A multimodal MRI study of the neural mechanisms of emotion regulation impairment in women with obesity

Steward, Trevor; Picó-Pérez, Maria; Mestre‐Bach, Gemma; Martínez‐Zalacaín, Ignacio; Suñol, Maria; Jiménez‐Murcia, Susana; Fernández-Formoso, José Antonio; Vilarrasa, Núria; García-Ruiz-de-Gordejuela, Amador; Heras, Misericordia Veciana de las; Custal, Núria; Virgili, N.; López-Urdiales, Rafael; Menchón, José M.; Granero, Roser; Soriano‐Mas, Carles; Fernández‐Aranda, Fernando

doi:10.1038/s41398-019-0533-3

Cited by 29 publications

(33 citation statements)

References 64 publications

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“…Based on our data, we propose that in BED, WM alterations in AD and FA in pathways connecting fronto‐limbic and temporal–parietal regions may be associated with repetitive difficulties during processes of eating‐related decisions (Bissonette & Roesch, 2016; Ostlund & Balleine, 2005; Steward et al, 2019).…”

Section: Discussionmentioning

confidence: 79%

Brain white matter microstructure in obese women with binge eating disorder

Estella

Sanches

Maranhão

et al. 2020

Euro Eating Disorders Rev

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Objective Research on potential brain circuit abnormalities in binge eating disorder (BED) is limited. Here, we assess white matter (WM) microstructure in obese women with BED. Method Diffusion tensor imaging data were acquired, and tract‐based spatial statistics used to examine WM in women with BED who were obese (n = 17) compared to normal‐weight (NWC) (n = 17) and to women who were obese (OBC) (n = 13). Body mass index (BMI) was a covariate in the analyses. Results The BED group (vs. NWC) had greater axial diffusion (AD) in the forceps minor, anterior thalamic radiation, superior and inferior longitudinal fasciculus, that is, in pathways connecting fronto‐limbic regions. Microstructures differences in AD between the BED and OBC groups were seen in fronto‐limbic pathways extending to temporoparietal pathways. The BED (vs. OBC) group had greater fractional anisotropy in the forceps minor and greater AD in the superior longitudinal fasciculus, cingulate gyrus, and corpus callosum, consistent with fronto‐tempoparietal pathways. Conclusion Women with BED show WM alterations in AD in fronto‐limbic and parietal pathways that are important in decision‐making processes. As BMI was a covariate in the analyses, alterations in BED may be part of the pathology, but whether they are a cause or effect of illness is unclear.

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Section: Discussionmentioning

confidence: 79%

Brain white matter microstructure in obese women with binge eating disorder

Estella

Sanches

Maranhão

et al. 2020

Euro Eating Disorders Rev

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“…Further, increased macroscale connectivity, particularly in the prefrontal, parietal, and cingulate cortices is known to be related to eating behaviors in people with obesity (Park et al, 2016; Park, Lee, et al, 2018; Park, Moon, et al, 2018). Indeed, imbalance in inhibitory control and food‐related reward system in the prefrontal cortex and paralimbic areas is associated with increased feelings of hunger (Tataranni et al, 1999; Tataranni & DelParigi, 2003) and may lead to overeating and weight gain (Brooks et al, 2013; Ding et al, 2020; Olivo et al, 2017; Steward, Juaneda‐Seguí, et al, 2019; Steward, Picó‐Pérez, et al, 2019; Vainik, Dagher, Dubé, & Fellows, 2013; Van Meer et al, 2019; Van Opstal et al, 2018; Van Opstal et al, 2019; Verdejo‐Román et al, 2017; Volkow, Wang, Telang, et al, 2008; Ziauddeen et al, 2015). In contrast, we found negative associations with obesity phenotypes in brain regions involved in multisensory processing, particularly precentral gyrus, inferior temporal gyrus, fusiform gyrus, superior temporal sulcus, and thalamus.…”

Section: Discussionmentioning

confidence: 99%

“…First, we used a large‐scale ( n ~ 2,400) fMRI dataset spanning four independent sites. Many previous studies had used small sample sizes and single cohorts, perhaps resulting in conflicting reports concerning obesity phenotype‐associated brain regions (Ding et al, 2020; Gupta et al, 2017; Herrmann et al, 2019; Marqués‐Iturria et al, 2013; Van Meer et al, 2019; Opel et al, 2015; Van Opstal et al, 2019; Park et al, 2015; Park et al, 2016; Park, Lee, et al, 2018; Park, Moon, et al, 2018; Shott et al, 2015; Steward, Picó‐Pérez, et al, 2019; Stoeckel et al, 2008). Our study attempted to circumvent these shortcomings by leveraging a large‐scale dataset from different cohorts, which included a wide range of ages and ethnicities.…”

Section: Discussionmentioning

confidence: 99%

“…Neurobiological studies have found that dysregulation of reward and inhibitory circuits gives rise to an increased threshold for satiation, ultimately leading to overeating (Martin et al, 2010; Murray et al, 2014; Steward, Miranda‐Olivos, Soriano‐Mas, & Fernández‐Aranda, 2019; Val‐Laillet et al, 2015; Van Opstal et al, 2018; Verdejo‐Román et al, 2017; Ziauddeen et al, 2015). Recent neuroimaging studies have increasingly shown associations between obesity and alterations in cortical and subcortical morphology (Herrmann, Tesar, Beier, Berg, & Warrings, 2019; Marqués‐Iturria et al, 2013; Shott et al, 2015), brain activity (Brooks, Cedernaes, & Schiöth, 2013; Goldstone et al, 2009; Gupta et al, 2018; Opel et al, 2015; Park, Hong, & Park, 2017; Steward, Juaneda‐Seguí, et al, 2019; Stoeckel et al, 2008; Van Meer et al, 2019), functional connectivity (García‐García et al, 2013; García‐García et al, 2015; Lips et al, 2014; Park, Seo, & Park, 2016; Park, Seo, Yi, & Park, 2015), and diffusivity (Gupta et al, 2017; Olivo et al, 2017; Steward, Picó‐Pérez, et al, 2019). These studies collectively show that the pathophysiology of obesity is associated with various types of brain measurements.…”

Section: Introductionmentioning

confidence: 99%

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Whole‐brain functional connectivity correlates of obesity phenotypes

Park

Byeon

Lee

et al. 2020

Human Brain Mapping

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Dysregulated neural mechanisms in reward and somatosensory circuits result in an increased appetitive drive for and reduced inhibitory control of eating, which in turn causes obesity. Despite many studies investigating the brain mechanisms of obesity, the role of macroscale whole‐brain functional connectivity remains poorly understood. Here, we identified a neuroimaging‐based functional connectivity pattern associated with obesity phenotypes by using functional connectivity analysis combined with machine learning in a large‐scale (n ~ 2,400) dataset spanning four independent cohorts. We found that brain regions containing the reward circuit positively associated with obesity phenotypes, while brain regions for sensory processing showed negative associations. Our study introduces a novel perspective for understanding how the whole‐brain functional connectivity correlates with obesity phenotypes. Furthermore, we demonstrated the generalizability of our findings by correlating the functional connectivity pattern with obesity phenotypes in three independent datasets containing subjects of multiple ages and ethnicities. Our findings suggest that obesity phenotypes can be understood in terms of macroscale whole‐brain functional connectivity and have important implications for the obesity neuroimaging community.

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“…This finding suggests the existence of a high-risk subset of individuals with OB that is characterized by decreased vmPFC activation and higher risk taking. Indeed, one recent study linked vmPFC alterations to emotion regulation deficits in OB [35], and impulsive eating behaviors have been associated with poorer decision making on the Iowa Gambling Task, a task whose performance is understood to be contingent on vmPFC activity [36]. Previous research has posited that the vmPFC, which is generally active in risk-taking tasks, integrates cognitive control and affect signals to attribute value to stimuli, to associate that value with choices, and to determine whether it should be approached or avoided [37].…”

Section: Discussionmentioning

confidence: 99%

What Difference Does it Make? Risk-Taking Behavior in Obesity after a Loss is Associated with Decreased Ventromedial Prefrontal Cortex Activity

Steward

Juaneda-Seguí

Mestre‐Bach

et al. 2019

JCM

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Altered activity in decision-making neural circuitry may underlie the maladaptive food choices found in obesity. Here, we aimed to identify the brain regions purportedly underpinning risk-taking behavior in individuals with obesity. Twenty-three adult women with obesity and twenty-three healthy weight controls completed the Risky Gains Task during functional magnetic resonance imaging (fMRI). This task allows participants to choose between a safe option for a small, guaranteed monetary reward and risky options with larger rewards. fMRI analyses comparing losing trials to winning trials found that participants with obesity presented decreased activity in the left anterior insula in comparison to controls (p < 0.05, AlphaSim corrected). Moreover, left insula activation during losses vs. wins was negatively correlated with UPPS-P questionnaire sensation seeking scores. During safe vs. risky trials following a loss, the control group exhibited increased activation in the ventromedial prefrontal cortex (vmPFC) (p < 0.05, AlphaSim corrected) in comparison to the OB group. Moreover, vmPFC response in the obesity group during post-loss trials was negatively correlated with risky choices on the task overall. As a whole, our findings support that diminished tuning of the insula towards interoceptive signals may lead to a lack of input to the vmPFC when weighing the costs and benefits of risky choices.

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A multimodal MRI study of the neural mechanisms of emotion regulation impairment in women with obesity

Cited by 29 publications

References 64 publications

Brain white matter microstructure in obese women with binge eating disorder

Brain white matter microstructure in obese women with binge eating disorder

Whole‐brain functional connectivity correlates of obesity phenotypes

What Difference Does it Make? Risk-Taking Behavior in Obesity after a Loss is Associated with Decreased Ventromedial Prefrontal Cortex Activity

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