Stem Cell Recovery
Penn Study Finds Hyperbaric Oxygen Treatments Mobilize Stem Cells Recovery of Injured and Diseased Tissue the Ultimate Goal
(Philadelphia, P A)- According to a study to be published in The American Journal of Physiology-Heart and Circulation Physiology, a typical course of hyperbaric oxygen treatments increases by eight-fold the number of stem cells circulating in a patient’s body. Stem cells, also called progenitor cells are crucial to injury repair. The study currently appears on-line and is scheduled for publication in the April 2006 edition of the American Journal.
Stem cells exist in the bone marrow of human beings and animals and are capable of changing their nature to become part of many different organs and tissues. In response to injury, these cells move from the bone marrow to the injured sites, where they differentiate into cells that assist in the healing process. The movement, or mobilization, of stem cells can be triggered by a variety of stimuli – including pharmaceutical agents and hyperbaric oxygen treatments. Where as drugs are associated with a host of side effects, hyperbaric oxygen treatments carry a significantly lower risk of such effects.
“This is the safest way clinically to increase stem cell circulation, far safer than any of the pharmaceutical options,” said Stephen Thorn, MD, PhD, Professor of Emergency Medicine at the University of Pennsylvania School of Medicine and lead author of the study. “This study provides information on the fundamental mechanisms for hyperbaric oxygen and offers a new theoretical therapeutic option for mobilizing stem cells.”
“We reproduced the observations from humans in animals in order to identify the mechanism for the hyperbaric oxygen effect,” added Thorn. “We found that hyperbaric oxygen mobilizes stem/progenitor cells because it increases synthesis of a molecule called nitric oxide in the bone marrow. This synthesis is thought to trigger enzymes that mediate stem/progenitor cell release.”
Hopefully, future study of hyperbaric oxygen’s role in mobilizing stem cells will provide a wide array of treatments for combating injury and disease.