Your search keyword '"Tim J Preston"' showing total 10 results

1. Impulsive choice in hippocampal but not orbitofrontal cortex-lesioned rats on a nonspatial decision-making maze task

Author

Thomas G. Campbell, Mark E. Walton, Stephen B. McHugh, Peter H. Rudebeck, Mark G. Baxter, Sarah R. Rudebeck, Matthew F. S. Rushworth, Timothy Y. Mariano, David M. Bannerman, J. N. P. Rawlins, and Tim J Preston

Subjects

Male, Decision Making, Water maze, Hippocampal formation, Intertemporal choice, Impulsivity, Spatial memory, behavioral disciplines and activities, Choice Behavior, Hippocampus, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, medicine, water maze, Animals, Maze Learning, 030304 developmental biology, 0303 health sciences, delay discounting, General Neuroscience, T-maze, Frontal Lobe, Rats, spatial, Frontal lobe, Impulsive Behavior, Orbitofrontal cortex, reversal, medicine.symptom, Psychology, Neuroscience, 030217 neurology & neurosurgery, psychological phenomena and processes, Cognitive psychology

Abstract

Orbitofrontal cortical (OFC) and hippocampal (HPC) lesions in primates and rodents have been associated with impulsive behaviour. We showed previously that OFC- or HPC-lesioned rats chose the immediate low-reward (LR) option in preference to the delayed high-reward (HR) option, where LR and HR were associated with different spatial responses in a uniform grey T-maze. We now report that on a novel nonspatial T-maze task in which the HR and LR options are associated with patterned goal arms (black-and-white stripes vs. gray), OFC-lesioned rats did not show impulsive behaviour, choosing the delayed HR option, and were indistinguishable from controls. In contrast, HPC-lesioned rats exhibited impulsive choice in the nonspatial decision-making task, although they chose the HR option on the majority of trials when there was a 10-s delay associated with both goal arms. The previously reported impairment in OFC-lesioned rats on the spatial version of the intertemporal choice task is unlikely to reflect a general problem with spatial learning, because OFC lesions were without effect on acquisition of the standard reference memory water-maze task and spatial working memory performance (nonmatching-to-place) on the T-maze. The differential effect of OFC lesions on the two versions of the intertemporal choice task may be explained instead in terms of the putative role of OFC in using associative information to represent expected outcomes and generate predictions. The impulsivity in HPC-lesioned rats may reflect impaired temporal information processing, and emphasizes a role for the hippocampus beyond the spatial domain.

Published

2016

2. Feature-Independent Neural Coding of Target Detection during Search of Natural Scenes

Author

Fei Guo, Barry Giesbrecht, Miguel P. Eckstein, Tim J Preston, and Koel Das

Subjects

Adult, Male, Signal Detection, Psychological, Eye Movements, genetic structures, Intraparietal sulcus, Visual system, Choice Behavior, Young Adult, Discrimination, Psychological, Lateral intraparietal cortex, Image Processing, Computer-Assisted, medicine, Humans, Attention, Visual Pathways, Visual search, Brain Mapping, Communication, business.industry, General Neuroscience, Brain, Eye movement, Pattern recognition, Articles, Magnetic Resonance Imaging, Oxygen, Dorsolateral prefrontal cortex, Visual cortex, medicine.anatomical_structure, Pattern Recognition, Visual, Area Under Curve, Female, Artificial intelligence, Psychology, business, Neural coding, Photic Stimulation

Abstract

Visual search requires humans to detect a great variety of target objects in scenes cluttered by other objects or the natural environment. It is unknown whether there is a general purpose neural detection mechanism in the brain that codes the presence of a wide variety of categories of objects embedded in natural scenes. We provide evidence for a feature-independent coding mechanism for detecting behaviorally relevant targets in natural scenes in the dorsal frontoparietal network. Pattern classifiers using single-trial fMRI responses in the dorsal frontoparietal network reliably predicted the presence of 368 different target objects and also the observer's choices. Other vision-related areas such as the primary visual cortex, lateral occipital complex, the parahippocampal, and the fusiform gyri did not predict target presence, while high-level association areas related to general purpose decision making, including the dorsolateral prefrontal cortex and anterior cingulate, did. Activity in the intraparietal sulcus, a main area in the dorsal frontoparietal network, correlated with observers' decision confidence and with the task difficulty of individual images. These results cannot be explained by physical differences across images or eye movements. Thus, the dorsal frontoparietal network detects behaviorally relevant targets in natural scenes independent of their defining visual features and may be the human analog of the priority map in monkey lateral intraparietal cortex.

Published

2012

3. Adaptive Estimation of Three-Dimensional Structure in the Human Brain

Author

Tim J Preston, Zoe Kourtzi, and Andrew E. Welchman

Subjects

Adult, media_common.quotation_subject, Young Adult, Imaging, Three-Dimensional, Form perception, Perception, Psychophysics, Humans, media_common, Brain Mapping, Communication, Monocular, business.industry, General Neuroscience, Brain, fMRI adaptation, Articles, Adaptation, Physiological, Form Perception, Binocular disparity, Kinetic depth effect, business, Depth perception, Psychology, Neuroscience, Photic Stimulation

Abstract

Perceiving the three-dimensional (3D) properties of the environment relies on the brain bringing together ambiguous cues (e.g., binocular disparity, shading, texture) with information gained from short- and long-term experience. Perceptual aftereffects, in which the perception of an ambiguous 3D stimulus is biased away from the shape of a previously viewed stimulus, provide a sensitive means of probing this process, yet little is known about their neural basis. Here, we investigate 3D aftereffects using psychophysical and functional MRI (fMRI) adaptation paradigms to gain insight into the cortical circuits that mediate the perceptual interpretation of ambiguous depth signals. Using two classic bistable stimuli (Mach card, kinetic depth effect), we test aftereffects produced by 3D shapes defined by binocular (disparity) or monocular (texture, shading) depth cues. We show that the processing of ambiguous 3D stimuli in dorsal visual cortical areas (V3B/KO, V7) and posterior parietal regions is modulated by adaptation in line with perceptual aftereffects. Similar behavioral and fMRI adaptation effects for the two types of bistable stimuli suggest common neural substrates for depth aftereffects independent of the inducing depth cues (disparity, texture, shading). In line with current thinking about the role of adaptation in sensory optimization, our findings provide evidence that estimation of 3D shape in dorsal cortical areas takes account of the adaptive context to resolve depth ambiguity and interpret 3D structure.

Published

2009

4. Multivoxel Pattern Selectivity for Perceptually Relevant Binocular Disparities in the Human Brain

Author

Andrew E. Welchman, Tim J Preston, Shengqiao Li, and Zoe Kourtzi

Subjects

Adult, Vision Disparity, genetic structures, parasitic diseases, medicine, Humans, Binocular neurons, Visual Cortex, Depth Perception, Communication, medicine.diagnostic_test, business.industry, General Neuroscience, Brain, Articles, Magnetic Resonance Imaging, Visual cortex, medicine.anatomical_structure, Stereopsis, Random dot stereogram, Multivariate Analysis, Binocular disparity, Depth perception, business, Psychology, Functional magnetic resonance imaging, Neuroscience, Photic Stimulation

Abstract

Processing of binocular disparity is thought to be widespread throughout cortex, highlighting its importance for perception and action. Yet the computations and functional roles underlying this activity across areas remain largely unknown. Here, we trace the neural representations mediating depth perception across human brain areas using multivariate analysis methods and high-resolution imaging. Presenting disparity-defined planes, we determine functional magnetic resonance imaging (fMRI) selectivity to near versus far depth positions. First, we test the perceptual relevance of this selectivity, comparing the pattern-based decoding of fMRI responses evoked by random dot stereograms that support depth perception (correlated RDS) with the decoding of stimuli containing disparities to which the perceptual system is blind (anticorrelated RDS). Preferential disparity selectivity for correlated stimuli in dorsal (visual and parietal) areas and higher ventral area LO (lateral occipital area) suggests encoding of perceptually relevant information, in contrast to early (V1, V2) and intermediate ventral (V3v, V4) visual cortical areas that show similar selectivity for both correlated and anticorrelated stimuli. Second, manipulating disparity parametrically, we show that dorsal areas encode the metric disparity structure of the viewed stimuli (i.e., disparity magnitude), whereas ventral area LO appears to represent depth position in a categorical manner (i.e., disparity sign). Our findings suggest that activity in both visual streams is commensurate with the use of disparity for depth perception but the neural computations may differ. Intriguingly, perceptually relevant responses in the dorsal stream are tuned to disparity content and emerge at a comparatively earlier stage than categorical representations for depth position in the ventral stream. ispartof: Journal of Neuroscience vol:28 issue:44 pages:11315-27 ispartof: location:United States status: published

Published

2008

5. O(P-3(J)) alignment from the photodissociation of SO2 at 193 nm

Author

Mark Brouard, Tim J Preston, R. Cireasa, A. P. Clark, Claire Vallance, Gerrit C. Groenenboom, and Oleg S. Vasyutinskii

Subjects

Physics, Magnetic moment, Landé g-factor, Applied Molecular Physics, Rotational transition, Azimuthal quantum number, Total angular momentum quantum number, Angular momentum of light, Angular momentum coupling, Physics::Atomic and Molecular Clusters, Orbital angular momentum of light, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics

Abstract

Contains fulltext : 60303.pdf (Publisher’s version ) (Open Access) The 193-nm photodissociation Of SO2 has been studied using the resonantly enhanced multiphoton ionization of ground-state O(P-3(J)), coupled with velocity-map ion imaging. The dependence of the ion images on the linear polarization of pump and probe radiation has been used to determine the electronic angular momentum alignment of the recoiling, state-selected atoms, together with their speed distribution and translational anisotropy. The polarization data for J = 1 and 2 have been used to estimate the state multipole moments of the O-atom electron spin and orbital angular momenta. The data suggest that both sources of O-atom electronic angular momentum are polarized. It is shown that the spin polarization could either arise from exit-channel couplings or be a manifestation of the participation of triplet states in the dissociation. The angular dependence of the potential energy in the exit channel is examined using long-range quadrupole-dipole and quadrupole-quadrupole interaction terms, from which molecular-frame multipole moments of the orbital angular momentum of the recoiling 0 atoms have been calculated. Comparison with the experimentally derived multipole moments is used to help provide insight into the dissociation mechanism. The results are also discussed in light of similar experimental data from the photodissociation of N2O.

Published

2004

6. The integration of motion and disparity cues to depth in dorsal visual cortex

Author

Alan Meeson, Hiroshi Ban, Tim J Preston, and Andrew E. Welchman

Subjects

Vision Disparity, genetic structures, Computer science, Motion Perception, Motion (physics), Article, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Motion perception, Sensory cue, Binocular neurons, 030304 developmental biology, Visual Cortex, 0303 health sciences, Depth Perception, General Neuroscience, Magnetic Resonance Imaging, eye diseases, Visual cortex, medicine.anatomical_structure, Binocular disparity, Cues, Depth perception, Neuroscience, 030217 neurology & neurosurgery, Photic Stimulation

Abstract

Humans exploit a range of visual depth cues to estimate three-dimensional (3D) structure. For example, the slant of a nearby tabletop can be judged by combining information from binocular disparity, texture and perspective. Behavioral tests show humans combine cues near-optimally, a feat that could depend on: (i) discriminating the outputs from cue-specific mechanisms, or (ii) fusing signals into a common representation. While fusion is computationally attractive, it poses a significant challenge, requiring the integration of quantitatively different signals. We used functional magnetic resonance imaging (fMRI) to provide evidence that dorsal visual area V3B/KO meets this challenge. Specifically, we found that fMRI responses are more discriminable when two cues (binocular disparity and relative motion) concurrently signal depth, and that information provided by one cue is diagnostic of depth indicated by the other. This suggests a cortical node important when perceiving depth, and highlights computations based on fusion in the dorsal stream.

Published

2011

7. The photodissociation dynamics of NO2 at 308 nm and of NO2 and N2O4 at 226 nm

Author

Mark Brouard, Tim J Preston, R. Cireasa, A. P. Clark, and Claire Vallance

Subjects

Angular momentum, Chemistry, Photodissociation, General Physics and Astronomy, Photoionization, Population inversion, Molecular physics, Ion, Wavelength, Absorption band, Ionization, Physics::Atomic and Molecular Clusters, Physical and Theoretical Chemistry, Atomic physics

Abstract

Velocity-map ion imaging has been applied to the photodissociation of NO(2) via the first absorption band at 308 nm using (2 + 1) resonantly enhanced multiphoton ionization detection of the atomic O((3)P(J)) products. The resulting ion images have been analyzed to provide information about the speed distribution of the O((3)P(J)) products, the translational anisotropy, and the electronic angular momentum alignment. The atomic speed distributions were used to provide information about the internal quantum-state distribution in the NO coproducts. The data were found to be consistent with an inverted NO vibrational quantum-state distribution, and thereby point to a dynamical, as opposed to a statistical dissociation mechanism subsequent to photodissociation at 308 nm. Surprisingly, at this wavelength the O-atom electronic angular momentum alignment was found to be small. Probe-only ion images obtained under a variety of molecular-beam backing-pressure conditions, and corresponding to O atoms generated in the photodissociation of either the monomer, NO(2), or the dimer, N(2)O(4), at 226 nm, are also reported. For the monomer, where 226 nm corresponds to excitation into the second absorption band, the kinetic-energy release distributions are also found to indicate a strong population inversion in the NO cofragment, and are shown to be remarkably similar to those previously observed in the wavelength range of 193-248 nm. Mechanistic implications of this result are discussed. At 226 nm it has also been possible to observe directly O atoms from the photodissociation of the dimer. The O-atom velocity distribution has been analyzed to provide information about its production mechanism.

Published

2006

8. Automatic neural coding of open and closed scenes in RSC and PPA during visual search

Author

Tim J Preston, Fei Guo, Miguel P. Eckstein, and Barry Giesbrecht

Subjects

Visual search, Ophthalmology, biology, Computer science, business.industry, biology.protein, Pattern recognition, Artificial intelligence, Chromatin structure remodeling (RSC) complex, Neural coding, business, Sensory Systems

Published

2012

9. Contextual location information relevant to visual search in natural scenes is encoded in extrastriate visual cortex and the anterior intraparietal sulcus

Author

Fei Guo, Barry Giesbrecht, Tim J Preston, and Miguel P. Eckstein

Subjects

Extrastriate body area, Visual search, Ophthalmology, Visual cortex, medicine.anatomical_structure, medicine, Natural (music), Intraparietal sulcus, Psychology, Neuroscience, Sensory Systems, Cognitive psychology

Published

2011

10. fMRI evidence for the neural representation of target detection in natural scenes

Author

Fei Guo, Miguel P. Eckstein, Tim J Preston, and Barry Giesbrecht

Subjects

Ophthalmology, Communication, Computer science, business.industry, Representation (systemics), Natural (music), Pattern recognition, Artificial intelligence, business, Sensory Systems

Published

2011