Your search keyword '"G Kunig"' showing total 5 results

1. Changes in reward-induced brain activation in opiate addicts

Author

Wolfram Schultz, A Mino, John Missimer, G Kunig, Chantal Martin-Soelch, Klaus L. Leenders, AF Chevalley, and S Magyar

Subjects

General Neuroscience, Addiction, media_common.quotation_subject, Dopaminergic, Striatum, Affect (psychology), Reward system, mental disorders, Orbitofrontal cortex, Opiate, Reinforcement, Psychology, Neuroscience, psychological phenomena and processes, media_common

Abstract

Many studies indicate a role of the cerebral dopaminergic reward system in addiction. Motivated by these findings, we examined in opiate addicts whether brain regions involved in the reward circuitry also react to human prototypical rewards. We measured regional cerebral blood flow (rCBF) with (H2O)-O-15 positron emission tomography (PET) during a visuo-spatial recognition task with delayed response in control subjects and in opiate addicts participating in a methadone program. Three conditions were defined by the types of feedback: nonsense feedback; nonmonetary reinforcement; or monetary reward, received by the subjects for a correct response. We found in the control subjects rCBF increases in regions associated with the meso-striatal and meso-corticolimbic circuits in response to both monetary reward and nonmonetary reinforcement. In opiate addicts, these regions were activated only in response to monetary reward. Furthermore, nonmonetary reinforcement elicited rCBF increases in limbic regions of the opiate addicts that were not activated in the control subjects. Because psychoactive drugs serve as rewards and directly affect regions of the dopaminergic system like the striatum, we conclude that the differences in rCBF increases between controls and addicts can be attributed to an adaptive consequence of the addiction process.

Published

2001

2. Reward mechanisms in the brain and their role in dependence: evidence from neurophysiological and neuroimaging studies

Author

Chantal Martin-Soelch, A Mino, G Kunig, S Magyar, Klaus L. Leenders, AF Chevalley, John Missimer, and Willibrordus Weijmar Schultz

Subjects

Primates, Substance-Related Disorders, media_common.quotation_subject, Movement, brain, DRUG-ABUSE, Striatum, PREFRONTAL CORTEX, DOPAMINE NEURONS, Reward system, BASAL GANGLIA, Premovement neuronal activity, Animals, Humans, animal, human, Prefrontal cortex, reward, media_common, learning, STRIATUM, General Neuroscience, Addiction, PERFORMANCE, PET, PRIMATE ORBITOFRONTAL CORTEX, EXPECTATION, Curiosity, Orbitofrontal cortex, Brain stimulation reward, Neurology (clinical), addiction, Nerve Net, dopamine, neurophysiology, NEURONAL-ACTIVITY, Psychology, orbitofrontal cortex, Neuroscience, Psychomotor Performance, psychological phenomena and processes, Cognitive psychology, Tomography, Emission-Computed, RESPONSES

Abstract

This article reviews neuronal activity related to reward processing in primate and human brains. In the primate brain, neurophysiological methods provide a differentiated view of reward processing in a limited number of brain structures. Dopamine neurons respond to unpredictable rewards and produce a global reinforcement signal. Some neurons in the striatum also react to the expectation and detection of reward. Other striatal neurons show reward-related activities related to the preparation, initiation and execution of movement. Orbitofrontal neurons discriminate among different rewards and code reward preferences. In the human brain, regions belonging to a meso-striatal and meso-corticolimbic loop respond to reinforcement stimuli in control subjects. These observations corroborate results obtained in primates. Additionally, reward induces activation in regions specific to task performance. Our results also show a similar pattern of reward-related activation in nicotine and opiate addicts. Thus, in contrast to healthy subjects, typical reward-related regions respond in addicts to monetary reward but not to nonmonetary reinforcement. Reduced activation in performance-related regions is also observed in both groups of dependent subjects. The results of animal and human studies suggest that dopamine and dopamine-related regions are associated with the integration of motivational information and movement execution. Dopamine-related pathological disorders can be associated with movement disorders, such as Parkinson's disease or with false motivational attributions such as drug dependence. (C) 2001 Elsevier Science B.V. All rights reserved.

Published

2001

3. The role of language areas in motor control dysfunction in Parkinson's disease

Author

Lorenzo Priano, K.L. Leenders, CM Soelch, G Kunig, Alessandro Mauro, G. Albani, and Emilia Martignoni

Subjects

Cerebellum, medicine.medical_specialty, Neurology, Parkinson's disease, Dermatology, Metronome, Functional Laterality, law.invention, ACTIVATION, Physical medicine and rehabilitation, Gait (human), law, medicine, Humans, Gait Disorders, Neurologic, Language, Verbal Behavior, Motor Cortex, Motor control, Brain, Parkinson Disease, General Medicine, Recovery of Function, medicine.disease, Frontal Lobe, Psychiatry and Mental health, medicine.anatomical_structure, PET, Cerebral blood flow, Cerebrovascular Circulation, Neurology (clinical), Cues, Psychology, Neuroscience, human activities, GAIT, Psychomotor Performance, Motor cortex, Tomography, Emission-Computed

Abstract

We evaluated the differences in motor control organization between parkinsonian patients with (seven cases) and without(ten cases) gait disorder. We used positron emission tomography (O-15-H2O-PET) to measure regional cerebral blood flow as a correlate for local neuronal activation. This has been assessed during repetitive joystick movements of the right hand, externally triggered using a metronome as an auditory cue. In patients with Parkinson's disease (PD) without gait disorder, the contralateral supplementary motor cortex and the bilateral cerebellum were activated, while in PD patients with gait disorder the contralateral Broca's area, the contralateral sensory motor cortex and the homolateral cerebellum were activated. Our results suggest that PD patients with gait disorder creates an internal verbal cue in order to control the output of the movement of joystick, supplying the loss of control of the supplementary motor cortex that is activated in patients without gait disorder.

Published

2001

4. Changes in brain activation associated with reward processing in smokers and nonsmokers

Author

John Missimer, G Kunig, Klaus L. Leenders, S Magyar, Willibrordus Weijmar Schultz, and C Martin-Solch

Subjects

Cingulate cortex, CORTEX, positron emission tomography, media_common.quotation_subject, striatum, DRUG-ABUSE, Striatum, Impulsivity, DOPAMINE NEURONS, CEREBRAL BLOOD-FLOW, Nicotine, NICOTINE, Basal ganglia, medicine, human, reward, media_common, tobacco smokers, General Neuroscience, Addiction, Dopaminergic, STIMULI, Orbitofrontal cortex, CIGARETTE SMOKERS, medicine.symptom, IMPULSIVITY, PSEUDOWORDS, Psychology, Neuroscience, WORDS, medicine.drug

Abstract

Tobacco smoking is the most frequent form of substance abuse. Several studies have shown that the addictive action of nicotine is mediated by the mesolimbic. dopamine system. This system is implicated in reward processing. In order to better understand the relationship between nicotine addiction and reward in humans, we investigated differences between smokers and nonsmokers in the activation of brain regions involved in processing reward information. Using [(H2O)-O-15] positron emission tomography (PET), we measured regional cerebral blood now (rCBF) in healthy smokers and nonsmokers while they performed a prelearned, pattern-recognition task. We compared two conditions involving nonmonetary reinforcement or monetary reward with a baseline condition in which nonsense feedback was presented. With monetary reward, we found activation in the frontal and orbitofrontal cortex, occipital cortex, cingulate-gyrus, cerebellum, and midbrain in both groups. Additionally, monetary reward activated typical dopaminergic regions such as the striatum in nonsmokers but not in smokers. We found a similar pattern of activation associated with nonmonetary reinforcement in nonsmokers, whereas activation was found in smokers only in the cerebellum. The different patterns of activation suggest that the brains of smokers react in a different way to reward than those of nonsmokers. This difference involves in particular the regions of the dopaminergic system including the striatum. In principle these observations could be interpreted either as a consequence of tobacco use or as a primitive condition of the brain that led people to smoke. Supported by related nonimaging studies, we interpret these differences as a consequence of tobacco smoking, even if a short-term effect of smoking prior to the experiment cannot be excluded.

Published

2001

5. Reduced reward processing in the brains of Parkinsonian patients

Author

Chantal Martin-Sölch, K. L. Leenders, John Missimer, G Kunig, Stefanie Magyar, and Wolfram Schultz

Subjects

Male, Parkinson's disease, Striatum, ACTIVATION, Midbrain, DOPAMINE, Reward, Dopamine, Heart Rate, Cortex (anatomy), medicine, Humans, Brain Chemistry, monetary reward, General Neuroscience, Precentral gyrus, Brain, Parkinson Disease, Human brain, Limbic lobe, Medial frontal gyrus, Middle Aged, (H2O)-O-15 positron emission tomography, PET, medicine.anatomical_structure, STIMULI, nervous system, Pattern Recognition, Visual, Cerebrovascular Circulation, Female, Psychology, Arousal, Neuroscience, psychological phenomena and processes, medicine.drug, Tomography, Emission-Computed

Abstract

Regional cerebral blood flow (rCBF) in healthy controls and non-demented, non-depressed Parkinsonian patients was measured using H(2)(15)0 PET while subjects performed a prelearned pattern recognition task with delayed response. To investigate differences between the two groups in response to reward, the experimental design consisted of three reinforcement conditions: no reinforcement consisting of nonsense feedback, positive symbolic reinforcement and monetary reward. In the controls, monetary reward activated bilaterally the striatum and anterior cingulate gyrus, as well as unilaterally the left cerebellum, midbrain and medial frontal gyrus. Symbolic reinforcement revealed a similar pattern of activation, except that the striatum and left midbrain showed no activation. The Parkinsonian patients responded to monetary reward with increased activation bilaterally in the cerebellum, medial frontal gyrus, and anterior cingulate gyrus as well as unilaterally in the right fusiform gyrus and midbrain and left caudate nucleus and precentral gyrus. Symbolic reinforcement induced significantly increased rCBF in the right cerebellum only. Compared with symbolic reinforcement, monetary reward produced extended activation of temporoparietal association cortex. The pattern observed in the controls demonstrates the role in reward processing of dopaminergic mesolimbic pathways in the healthy human brain, whereas the pattern in the Parkinsonian patients suggests the involvement of compensatory cortical loops in the diseased brain. NeuroReport 11:3681-3687 (C) 2000 Lippincott Williams & Wilkins.

Published

2000