Your search keyword '"aMCC, anterior mid cingulate cortex"' showing total 2 results

1. Patterns of brain structural connectivity differentiate normal weight from overweight subjects

Author

Jennifer S. Labus, Benjamin M. Ellingson, Claudia P. Sanmiguel, John D. Van Horn, Kirsten Tillisch, Connor Fling, Emeran A. Mayer, Aubrey D. Love, Davis C. Woodworth, and Arpana Gupta

Subjects

Male, HC, VIP, variable importance in projection, sgACC, subgenual anterior cingulate cortex, FACT, fiber assignment by continuous tracking, general linear model, variable importance in projection, Brain mapping, CT, cortical thickness, 0302 clinical medicine, MC, mean curvature, GLM, general linear model, sgACC, dlPFC, dorsolateral prefrontal cortex, negative predictive value, gray matter volume, repetition time, FOV, TE, echo time, 0303 health sciences, ANOVA, Brain, Regular Article, diffusion tensor imaging, anterior cingulate cortex, Diffusion Tensor Imaging, NPV, negative predictive value, Neurology, DTI, GMV, gray matter volume, Biomedical Imaging, sparse partial least squares for discrimination Analysis, posterior parietal cortex, FACT, ventral tegmental area, mean curvature, aMCC, sPLS-DA, sparse partial least squares for discrimination Analysis, lcsh:Computer applications to medicine. Medical informatics, Basic Behavioral and Social Science, Classification algorithm, NPV, 03 medical and health sciences, SA, Clinical Research, diffusion-weighted MRIs, Humans, Risk factor, HAD, hospital anxiety and Depression Scale, Morphological gray-matter, healthy control, Reward network, surface area, sPLS-DA, medicine.disease, Obesity, VIP, false-discovery rate, Neurology (clinical), DTI, diffusion tensor imaging, Anatomical white-matter connectivity, GLM, Neuroscience, Body mass index, 030217 neurology & neurosurgery, SPSS, PPC, posterior parietal cortex, TR, BMI, body mass index, DWI, Overweight, FOV, field of view, lcsh:RC346-429, Computer-Assisted, aMCC, anterior mid cingulate cortex, Neural Pathways, MC, hospital anxiety and Depression Scale, ANOVA, analysis of variance, 2. Zero hunger, dorsolateral prefrontal cortex, Brain Mapping, OFG, orbitofrontal gyrus, GMV, ACC, anterior cingulate cortex, HC, healthy control, Magnetic Resonance Imaging, TR, repetition time, lcsh:R858-859.7, Female, medicine.symptom, Psychology, field of view, dlPFC, PPC, VTA, Algorithms, CT, TE, Adult, analysis of variance, FA, orbitofrontal gyrus, OFG, Cognitive Neuroscience, body mass index, PPV, vmPFC, ventromedial prefrontal cortex, DWI, diffusion-weighted MRIs, ventromedial prefrontal cortex, echo time, VTA, ventral tegmental area, FDR, BMI, Neurochemical, vmPFC, Neuroimaging, Behavioral and Social Science, Image Interpretation, Computer-Assisted, medicine, Radiology, Nuclear Medicine and imaging, SPSS, statistical package for the social sciences, ACC, Image Interpretation, lcsh:Neurology. Diseases of the nervous system, 030304 developmental biology, Nutrition, fiber assignment by continuous tracking, subgenual anterior cingulate cortex, HAD, Neurosciences, Feeding Behavior, FDR, false-discovery rate, cortical thickness, statistical package for the social sciences, anterior mid cingulate cortex, SA, surface area, PPV, positive predictive value, FA, flip angle, flip angle, Multivariate analysis, positive predictive value, Ingestive behaviors

Abstract

Background Alterations in the hedonic component of ingestive behaviors have been implicated as a possible risk factor in the pathophysiology of overweight and obese individuals. Neuroimaging evidence from individuals with increasing body mass index suggests structural, functional, and neurochemical alterations in the extended reward network and associated networks. Aim To apply a multivariate pattern analysis to distinguish normal weight and overweight subjects based on gray and white-matter measurements. Methods Structural images (N = 120, overweight N = 63) and diffusion tensor images (DTI) (N = 60, overweight N = 30) were obtained from healthy control subjects. For the total sample the mean age for the overweight group (females = 32, males = 31) was 28.77 years (SD = 9.76) and for the normal weight group (females = 32, males = 25) was 27.13 years (SD = 9.62). Regional segmentation and parcellation of the brain images was performed using Freesurfer. Deterministic tractography was performed to measure the normalized fiber density between regions. A multivariate pattern analysis approach was used to examine whether brain measures can distinguish overweight from normal weight individuals. Results 1. White-matter classification: The classification algorithm, based on 2 signatures with 17 regional connections, achieved 97% accuracy in discriminating overweight individuals from normal weight individuals. For both brain signatures, greater connectivity as indexed by increased fiber density was observed in overweight compared to normal weight between the reward network regions and regions of the executive control, emotional arousal, and somatosensory networks. In contrast, the opposite pattern (decreased fiber density) was found between ventromedial prefrontal cortex and the anterior insula, and between thalamus and executive control network regions. 2. Gray-matter classification: The classification algorithm, based on 2 signatures with 42 morphological features, achieved 69% accuracy in discriminating overweight from normal weight. In both brain signatures regions of the reward, salience, executive control and emotional arousal networks were associated with lower morphological values in overweight individuals compared to normal weight individuals, while the opposite pattern was seen for regions of the somatosensory network. Conclusions 1. An increased BMI (i.e., overweight subjects) is associated with distinct changes in gray-matter and fiber density of the brain. 2. Classification algorithms based on white-matter connectivity involving regions of the reward and associated networks can identify specific targets for mechanistic studies and future drug development aimed at abnormal ingestive behavior and in overweight/obesity., Highlights • Multivariate analysis can be used to classify overweight from normal weight individuals. • Anatomical connectivity achieved 97% accuracy in the classification algorithm. • Greater connectivity was observed in extended reward and somatosensory regions. • Morphological gray-matter achieved 69% accuracy in the classification algorithm. • Lower morphological values were observed in regions of the extended reward network.

Published

2015

2. Patterns of brain structural connectivity differentiate normal weight from overweight subjects.

Author

Gupta A, Mayer EA, Sanmiguel CP, Van Horn JD, Woodworth D, Ellingson BM, Fling C, Love A, Tillisch K, and Labus JS

Subjects

Adult, Algorithms, Diffusion Tensor Imaging, Feeding Behavior physiology, Female, Humans, Magnetic Resonance Imaging, Male, Brain pathology, Brain Mapping, Image Interpretation, Computer-Assisted methods, Neural Pathways pathology, Overweight physiopathology

Abstract

Background: Alterations in the hedonic component of ingestive behaviors have been implicated as a possible risk factor in the pathophysiology of overweight and obese individuals. Neuroimaging evidence from individuals with increasing body mass index suggests structural, functional, and neurochemical alterations in the extended reward network and associated networks., Aim: To apply a multivariate pattern analysis to distinguish normal weight and overweight subjects based on gray and white-matter measurements., Methods: Structural images (N = 120, overweight N = 63) and diffusion tensor images (DTI) (N = 60, overweight N = 30) were obtained from healthy control subjects. For the total sample the mean age for the overweight group (females = 32, males = 31) was 28.77 years (SD = 9.76) and for the normal weight group (females = 32, males = 25) was 27.13 years (SD = 9.62). Regional segmentation and parcellation of the brain images was performed using Freesurfer. Deterministic tractography was performed to measure the normalized fiber density between regions. A multivariate pattern analysis approach was used to examine whether brain measures can distinguish overweight from normal weight individuals., Results: 1. White-matter classification: The classification algorithm, based on 2 signatures with 17 regional connections, achieved 97% accuracy in discriminating overweight individuals from normal weight individuals. For both brain signatures, greater connectivity as indexed by increased fiber density was observed in overweight compared to normal weight between the reward network regions and regions of the executive control, emotional arousal, and somatosensory networks. In contrast, the opposite pattern (decreased fiber density) was found between ventromedial prefrontal cortex and the anterior insula, and between thalamus and executive control network regions. 2. Gray-matter classification: The classification algorithm, based on 2 signatures with 42 morphological features, achieved 69% accuracy in discriminating overweight from normal weight. In both brain signatures regions of the reward, salience, executive control and emotional arousal networks were associated with lower morphological values in overweight individuals compared to normal weight individuals, while the opposite pattern was seen for regions of the somatosensory network., Conclusions: 1. An increased BMI (i.e., overweight subjects) is associated with distinct changes in gray-matter and fiber density of the brain. 2. Classification algorithms based on white-matter connectivity involving regions of the reward and associated networks can identify specific targets for mechanistic studies and future drug development aimed at abnormal ingestive behavior and in overweight/obesity.

Published

2015