Your search keyword '"Luke Priestley"' showing total 6 results

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

Author

Mo Shahdloo, Nima Khalighinejad, Luke Priestley, Matthew Rushworth, and Mark Chiew

Subjects

fMRI, non-human primate (NHP), raw data correction, off-resonance artifacts, simultaneous multi-slice, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionUse of functional MRI in awake non-human primate (NHPs) has recently increased. Scanning animals while awake makes data collection possible in the absence of anesthetic 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. In this study, we sought to thoroughly investigate the effect of a newly proposed dynamic off-resonance correction method on brain activation estimates using extended awake NHP data.MethodsWe correct for dynamic B0 changes in reconstruction of highly accelerated simultaneous multi-slice EPI acquisitions by estimating and correcting for dynamic field perturbations. Functional MRI data were collected in four male rhesus monkeys performing a decision-making task in the scanner, and analyses of improvements in sensitivity and reliability were performed compared to conventional image reconstruction.ResultsApplying the correction resulted in reduced bias and improved temporal stability in the reconstructed time-series data. We found increased sensitivity to functional activation at the individual and group levels, as well as improved reliability of statistical parameter estimates.ConclusionsOur 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.

Published

2024

2. A habenula-insular circuit encodes the willingness to act

Author

Nima Khalighinejad, Neil Garrett, Luke Priestley, Patricia Lockwood, and Matthew F. S. Rushworth

Subjects

Science

Abstract

A crucial component of voluntary behaviour is deciding that it is worth doing something rather than nothing. Here the authors show the brain network that encodes this decision, which includes the habenula and anterior insula.

Published

2021

3. Relationship between nuclei-specific amygdala connectivity and mental health dimensions in humans

Author

Miriam C. Klein-Flügge, Daria E. A. Jensen, Yu Takagi, Luke Priestley, Lennart Verhagen, Stephen M. Smith, and Matthew F. S. Rushworth

Subjects

Behavioral Neuroscience, All institutes and research themes of the Radboud University Medical Center, Social Psychology, Action, intention, and motor control, Experimental and Cognitive Psychology, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3]

Abstract

Item does not contain fulltext There has been increasing interest in using neuroimaging measures to predict psychiatric disorders. However, predictions usually rely on large brain networks and large disorder heterogeneity. Thus, they lack both anatomical and behavioural specificity, preventing the advancement of targeted interventions. Here we address both challenges. First, using resting-state functional magnetic resonance imaging, we parcellated the amygdala, a region implicated in mood disorders, into seven nuclei. Next, a questionnaire factor analysis provided subclinical mental health dimensions frequently altered in anxious-depressive individuals, such as negative emotions and sleep problems. Finally, for each behavioural dimension, we identified the most predictive resting-state functional connectivity between individual amygdala nuclei and highly specific regions of interest, such as the dorsal raphe nucleus in the brainstem or medial frontal cortical regions. Connectivity in circumscribed amygdala networks predicted behaviours in an independent dataset. Our results reveal specific relations between mental health dimensions and connectivity in precise subcortical networks. 18 p.

Published

2022

4. A habenula-insular circuit encodes the willingness to act

Author

Patricia L. Lockwood, Matthew F. S. Rushworth, Luke Priestley, Nima Khalighinejad, and Neil Garrett

Subjects

Adult, Male, Adolescent, Science, Decision Making, Decision, General Physics and Astronomy, Context (language use), Variation (game tree), General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Reward, Human behaviour, medicine, Contextual information, Animals, Humans, 030304 developmental biology, Probability, Brain network, Cerebral Cortex, 0303 health sciences, Anterior insula, Behavior, Habenula, Motivation, Multidisciplinary, Supplementary motor area, Brain, General Chemistry, Magnetic Resonance Imaging, medicine.anatomical_structure, Basal ganglia, Female, Psychology, 030217 neurology & neurosurgery, Cognitive psychology

Abstract

The decision that it is worth doing something rather than nothing is a core yet understudied feature of voluntary behaviour. Here we study “willingness to act”, the probability of making a response given the context. Human volunteers encountered opportunities to make effortful actions in order to receive rewards, while watching a movie inside a 7 T MRI scanner. Reward and other context features determined willingness-to-act. Activity in the habenula tracked trial-by-trial variation in participants’ willingness-to-act. The anterior insula encoded individual environment features that determined this willingness. We identify a multi-layered network in which contextual information is encoded in the anterior insula, converges on the habenula, and is then transmitted to the supplementary motor area, where the decision is made to either act or refrain from acting via the nigrostriatal pathway., A crucial component of voluntary behaviour is deciding that it is worth doing something rather than nothing. Here the authors show the brain network that encodes this decision, which includes the habenula and anterior insula.

Published

2022

5. Human decisions about when to act originate within a basal forebrain–nigral circuit

Author

Saad Jbabdi, Luke Priestley, Nima Khalighinejad, and Matthew F. S. Rushworth

Subjects

Adult, Male, Basal Forebrain, Decision Making, Models, Neurological, Substantia nigra, Striatum, structural equation modeling, medicine, Humans, human, Anterior cingulate cortex, Pedunculopontine nucleus, Basal forebrain, Multidisciplinary, Psychophysiological Interaction, Biological Sciences, Magnetic Resonance Imaging, Substantia Nigra, medicine.anatomical_structure, Habenula, Action (philosophy), ultrahigh-field MRI, Female, Nerve Net, Psychology, Neuroscience, self-initiated action

Abstract

Significance Decision-making studies often focus on brain mechanisms for selecting between goals and actions; however, another important, and often neglected, aspect of decision-making in humans concerns whether, at any given point in time, it is worth making any action at all. We showed that a considerable portion of the variance in when voluntary actions are emitted can be explained by a simple model that that takes into account key features of the current environment. By using ultrahigh-field MRI we identified a multilayered circuit in the human brain originating far beyond the medial frontal areas typically linked to human voluntary action starting in the basal forebrain and brain stem, converging in the dopaminergic midbrain, and only then projecting to striatum and cortex., Decisions about when to act are critical for survival in humans as in animals, but how a desire is translated into the decision that an action is worth taking at any particular point in time is incompletely understood. Here we show that a simple model developed to explain when animals decide it is worth taking an action also explains a significant portion of the variance in timing observed when humans take voluntary actions. The model focuses on the current environment’s potential for reward, the timing of the individual’s own recent actions, and the outcomes of those actions. We show, by using ultrahigh-field MRI scanning, that in addition to anterior cingulate cortex within medial frontal cortex, a group of subcortical structures including striatum, substantia nigra, basal forebrain (BF), pedunculopontine nucleus (PPN), and habenula (HB) encode trial-by-trial variation in action time. Further analysis of the activity patterns found in each area together with psychophysiological interaction analysis and structural equation modeling suggested a model in which BF integrates contextual information that will influence the decision about when to act and communicates this information, in parallel with PPN and HB influences, to nigrostriatal circuits. It is then in the nigrostriatal circuit that action initiation per se begins.

Published

2020

6. Relationship between nuclei-specific amygdala connectivity and mental health dimensions in humans

Author

Miriam C, Klein-Flügge, Daria E A, Jensen, Yu, Takagi, Luke, Priestley, Lennart, Verhagen, Stephen M, Smith, and Matthew F S, Rushworth

Abstract

There has been increasing interest in using neuroimaging measures to predict psychiatric disorders. However, predictions usually rely on large brain networks and large disorder heterogeneity. Thus, they lack both anatomical and behavioural specificity, preventing the advancement of targeted interventions. Here we address both challenges. First, using resting-state functional magnetic resonance imaging, we parcellated the amygdala, a region implicated in mood disorders, into seven nuclei. Next, a questionnaire factor analysis provided subclinical mental health dimensions frequently altered in anxious-depressive individuals, such as negative emotions and sleep problems. Finally, for each behavioural dimension, we identified the most predictive resting-state functional connectivity between individual amygdala nuclei and highly specific regions of interest, such as the dorsal raphe nucleus in the brainstem or medial frontal cortical regions. Connectivity in circumscribed amygdala networks predicted behaviours in an independent dataset. Our results reveal specific relations between mental health dimensions and connectivity in precise subcortical networks.

Published

2020