The Way Doctors Treat Patients With Cancer And Autoimmune Diseases Could Change Following New Discovery

Researchers in the Faculty of Medicine & Dentistry at the University of Alberta have made an important discovery that provides a new understanding of how our immune system "learns" not to attack our own body, and this could affect the way doctors treat patients with autoimmune diseases and cancer.

When patients undergo chemotherapy for cancer or as part of experimental therapies to treat autoimmune diseases such as diabetes and lupus, the treatment kills the patients' white blood cells. What can be done afterwards, is to give these patients blood stem cells through transplantation. Stem cells are taken from patients then injected back into them - with the theory being that the patients' immune system won't attack their own cells, and the stem cells can get to work healing their bodies.

But U of A medical researchers Govindarajan Thangavelu, Colin Anderson and their collaborators discovered that if a particular molecule is not working properly in T-cells, the body will attack itself. This is significant for stem-cell transplantation treatment because it means the immune systems of the patients could consider their own cells "foreign" and initiate an attack.

"So your own cells would be killing you," says Thangavelu, a PhD student specializing in immunology, who was the first author in the research study, which was recently published in the peer-reviewed Journal of Autoimmunity. "What we found is if this molecule is absent in T-cells, if the pathway isn't intact, it will cause severe autoimmunity to the subject's own body. In essence, subjects become allergic to their own cells."

Anderson, an associate professor with the Alberta Diabetes Institute and Principal Investigator added: "The ability of our immune system to attack dangerous microbes while not attacking our own cells or tissues is a delicate balance. Restarting the immune system after wiping it out in patients with autoimmune diseases or cancer requires re-establishing this appropriate balance. We discovered that a particular immune system molecule is critical to prevent the immune system from attacking our own cells or tissues when the immune system is restarted. If that molecule is missing, the immune system will wreak havoc on the body."

T-cells are supposed to protect people and animals from things invading their bodies. But this research demonstrates if these cells become unregulated because they are missing a molecule, it can lead to autoimmunity - particularly dangerous in scenarios where patients have lost white blood cells when they are being treated for autoimmune diseases or cancer.

Thangavelu has won awards for this research. He was invited to present his work at an international conference of immunology in Japan last year. He has also travelled to the United Kingdom to talk about his findings with the medical community.

This research was funded by: the Juvenile Diabetes Research Foundation, the Canadian Institutes of Health Research, Alberta Innovates-Health Solutions and the Alberta Diabetes Institute.

Source:
Raquel Maurier
University of Alberta Faculty of Medicine & Dentistry

ACT Files European Clinical Trial Application For Phase 1/2 Study Using Embryonic Stem Cells To Treat Macular Degeneration

Advanced Cell Technology, Inc. ("ACT"; OTCBB: ACTC), a leader in the field of regenerative medicine, announced today that it has filed a clinical trial application (CTA) with the European Medicines and Healthcare products Regulatory Agency (MHRA) seeking clearance to initiate its Phase 1/2 clinical trial using retinal pigment epithelial (RPE) cells derived from human embryonic stem cells (hESCs) to treat patients with Stargardt's Macular Dystrophy (SMD).

"With this filing, our initiatives in Europe are really starting to gain momentum," said Gary Rabin, interim chairman and CEO of ACT. "Through data from this proposed trial, and the two trials we are preparing to commence in the United States, we are eagerly anticipating beginning to assess the capabilities of our RPE cells to repair and regenerate the retina. As in the US, we also intend to file in Europe for clinical trials involving Dry Age-Related Macular Degeneration (Dry AMD) and other degenerative diseases of the retina, concurrently targeting the two largest pharmaceutical markets in the world."

The proposed clinical trial will be a prospective, open-label study that is designed to determine the safety and tolerability of the RPE cells following sub-retinal transplantation to patients with advanced SMD, similar to the FDA-cleared U.S. trial which is set to commence in the first half of this year. During the CTA review process, which requires a minimum of 60 days, the reviewers decide if an applicant is permitted to proceed with its proposed clinical trial. Additional information may be requested from the applicant, which could extend the review period.

"We are very excited about this European filing, because our preclinical data from various animal models with hESC-derived RPE cells have been tremendously encouraging," said Robert Lanza, M.D., chief scientific officer at ACT. "In rats we have seen 100 percent improvement in visual performance over untreated animals without any adverse effects. Near-normal function was also achieved in a mouse model of Stargardt's disease."

In 2010, the US Food and Drug Administration (FDA) granted Orphan Drug designation for ACT's RPE cells for treating SMD, and earlier this year the company received a positive opinion from the Committee for Orphan Medicinal Products (COMP) of the European Medicines Agency (EMA) towards designation of this product as an orphan medicinal product for the treatment of Stargardt's disease. ACT anticipates adoption of the EMA's recommendation by the European Commission in coming weeks.

About Stargardt's Macular Dystrophy and Degenerative Diseases of the Retina

Stargardt's Macular Dystrophy (SMD) is one of the most common forms of macular degeneration in the world. SMD causes progressive vision loss, usually starting in children between 10 to 20 years of age. Eventually, blindness results from photoreceptor loss associated with degeneration in the pigmented layer of the retina, called the retinal pigment epithelium or RPE cell layer.

Degenerative diseases of the retina are among the most common causes of untreatable blindness in the world. As many as thirty million people in the United States and Europe suffer from macular degeneration, which represents a $25-30 billion worldwide market that has yet to be effectively addressed. Approximately 10% of people ages 66 to 74 will have symptoms of macular degeneration, the vast majority the "dry" form of AMD which is currently untreatable. The prevalence increases to 30% in patients 75 to 85 years of age.

Source: Advanced Cell Technology, Inc

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