Prefrontal Activation Evoked by Infrequent Target and Novel Stimuli in a Visual Target Detection Task: An Event-Related Functional Magnetic Resonance Imaging Study

An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 t...

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Published in	The Journal of neuroscience Vol. 20; no. 17; pp. 6612 - 6618
Main Authors	Kirino, Eiji, Belger, Aysenil, Goldman-Rakic, Patricia, McCarthy, Gregory
Format	Journal Article
Language	English
Published	United States Soc Neuroscience 01.09.2000 Society for Neuroscience
Subjects	Adult Brain Mapping - methods Color Perception - physiology Event-Related Potentials, P300 - physiology Evoked Potentials, Visual - physiology Female Humans Magnetic Resonance Imaging - methods Male middle frontal gyrus Pattern Recognition, Visual - physiology Prefrontal Cortex - physiology Psychomotor Performance - physiology Reaction Time
Online Access	Get full text
ISSN	0270-6474 1529-2401
DOI	10.1523/jneurosci.20-17-06612.2000

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Abstract	An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on approximately 92% of trials. Targets were color circles of varying sizes presented irregularly on approximately 4% of trials. Novels were pictures of everyday objects that were also presented irregularly on approximately 4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response.
AbstractList	An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on approximately 92% of trials. Targets were color circles of varying sizes presented irregularly on approximately 4% of trials. Novels were pictures of everyday objects that were also presented irregularly on approximately 4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response. An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on similar to 92% of trials. Targets were color circles of varying sizes presented irregularly on similar to 4% of trials. Novels were pictures of everyday objects that were also presented irregularly on similar to 4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response. An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual “oddball” target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on ∼92% of trials. Targets were color circles of varying sizes presented irregularly on ∼4% of trials. Novels were pictures of everyday objects that were also presented irregularly on ∼4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response. An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on approximately 92% of trials. Targets were color circles of varying sizes presented irregularly on approximately 4% of trials. Novels were pictures of everyday objects that were also presented irregularly on approximately 4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response.An event-related functional magnetic resonance imaging study of prefrontal cortex was conducted during which subjects performed a visual "oddball" target detection task. Exemplars of three stimulus categories were presented at a rate of one per 1.5 sec for 10 runs, each consisting of 132 trials. Standards were color squares of varying sizes that were presented on approximately 92% of trials. Targets were color circles of varying sizes presented irregularly on approximately 4% of trials. Novels were pictures of everyday objects that were also presented irregularly on approximately 4% of trials. Ten subjects participated in two separate sessions in which they were required to count mentally or to push a button whenever a target appeared. Targets evoked activation within prefrontal cortex, primarily within the middle frontal gyri (MFG). This MFG activation did not differ as a function of the required response. Novels did not evoke significant activity within this region despite evidence from a separate behavioral and event-related potential study demonstrating their strong influence on processing. In additional imaging sessions with two subjects, the rules were reversed to require a button press whenever an object, but not a circle, appeared. These former novels now evoked activation in the MFG, but the former target circles did not. These experiments indicate that MFG activation is reliably evoked by exemplars from arbitrary stimulus categories that are mapped by experimental rules onto an arbitrary covert or overt response.
Author	Kirino, Eiji Belger, Aysenil Goldman-Rakic, Patricia McCarthy, Gregory
AuthorAffiliation	4 Neurobiology, Yale University School of Medicine, New Haven, Connecticut 06510 1 Veterans Administration Medical Center, West Haven, Connecticut 06516, and Departments of 2 Neurosurgery 3 Psychiatry, and
AuthorAffiliation_xml	– name: 2 Neurosurgery – name: 1 Veterans Administration Medical Center, West Haven, Connecticut 06516, and Departments of – name: 3 Psychiatry, and – name: 4 Neurobiology, Yale University School of Medicine, New Haven, Connecticut 06510
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BackLink	https://www.ncbi.nlm.nih.gov/pubmed/10964966$$D View this record in MEDLINE/PubMed
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SubjectTerms	Adult Brain Mapping - methods Color Perception - physiology Event-Related Potentials, P300 - physiology Evoked Potentials, Visual - physiology Female Humans Magnetic Resonance Imaging - methods Male middle frontal gyrus Pattern Recognition, Visual - physiology Prefrontal Cortex - physiology Psychomotor Performance - physiology Reaction Time
Title	Prefrontal Activation Evoked by Infrequent Target and Novel Stimuli in a Visual Target Detection Task: An Event-Related Functional Magnetic Resonance Imaging Study
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