ImStem Makes Progress on MS Treatment with Embryonic Stem Cells
News Jun 07, 2014
ImStem Biotechnology, Inc. (ImStem) has announced that it has successfully treated an animal model of multiple sclerosis (MS) using human embryonic stem cells (hESC) derived mesenchymal stem cells (MSCs), called hES-MSCs.
MS is a chronic neuroinflammatory disease with no cure. Most current MS therapies offer only palliative relief without repairing damaged nerve cells. MSCs may reduce neuroinflammation and promote nerve cell regeneration in MS.
Now researchers from ImStem, in collaboration with University of Connecticut Health Center (UCHC) and Advanced Cell Technology, Inc.(OTCBB:ACTC), have developed a novel therapy to treat MS with hES-MSCs. They found that hES-MSCs are more effective in treating animal model of MS than MSCs from bone marrow of adult human donors (BM-MSC). This work is published in the June 5th 2014 online edition of Stem Cell Reports, the official journal of International Society for Stem Cell Research.
“The beauty of the new hES-MSCs is their consistently high efficacy in MS model. This is a big surprise when we found that most BM-MSC lines show poor or no efficacy. Additionally, BM-MSCs but not hES-MSCs express high level of IL-6, a proinflammatory cytokine can worsen the disease. This definitely adds more advantages to hES-MSCs, which are younger, purer and only express the right factors" says the lead author Dr. Xiaofang Wang, CTO of ImStem.
"These great advantages perfectly match the requirements for safety and quality control of clinical-grade MSCs as a potential therapy for autoimmune diseases such as multiple sclerosis, inflammatory bowel disease and rheumatoid arthritis.” says Dr. Ren-He Xu, the corresponding author, CSO of ImStem and professor of the University of Macau.
Dr. Joel Pachter, a UCHC collaborator, observed fluorescently labeled hES-MSCs but not BM-MSCs effectively penetrated the blood brain barrier and migrated into inflamed spinal cord. He remarks, "This difference is extraordinary as it could hold a key to the therapeutic action(s) of hES-MSCs. MSCs might require access to specific sites within the central nervous system in order to remediate disease."
"This was unexpected as bone marrow MSCs are widely believed to be effective in this EAE animal model. Our data indicate that the use of BM-MSCs is highly variable and there may be a previously unrecognized risk of poor outcome associated with IL-6 produced by these cells," says Dr. Stephen Crocker, another UCHC collaborator.
Imstem was founded by Dr. Xiaofang Wang and Dr. Ren-He Xu, former director of UConn Stem Cell Core in 2012. In 2013, ImStem was awarded a $1.13M grant from the State of Connecticut Stem Cell Research Program and a $150,000 pre-seed fund from Connecticut Innovations. With these supports, ImStem has improved the hES-MSC technology with better efficiency and safety and has developed clinical grade hES-MSCs in its cGMP facility. ImStem is now seeking approval for Phase I clinical trials using its hES-MSCs and is looking for investors to fasten the progress.
"ImStem, our first spinoff company from the UConn Stem Cell Core, is uncovering the translational potential of hES-MSCs. ImStem’s cutting-edge work demonstrates the success of Connecticut’s Stem Cell and Regenerative Medicine funding program in moving stem cells from bench to bedside." says Dr. Marc Lalande, director of the University of Connecticut Stem Cell Institute.
“Connecticut’s investment in stem cells, especially human embryonic stem cells, continues to position our state as a leader in biomedical research,” said Governor Dannel P. Malloy. “This new study move us one step closer to a stem cell based clinical product which could improve people’s lives.”
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