Model‐based dynamic off‐resonance correction for improved accelerated fMRI in awake behaving nonhuman primates

Shahdloo, Mohammad; Schüffelgen, Urs; Papp, Daniel S.; Miller, Karla L.; Chiew, Mark

doi:10.1002/mrm.29167

Cited by 5 publications

(10 citation statements)

References 46 publications

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“…T2 ∗ EPI images acquired during the experimental task were reconstructed using a custom offline reconstruction script, using techniques described previously. 49 Preprocessing of structural and functional images involved tools from the FMRIB Software Library (FSL), 50 MATLAB (R2022a, Mathworks), Advanced Normalisation Tools (ANTs; http://stnava.github.io/ANTs ), 45 and the Magnetic Resonance Comparative Anatomy Toolbox (MrCat; http://github.com/neuroecology/MrCat ).…”

Section: Methodsmentioning

confidence: 99%

A frontopolar-temporal circuit determines the impact of social information in macaque decision making

Mahmoodi,

Harbison,

Bongioanni

et al. 2024

Neuron

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Section: Methodsmentioning

confidence: 99%

A frontopolar-temporal circuit determines the impact of social information in macaque decision making

Mahmoodi,

Harbison,

Bongioanni

et al. 2024

Neuron

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“…Single-band reference data and fully sampled calibration data were acquired along with the functional data as separate parts of the imaging sequence. Standard Nyquist ghost correction and dynamic zeroth-order B0 correction were applied on all reconstructions prior to off-resonance estimation and correction (Shahdloo et al, 2022).…”

Section: Methodsmentioning

confidence: 99%

“…Recently, we proposed a method to correct for these dynamic B0 changes (Shahdloo et al, 2022) by using the reference navigator data which are often available in most standard echo planar imaging (EPI) sequences used for fMRI data acquisition (Fig. 1a).…”

Section: Introductionmentioning

confidence: 99%

“… (a,b) EPI reference navigators in each frame are compared to a reference frame to estimate the dynamic linear off-resonance. These estimates are then used to correct the imaging data (Shahdloo et al, 2022). (c) This off-resonance correction method was validated in a decision-making task in awake NHPs, where the animals decide to act based on the number and colour of dots appearing on the screen, respond by touching a pad, and receive a liquid reward based on the response.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic off-resonance correction improves functional image analysis in fMRI of awake behaving non-human primates

Shahdloo,

Khalighinejad,

Priestley

et al. 2023

Preprint

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Use of functional MRI in awake non-human primate (NHPs) has recently increased. Scanning animals while awake makes data collection possible in the absence of anaesthetic modulation and with an extended range of possible experimental designs. Robust awake NHP imaging however is challenging due to the strong artifacts caused by time-varying off-resonance changes introduced by the animal's body motion. Recently, an image reconstruction technique has been proposed to estimate these off-resonance changes using the navigator data that is typically collected during fMRI scans to correct the data and compensate for the changes. In this study, we sought to thoroughly investigate the effect of this correction on the brain activation estimates using extended awake NHP data. Our results show significant improvements in image fidelity using our proposed correction strategy, as well as greatly enhanced and more reliable activation estimates in GLM analyses.

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“…Offline reconstruction of the raw functional data was performed following the dynamic off-resonance correction method developed by Shahdloo et al 80 . In summary, standard Nyquist ghost correction and dynamic zeroth-order B0 correction were applied first.…”

Section: Supplementary Materialsmentioning

confidence: 99%

Dorsal Raphe Nucleus Controls Motivational State Transitions in Monkeys

Priestley,

Chiew,

Shahdloo

et al. 2024

Preprint

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The dorsal raphe nucleus (DRN) is an important source of serotonin in the brain but fundamental aspects of its function remain elusive. Here, we present a combination of minimally invasive recording and disruption studies to show that DRN brings about changes in motivation states. We use recently developed methods for identifying temporal patterns in behaviour to show that monkeys change their motivation depending on the availability of rewards in the environment. Distinctive patterns of DRN activity occur when monkeys transition between a high motivation state occupied when rewards are abundant, to a low motivation state engendered by reward scarcity. Disrupting DRN diminishes sensitivity to the reward environment and perturbs transitions in motivational states.

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Model‐based dynamic off‐resonance correction for improved accelerated fMRI in awake behaving nonhuman primates

Cited by 5 publications

References 46 publications

A frontopolar-temporal circuit determines the impact of social information in macaque decision making

A frontopolar-temporal circuit determines the impact of social information in macaque decision making

Dynamic off-resonance correction improves functional image analysis in fMRI of awake behaving non-human primates

Dorsal Raphe Nucleus Controls Motivational State Transitions in Monkeys

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