A comprehensive macaque fMRI pipeline and hierarchical atlas

Jung, Benjamin; Taylor, Paul A.; Seidlitz, Jakob; Sponheim, Caleb; Perkins, Pierce; Ungerleider, Leslie G.; Glen, Daniel R.; Messinger, Adam

doi:10.1101/2020.08.05.237818

Cited by 7 publications

(15 citation statements)

References 53 publications

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“…AFNI @animal_warper uses 3dAllineate and 3dQwarp to compute affine and nonlinear alignments. The same NIMH Macaque Template (NMT) was used in Flirt+ANTs and AFNI @animal_warper pipelines (Jung et al, 2020; Seidlitz et al, 2018). The Macaque Dataset I and II were manually edited by well-trained experts (J.W.C, A.K, and T.X.)…”

Section: Methodsmentioning

confidence: 99%

“…To compare our deep learning models with state-of-the-art methods for brain extraction, we employed five widely-used skull stripping pipelines implemented in commonly used MRI packages (AFNI, ANTs, FSL, and FreeSurfer) (Avants et al, 2009; Cox, 1996; Fischl, 2012; Jenkinson et al, 2012). Specifically, we tested three intensity-based approaches (FSL BET, FreeSurfer HWA, and AFNI 3dSkullStrip) and two template-driven pipelines (Flirt+ANTS and AFNI @animal_warper) (Jung et al, 2020; Seidlitz et al, 2018; Tustison et al, 2020). The command and parameters of intensity-based approaches were selected based on the experiments and suggestions from the prior studies as follows (Xu et al, 2019; Zhao et al, 2018).…”

Section: Methodsmentioning

confidence: 99%

“…In recent years, registration-based label transferring (i.e. template-driven) approaches have been proposed as a potential solution for NHP brain extraction (Jung et al, 2020; Lohmeier et al, 2019; Seidlitz et al, 2018; Tasserie et al, 2020). These approaches start by registering an individual’s anatomical image to the template in order to establish the deformation between the subject-specific head and template head.…”

Section: Introductionmentioning

confidence: 99%

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U-Net Model for Brain Extraction: Trained on Humans for Transfer to Non-human Primates

Wang

et al. 2020

Preprint

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Brain extraction (a.k.a. skull stripping) is a fundamental step in the neuroimaging pipeline as it can affect the accuracy of downstream preprocess such as image registration, tissue classification, etc. Most brain extraction tools have been mainly orientated for human data and are often challenging for non-human primates (NHP). In recent attempts to improve the performance in NHP, deep learning models appear to outperform the traditional tools. However, given the minimal sample size of most NHP studies and notable variations in data quality, the deep learning models are very rarely applied in multi-site samples in NHP imaging. To overcome this challenge, we propose to use transfer-learning framework that leverages a large human imaging dataset to pretrain a convolutional neural network (i.e. U-Net Model), and then transferred to NHP data using a small NHP training sample. The resulting transfer-learning model converged faster and achieved more accurate performance than a similar U-Net Model trained exclusively on NHP samples. We improved the generalizability of the model by upgrading the transfer-learned model using additional training datasets from multiple research sites in the Primate Data-Exchange (PRIME-DE) consortium. Our final model outperformed brain extraction routines from popular MRI packages (AFNI, FSL, and FreeSurfer) across multiple heterogeneous multiple sites from PRIME-DE with less computational cost (20s~10min). Our model, code, and the skull-stripped mask repository of 136 macaque monkeys are publicly available for unrestricted use by the neuroimaging community at https://github.com/HumanBrainED/NHP-BrainExtraction.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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U-Net Model for Brain Extraction: Trained on Humans for Transfer to Non-human Primates

Wang

et al. 2020

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“…We developed a semi-automated lesion mapping procedure to assess the location and extent of the lesions. For all T2-weighted scans, volume estimates were taken by performing rigid (6-parameter rigid body transformation) and affine (diffeomorphic -allowing for 12parameter local warps in structure) warps on each scan to the NIMH Macaque Template version 2.0 (NMT; 0.5 mm 3 resolution) (Seidlitz et al, 2018;Jung et al, 2020) using AFNI's 3dAllineate function for the rigid transform (Cox, 1996;Saad et al, 2009) and antsRegistrationSyN in ANTs for the affine transform (Avants et al, 2011). We then applied thresholding to identify the area of hyperintensity on the transformed T2-weighted scans to generate a binary mask that corresponded to the area of damage.…”

Section: Lesion Assessmentmentioning

confidence: 99%

“…For the T1 scans showing MFC damage, we used AFNI's @animal_warper (Saad et al, 2009;Jung et al, 2020) to perform a rigid and affine alignment for each subject to the standard NMT version 2.0. For MFC damage, because the aspiration lesion resulted in collapse of nearby tissue into the space created by the lesion, we interpreted the extent of the damage in the transformed T1 scans by comparing the area of damage with the comparable region in the intact contralateral hemisphere, using anatomical and sulcal landmarks of the NMT as references.…”

Section: Lesion Assessmentmentioning

confidence: 99%

Selective prefrontal-amygdala circuit interactions underlie social and nonsocial valuation in rhesus macaques

et al. 2021

Preprint

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Lesion studies in macaques suggest dissociable functions of the orbitofrontal cortex (OFC) and medial frontal cortex (MFC), with OFC being essential for goal-directed decision making and MFC supporting social cognition. Bilateral amygdala damage results in impairments in both of these domains. There are extensive reciprocal connections between these prefrontal areas and the amygdala; however, it is not known whether the dissociable roles of OFC and MFC depend on functional interactions with the amygdala. To test this possibility, we compared the performance of male rhesus macaques (Macaca mulatta) with crossed surgical disconnection of the amygdala and either MFC (MFC x AMY, n=4) or OFC (OFC x AMY, n=4) to a group of unoperated controls (CON, n=5). All monkeys were assessed for their performance on two tasks to measure: (1) food-retrieval latencies while viewing videos of social and nonsocial stimuli in a test of social interest, and (2) object choices based on current food value using reinforcer devaluation in a test of goal-directed decision making. Compared to the CON group, the MFC x AMY group, but not the OFC x AMY group, showed significantly reduced food-retrieval latencies while viewing videos of conspecifics, indicating reduced social valuation and/or interest. By contrast, on the devaluation task, group OFC x AMY, but not group MFC x AMY, displayed deficits on object choices following changes in food value. These data indicate that the MFC and OFC must functionally interact with the amygdala to support normative social and nonsocial valuation, respectively.

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Longitudinal brain atlases of early developing cynomolgus macaques from birth to 48 months of age

Zhong

Wei

et al. 2022

NeuroImage

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A comprehensive macaque fMRI pipeline and hierarchical atlas

Cited by 7 publications

References 53 publications

U-Net Model for Brain Extraction: Trained on Humans for Transfer to Non-human Primates

U-Net Model for Brain Extraction: Trained on Humans for Transfer to Non-human Primates

Selective prefrontal-amygdala circuit interactions underlie social and nonsocial valuation in rhesus macaques

Longitudinal brain atlases of early developing cynomolgus macaques from birth to 48 months of age

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