Altered neural circuitry may lead to anorexia and bulimia
A landmark study, with first author Tyson Oberndorfer, MD, and led by Walter H. Kaye, MD, professor of psychiatry at the University of California, San Diego School of Medicine, suggests that the altered function of neural circuitry contributes to restricted eating in anorexia and overeating in bulimia.
The research, published June 4 in the early on-line edition of the American Journal of Psychiatry, may offer a pathway to new and more effective treatments for these serious eating disorders.
“It has been unknown whether individuals with anorexia or bulimia have a disturbance in the system that regulates appetite in the brain, or whether eating behavior is driven by other phenomena, such as an obsessional preoccupation with body image,” said Kaye, director of the UCSD Eating Disorders Treatment and Research Program. “However, this study confirms earlier studies by our group and others that establish a clear link between these disorders and neural processes in the insula, an area of the brain where taste is sensed and integrated with reward to help determine whether an individual hungry or full.”
The UC San Diego study used functional MRI to test this neurocircuitry by measuring the brain response to sweet tastes in 28 women who had recovered from either anorexia or bulimia.
Relative to a cohort of 14 women who had never suffered from either disorder, those recovered from anorexia had significantly diminished, and those recovered from bulimia, significantly elevated responses to the taste of sucrose in the right anterior insula.
“One possibility is that restricted eating and weight loss occurs in anorexia because the brain fails to accurately recognize hunger signals,” said Oberndorfer. “Alternately, overeating in bulimia could represent an exaggerated perception of hunger signals.”
A recent complementary study that investigated brain structure in anorexia and bulimia nervosa (Frank et al 2013) similarly highlights that the insula could be an integral part of eating disorder pathology.
The researchers added that such studies could have very important implications for treatment, and that identifying abnormal neural substrates could help to reformulate the basic pathology of eating disorders and offer new targets for treatment.
“It may be possible to modulate the experience by, for example, enhancing insula activity in individuals with anorexia or dampening the exaggerated or unstable response to food in those with bulimia,” said Kaye. Studies indicate that healthy subjects can use real-time fMRI, biofeedback or mindfulness training to alter the brain's response to food stimuli. For patients with anorexia who have an overly active satiety signal in response to palatable foods, the researchers suggest bland or even slightly aversive foods might prevent the brain's overstimulation. Medications may also be found that enhance the reward response to food, or decrease inhibition to food consumption in the brain's reward circuitry.
This study was supported in part by grants from the National Institute of Mental Health (grants MH46001, MH42984, K05-MD01894 and training grant T32-MH18399) and by the Price Foundation.
Additional contributors to the study include Guido K.W. Frank, MD; Alan N. Simmons, PhD; Angela Wagner, MD, PhD; Danyale McCurdy, PhD; Julie L. Fudge, MD; Tony T. Yang, MD, PhD; and Martin P. Paulus, MD.
The UCSD Eating Disorder Treatment and Research Program has a number of innovative programs and clinical trials for individuals with anorexia, bulimia or other eating disorders. For more information, go to http://eatingdisorders.ucsd.edu/
Media Contact
More Information:
http://www.ucsd.eduAll latest news from the category: Studies and Analyses
innovations-report maintains a wealth of in-depth studies and analyses from a variety of subject areas including business and finance, medicine and pharmacology, ecology and the environment, energy, communications and media, transportation, work, family and leisure.
Newest articles
Future AR/VR controllers could be the palm of your hand
Carnegie Mellon University’s EgoTouch creates simple interfaces for virtual and augmented reality. The new generation of augmented and virtual reality controllers may not just fit in the palm of your…
‘Game changer’ in lithium extraction
Rice researchers develop novel electrochemical reactor. A team of Rice University researchers led by Lisa Biswal and Haotian Wang has developed an innovative electrochemical reactor to extract lithium from natural…
The blue-green sustainable proteins of seaweed
… may soon be on your plate. The protein in sea lettuce, a type of seaweed, is a promising complement to both meat and other current alternative protein sources. Seaweed…