Jan. 2, 2008 — Magnets have been touted for their healing
properties since ancient Greece. Magnetic therapy is still widely used
today as an alternative method for treating a number of conditions, from
arthritis to depression, but there hasn't been scientific proof that magnets
can heal.
Lack of regulation and widespread public acceptance have turned
magnetic therapy into a $5 billion world market. Hopeful consumers buy
bracelets, knee braces, shoe inserts, mattresses, and other products that are
embedded with magnets based on anecdotal evidence, hoping for a non-invasive
and drug-free cure to what ails them.
“The FDA regulates specific claims of medical efficacy, but in
general static magnetic fields are viewed as safe,” notes Thomas Skalak,
professor and chair of biomedical engineering at U.Va.
Skalak has been carefully studying magnets for a number of years in order to develop real scientific evidence about the effectiveness of magnetic therapy.
Skalak has been carefully studying magnets for a number of years in order to develop real scientific evidence about the effectiveness of magnetic therapy.
Skalak’s lab leads the field in the area of microcirculation
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 microcirculation. Initially,
they sought to examine a major claim made by companies that sell magnets: that
magnets increase blood flow.
The researchers first found evidence to support this claim through
research with laboratory rats. In their initial study, magnets of 70
milliTesla (mT) field strength—about 10 times the strength of the common
refrigerator variety—were placed near the rat’s blood vessels.
Quantitative measurements of blood vessel diameter were taken both before and
after exposure to the static magnetic fields—the force created by the
magnets. Morris and Skalak found that the force had a significant effect:
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.
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.
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. “If an
injury doesn’t swell, it will heal faster—and the person will experience less
pain and better mobility,” says Skalak. 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. The ready
availability and low cost of this treatment could produce huge gains in worker
productivity and quality of life.
Skalak envisions the magnets being particularly useful to high
school, college, and professional sports teams, as well as school nurses and
retirement communities. He has plans to continue testing the effectiveness of
magnets through clinical trials and testing in elite athletes. 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.
“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,” says Skalak.
— Written by Melissa Maki
About the Author
U.Va.
News Staff
(434) 924-7116
Cr - www.virginia.edu
No comments:
Post a Comment