500 research outputs found

    Deficits in attentional control: Cholinergic mechanisms and circuitry-based treatment approaches.

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    The cognitive control of attention involves maintaining task rules in working memory (or "online"), monitoring reward and error rates, filtering distractors, and suppressing prepotent, and competitive responses. Weak attentional control increases distractibility and causes attentional lapses, impulsivity, and attentional fatigue. Levels of tonic cholinergic activity (changes over tens of seconds or minutes) modulate cortical circuitry as a function of the demands on cognitive control. Increased cholinergic modulation enhances the representation of cues, by augmenting cue-evoked activity in thalamic glutamatergic afferents, thereby increasing the rate of detection. Such cholinergic modulation is mediated primarily via α4β2* nicotinic acetylcholine receptors. Animal experiments and clinical trials in adult patients with ADHD indicate that attentional symptoms and disorders may benefit from drugs that stimulate this receptor. Tonic cholinergic modulation of cue-evoked glutamatergic transients in prefrontal regions is an essential component of the brain's executive circuitry. This circuitry model guides the development of treatments of deficits in attentional control. © 2011 American Psychological Association

    Sustained Attention and Associated Acetylcholine Release in Choline High-Affinity Transporter Hemizygous Mice

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    Honors (Bachelor's)NeuroscienceUniversity of Michiganhttp://deepblue.lib.umich.edu/bitstream/2027.42/91863/1/malloryc.pd

    Staying on task versus taking cocaine: Individual differences in drug cue-evoked competition for attention

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    Honors (Bachelor's)NeuroscienceUniversity of Michiganhttp://deepblue.lib.umich.edu/bitstream/2027.42/120628/1/woodta.pd

    Anatomical differences in the human inferior colliculus relate to the perceived valence of musical consonance and dissonance

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    Helmholtz himself speculated about a role of the cochlea in the perception of musical dissonance. Here we indirectly investigated this issue, assessing the valence judgment of musical stimuli with variable consonance/dissonance and presented diotically (exactly the same dissonant signal was presented to both ears) or dichotically (a consonant signal was presented to each ear - both consonant signals were rhythmically identical but differed by a semitone in pitch). Differences in brain organisation underlying inter-subject differences in the percept of dichotically presented dissonance were determined with voxel-based morphometry. Behavioral results showed that diotic dissonant stimuli were perceived as more unpleasant than dichotically presented dissonance, indicating that interactions within the cochlea modulated the valence percept during dissonance. However, the behavioral data also suggested that the dissonance percept did not depend crucially on the cochlea, but also occurred as a result of binaural integration when listening to dichotic dissonance. These results also showed substantial between-participant variations in the valence response to dichotic dissonance. These differences were in a voxel-based morphometry analysis related to differences in gray matter density in the inferior colliculus, which strongly substantiated a key role of the inferior colliculus in consonance/dissonance representation in humans

    Advanced paternal age is associated with alterations in discrete behavioural domains and cortical neuroanatomy of C57BL/6J mice

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    Advanced paternal age (APA) is associated with an increased risk of neurodevelopmental disorders such as autism and schizophrenia. A previous study in mice suggested that the offspring of aged sires have altered locomotion and avoidance learning. The aim of the current study was to conduct a comprehensive behavioural screen in adult offspring of mice of APA. We also examined brain morphology in neonate and adult mice. The adult offspring of 12- to18-month-old (APA) and 4-month-old (control) male C57BL/6J mice underwent a behavioural test battery comprising tests for locomotion, anxiety, exploration, social behaviour, learned helplessness and sensorimotor gating. The brains of these mice were collected at 3 months and imaged ex vivo using a 16.4T MRI scanner to assess gross neuroanatomy. Neuroanatomy was also examined at birth in a separate cohort of animals. Overall, the APA mouse model was associated with subtle behavioural changes and altered cortical morphology. The behavioural phenotype of female APA mice included increased anxiety-related behaviour, increased exploration and decreased learned helplessness compared to control females. Male APA mice had thinner cortices at birth and increased cortical volume as adults. This animal model may assist in exploring the mechanism of action linking APA with disorders such as schizophrenia and autism

    The Role of Cingulate Cortex in the Detection of Errors with and without Awareness: a High-density Electrical Mapping Study

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    Error-processing research has demonstrated that the brain uses a specialized neural network to detect errors during task performance but the brain regions necessary for conscious awareness of an error are poorly understood. In the present study we show that two well-known error-related event-related potential (ERP) components, the error-related negativity (ERN) and error positivity (Pe) have a differential relationship with awareness during performance of a manual response inhibition task optimized to examine error awareness. While the ERN was unaffected by the participants’ conscious experience of errors, the Pe was only seen when participants were aware of committing an error. Source localization of these components indicated that the ERN was generated by a caudal region of the anterior cingulate cortex (ACC) while the Pe was associated with contributions from a more anterior ACC region and the posterior cingulate–precuneus. Tonic EEG measures of cortical arousal were correlated with individual rates of error awareness and showed a specific relationship with the amplitude of the Pe. The latter finding is consistent with evidence that the Pe represents a P3-like facilitation of information processing modulated by subcortical arousal systems. Our data suggest that the ACC might participate in both preconscious and conscious error detection and that cortical arousal provides a necessary setting condition for error awareness. These findings may be particularly important in the context of clinical studies in which a proper understanding of self-monitoring deficits requires an explicit measurement of error awareness

    Corticomotor excitability of back muscles is affected by intervertebral disc lesion in pigs

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    Morphological and behavioural changes in back muscles are common in back pain and injury. Recent data indicate a rapid reduction in the size of the multifidus, a deep back muscle, within 3 days of experimental intervertebral disc (IVD) injury in pigs. A reduced neural drive may contribute to this. We investigated changes in corticomotor excitability following IVD lesion by evaluation of the response of back muscles to electrical stimulation of the motor cortex. Motor evoked potentials (MEPs) were studied in 12 Swedish landrace pigs before injury, immediately after abdominal incision, immediately after L3-4 IVD lesion with a scalpel, and 15 min later. In two animals, responses were also evoked by descending volleys excited at the level of the mastoid processes (cervicomedullary evoked potentials) without motor cortex activation. In five animals, a sham procedure was followed without IVD lesion. MEPs were recorded in short (deep) and long (superficial) fibres of the multifidus at L3-5 on the lesioned side and at L4 contralaterally with intramuscular wire electrodes. Although the MEP amplitude increased in several muscles after incision, at 15 min after IVD lesion only the MEP amplitude of the deep L4 multifidus on the lesioned side was increased [36% (SD 15%), P < 0.05]. There were no changes in MEP amplitude after 15 min at adjacent or contralateral levels. The response to cervicomedullary stimulation reduced slightly. This suggests that the increased MEP amplitude was due to changes in cortical excitability. These data indicate that IVD lesion induces localized increases, and not decreases, in the excitability of cortical inputs to the deep paraspinal muscles that cross a lesioned disc

    Exploring the Link between Drug Addiction Propensity and Improper Top-Down Control in Sustained Attention Tasks

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    Honors (Bachelor's)NeuroscienceUniversity of Michiganhttp://deepblue.lib.umich.edu/bitstream/2027.42/98935/1/leonav.pd

    Animal cognition: defining the issues

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    Attention

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