Multi-Atlas Library for Eliminating Normalization Failures in Non-Human Primates

Maldjian, Joseph A.; Shively, Carol A.; Nader, Michael A.; Friedman, David P.; Whitlow, Christopher T.

doi:10.1007/s12021-015-9291-4

Cited by 9 publications

(8 citation statements)

References 16 publications

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“…Data for the frontal cortex were defined from a well-established nonhuman primate atlas, UNC-parcellation [ 45 ]. Complete methods for regional CMR generation with the two atlases can be found at Maldjian et al 2015 [ 46 ].…”

Section: Methodsmentioning

confidence: 99%

Blood‐Based Bioenergetic Profiling Reflects Differences in Brain Bioenergetics and Metabolism

Tyrrell

Bharadwaj

Jorgensen

et al. 2017

Oxidative Medicine and Cellular Longevity

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Blood-based bioenergetic profiling provides a minimally invasive assessment of mitochondrial health shown to be related to key features of aging. Previous studies show that blood cells recapitulate mitochondrial alterations in the central nervous system under pathological conditions, including the development of Alzheimer's disease. In this study of nonhuman primates, we focus on mitochondrial function and bioenergetic capacity assessed by the respirometric profiling of monocytes, platelets, and frontal cortex mitochondria. Our data indicate that differences in the maximal respiratory capacity of brain mitochondria are reflected by CD14+ monocyte maximal respiratory capacity and platelet and monocyte bioenergetic health index. A subset of nonhuman primates also underwent [18F] fluorodeoxyglucose positron emission tomography (FDG-PET) imaging to assess brain glucose metabolism. Our results indicate that platelet respiratory capacity positively correlates to measures of glucose metabolism in multiple brain regions. Altogether, the results of this study provide early evidence that blood-based bioenergetic profiling is related to brain mitochondrial metabolism. While these measures cannot substitute for direct measures of brain metabolism, provided by measures such as FDG-PET, they may have utility as a metabolic biomarker and screening tool to identify individuals exhibiting systemic bioenergetic decline who may therefore be at risk for the development of neurodegenerative diseases.

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Section: Methodsmentioning

confidence: 99%

Blood‐Based Bioenergetic Profiling Reflects Differences in Brain Bioenergetics and Metabolism

Tyrrell

Bharadwaj

Jorgensen

et al. 2017

Oxidative Medicine and Cellular Longevity

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“…Voxel-based morphometry is a powerful method for investigating anatomical brain abnormalities associated with human neurodevelopmental and psychiatric disorders. Although widely used in human neuroimaging studies, the application of VBM to vertebrate model organisms such as non-human primates and rodents has been limited by the accuracy of brain registration methods [57,58]. Advances in non-linear registration techniques and the construction of digital atlases have now allowed us to develop quantitative methods for voxel, deformation and volume-based analysis of zebrafish brains.…”

Section: Discussionmentioning

confidence: 99%

Morphometric analysis and neuroanatomical mapping of the zebrafish brain

Gupta

Marquart

Horstick

et al. 2018

Methods

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Large-scale genomic studies have recently identified genetic variants causative for major neurodevelopmental disorders, such as intellectual disability and autism. However, determining how underlying developmental processes are affected by these mutations remains a significant challenge in the field. Zebrafish is an established model system in developmental neurogenetics that may be useful in uncovering the mechanisms of these mutations. Here we describe the use of voxel-intensity, deformation field, and volume-based morphometric techniques for the systematic and unbiased analysis of gene knock-down and environmental exposure-induced phenotypes in zebrafish. We first present a computational method for brain segmentation based on transgene expression patterns to create a comprehensive neuroanatomical map. This map allowed us to disclose statistically significant changes in brain microstructure and composition in neurodevelopmental models. We demonstrate the effectiveness of morphometric techniques in measuring changes in the relative size of neuroanatomical subdivisions in atoh7 morphant larvae and in identifying phenotypes in larvae treated with valproic acid, a chemical demonstrated to increase the risk of autism in humans. These tools enable rigorous evaluation of the effects of gene mutations and environmental exposures on neural development, providing an entry point for cellular and molecular analysis of basic developmental processes as well as neurodevelopmental and neurodegenerative disorders.

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“…Ballanger et al applied MaS method to extract brain from T1weighted (T1w) MR images of crab-eating monkeys (Macaca fascicularis) (Ballanger et al, 2013), and they reported the first MaS dataset for NHP. Maldjian et al (2016) presented studyspecific atlases for rhesus, vervet, and cynomolgus monkeys. Brain extraction was used to transform the labels in the best performed atlas judged by image similarity; no quantitative evaluation was reported though.…”

Section: Brain Extractionmentioning

confidence: 99%

MonkeyCBP: A Toolbox for Connectivity-Based Parcellation of Monkey Brain

Yang

Fan

et al. 2020

Front. Neuroinform.

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Non-human primate models are widely used in studying the brain mechanism underlying brain development, cognitive functions, and psychiatric disorders. Neuroimaging techniques, such as magnetic resonance imaging, play an important role in the examinations of brain structure and functions. As an indispensable tool for brain imaging data analysis, brain atlases have been extensively investigated, and a variety of versions constructed. These atlases diverge in the criteria based on which they are plotted. The criteria range from cytoarchitectonic features, neurotransmitter receptor distributions, myelination fingerprints, and transcriptomic patterns to structural and functional connectomic profiles. Among them, brainnetome atlas is tightly related to brain connectome information and built by parcellating the brain on the basis of the anatomical connectivity profiles derived from structural neuroimaging data. The pipeline for building the brainnetome atlas has been published as a toolbox named ATPP (A Pipeline for Automatic Tractography-Based Brain Parcellation). In this paper, we present a variation of ATPP, which is dedicated to monkey brain parcellation, to address the significant differences in the process between the two species. The new toolbox, MonkeyCBP, has major alterations in three aspects: brain extraction, image registration, and validity indices. By parcellating two different brain regions (posterior cingulate cortex) and (frontal pole) of the rhesus monkey, we demonstrate the efficacy of these alterations. The toolbox has been made public (https://github.com/bheAI/MonkeyCBP_CLI, https: //github.com/bheAI/MonkeyCBP_GUI). It is expected that the toolbox can benefit the non-human primate neuroimaging community with high-throughput computation and low labor involvement.

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Multi-Atlas Library for Eliminating Normalization Failures in Non-Human Primates

Cited by 9 publications

References 16 publications

Blood‐Based Bioenergetic Profiling Reflects Differences in Brain Bioenergetics and Metabolism

Blood‐Based Bioenergetic Profiling Reflects Differences in Brain Bioenergetics and Metabolism

Morphometric analysis and neuroanatomical mapping of the zebrafish brain

MonkeyCBP: A Toolbox for Connectivity-Based Parcellation of Monkey Brain

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