an increasingly larger percentage of the U. S. population.
Function
Treatments for macular degeneration work to preserve vision ability at the time of treatment, and slow the progression of the disease (it's a progressive disease that affects vision over time). Treatment cannot restore vision that is already lost through the disease. There is no cure or treatment to stop the progression of macular degeneration, there are ways to preserve and prolong current vision.
Eye Injections
Lucentis and Macugen are FDA-approved ocular injection treatments, and are highly effective for preserving vision and inhibiting macular degeneration symptoms, according to AllAboutVision.com. A 2005 study on Lucentis demonstrated success rate of 95 percent for improving and sustaining vision in macular degeneration patients.
Laser Treatment
Laser technology is now used to destroy the abnormal, leaky blood vessels that cause vision loss in macular degeneration patients. The National Eye Institute points out, however, that while this treatment may be effective for preventing vision loss, it is also comes with the risk of destroying healthy tissue that surrounds the treatment area.
Photodynamic Therapy
This method uses special light treatment to activate an injected drug, verteporfin, in the blood vessels, so that it destroys the new, abnormal blood vessels being hyper-produced in the eye (those that cause vision impairment or loss). The National Eye Institute reports that this light-activation method slows vision loss, but doesn't stop it.
Investigational Treatments
Investigational treatments for macular degeneration, in various stages of research and FDA clinical studies, include Avastin, a cancer treatment drug. As of 2009, the National Eye Institute reports that no available treatment provides a cure for macular degeneration, and that vision loss may result, despite treatment.
About the Author
Isobel Washington has been a freelance journalist since 2007. Washington's work first surfaced in Europe, where she served as a restaurant critic and journalist for "LifeStyles" magazine. Her love of travel and culture inspired her first novel, which is currently underway. Washington has a 10-year career in marketing communication and holds a Bachelor of Science degree.
Saturday, October 30, 2010
Retinal Disease Highlights From the 2010 AAO Meeting
By Dr. Randall Wong
Many of us just returned from the largest ophthalmic “trade show” in the world. The American Academy of Ophthalmology convened in Chicago last week. This meeting was combined with the Middle East Africa Council of Ophthalmology (MEACO). Perhaps 40 K attended the meeting.
I also attended the 2 day retinal subspecialty meeting which preceded the larger AAO meeting. Thus, I had 5 days to expand my knowledge.
Most of the congress was focused on technology, especially electronic medical records. Few discoveries were revealed. This may be for two reasons: there is nothing really new going on right now, and/or, the Internet allows such rapid sharing of information, that it is impossible to “wow” anyone at this meeting. Probably both are true.
With regard to retinal disease, my particular specialty, there is little new, but lots to be excited about.
Avastin and Lucentis continue to be the mainstays of treatment for wet macular degeneration. There is evidence that the two drugs are similar in clinical efficacy…a notion I support. It is likely that these types of drugs will be delivered with a sustained release system, thus, obviating the need for repeated intraocular injections.
Ozurdex is now indicated for the treatment of uveitis. It was originally FDA approved for the treatment of RVO only. By itself, not earth-shattering, but does make sense clinically. Sustained release steroids for chronic intraocular inflammation. Sounds much better.
The highlight of the meeting is the potential for Iluvien to be FDA approved soon. Iluvien is similar to Ozurdex in that both are injectable intraocular sustained release systems. Iluvien will be a sustained release system that delivers intraocular steroids for the treatment of diabetic macular edema. While this is a particularly promising development for patients with diabetic retinopathy, this has larger implications for eye treatment overall.
What Does This Mean? Illuvien is likely to be the second FDA approved intraocular drug delivery system. This will be a significant endorsement of drug delivery to the eye. We are entering a new era of pharmaceutical therapeutics; sustained release inside the eye. For now, we are focused on retinal disease. But soon, very soon, devices will emerge promising better therapeutics for almost any eye condition.
Just think, glaucoma may be treated by such a device.
Many of us just returned from the largest ophthalmic “trade show” in the world. The American Academy of Ophthalmology convened in Chicago last week. This meeting was combined with the Middle East Africa Council of Ophthalmology (MEACO). Perhaps 40 K attended the meeting.
I also attended the 2 day retinal subspecialty meeting which preceded the larger AAO meeting. Thus, I had 5 days to expand my knowledge.
Most of the congress was focused on technology, especially electronic medical records. Few discoveries were revealed. This may be for two reasons: there is nothing really new going on right now, and/or, the Internet allows such rapid sharing of information, that it is impossible to “wow” anyone at this meeting. Probably both are true.
With regard to retinal disease, my particular specialty, there is little new, but lots to be excited about.
Avastin and Lucentis continue to be the mainstays of treatment for wet macular degeneration. There is evidence that the two drugs are similar in clinical efficacy…a notion I support. It is likely that these types of drugs will be delivered with a sustained release system, thus, obviating the need for repeated intraocular injections.
Ozurdex is now indicated for the treatment of uveitis. It was originally FDA approved for the treatment of RVO only. By itself, not earth-shattering, but does make sense clinically. Sustained release steroids for chronic intraocular inflammation. Sounds much better.
The highlight of the meeting is the potential for Iluvien to be FDA approved soon. Iluvien is similar to Ozurdex in that both are injectable intraocular sustained release systems. Iluvien will be a sustained release system that delivers intraocular steroids for the treatment of diabetic macular edema. While this is a particularly promising development for patients with diabetic retinopathy, this has larger implications for eye treatment overall.
What Does This Mean? Illuvien is likely to be the second FDA approved intraocular drug delivery system. This will be a significant endorsement of drug delivery to the eye. We are entering a new era of pharmaceutical therapeutics; sustained release inside the eye. For now, we are focused on retinal disease. But soon, very soon, devices will emerge promising better therapeutics for almost any eye condition.
Just think, glaucoma may be treated by such a device.
Saturday, October 23, 2010
Novartis therapy Lucentis recommended for approval in EU to treat Diabetic Macular Edema
By Thomas Reuters
- CHMP positive opinion supports Lucentis approval in EU for treatment in patients with visual impairment due to diabetic macular edema (DME)
- Pivotal data shows Lucentis provided rapid, superior and sustained vision gains compared to the current standard of care
- Diabetes-associated eye diseases such as DME are a leading cause of blindness in most developed countries in the working-age population
Basel, October 22, 2010 - Novartis has received a positive opinion from the Committee for Medicinal Products for Human Use (CHMP) for Lucentis(R) (ranibizumab) for the treatment of patients with visual impairment due to diabetic macular edema (DME), a leading cause of blindness in the working-age population in most developed countries.
"Lucentis was designed specifically for use in the eye, and its efficacy and safety have now been demonstrated in patients suffering loss of vision due to diabetic macular edema through a robust program of clinical trials," said David Epstein, Division Head of Novartis Pharmaceuticals.
The submission was supported by data from two Novartis-funded clinical trials, RESTORE and RESOLVE, which showed that Lucentis was superior in providing rapid and sustained visual acuity gain versus sham (dummy therapy) or laser therapy, the current standard of care. The RESTORE study showed patients treated with Lucentis alone or with Lucentis plus laser therapy achieved an average 5.9 letters and 5.5 letters gain in visual acuity at 12 months, respectively, compared to laser-treated patients as measured on a standard ETDRS eye chart.
The RESOLVE study showed that Lucentis-treated patients achieved an average 11.7 letters gain in visual acuity at 12 months compared to sham-treated patients, some of whom received laser treatment.
The pivotal data from RESTORE and RESOLVE are further supported by results of an independent US study conducted by the Diabetic Retinopathy Clinical Research Network (DRCR.net), showing that at one year nearly 50% of patients' eyes treated with Lucentis and laser therapy improved their visual acuity by 10 letters or more, compared to 28% with laser alone. In addition, the study demonstrated superior gains in visual acuity among Lucentis-treated patients up to two years.
Lucentis was generally well tolerated in clinical studies, either when given as monotherapy or when combined with laser treatment. Its safety profile was consistent with that previously reported in large controlled clinical trials, and in rigorous monitoring since Lucentis was first approved for wet age-related macular degeneration (AMD). Lucentis is currently licensed in more than 85 countries for the treatment of wet AMD.
Diabetic macular edema (DME) is a consequence of diabetic retinopathy - the most common diabetic eye complication, characterized by changes in the blood vessels of the retina - to the light-sensitive layer at the back of the eye. In patients with DME, leakage from these abnormal blood vessels occurs in the central portion of the retina, called the macula. Because this part of the eye is responsible for sharp central vision, DME can lead to significant visual impairment. Visual impairment due to DME affects approximately 1-3% of patients with diabetes, and DME is a leading cause of blindness in the working-age population in most developed countries.
Lucentis offers an entirely new pharmacological approach to treatment compared to the current standard of care for DME that involves the use of laser burns to stop the capillary leakage and to reduce swelling. Lucentis is an antibody fragment that is injected into the eye and acts by neutralizing vascular endothelial growth factor (VEGF), a protein that is known to increase vascular permeability, resulting in capillary leakage and macular edema in patients with diabetes.
Lucentis was developed by Genentech and Novartis. Genentech has the commercial rights to Lucentis in the United States where Lucentis is also approved for the treatment of macular edema following retinal vein occlusion (RVO). In addition, Genentech is conducting two Phase III studies, RISE and RIDE, in patients with diabetic macular edema. The results are expected in 2011. Novartis has exclusive rights in the rest of the world and plans to file in the European Union for approval of Lucentis for the treatment of visual impairment due to macular edema following RVO.
Disclaimer
The foregoing release contains forward-looking statements that can be identified by terminology such as "recommended," "plans," or similar expressions, or by express or implied discussions regarding potential new indications or labeling for Lucentis or regarding potential future revenues from Lucentis. You should not place undue reliance on these statements. Such forward-looking statements reflect the current views of management regarding future events, and involve known and unknown risks, uncertainties and other factors that may cause actual results with Lucentis to be materially different from any future results, performance or achievements expressed or implied by such statements. There can be no guarantee that Lucentis will be submitted or approved for any additional indications or labeling in any market. Nor can there be any guarantee that Lucentis will achieve any particular levels of revenue in the future. In particular, management's expectations regarding Lucentis could be affected by, among other things, unexpected clinical trial results, including unexpected new clinical data and unexpected additional analysis of existing clinical data; unexpected regulatory actions or delays or government regulation generally; competition in general; government, industry and general public pricing pressures; the company's ability to obtain or maintain patent or other proprietary intellectual property protection; the impact that the foregoing factors could have on the values attributed to the Novartis Group's assets and liabilities as recorded in the Group's consolidated balance sheet, and other risks and factors referred to in Novartis AG's current Form 20-F on file with the US Securities and Exchange Commission. Should one or more of these risks or uncertainties materialize, or should underlying assumptions prove incorrect, actual results may vary materially from those anticipated, believed, estimated or expected. Novartis is providing the information in this press release as of this date and does not undertake any obligation to update any forward-looking statements contained in this press release as a result of new information, future events or otherwise.
- CHMP positive opinion supports Lucentis approval in EU for treatment in patients with visual impairment due to diabetic macular edema (DME)
- Pivotal data shows Lucentis provided rapid, superior and sustained vision gains compared to the current standard of care
- Diabetes-associated eye diseases such as DME are a leading cause of blindness in most developed countries in the working-age population
Basel, October 22, 2010 - Novartis has received a positive opinion from the Committee for Medicinal Products for Human Use (CHMP) for Lucentis(R) (ranibizumab) for the treatment of patients with visual impairment due to diabetic macular edema (DME), a leading cause of blindness in the working-age population in most developed countries.
"Lucentis was designed specifically for use in the eye, and its efficacy and safety have now been demonstrated in patients suffering loss of vision due to diabetic macular edema through a robust program of clinical trials," said David Epstein, Division Head of Novartis Pharmaceuticals.
The submission was supported by data from two Novartis-funded clinical trials, RESTORE and RESOLVE, which showed that Lucentis was superior in providing rapid and sustained visual acuity gain versus sham (dummy therapy) or laser therapy, the current standard of care. The RESTORE study showed patients treated with Lucentis alone or with Lucentis plus laser therapy achieved an average 5.9 letters and 5.5 letters gain in visual acuity at 12 months, respectively, compared to laser-treated patients as measured on a standard ETDRS eye chart.
The RESOLVE study showed that Lucentis-treated patients achieved an average 11.7 letters gain in visual acuity at 12 months compared to sham-treated patients, some of whom received laser treatment.
The pivotal data from RESTORE and RESOLVE are further supported by results of an independent US study conducted by the Diabetic Retinopathy Clinical Research Network (DRCR.net), showing that at one year nearly 50% of patients' eyes treated with Lucentis and laser therapy improved their visual acuity by 10 letters or more, compared to 28% with laser alone. In addition, the study demonstrated superior gains in visual acuity among Lucentis-treated patients up to two years.
Lucentis was generally well tolerated in clinical studies, either when given as monotherapy or when combined with laser treatment. Its safety profile was consistent with that previously reported in large controlled clinical trials, and in rigorous monitoring since Lucentis was first approved for wet age-related macular degeneration (AMD). Lucentis is currently licensed in more than 85 countries for the treatment of wet AMD.
Diabetic macular edema (DME) is a consequence of diabetic retinopathy - the most common diabetic eye complication, characterized by changes in the blood vessels of the retina - to the light-sensitive layer at the back of the eye. In patients with DME, leakage from these abnormal blood vessels occurs in the central portion of the retina, called the macula. Because this part of the eye is responsible for sharp central vision, DME can lead to significant visual impairment. Visual impairment due to DME affects approximately 1-3% of patients with diabetes, and DME is a leading cause of blindness in the working-age population in most developed countries.
Lucentis offers an entirely new pharmacological approach to treatment compared to the current standard of care for DME that involves the use of laser burns to stop the capillary leakage and to reduce swelling. Lucentis is an antibody fragment that is injected into the eye and acts by neutralizing vascular endothelial growth factor (VEGF), a protein that is known to increase vascular permeability, resulting in capillary leakage and macular edema in patients with diabetes.
Lucentis was developed by Genentech and Novartis. Genentech has the commercial rights to Lucentis in the United States where Lucentis is also approved for the treatment of macular edema following retinal vein occlusion (RVO). In addition, Genentech is conducting two Phase III studies, RISE and RIDE, in patients with diabetic macular edema. The results are expected in 2011. Novartis has exclusive rights in the rest of the world and plans to file in the European Union for approval of Lucentis for the treatment of visual impairment due to macular edema following RVO.
Disclaimer
The foregoing release contains forward-looking statements that can be identified by terminology such as "recommended," "plans," or similar expressions, or by express or implied discussions regarding potential new indications or labeling for Lucentis or regarding potential future revenues from Lucentis. You should not place undue reliance on these statements. Such forward-looking statements reflect the current views of management regarding future events, and involve known and unknown risks, uncertainties and other factors that may cause actual results with Lucentis to be materially different from any future results, performance or achievements expressed or implied by such statements. There can be no guarantee that Lucentis will be submitted or approved for any additional indications or labeling in any market. Nor can there be any guarantee that Lucentis will achieve any particular levels of revenue in the future. In particular, management's expectations regarding Lucentis could be affected by, among other things, unexpected clinical trial results, including unexpected new clinical data and unexpected additional analysis of existing clinical data; unexpected regulatory actions or delays or government regulation generally; competition in general; government, industry and general public pricing pressures; the company's ability to obtain or maintain patent or other proprietary intellectual property protection; the impact that the foregoing factors could have on the values attributed to the Novartis Group's assets and liabilities as recorded in the Group's consolidated balance sheet, and other risks and factors referred to in Novartis AG's current Form 20-F on file with the US Securities and Exchange Commission. Should one or more of these risks or uncertainties materialize, or should underlying assumptions prove incorrect, actual results may vary materially from those anticipated, believed, estimated or expected. Novartis is providing the information in this press release as of this date and does not undertake any obligation to update any forward-looking statements contained in this press release as a result of new information, future events or otherwise.
Sunday, October 17, 2010
Complement inhibition may be the future of dry AMD therapy
CHICAGO — Ongoing clinical trials exploring the use of complement inhibitors for treating nonexudative age-related macular degeneration offer promise for a disease state that has long been considered difficult to treat.
A number of recent studies have implicated the complement immune system in AMD. However, nonexudative AMD remains a "uniquely human disease," and, therefore, no animal model exists in which to prove potential therapeutic strategies, Philip J. Rosenfeld, MD, PhD, said here are Retina Subspecialty day preceding the joint meeting of the American Academy of Ophthalmology and the Middle East Africa Council of Ophthalmology.
As a result, Dr. Rosenfeld said, human trials will prove important in determining whether complement inhibition is of any real clinical benefit.
Several such trials are already underway. Alcon is currently investigating its POT-4 (AL-78898A) anti-C3 cyclic peptide in human trials. There is some evidence that POT-4 may also affect VEGF expression in the retina, Dr. Rosenfeld said.
Separately, Genetech/Roche has an anti-factor D (FCFD4514S) that inhibits the C3 and C5 alternative pathway convertases. Phase 1 studies have been successfully completed with that agent, Dr. Rosenfeld said.
Two separate C5 inhibitors are being studied: Eculizumab/Sollris (Alexion) and ARC1905, an anti-C5 aptamer (Ophthotech).
"One of the advantages is that while you block the downstream activated species, you preserve the more proximal species that are important for the clearance of bacteria, particularly the encapsulated organisms," Dr. Rosenfeld said.
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A number of recent studies have implicated the complement immune system in AMD. However, nonexudative AMD remains a "uniquely human disease," and, therefore, no animal model exists in which to prove potential therapeutic strategies, Philip J. Rosenfeld, MD, PhD, said here are Retina Subspecialty day preceding the joint meeting of the American Academy of Ophthalmology and the Middle East Africa Council of Ophthalmology.
As a result, Dr. Rosenfeld said, human trials will prove important in determining whether complement inhibition is of any real clinical benefit.
Several such trials are already underway. Alcon is currently investigating its POT-4 (AL-78898A) anti-C3 cyclic peptide in human trials. There is some evidence that POT-4 may also affect VEGF expression in the retina, Dr. Rosenfeld said.
Separately, Genetech/Roche has an anti-factor D (FCFD4514S) that inhibits the C3 and C5 alternative pathway convertases. Phase 1 studies have been successfully completed with that agent, Dr. Rosenfeld said.
Two separate C5 inhibitors are being studied: Eculizumab/Sollris (Alexion) and ARC1905, an anti-C5 aptamer (Ophthotech).
"One of the advantages is that while you block the downstream activated species, you preserve the more proximal species that are important for the clearance of bacteria, particularly the encapsulated organisms," Dr. Rosenfeld said.
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Sunday, October 10, 2010
Angiogenesis Discovery Points to Novel Therapy for Multiple Diseases
Tatiana Byzova, PhD, a faculty member in Lerner Research Institute's Department of Molecular Cardiology and Director of the Center for Angiogenesis Research, and colleagues have discovered a fundamental biological pathway in angiogenesis (formation of blood vessels), published online October 3, 2010 in Nature (DOI: 10.1038/nature09421). The significance of this discovery is summarized by Dr. Byzova, in that "it affects many biological processes - from wound healing to aging."
Some pathologies included in that spectrum are age-related macular degeneration, atherosclerosis, and rheumatoid arthritis, while their published data indicate a particularly notable role in cancer. The results of this advanced understanding point to an exciting new approach for novel therapies.
In 1989, a protein called vascular endothelial growth factor (VEGF) was identified as a trigger of angiogenesis. This discovery led Genentech to develop the first effective treatment for macular degeneration; related work contributed to the development of a drug to block VEGF function in cancer, essentially starving the tumor of the nutrients the blood would otherwise bring.
However, although many tumors respond to anti-VEGF treatment, most develop resistance to the therapy and continue to survive over time. One possible explanation is that VEGF is not the only trigger leading to angiogenesis. This is precisely what Dr. Byzova's team has found.
Dr. Byzova's research has identified a class of oxidized lipids that are abundantly present in highly vasculated tumors. Further interrogation parsed out the process through which these products induce new blood vessel formation. It appears that cells use a family of receptors previously known to recognize foreign products such as bacteria to sense and respond to the danger of oxidation. The results point to a novel therapy that may well be an alternate way to starve the tumors that have managed to survive despite VEGF inhibition. Through uncovering a potential way to get around tumor resistance to VEGF, Dr. Byzova's group has opened up new doors for developing treatments for cancer. The fundamental discovery also provides substantial insight for novel treatments for other diseases that involve inflammation, oxidative stress, and angiogenesis.
Overall, this foundational discovery of a novel mechanism of angiogenesis comes just one year after Dr. Byzova headed a study that pioneered the identification of a new genetic-based human disease, published in Nature Medicine.
Some pathologies included in that spectrum are age-related macular degeneration, atherosclerosis, and rheumatoid arthritis, while their published data indicate a particularly notable role in cancer. The results of this advanced understanding point to an exciting new approach for novel therapies.
In 1989, a protein called vascular endothelial growth factor (VEGF) was identified as a trigger of angiogenesis. This discovery led Genentech to develop the first effective treatment for macular degeneration; related work contributed to the development of a drug to block VEGF function in cancer, essentially starving the tumor of the nutrients the blood would otherwise bring.
However, although many tumors respond to anti-VEGF treatment, most develop resistance to the therapy and continue to survive over time. One possible explanation is that VEGF is not the only trigger leading to angiogenesis. This is precisely what Dr. Byzova's team has found.
Dr. Byzova's research has identified a class of oxidized lipids that are abundantly present in highly vasculated tumors. Further interrogation parsed out the process through which these products induce new blood vessel formation. It appears that cells use a family of receptors previously known to recognize foreign products such as bacteria to sense and respond to the danger of oxidation. The results point to a novel therapy that may well be an alternate way to starve the tumors that have managed to survive despite VEGF inhibition. Through uncovering a potential way to get around tumor resistance to VEGF, Dr. Byzova's group has opened up new doors for developing treatments for cancer. The fundamental discovery also provides substantial insight for novel treatments for other diseases that involve inflammation, oxidative stress, and angiogenesis.
Overall, this foundational discovery of a novel mechanism of angiogenesis comes just one year after Dr. Byzova headed a study that pioneered the identification of a new genetic-based human disease, published in Nature Medicine.
Monday, October 4, 2010
Retinal Degeneration Can be Prevented with Nanotechnology Gene Therapy
Friday, 01 October 2010
Researchers from Tufts University published results from a study showing vision-saving gene therapy to the eyes can be delivered via nanotechnology. A protein called Glial Cell Line-Derived Neurtrophic Factor (GDNF) can protect the eyes from diseases of the retina, such as and retinitis pigmentosa.
The previous method for delivering genetic material with a virus had several problems and side effects. Although the study is in its infancy, and the results are temporary, mice injected with the GDNF carrying nanoparticle had a 3.9 to 7.7-fold reduction in damage to the retina. Seven days after treatment, the GDNF-nanoparticle treated mice had up to 39% better eyesight than mice in the control group.
Two weeks after the treatment, GDNF-nanoparticle-injected mice had nuclear layers of the retina that were almost 24 to over 39 percent thicker than control mice. However, after 14 days, these advantages seem to have vanished. According to Dr. Brett Katzen, "The idea of using gene therapy to help cure - or at least improve - the eyesight of patients with macular degeneration should be exciting to eye doctors everywhere. This is a great first step." The research shows an incredible potential for nanotechnology to develop an effective carrier for delivering gene therapy.
This therapy can then lead to a new generation of treatments for retinal diseases. Age-related macular degeneration is the leading cause of blindness in Americans over the age of 65.
Researchers from Tufts University published results from a study showing vision-saving gene therapy to the eyes can be delivered via nanotechnology. A protein called Glial Cell Line-Derived Neurtrophic Factor (GDNF) can protect the eyes from diseases of the retina, such as and retinitis pigmentosa.
The previous method for delivering genetic material with a virus had several problems and side effects. Although the study is in its infancy, and the results are temporary, mice injected with the GDNF carrying nanoparticle had a 3.9 to 7.7-fold reduction in damage to the retina. Seven days after treatment, the GDNF-nanoparticle treated mice had up to 39% better eyesight than mice in the control group.
Two weeks after the treatment, GDNF-nanoparticle-injected mice had nuclear layers of the retina that were almost 24 to over 39 percent thicker than control mice. However, after 14 days, these advantages seem to have vanished. According to Dr. Brett Katzen, "The idea of using gene therapy to help cure - or at least improve - the eyesight of patients with macular degeneration should be exciting to eye doctors everywhere. This is a great first step." The research shows an incredible potential for nanotechnology to develop an effective carrier for delivering gene therapy.
This therapy can then lead to a new generation of treatments for retinal diseases. Age-related macular degeneration is the leading cause of blindness in Americans over the age of 65.
Saturday, September 18, 2010
Glaucoma eye drops showing some effect against Macular Degeneration
by Dr. Edward Paul
Eye redness was the clue that something was happening to Celia Ramirez's vision. Although she wasn't having trouble driving or doing other tasks, her children urged her to have a checkup. It turned out she was in the early stages of age-related macular degeneration (AMD), a disease that attacks a person's central field of vision.
Mrs. Ramirez, who lives in the Rio Grande Valley, had surgery that successfully controlled her eye pressure, but her central vision continued to degrade.Eye specialist William Sponsel, Ph.D., associate professor and director of research at the Department of Ophthalmology at the University of Texas Health Science Center at San Antonio (UTHSC).Found a treatment with a new combination of drugs.
The miracle is the carbon dioxide, which is crucial for vision. The healthy eye produces enough carbon dioxide to dilate blood vessels around the retina and maintain proper blood flow. The ailing eye does not produce enough. This holds important implications for the treatment of patients with blinding eye diseases such as AMD and glaucoma, which are marked by diminished circulation of blood in the back of the eye. Eye pressure also is a conventional barometer of eye health.
About 60 of 65 patients have seen their vision improve while receiving treatment at UTHSC's teaching hospital, University Hospital. "The patients are receiving combination drug therapy, including agents that trick the eye into retaining more of its carbon dioxide," Dr. Sponsel said. "We have patients with glaucoma and no AMD, patients with AMD and no glaucoma, and patients with both disorders. All appear to demonstrate benefit in the central visual area, regardless of the cause of that visual loss."
The Health Science Center is the first medical center to initiate this combination therapy for patients with central visual loss, Dr. Sponsel said. Considerable research yielded the conclusions that now help patients. "You don't expect these patients to get better, you expect them to get worse," he said. "We have seen dramatic results that bode well for treatment of these disorders in the future."
The researchers measure patients' sensitivity to light on visual function tests. An increase of 10 points represents more than a million-fold increase in actual visual acuity. Mrs. Ramirez's vision in the macula -- the central visual area that enables perception of letters and colors -- was scored as virtually zero on early tests. After the recent treatment, her score is now 24.
The miracle agents are called "carbonic anhydrase inhibitors" (CAI's). Given as eye drops, CAI's reach the back of the eye rapidly and slow the clearance of carbon dioxide while increasing the supply of nutrients. They help dilate blood vessels within and behind the retina, which is the structure that receives, processes and transmits visual images relayed from the brain.
Dr. Sponsel pursued this line of research in an intriguing way -- after discovering that adults who hyperventilated and rapidly blew off their body's carbon dioxide showed decreased vision, eye pressure and circulation in the back of the eye. He was treating subjects one week with a CAI called dorzolamide and the next week with placebo eye drops. During hyperventilation, the subjects on dorzolamide maintained good light sensitivity in their central field of vision, while the same subjects during placebo treatment showed central visual loss. Dr. Sponsel holds two U.S. patents on this work. One valuable aspect of the research is that it proves increased eye pressure is not necessarily the definitive indicator of eye vessel disease.
Eye redness was the clue that something was happening to Celia Ramirez's vision. Although she wasn't having trouble driving or doing other tasks, her children urged her to have a checkup. It turned out she was in the early stages of age-related macular degeneration (AMD), a disease that attacks a person's central field of vision.
Mrs. Ramirez, who lives in the Rio Grande Valley, had surgery that successfully controlled her eye pressure, but her central vision continued to degrade.Eye specialist William Sponsel, Ph.D., associate professor and director of research at the Department of Ophthalmology at the University of Texas Health Science Center at San Antonio (UTHSC).Found a treatment with a new combination of drugs.
The miracle is the carbon dioxide, which is crucial for vision. The healthy eye produces enough carbon dioxide to dilate blood vessels around the retina and maintain proper blood flow. The ailing eye does not produce enough. This holds important implications for the treatment of patients with blinding eye diseases such as AMD and glaucoma, which are marked by diminished circulation of blood in the back of the eye. Eye pressure also is a conventional barometer of eye health.
About 60 of 65 patients have seen their vision improve while receiving treatment at UTHSC's teaching hospital, University Hospital. "The patients are receiving combination drug therapy, including agents that trick the eye into retaining more of its carbon dioxide," Dr. Sponsel said. "We have patients with glaucoma and no AMD, patients with AMD and no glaucoma, and patients with both disorders. All appear to demonstrate benefit in the central visual area, regardless of the cause of that visual loss."
The Health Science Center is the first medical center to initiate this combination therapy for patients with central visual loss, Dr. Sponsel said. Considerable research yielded the conclusions that now help patients. "You don't expect these patients to get better, you expect them to get worse," he said. "We have seen dramatic results that bode well for treatment of these disorders in the future."
The researchers measure patients' sensitivity to light on visual function tests. An increase of 10 points represents more than a million-fold increase in actual visual acuity. Mrs. Ramirez's vision in the macula -- the central visual area that enables perception of letters and colors -- was scored as virtually zero on early tests. After the recent treatment, her score is now 24.
The miracle agents are called "carbonic anhydrase inhibitors" (CAI's). Given as eye drops, CAI's reach the back of the eye rapidly and slow the clearance of carbon dioxide while increasing the supply of nutrients. They help dilate blood vessels within and behind the retina, which is the structure that receives, processes and transmits visual images relayed from the brain.
Dr. Sponsel pursued this line of research in an intriguing way -- after discovering that adults who hyperventilated and rapidly blew off their body's carbon dioxide showed decreased vision, eye pressure and circulation in the back of the eye. He was treating subjects one week with a CAI called dorzolamide and the next week with placebo eye drops. During hyperventilation, the subjects on dorzolamide maintained good light sensitivity in their central field of vision, while the same subjects during placebo treatment showed central visual loss. Dr. Sponsel holds two U.S. patents on this work. One valuable aspect of the research is that it proves increased eye pressure is not necessarily the definitive indicator of eye vessel disease.
Wednesday, August 4, 2010
Visudyne therapy
Age-related macular degeneration (AMD) is a progressive disease of the eye, meaning that it can’t be cured. The good news is that AMD can be controlled. Treatments available today can slow the vision loss associated with AMD and even restore some vision.
Wet and dry age-related macular degeneration (AMD) differ in several important respects, including treatment options. The only way to find out which AMD treatment regimen or management plan is right for you is to talk to your ophthalmologist or retinal specialist.
Visudyne therapy treats a form of AMD called predominantly classic subfoveal CNV due to AMD.
In this form of AMD, abnormal blood vessels leak fluid and/or blood under the macula—the part of the eye responsible for central vision—causing serious vision loss. During therapy, Visudyne is injected into the patient (generally through the arm). Next, light from a low-energy laser activates Visudyne, causing it to destroy the leaky vessels. As a part of a wet AMD treatment regimen, Visudyne therapy may help slow its progression.
Ask your ophthalmologist or retinal specialist if Visudyne therapy may be right for you.
Other treatment options
Anti-VEGF (anti-vascular endothelial growth factor) treatments block the formation of new abnormal blood vessels
Wet and dry age-related macular degeneration (AMD) differ in several important respects, including treatment options. The only way to find out which AMD treatment regimen or management plan is right for you is to talk to your ophthalmologist or retinal specialist.
Visudyne therapy treats a form of AMD called predominantly classic subfoveal CNV due to AMD.
In this form of AMD, abnormal blood vessels leak fluid and/or blood under the macula—the part of the eye responsible for central vision—causing serious vision loss. During therapy, Visudyne is injected into the patient (generally through the arm). Next, light from a low-energy laser activates Visudyne, causing it to destroy the leaky vessels. As a part of a wet AMD treatment regimen, Visudyne therapy may help slow its progression.
Ask your ophthalmologist or retinal specialist if Visudyne therapy may be right for you.
Other treatment options
Anti-VEGF (anti-vascular endothelial growth factor) treatments block the formation of new abnormal blood vessels
Tuesday, July 27, 2010
Medicine from Moss to produce human protien
Diabetics use human insulin produced in bacteria in order to treat their metabolic disorder. Many other genetically engineered proteins are also on the advance. They are being used for diagnosis as well as for therapy.
Whereas insulin used to be extracted from slaughterhouse waste, today it is produced genetically in bacteria. However, more complex proteins have to be synthesised in more complex organisms. This takes place mostly in bioreactors using animal cell lines. Biotechnologist Prof. Ralf Reski from Freiburg, Germany, has developed the moss Physcomitrella patens into a safe and inexpensive alternative supplier of medicine.
His group has now, under Dr. Eva Decker, for the first time succeeded in producing a human protein in a moss bioreactor, which has been assigned the "orphan drug" status by the respective EU authorities. This means the development and approval of such medication receive particular support from the authorities. In many people the amount of this protein decreases with old age - with severe consequences. Eva Decker explains: "With the complement factor H we have produced a protein in moss that otherwise occurs only in blood and is important for the immune system. Not enough of this protein in older people is the main cause of blindness for 50 million people worldwide. This age-related macular degeneration (AMD) is a problem, particularly in industrialised countries."
Biochemists from the Freiburg Centre for Systems Biology under Dr. Andreas Schlosser were able to show with the help of high-performance mass spectrometers that the human factor H engineered into and produced by moss was a complete protein. Infection biologists headed by Prof. Peter F. Zipfel from the Hans-Knöll-Institute in Jena, Germany, were able to prove in biological assays that factor H from moss is fully functional. "Currently factor H is not available in pharmacies, so treatment for AMD with this protein is not possible. To date recombinant production of factor H was barely feasible. I am convinced that for the first time the moss bioreactor is a promising option", says Peter Zipfel.
This work was supported by the German Federal Ministry of Education and Research (BMBF), the Freiburg Initiative for Systems Biology and the Cluster of Excellence BIOSS.
Dr. Annette Büttner-Mainik, first author of the publication, was a Kekulé scholarship holder from the endowment fund of the German Chemical Industry (FCI).
The title of the original publication is: Annette Büttner-Mainik, Juliana Parsons, Hanna Jérôme, Andrea Hartmann, Stephanie Lamer, Andreas Schaaf, Andreas Schlosser, Peter F. Zipfel, Ralf Reski, Eva L. Decker (2010): Production of biologically active recombinant human Factor H in Physcomitrella. Plant Biotechnology Journal, doi: 10.1111/j.1467-7652.2010.00552.x.
"It will take a while before medication produced in moss is available in pharmacies", says Ralf Reski, member of the Innovation Think Tank of the governor of Baden-Wuerttemberg. "We are further optimising the moss bioreactor using methods from Systems Biology and Synthetic Biology. However, the implementation of clinical studies and the setting up of industrial production is long-winded and expensive; this is the task of industry and not of university research."
Whereas insulin used to be extracted from slaughterhouse waste, today it is produced genetically in bacteria. However, more complex proteins have to be synthesised in more complex organisms. This takes place mostly in bioreactors using animal cell lines. Biotechnologist Prof. Ralf Reski from Freiburg, Germany, has developed the moss Physcomitrella patens into a safe and inexpensive alternative supplier of medicine.
His group has now, under Dr. Eva Decker, for the first time succeeded in producing a human protein in a moss bioreactor, which has been assigned the "orphan drug" status by the respective EU authorities. This means the development and approval of such medication receive particular support from the authorities. In many people the amount of this protein decreases with old age - with severe consequences. Eva Decker explains: "With the complement factor H we have produced a protein in moss that otherwise occurs only in blood and is important for the immune system. Not enough of this protein in older people is the main cause of blindness for 50 million people worldwide. This age-related macular degeneration (AMD) is a problem, particularly in industrialised countries."
Biochemists from the Freiburg Centre for Systems Biology under Dr. Andreas Schlosser were able to show with the help of high-performance mass spectrometers that the human factor H engineered into and produced by moss was a complete protein. Infection biologists headed by Prof. Peter F. Zipfel from the Hans-Knöll-Institute in Jena, Germany, were able to prove in biological assays that factor H from moss is fully functional. "Currently factor H is not available in pharmacies, so treatment for AMD with this protein is not possible. To date recombinant production of factor H was barely feasible. I am convinced that for the first time the moss bioreactor is a promising option", says Peter Zipfel.
This work was supported by the German Federal Ministry of Education and Research (BMBF), the Freiburg Initiative for Systems Biology and the Cluster of Excellence BIOSS.
Dr. Annette Büttner-Mainik, first author of the publication, was a Kekulé scholarship holder from the endowment fund of the German Chemical Industry (FCI).
The title of the original publication is: Annette Büttner-Mainik, Juliana Parsons, Hanna Jérôme, Andrea Hartmann, Stephanie Lamer, Andreas Schaaf, Andreas Schlosser, Peter F. Zipfel, Ralf Reski, Eva L. Decker (2010): Production of biologically active recombinant human Factor H in Physcomitrella. Plant Biotechnology Journal, doi: 10.1111/j.1467-7652.2010.00552.x.
"It will take a while before medication produced in moss is available in pharmacies", says Ralf Reski, member of the Innovation Think Tank of the governor of Baden-Wuerttemberg. "We are further optimising the moss bioreactor using methods from Systems Biology and Synthetic Biology. However, the implementation of clinical studies and the setting up of industrial production is long-winded and expensive; this is the task of industry and not of university research."
Tuesday, July 20, 2010
Stem Cell Transplants Stalled Blindness in Rats
Researchers say putting nerve stem cells from StemCells Inc near the retinas of rats with a form of macular degeneration helped keep the disease from advancing to blindness for several months.Nerve stem cell transplants may help slow the progression of macular degeneration, the most common cause of blindness in the developed world, U.S. researchers said on Monday.
They said putting nerve stem cells from StemCells Inc near the retinas of rats with a form of macular degeneration helped keep the disease from advancing to blindness for several months.
"These cells improve the chemical environment in the back of the eye," said Ray Lund of the Casey Eye Institute at Oregon Health & Science University in Portland, whose findings were presented at the Society for Neuroscience meeting in Chicago.
Lund said the mechanism is not clear, but he suspects that when immature nerve cells are placed near the retina, they produce growth factors that protect the cells from damage by the disease.
"It's basically a chemical pump that is sitting in the right place and producing the right things," Lund said in a telephone interview.
Where normally animals with eye disease lost their vision by three months old, rats that got the transplants kept their vision for at least seven months, he said.
"There is no evidence that they (the transplanted cells) do any damage," Lund said, adding that the animals do not develop tumors, a key worry for stem cell transplants.
The findings raise hope for use of the treatment in humans with a range of diseases in which the retina become damaged, including age-related macular degeneration or AMD, which affects nearly 30 million people worldwide, including 15 million Americans.
People with AMD lose central vision when delicate light-sensing cells of the macula, a region at the center of the retina, become damaged.
In the rats, the researchers transplanted immature nerve cells into the space near the retina. Lund said the same could be done in people with retinal disease.
Dr. Stephen Huhn, head of the Central Nervous System research program at StemCells Inc, said the cells are adult neural stem cells. He said they are multipotent, meaning they can morph into different types of nerve cells.
The company has already tested the treatment in a study of six patients with Batten's disease, a fatal inherited disorder of the nervous system.
"Having a cell that has already entered clinical testing that has been well tolerated at very high doses in the brain gives us a lot of confidence about exploring the same type of strategy in the eye," Huhn said.
Huhn said he thinks the cells may be especially well suited for use in the retina, brain and spinal cord, which are less likely to reject the cells than other parts of the body.
Ultimately, he said the hope is to develop a treatment for the dry form of macular degeneration, which affects around 90 percent of patients diagnosed with AMD. No treatments are available for this form of the disease.
Huhn said treating this form of the disease may prevent some people from developing wet AMD, in which tiny new blood vessels grow between the retina and the back of the eye.
This form of the disease can be treated with modern drugs like Lucentis, from Novartis and Roche's Genentech, and Pfizer's Macugen.
They said putting nerve stem cells from StemCells Inc near the retinas of rats with a form of macular degeneration helped keep the disease from advancing to blindness for several months.
"These cells improve the chemical environment in the back of the eye," said Ray Lund of the Casey Eye Institute at Oregon Health & Science University in Portland, whose findings were presented at the Society for Neuroscience meeting in Chicago.
Lund said the mechanism is not clear, but he suspects that when immature nerve cells are placed near the retina, they produce growth factors that protect the cells from damage by the disease.
"It's basically a chemical pump that is sitting in the right place and producing the right things," Lund said in a telephone interview.
Where normally animals with eye disease lost their vision by three months old, rats that got the transplants kept their vision for at least seven months, he said.
"There is no evidence that they (the transplanted cells) do any damage," Lund said, adding that the animals do not develop tumors, a key worry for stem cell transplants.
The findings raise hope for use of the treatment in humans with a range of diseases in which the retina become damaged, including age-related macular degeneration or AMD, which affects nearly 30 million people worldwide, including 15 million Americans.
People with AMD lose central vision when delicate light-sensing cells of the macula, a region at the center of the retina, become damaged.
In the rats, the researchers transplanted immature nerve cells into the space near the retina. Lund said the same could be done in people with retinal disease.
Dr. Stephen Huhn, head of the Central Nervous System research program at StemCells Inc, said the cells are adult neural stem cells. He said they are multipotent, meaning they can morph into different types of nerve cells.
The company has already tested the treatment in a study of six patients with Batten's disease, a fatal inherited disorder of the nervous system.
"Having a cell that has already entered clinical testing that has been well tolerated at very high doses in the brain gives us a lot of confidence about exploring the same type of strategy in the eye," Huhn said.
Huhn said he thinks the cells may be especially well suited for use in the retina, brain and spinal cord, which are less likely to reject the cells than other parts of the body.
Ultimately, he said the hope is to develop a treatment for the dry form of macular degeneration, which affects around 90 percent of patients diagnosed with AMD. No treatments are available for this form of the disease.
Huhn said treating this form of the disease may prevent some people from developing wet AMD, in which tiny new blood vessels grow between the retina and the back of the eye.
This form of the disease can be treated with modern drugs like Lucentis, from Novartis and Roche's Genentech, and Pfizer's Macugen.
Thursday, June 10, 2010
Ann Arbor Pharma Firm Testing Zinc For Alzheimer's Treatment
Ann Arbor-based Adeona Pharmaceuticals Inc. (AMEX: AEN) Monday announced the completion of 50 percnet enrollment in Part 2 of its clinical study, "A Prospective, Randomized, Double Blind Trial of a Novel Oral Zinc Cysteine Preparation in Alzheimer's Disease (CopperProof-2)."
The CopperProof-2 study represents the first controlled clinical study of oral zinc cysteine for the dietary management of Alzheimer's disease and mild cognitive impairment.
Part 2 of the CopperProof-2 study is designed as a 60-subject comparator study. Subjects are randomized on a 50:50 basis to receive either Zinthionein ZC or matching placebo. After 3 and 6 months on clinical trial material, serum measurements of zinc and copper are taken, and any changes in cognitive function using standard clinical tests used in Alzheimer's disease and mild cognitive impairment are recorded.
The completion of 50 percent enrollment follows Adeona's April 14 announcement of positive results from Part 1 of the CopperProof-2 study. Part 1 demonstrated a substantially lower incidence of adverse effects in Alzheimer's disease and mild cognitive impairment subjects (33 percent versus 100 percent) in favor of Zinthionein ZC (containing 150 mg of elemental zinc acetate and 100 mg of cysteine) compared to Galzin (containing either 50 mg or 100 mg of elemental zinc as zinc acetate).
Zinthionein ZC also demonstrated superior serum zinc bioavailability in Alzheimer's disease and mild cognitive impairment subjects compared to both the 50 mg and 100 mg dose levels of Galzin.
"Having pioneered the use of oral zinc therapy in dry age-related macular degeneration, which has now become the standard of care, I believe that Adeona's once-daily, high bioavailability, well-tolerated oral zinc cysteine formulation has the potential to ameliorate the sub-clinical zinc deficiency in Alzheimer's and mild cognitive impairment subjects and substantially grow current markets for oral zinc-based therapies," said David Newsome, M.D., Adeona's senior vice president for research and development.
Added Adeona CEO James S. Kuo, M.D.: "We are pleased to have reached this enrollment milestone on a timely basis and within budget. Along with the recently announced Meda collaboration for flupirtine's development and completion of 50 percent enrollment in the Trimesta multiple sclerosis clinical trial, it represents one of several major transformational changes taking place at the company in the past few months."
Observations by Adeona scientists and other scientists of sub-clinical zinc deficiency in Alzheimer's disease patients plus a body of published literature that chronic elevated copper exposure contributes to the progression of Alzheimer's disease and mild cognitive impairment prompted the present CopperProof-2 clinical study.
Alzheimer's disease can affect the entire brain but it is particularly associated with loss of tissue in the hippocampus, the area in the brain responsible for several functions including short-term memory retention and processing. The hippocampus has one of the highest concentrations of zinc in the brain. Hippocampal zinc is thought to play a role in hundreds of protective enzymes and other systems, including those that detoxify amyloid beta, an abnormally folded peptide that accumulates in aging and is a biomarker for Alzheimer's disease. When cerebrospinal fluid zinc is low, levels of the particularly toxic beta amyloid 42 are elevated.
Hippocampal zinc serves as a neurotransmitter, and also modulates a specific neuroreceptor. If the neuroexcitation goes uncontrolled, there is a derangement of brain tissue function, and possibly neuronal death. By elevating cerebrospinal fluid zinc, the receptor excitation may be better controlled, improving tissue function and thereby acute cognition and tissue survival, as may have been seen in the 1992 study. NMDA-receptor antagonists now available for Alzheimer's, including Namenda and Axura, annually sell an estimated $2.6 billion.
Zinthionein ZC is a once-daily, gastroretentive, sustained-release, oral tablet formulation of zinc and cysteine. Zinc, an essential nutrient, participates as a necessary factor in the activity of over 200 enzymes and the DNA binding capacity of over 400 nuclear regulatory elements. Zinc may also directly participate in antioxidant protection by reducing the susceptibility of sulfhydril groups to damage by oxidative free radicals. Cysteine is an amino acid that has potent anti-oxidant properties and is a necessary component of the copper-zinc-binding protein, metallothionein.
Zinthionein ZC was invented and developed by Adeona scientists to achieve the convenience of once-daily dosing, high oral bioavailability and to minimize gastrointestinal side effects associated with other commercially available, oral zinc products. All of Zinthionein ZC's constituents have GRAS (Generally Regarded as Safe) status. Adeona is developing Zinthionein ZC as a prescription medical food for the dietary management of Alzheimer's disease and mild cognitive impairment. Zinthionein ZC is protected by multiple U.S. and international pending patent applications held by Adeona.
Adeona is a pharmaceutical company developing new medicines for serious central nervous systems diseases. Adeona's primary strategy is to in-license clinical-stage drug candidates that have already demonstrated a certain level of clinical efficacy and develop them to an inflection point in valuation resulting in a significant development and marketing collaboration.
Its other drugs include Trimesta (estriol) is an investigational oral drug for the treatment of relapsing remitting multiple sclerosis, currently in clinical trials, and Effirma (flupirtine), a centrally-acting investigational oral drug for the treatment of fibromyalgia syndrome. Adeona has entered into a potential $17.5 million corporate partnership with Meda AB. As part of the agreement, Meda will assume all future development costs while Adeona is entitled to receive milestone payments and royalties.
The CopperProof-2 study represents the first controlled clinical study of oral zinc cysteine for the dietary management of Alzheimer's disease and mild cognitive impairment.
Part 2 of the CopperProof-2 study is designed as a 60-subject comparator study. Subjects are randomized on a 50:50 basis to receive either Zinthionein ZC or matching placebo. After 3 and 6 months on clinical trial material, serum measurements of zinc and copper are taken, and any changes in cognitive function using standard clinical tests used in Alzheimer's disease and mild cognitive impairment are recorded.
The completion of 50 percent enrollment follows Adeona's April 14 announcement of positive results from Part 1 of the CopperProof-2 study. Part 1 demonstrated a substantially lower incidence of adverse effects in Alzheimer's disease and mild cognitive impairment subjects (33 percent versus 100 percent) in favor of Zinthionein ZC (containing 150 mg of elemental zinc acetate and 100 mg of cysteine) compared to Galzin (containing either 50 mg or 100 mg of elemental zinc as zinc acetate).
Zinthionein ZC also demonstrated superior serum zinc bioavailability in Alzheimer's disease and mild cognitive impairment subjects compared to both the 50 mg and 100 mg dose levels of Galzin.
"Having pioneered the use of oral zinc therapy in dry age-related macular degeneration, which has now become the standard of care, I believe that Adeona's once-daily, high bioavailability, well-tolerated oral zinc cysteine formulation has the potential to ameliorate the sub-clinical zinc deficiency in Alzheimer's and mild cognitive impairment subjects and substantially grow current markets for oral zinc-based therapies," said David Newsome, M.D., Adeona's senior vice president for research and development.
Added Adeona CEO James S. Kuo, M.D.: "We are pleased to have reached this enrollment milestone on a timely basis and within budget. Along with the recently announced Meda collaboration for flupirtine's development and completion of 50 percent enrollment in the Trimesta multiple sclerosis clinical trial, it represents one of several major transformational changes taking place at the company in the past few months."
Observations by Adeona scientists and other scientists of sub-clinical zinc deficiency in Alzheimer's disease patients plus a body of published literature that chronic elevated copper exposure contributes to the progression of Alzheimer's disease and mild cognitive impairment prompted the present CopperProof-2 clinical study.
Alzheimer's disease can affect the entire brain but it is particularly associated with loss of tissue in the hippocampus, the area in the brain responsible for several functions including short-term memory retention and processing. The hippocampus has one of the highest concentrations of zinc in the brain. Hippocampal zinc is thought to play a role in hundreds of protective enzymes and other systems, including those that detoxify amyloid beta, an abnormally folded peptide that accumulates in aging and is a biomarker for Alzheimer's disease. When cerebrospinal fluid zinc is low, levels of the particularly toxic beta amyloid 42 are elevated.
Hippocampal zinc serves as a neurotransmitter, and also modulates a specific neuroreceptor. If the neuroexcitation goes uncontrolled, there is a derangement of brain tissue function, and possibly neuronal death. By elevating cerebrospinal fluid zinc, the receptor excitation may be better controlled, improving tissue function and thereby acute cognition and tissue survival, as may have been seen in the 1992 study. NMDA-receptor antagonists now available for Alzheimer's, including Namenda and Axura, annually sell an estimated $2.6 billion.
Zinthionein ZC is a once-daily, gastroretentive, sustained-release, oral tablet formulation of zinc and cysteine. Zinc, an essential nutrient, participates as a necessary factor in the activity of over 200 enzymes and the DNA binding capacity of over 400 nuclear regulatory elements. Zinc may also directly participate in antioxidant protection by reducing the susceptibility of sulfhydril groups to damage by oxidative free radicals. Cysteine is an amino acid that has potent anti-oxidant properties and is a necessary component of the copper-zinc-binding protein, metallothionein.
Zinthionein ZC was invented and developed by Adeona scientists to achieve the convenience of once-daily dosing, high oral bioavailability and to minimize gastrointestinal side effects associated with other commercially available, oral zinc products. All of Zinthionein ZC's constituents have GRAS (Generally Regarded as Safe) status. Adeona is developing Zinthionein ZC as a prescription medical food for the dietary management of Alzheimer's disease and mild cognitive impairment. Zinthionein ZC is protected by multiple U.S. and international pending patent applications held by Adeona.
Adeona is a pharmaceutical company developing new medicines for serious central nervous systems diseases. Adeona's primary strategy is to in-license clinical-stage drug candidates that have already demonstrated a certain level of clinical efficacy and develop them to an inflection point in valuation resulting in a significant development and marketing collaboration.
Its other drugs include Trimesta (estriol) is an investigational oral drug for the treatment of relapsing remitting multiple sclerosis, currently in clinical trials, and Effirma (flupirtine), a centrally-acting investigational oral drug for the treatment of fibromyalgia syndrome. Adeona has entered into a potential $17.5 million corporate partnership with Meda AB. As part of the agreement, Meda will assume all future development costs while Adeona is entitled to receive milestone payments and royalties.
Sunday, May 10, 2009
Foundation Fighting Blindness’ National Neurovision Research Institute Heralds Collaboration for Gene Therapy Advancements
Foundation Fighting Blindness’ National Neurovision Research Institute Heralds Collaboration for Gene Therapy Advancements
OWINGS MILLS, Md.--(BUSINESS WIRE)--The National Neurovision Research Institute (NNRI), the Foundation Fighting Blindness’ clinical trial support organization, announced today that one of its key partners, biopharmaceutical company Oxford BioMedica, has established a collaboration with sanofi-aventis, a major international pharmaceutical company, to develop and commercialize gene therapy treatments for vision-robbing retinal degenerative diseases that affect tens of millions of people around the world.
The collaboration will significantly bolster the development of the following gene therapy products: StarGen™ for the treatment of Stargardt disease, a form of early-onset macular degeneration; UshStat™ for the treatment of Usher syndrome, the leading cause of deaf-blindness; RetinoStat® for the treatment of age-related macular degeneration, the leading cause vision loss in people 55 and older in developed countries; and EncorStat™ for corneal graft rejection.
The development of treatments for these and other retinal degenerative diseases is a key goal of the National Neurovision Research Institute and is the basis for its partnership with Oxford BioMedica. In 2006, Paul and Diane Manning, with the National Neurovision Research Institute, established a partnership with Oxford BioMedica to advance gene therapies for these and other related retinal degenerative diseases.
“The investment from sanofi-aventis is a wonderful boost for the development of Oxford BioMedica’s gene therapy products and will greatly enhance our ability to move these emerging treatments into and through the clinical trial process,” says Stephen Rose, Ph.D., chief research officer, Foundation Fighting Blindness. “This collaboration affirms the great potential for gene therapy to treat and cure a number of retinal degenerative diseases including Stargardt disease and Usher syndrome that, as rare diseases, often do not receive the attention or investment necessary to bring about promising treatments.”
“An important goal of the Foundation, through NNRI, is to attract investment from large pharmaceutical companies for the development and production of treatments for inherited retinal disease,” says Morton Goldberg, M.D., chairman of the board of NNRI. “The NNRI-Oxford partnership is an excellent model of how NNRI collaborations can accelerate the translation of laboratory-based research into clinical trials, ultimately getting successful treatments for rare diseases like inherited retinal degenerations to the market and out to the people who need them.”
Based on the agreement, Oxford BioMedica will receive approximately €43 million ($56 million) from sanofi-aventis over a three-year period. Oxford BioMedica is eligible to receive additional fees if development efforts are successful.
The treatments will utilize Oxford BioMedica’s LentiVector® gene delivery technology to deliver healthy vision-saving genes to the retina.
About Foundation Fighting Blindness
The Foundation Fighting Blindness is the largest source of non-governmental funding for retinal degenerative disease research in the world. The urgent mission of the Foundation Fighting Blindness is to drive the research that will provide preventions, treatments and cures for people affected by retinitis pigmentosa, macular degeneration, Usher syndrome, and the entire spectrum of retinal degenerative diseases. The Foundation has invested over $140 million to provide seed money for scientific research of diseases of the retina, which cause blindness. Further information is available at www.FightBlindness.org.
About National Neurovision Research Institute (NNRI)
NNRI is a recently-established non-profit support organization of the Foundation Fighting Blindness (FFB), the leading non-government funding source for inherited orphan retinal degeneration research. The mission of NNRI is to accelerate the translation of laboratory based research into clinical trials for treatments and cures of retinal degenerative diseases. It is a medical research institute that obtains support from government agencies, corporations and private foundations. It may also receive royalties or licensing fees from the drug discovery processes and commercialization of new therapies. Further information is available at www.nnri.info.
OWINGS MILLS, Md.--(BUSINESS WIRE)--The National Neurovision Research Institute (NNRI), the Foundation Fighting Blindness’ clinical trial support organization, announced today that one of its key partners, biopharmaceutical company Oxford BioMedica, has established a collaboration with sanofi-aventis, a major international pharmaceutical company, to develop and commercialize gene therapy treatments for vision-robbing retinal degenerative diseases that affect tens of millions of people around the world.
The collaboration will significantly bolster the development of the following gene therapy products: StarGen™ for the treatment of Stargardt disease, a form of early-onset macular degeneration; UshStat™ for the treatment of Usher syndrome, the leading cause of deaf-blindness; RetinoStat® for the treatment of age-related macular degeneration, the leading cause vision loss in people 55 and older in developed countries; and EncorStat™ for corneal graft rejection.
The development of treatments for these and other retinal degenerative diseases is a key goal of the National Neurovision Research Institute and is the basis for its partnership with Oxford BioMedica. In 2006, Paul and Diane Manning, with the National Neurovision Research Institute, established a partnership with Oxford BioMedica to advance gene therapies for these and other related retinal degenerative diseases.
“The investment from sanofi-aventis is a wonderful boost for the development of Oxford BioMedica’s gene therapy products and will greatly enhance our ability to move these emerging treatments into and through the clinical trial process,” says Stephen Rose, Ph.D., chief research officer, Foundation Fighting Blindness. “This collaboration affirms the great potential for gene therapy to treat and cure a number of retinal degenerative diseases including Stargardt disease and Usher syndrome that, as rare diseases, often do not receive the attention or investment necessary to bring about promising treatments.”
“An important goal of the Foundation, through NNRI, is to attract investment from large pharmaceutical companies for the development and production of treatments for inherited retinal disease,” says Morton Goldberg, M.D., chairman of the board of NNRI. “The NNRI-Oxford partnership is an excellent model of how NNRI collaborations can accelerate the translation of laboratory-based research into clinical trials, ultimately getting successful treatments for rare diseases like inherited retinal degenerations to the market and out to the people who need them.”
Based on the agreement, Oxford BioMedica will receive approximately €43 million ($56 million) from sanofi-aventis over a three-year period. Oxford BioMedica is eligible to receive additional fees if development efforts are successful.
The treatments will utilize Oxford BioMedica’s LentiVector® gene delivery technology to deliver healthy vision-saving genes to the retina.
About Foundation Fighting Blindness
The Foundation Fighting Blindness is the largest source of non-governmental funding for retinal degenerative disease research in the world. The urgent mission of the Foundation Fighting Blindness is to drive the research that will provide preventions, treatments and cures for people affected by retinitis pigmentosa, macular degeneration, Usher syndrome, and the entire spectrum of retinal degenerative diseases. The Foundation has invested over $140 million to provide seed money for scientific research of diseases of the retina, which cause blindness. Further information is available at www.FightBlindness.org.
About National Neurovision Research Institute (NNRI)
NNRI is a recently-established non-profit support organization of the Foundation Fighting Blindness (FFB), the leading non-government funding source for inherited orphan retinal degeneration research. The mission of NNRI is to accelerate the translation of laboratory based research into clinical trials for treatments and cures of retinal degenerative diseases. It is a medical research institute that obtains support from government agencies, corporations and private foundations. It may also receive royalties or licensing fees from the drug discovery processes and commercialization of new therapies. Further information is available at www.nnri.info.
Sunday, April 19, 2009
Vigorous Exercise May Help Prevent Vision Loss
Vigorous exercise may help prevent vision loss, according to a pair of studies from the U.S. Department of Energy's Lawrence Berkeley National Laboratory. The studies tracked approximately 31,000 runners for more than seven years, and found that running reduced the risk of both cataracts and age-related macular degeneration.
The research, which is among the first to suggest that vigorous exercise may help prevent vision loss, offers hope for people seeking to fend off the onset of eye disease.
"In addition to obtaining regular eye exams, people can take a more active role in preserving their vision," says Paul Williams, an epidemiologist in Berkeley Lab's Life Sciences Division who conducted the research. "The studies suggest that people can perhaps lessen their risk for cataracts and macular degeneration by taking part in a fitness regimen that includes vigorous exercise."
A cataract, which is a cloudy opacity of the eye lens, is the leading cause of blindness. More than one-half of people in the U.S. over the age of 65 suffer from some form of cataracts. Macular degeneration, which is damage to the retina, is the leading cause of irreversible vision loss in older white Americans, affecting 28 percent of people aged 75 and older.
Macular degeneration gradually destroys sharp, central vision. Macular degeneration affects the macula, the part of the eye that allows you to see fine detail. The macula is located in the center of the retina, the light-sensitive tissue at the back of the eye. The retina instantly converts light, or an image, into electrical impulses. The retina then sends these impulses, or nerve signals, to the brain. Macular degeneration causes no pain.
The diseases have several known risk factors, such as sunlight exposure and diabetes in the case of cataracts, but few interventions. Now, it appears that vigorous cardiovascular exercise may be one way to derail the diseases.
To conduct the research, Williams analyzed data collected in the National Runners' Health Study, which he established in 1991 to determine the health benefits of running.
In this case, he followed approximately 29,000 male runners and 12,000 female runners for more than seven years. Of these people, 733 men reported being diagnosed with cataracts on a questionnaire filled out at the end of the study. Too few women reported cataracts to track.
Men who ran more than 5.7 miles per day had a 35 percent lower risk of developing cataracts than men who ran less than 1.4 miles per day. The study also analyzed men's 10-kilometer race performances, which is a good indicator of overall fitness. The fittest men boasted one-half the risk of developing cataracts compared to the least-fit men.
A second study found that running appeared to reduce the risk of macular degeneration. In the study, 152 men and women reported being diagnosed with the disease. Compared to people who ran less than 1.2 miles per day, people who averaged between 1.2 and 2.4 miles per day had a 19 percent lower risk for the disease, and people who ran more than 2.4 miles per day had between 42 percent and 54 percent lower risk of macular degeneration.
"These findings are compelling because of the large size of the study, and the fact that we are looking at something that is fairly well defined: vigorous exercise, as opposed to more moderate exercise," says Williams.
Most of the runners in the study exceeded the current public health recommendations for physical activity, which is at least 30 minutes of moderate-intensity activities such as brisk walking five days a week, or smaller doses of more vigorous exercise such as running. It is unclear whether people might also lower their risk for cataracts and age-related macular degeneration by walking.
"We know there are important health benefits to walking, including lowering heart disease risk," says Williams. "It is quite likely that the studies' results might apply to a lesser extent to smaller doses of more moderate exercise."
Williams also adds that further research is needed to explore why there is a link between vigorous exercise and a decreased risk for eye disease.
"We know some of the physiological benefits of exercise, and we know about the physiological background of these diseases, so we need to better understand where there's an overlap," says Williams.
The research, which is among the first to suggest that vigorous exercise may help prevent vision loss, offers hope for people seeking to fend off the onset of eye disease.
"In addition to obtaining regular eye exams, people can take a more active role in preserving their vision," says Paul Williams, an epidemiologist in Berkeley Lab's Life Sciences Division who conducted the research. "The studies suggest that people can perhaps lessen their risk for cataracts and macular degeneration by taking part in a fitness regimen that includes vigorous exercise."
A cataract, which is a cloudy opacity of the eye lens, is the leading cause of blindness. More than one-half of people in the U.S. over the age of 65 suffer from some form of cataracts. Macular degeneration, which is damage to the retina, is the leading cause of irreversible vision loss in older white Americans, affecting 28 percent of people aged 75 and older.
Macular degeneration gradually destroys sharp, central vision. Macular degeneration affects the macula, the part of the eye that allows you to see fine detail. The macula is located in the center of the retina, the light-sensitive tissue at the back of the eye. The retina instantly converts light, or an image, into electrical impulses. The retina then sends these impulses, or nerve signals, to the brain. Macular degeneration causes no pain.
The diseases have several known risk factors, such as sunlight exposure and diabetes in the case of cataracts, but few interventions. Now, it appears that vigorous cardiovascular exercise may be one way to derail the diseases.
To conduct the research, Williams analyzed data collected in the National Runners' Health Study, which he established in 1991 to determine the health benefits of running.
In this case, he followed approximately 29,000 male runners and 12,000 female runners for more than seven years. Of these people, 733 men reported being diagnosed with cataracts on a questionnaire filled out at the end of the study. Too few women reported cataracts to track.
Men who ran more than 5.7 miles per day had a 35 percent lower risk of developing cataracts than men who ran less than 1.4 miles per day. The study also analyzed men's 10-kilometer race performances, which is a good indicator of overall fitness. The fittest men boasted one-half the risk of developing cataracts compared to the least-fit men.
A second study found that running appeared to reduce the risk of macular degeneration. In the study, 152 men and women reported being diagnosed with the disease. Compared to people who ran less than 1.2 miles per day, people who averaged between 1.2 and 2.4 miles per day had a 19 percent lower risk for the disease, and people who ran more than 2.4 miles per day had between 42 percent and 54 percent lower risk of macular degeneration.
"These findings are compelling because of the large size of the study, and the fact that we are looking at something that is fairly well defined: vigorous exercise, as opposed to more moderate exercise," says Williams.
Most of the runners in the study exceeded the current public health recommendations for physical activity, which is at least 30 minutes of moderate-intensity activities such as brisk walking five days a week, or smaller doses of more vigorous exercise such as running. It is unclear whether people might also lower their risk for cataracts and age-related macular degeneration by walking.
"We know there are important health benefits to walking, including lowering heart disease risk," says Williams. "It is quite likely that the studies' results might apply to a lesser extent to smaller doses of more moderate exercise."
Williams also adds that further research is needed to explore why there is a link between vigorous exercise and a decreased risk for eye disease.
"We know some of the physiological benefits of exercise, and we know about the physiological background of these diseases, so we need to better understand where there's an overlap," says Williams.
Saturday, March 21, 2009
Food For The Eyes
Food for the Eyes
Last Update: 3/20 1:19 pm
Source: WXYZ Detroit
Many of us plan our meals around certain foods hoping to keep our bodies healthy, but not many of us think specifically about our eyes. We have a heads up on culinary choices that can help you see better, longer. In fact, these can be called 'food for the eyes!'
Blair Carper, (worried about his vision)
"I used to be able to see things really sharp and now I don't see things as well."
He's heard carrots are good for the eyes and he's right, but they're not the only way to protect your view of the world. A recent study shows several nutrients in supplemental form help slow the progression of serious eye diseases. Ophthalmologist Sunil Srivastava says incorporating even small amounts into your regular diet can only help. One food with benefits-eggs.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Eggs do have a lot of good vitamins, such as vitamin A. Vitamin A is important in the function of the eye, specifically the retina, so vitamin A deficiencies can actually lead to night blindness."
Then there are raspberries. The vitamin C in them helps reduce the risk of cataract formation. Almonds are up next because they contain vitamin E.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Vitamin C and vitamin E have been shown to, at elevated levels, reduce the risk of things like macular degeneration in high risk patients."
Salmon or more specifically fish oil, along with green leafy vegetables, also help prevent macular degeneration, an illness that causes blindness. Ten million Americans are already coping with the disease.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Lutein and zeaxanthin are certain types of pigments that actually are concentrated in the macula of our retina, which is the center part of our vision, and foods like broccoli and spinach have high levels of lutein and zeaxanthin."
Aslo, try yogurt because the zinc in it helps the body absorb antioxidants, which also help the eyes.
Other good sources of vitamin A are cantaloupe, sweet potatoes, and mango.
Last Update: 3/20 1:19 pm
Source: WXYZ Detroit
Many of us plan our meals around certain foods hoping to keep our bodies healthy, but not many of us think specifically about our eyes. We have a heads up on culinary choices that can help you see better, longer. In fact, these can be called 'food for the eyes!'
Blair Carper, (worried about his vision)
"I used to be able to see things really sharp and now I don't see things as well."
He's heard carrots are good for the eyes and he's right, but they're not the only way to protect your view of the world. A recent study shows several nutrients in supplemental form help slow the progression of serious eye diseases. Ophthalmologist Sunil Srivastava says incorporating even small amounts into your regular diet can only help. One food with benefits-eggs.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Eggs do have a lot of good vitamins, such as vitamin A. Vitamin A is important in the function of the eye, specifically the retina, so vitamin A deficiencies can actually lead to night blindness."
Then there are raspberries. The vitamin C in them helps reduce the risk of cataract formation. Almonds are up next because they contain vitamin E.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Vitamin C and vitamin E have been shown to, at elevated levels, reduce the risk of things like macular degeneration in high risk patients."
Salmon or more specifically fish oil, along with green leafy vegetables, also help prevent macular degeneration, an illness that causes blindness. Ten million Americans are already coping with the disease.
Sunil Srivastava, MD, Ophthalmologist, Emory University
"Lutein and zeaxanthin are certain types of pigments that actually are concentrated in the macula of our retina, which is the center part of our vision, and foods like broccoli and spinach have high levels of lutein and zeaxanthin."
Aslo, try yogurt because the zinc in it helps the body absorb antioxidants, which also help the eyes.
Other good sources of vitamin A are cantaloupe, sweet potatoes, and mango.
Saturday, March 14, 2009
Eat Better Foods to Keep Eyes Healthy
March is Save Your Vision Month, sponsored by the American Optometric Association, or AOA. This year's theme is to pay more attention to nutrition to care for your eyes.
The AOA recommends increasing nutrients for healthy eyes, especially for people coping with vision loss or other eye problems.
Cataracts and age-related macular degeneration are the two leading causes of vision loss and blindness. One out of four Americans age 40 and older suffer from some level of vision loss. Patient clinical trials by the National Institutes of Health found age-related macular degeneration to be a nutrition responsive disorder. Multivitamins typically deliver nutrients below the recommended level for eye health.
Having a daily intake of certain nutrients has been linked to healthy eyes and may reduce the risk of some chronic eye conditions. Intake can be either through foods or supplements. Consult your eye health professional or physician before making changes in your diet or supplementation.
Eat foods rich in the following nutrients to help protect your eye sight and vision.
Lutein is found in colorful produce such as green beans, spinach, broccoli, oranges and corn.
Essential fatty acids are found in tuna, salmon, whole grains, lean meats and eggs.
Vitamin C is found in papaya, oranges, green peppers, and tomatoes.
Vitamin E is found in nuts & seeds like almonds, pecans, peanut butter and sunflower seeds, also sweet potatoes.
Zinc is found in whole grains, baked beans, poultry, shellfish, milk and red meat.
Renee Veksler is a Guam Memorial Hospital health educator and community partner with the Get Healthy Guam Coalition. Contact her at 647-2351.
The AOA recommends increasing nutrients for healthy eyes, especially for people coping with vision loss or other eye problems.
Cataracts and age-related macular degeneration are the two leading causes of vision loss and blindness. One out of four Americans age 40 and older suffer from some level of vision loss. Patient clinical trials by the National Institutes of Health found age-related macular degeneration to be a nutrition responsive disorder. Multivitamins typically deliver nutrients below the recommended level for eye health.
Having a daily intake of certain nutrients has been linked to healthy eyes and may reduce the risk of some chronic eye conditions. Intake can be either through foods or supplements. Consult your eye health professional or physician before making changes in your diet or supplementation.
Eat foods rich in the following nutrients to help protect your eye sight and vision.
Lutein is found in colorful produce such as green beans, spinach, broccoli, oranges and corn.
Essential fatty acids are found in tuna, salmon, whole grains, lean meats and eggs.
Vitamin C is found in papaya, oranges, green peppers, and tomatoes.
Vitamin E is found in nuts & seeds like almonds, pecans, peanut butter and sunflower seeds, also sweet potatoes.
Zinc is found in whole grains, baked beans, poultry, shellfish, milk and red meat.
Renee Veksler is a Guam Memorial Hospital health educator and community partner with the Get Healthy Guam Coalition. Contact her at 647-2351.
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