How could a single, nonpharmacological intervention help patients deal with disorders ranging from high blood pressure, to pain syndromes, to infertility, to rheumatoid arthritis? That question may have been answered by a study finding that eliciting the relaxation response – a physiologic state of deep rest – influences the activation patterns of genes associated with the body’s response to stress. The collaborative investigation by members of the Benson-Henry Institute for Mind/Body Medicine at Massachusetts General Hospital (MGH) and the Genomics Center at Beth Israel Deaconess Medical Center (BIDMC) appears in the open-access journal PLoS One.
“For hundreds of years Western medicine has looked at mind and body as totally separate entities, to the point where saying something ‘is all in your head’ implied that it was imaginary,” says Herbert Benson, MD, director emeritus of the Benson-Henry Institute and co-senior author of the PloS One report. “Now we’ve found how changing the activity of the mind can alter the way basic genetic instructions are implemented.”
Towia Libermann, PhD, director of the BIDMC Genomics Center and the report’s co-senior author, adds, “This is the first comprehensive study of how the mind can affect gene expression, linking what has been looked on as a ‘soft’ science with the ‘hard’ science of genomics. It is also important because of its focus on gene expression in healthy individuals, rather than in disease states.”
More than 35 years ago Benson first described the relaxation response, which can be elicited by practices including meditation, deep breathing and prayer; and his team has pioneered the field of mind/body medicine. Over the years, studies in many peer-reviewed journals documented how the relaxation response not only alleviates symptoms of psychological disorders such as anxiety but also affects physiologic factors such as heart rate, blood pressure, oxygen consumption and brain activity. While it became evident that the relaxation response was the opposite of the well documented fight-or-flight response, the mechanism underlying these effects was still unknown.
The current study was designed to investigate if changes in gene expression – whether specific genes are activated or repressed – were behind the wide-ranging effects of the relaxation response. The first phase compared gene expression patterns of 19 long-term practitioners of different relaxation response techniques with those of 19 individuals who had never engaged in such practices. Those control participants then went through an 8-week training program to investigate whether initiating relaxation response practice would change gene expression over time.
Both phases of the study indicated that the relaxation response alters the expression of genes involved with processes such as inflammation, programmed cell death and how the body handles free radicals – molecules produced by normal metabolism that, if not appropriately neutralized, can damage cells and tissues. To validate those results, both phases were repeated in 6 different relaxation response practitioners and 5 non-practitioners, resulting in significantly similar changes in gene expression.
Jeffery Dusek, PhD, co-lead author of the study notes, “Changes in the activation of these same genes have previously been seen in conditions such as post-traumatic stress disorder; but the relaxation-response-associated changes were the opposite of stress-associated changes and were much more pronounced in the long-term practitioners.” Formerly with the Benson-Henry Institute, Dusek is now at Abbott
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