SBIR-STTR Award

In alignment with Healthy People 2010 (Arthritis/Osteoporosis) and research objectives established by the NIAMS, the overall goal of this study is to prevent illness and disability related to arthritis and osteoporosis. This study will develop a marrow population of mesenchymal cells (MSCs) that are very small and have embryonic-like properties (VSEL cells). This study will develop MSCs for true regenerative medicine. We hypothesize that human VSEL cells represent true MSC cells that can be utilized for osseous regeneration - and ultimately for the treatment of osteoporosis. The aim of this study is to test in vivo the capacity of human VSEL cells to form bone in an animal model. The goals and objectives of this study are closely aligned with the official NIH position regarding stem cell research: to examine stem cells as a renewable source of replacement cells to treat diseases, conditions, and disabilities.

Public Health Relevance:
NeoStem will conduct research on stem cells and explore their enormous promise to produce breakthrough therapies and cures. The study will investigate the effect of a marrow population of mesenchymal cells (MSCs) that are very small and have embryonic-like properties (VSEL cells) that can be utilized for bone regeneration - and ultimately for the treatment of osteoporosis. This study will test in vivo the capacity of human VSEL cells to form bone in an animal model and regenerate a critical sized boney defect.

Public Health Relevance Statement:
Project Narrative NeoStem will conduct research on stem cells and explore their enormous promise to produce breakthrough therapies and cures. The study will investigate the effect of a marrow population of mesenchymal cells (MSCs) that are very small and have embryonic-like properties (VSEL cells) that can be utilized for bone regeneration - and ultimately for the treatment of osteoporosis. This study will test in vivo the capacity of human VSEL cells to form bone in an animal model and regenerate a critical sized boney defect.

NIH Spending Category:
Aging; Clinical Research; Osteoporosis; Regenerative Medicine; Stem Cell Research; Stem Cell Research - Nonembryonic - Human; Transplantation

Project Terms:
Adult; Animal Model; Area; Arthritis; Attention; Biological Assay; bone; Bone Regeneration; Cell Therapy; Cells; Defect; Development; disability; Disease; Embryo; Generations; Goals; Healthy People 2010; Human; human stem cells; in vivo; Legal patent; Marrow; Mesenchymal; Mesenchymal Stem Cell Transplantation; Mesenchymal Stem Cells; Molecular; National Institute of Arthritis and Musculoskeletal and Skin Diseases; Natural regeneration; Osteoporosis; Phase I Clinical Trials; Population; Positioning Attribute; prevent; product development; Property; public health relevance; Regenerative Medicine; repaired; Research; Source; Spinal Fractures; Stem Cell Research; Stem cells; Testing; Tissues; tool; United States National Institutes of Health

Bone loss due to fractures and disease is a serious medical condition in the US affecting millions of Americans. It is particularly a problem with oral craniofacial disorders were the costs of treating damage exceeds $60 billion annually. Furthermore, periodontitis is associated with systemic disorders such as diabetes mellitus, preterm low birth weight, and cardiovascular disease. While major efforts have been made to understand mechanisms of healing of large bones and to develop therapeutics to treat overall bone loss, very little information is available on bone remodeling in the human craniofacial skeleton, nor the mechanisms involved in osteonecrosis of the jaw and there are few effective treatments. The results of our phase 1 SBIR showed that a unique population of human, adult, pluripotent, Very Small Embryonic like (VSEL) stem cells, have important bone regenerative properties and could be useful in treating oral-craniofacial disorders. Human VSELs are pluripotent stem cells involved in the normal turnover and regeneration of tissues and their circulating levels greatly increase in response to injury. They are able to repair injured tissues such as the heart after myocardial infarct. Adult human VSELs, are SSEA-4+/Oct-4+/CD133+/CXCR4+/Lin-/CD45-, express pluripotency markers (Oct-4 and Nanog) and are capable of differentiation into cells from all three germ lineages. With our collaborator, Dr. Russell Taichman of the University of Michigan we showed that VSELs differentiate to osteoblastic lineage after intra-marrow transplant. Importantly, VSELs from adult humans repaired a calvarial defect in SCID mice. The human VSELs formed new bone when applied in the injured area as measured by u-CT scan, and histological analysis demonstrated osteogeneis, significant new bone formation, dense thickening of the trabeculae and bone marrow formation. Most importantly, new bone tissue was derived from the human VSELs. These studies show that VSELs can generate new bone and have the potential to repair bone injuries. In this phase 2 SBIR, we propose to further test the effectiveness of human VSELs to regenerate bone in human patients. Specifically, we will test the ability of VSELs to promote bone remodeling in the human craniofacial skeleton. For our studies, we will test the efficacy of human VSELs to generate bone in humans in a tooth extraction model in which individuals requiring tooth extraction due to caries or periodontal disease will be the subjects. In these individuals, the underlying jaw bone tissue is injured and depleted and while there is some healing overtime after tooth extraction, the process is slow. We will test whether VSELs isolated from the patient expedite bone growth in the oral cavity after tooth removal. The VSELs are autologous and will not cause rejection and do not form tumors or cause other health risks. This is not a clinical trial but a focused patient based study intended to move forward the development of VSELs as a therapeutic for bone repair. It successful, these studies will provide the basis for the rapid clinical development of VSELs for craniofacial osseous regeneration and treatment of a number of other skeletal based disorders.

Public Health Relevance:
It is a goal of NeoStem to develop the therapeutic capabilities of Human VSELs to treat a host of diseases and disorders. Studies in this proposal are focused on establishing the utility of VSELs to repair bone and treat oral-craniofacial disorders. If the results of these studies in humans show safety and efficacy of adult autologous VSELs in bone repair, then we will attempt to further develop this cell therapy in clinical studies in the futureto establish the cells as a standard of care for the treatment of bone disease and loss.