Stressing diets? Amygdala networks, cumulative cortisol, and weight loss in adolescents with excess weight

Martin-Perez, Cristina; Contreras-Rodriguez, Oren; Verdejo-Roman, Juan; Vilar-Lopez, Raquel; Gonzalez-Perez, Raquel; Verdejo-Garcia, Antonio

Publicación: INTERNATIONAL JOURNAL OF OBESITY
2020
VL / 44 - BP / 2001 - EP / 2010
abstract
Objective The amygdala is importantly involved in stress and obesity, but its role on weight change and diet-related stress remains unexplored among adolescents with excess weight. We aimed to examine the functional connectivity of the Central and Basolateral amygdala nuclei (CeA and BLA) among adolescents, and to explore the longitudinal association between brain connectivity measures and diet-related cortisol and weight loss in adolescents with excess weight. Methods We compared resting-state functional connectivity between adolescents with excess (EW,N = 34; Age = 16.44 +/- 1.66) and normal weight (NW,N = 36; Age = 16.50 +/- 1.40) using a seed-based (CeA and BLA) whole-brain approach. Then, in a subset of 30 adolescents with EW, followed-up after 3-months of dietary/lifestyle intervention, we explored for interactions between connectivity in the CeA/BLA networks and weight loss. Regression analyses were performed to explore the relationship between accumulated cortisol and weight loss, and to test the potential effect of the amygdala networks on such association. Results In EW compared with NW, the CeA regions showed higher functional connectivity with anterior portions, and lower connectivity with posterior portions of the cingulate cortex, while the left BLA regions showed lower connectivity with the dorsal caudate and angular gyrus. In addition, higher connectivity between the left CeA-midbrain network was negatively associated with weight loss. Hair cortisol significantly predicted weight change (p = 0.012). However, this association was no longer significant (p = 0.164) when considering the CeA-midbrain network in the model as an additional predictor. Conclusions Adolescents with EW showed functional connectivity alterations within the BLA/CeA networks. The CeA-midbrain network might constitute an important brain pathway regulating weight change.

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