01.19.08
Magnetic Therapy
In today’s show, adapted from an article published this month on the Oscar web site written by Melissa Maki, we examine the continuing studies of UVa professor and chair of biomedical engineering Thomas Skalak and his efforts to develop real scientific evidence about the effectiveness of magnetic therapy.
Magnetic therapy, touted for healing properties since ancient Greece, is still widely used today as an alternative method for treating a number of conditions, from arthritis to depression. Yet, in spite of no scientific proof that magnets can heal, a lack of regulation and widespread public acceptance based on anecdotal evidence, hopeful consumers have created a $5 billion world market as they buy bracelets, knee braces, shoe inserts, mattresses and other products embedded with magnets, hoping for a non-invasive and drug-free cure to what ails them.
Thomas Skalak, professor and chair of biomedical engineering at U.Va., has carefully studied magnets for a number of years in order to develop real scientific evidence about the effectiveness of magnetic therapy. His lab leads the field in the area of micro-circulation research - the study of blood flow through the body’s tiniest blood vessels. With a five-year, $875,000 grant from the National Institutes of Health’s National Center for Complementary and Alternative Medicine, Skalak and Cassandra Morris, former Ph.D. student in biomedical engineering, set out to investigate the effect of magnetic therapy on micro-circulation.
Initially, they sought to examine a major claim, that magnets increase blood flow, made by the companies that sell magnet. They first found evidence to support this claim in their initial research with laboratory rats. Magnets of 70 milliTesla (mT) field strength - about 10 times the strength commonly found on a refrigerator - were placed near the rat’s blood vessels. Measurements of blood vessel diameter were taken both before and after exposure to the force created by the magnets. They effect found was significant. The vessels that had been dilated constricted, and the constricted vessels dilated, implying that the magnetic field could induce vessel relaxation in tissues with constrained blood supply, ultimately increasing blood flow.
Since dilation of blood vessels is often a major cause of swelling at sites of trauma to soft tissues such as muscles or ligaments, the prior results on vessel constriction led Morris and Skalak to look closer at whether magnets, by limiting blood flow in such cases, would also reduce swelling. Their most recent research, published in the November 2007 issue of the American Journal of Physiology, yielded affirmative results.
In this study, the hind paws of anesthetized rats were treated with inflammatory agents in order to simulate tissue injury. Magnetic therapy was then applied to the paws. The research results indicate that magnets can significantly reduce swelling if applied immediately after tissue trauma.
Since muscle bruising and joint sprains are the most common injuries worldwide, this discovery has significant implications. Skalak said, “if an injury doesn’t swell, it will heal faster - and the person will experience less pain and better mobility.” This means that magnets could be used much the way ice packs and compression are now used for everyday sprains, bumps and bruises, but with more beneficial results.
A key to the success of magnetic therapy for tissue swelling is careful engineering of the proper field strength at the tissue location, a challenge in which most currently available commercial magnet systems fall short. The new research should allow Skalak’s biomedical engineering group to design field strengths that provide real benefit for specific injuries and parts of the body.
The ready availability and low cost of this treatment could produce huge gains in worker productivity and quality of life. Skalak, who plans to continue testing magnet effectiveness through clinical trials and on elite athletes, envisions the magnets being particularly useful to high school, college and professional sports teams, as well as school nurses and retirement communities.
Skalak said, “we now hope to implement a series of steps, including private investment partners and eventually a major corporate partner, to realize these very widespread applications that will make a positive difference for human health.”
You’ve been listening to the Oscar Show… I’m Jacob Canon. Join us next week when continue with the topic of biomedical engineering by examining the work of two University of Virginia professors who have created a system, the HemoShear 2.0, which offers researchers the ability to observe the behavior patterns of vascular cells under a variety of blood flow conditions.