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饮食抑制违反会影响伏隔核和杏仁核的奖励反应。

Dietary restraint violations influence reward responses in nucleus accumbens and amygdala.

机构信息

Dartmouth College, USA.

出版信息

J Cogn Neurosci. 2011 Aug;23(8):1952-63. doi: 10.1162/jocn.2010.21568. Epub 2010 Aug 31.

DOI:10.1162/jocn.2010.21568
PMID:20807052
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3034108/
Abstract

Numerous studies have demonstrated that consuming high-calorie food leads to subsequent overeating by chronic dieters. The present study investigates the neural correlates of such self-regulatory failures using fMRI. Chronic dieters (n = 50) and non-dieters (n = 50) consumed either a 15-oz glass of cold water or a 15-oz milkshake and were subsequently imaged while viewing pictures of animals, environmental scenes, people, and appetizing food items. Results revealed a functional dissociation in nucleus accumbens and amygdala activity that paralleled well-established behavioral patterns of eating observed in dieters and non-dieters. Whereas non-dieters showed the greatest nucleus accumbens activity in response to food items after water consumption, dieters showed the greatest activity after consuming the milkshake. Activity in the left amygdala demonstrated the reverse interaction. Considered together with previously reported behavioral findings, the present results offer a suggested neural substrate for diet failure.

摘要

许多研究表明,高热量食物的摄入会导致习惯性节食者随后的过度进食。本研究使用 fMRI 来研究这种自我调节失败的神经相关性。慢性节食者(n = 50)和非节食者(n = 50)分别饮用 15 盎司的冷水或 15 盎司的奶昔,然后在观看动物、环境场景、人物和开胃食物的图片时进行成像。结果显示,伏隔核和杏仁核的活动存在功能分离,与节食者和非节食者观察到的饮食行为模式非常吻合。非节食者在饮水后对食物的反应中表现出最大的伏隔核活动,而节食者在饮用奶昔后表现出最大的活动。左杏仁核的活动则表现出相反的相互作用。与之前报道的行为研究结果相结合,本研究结果为节食失败提供了一个建议的神经基础。

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