Your search keyword '"M-REGION"' showing total 7 results

1. The central control of micturition and continence

Subjects

M-REGION, DIRECT PROJECTIONS, pontine micturition centre, CAT, BLADDER, Barrington's area, BRAIN-STEM, URETHRAL SPHINCTER, pontine storage centre, PERIAQUEDUCTAL GRAY, overactive bladder, ULTRASTRUCTURAL EVIDENCE, URINARY-INCONTINENCE, SPINAL-CORD

Published

1999

2. The central control of micturition and continence

Subjects

M-REGION, DIRECT PROJECTIONS, pontine micturition centre, CAT, BLADDER, Barrington's area, BRAIN-STEM, URETHRAL SPHINCTER, pontine storage centre, PERIAQUEDUCTAL GRAY, overactive bladder, ULTRASTRUCTURAL EVIDENCE, URINARY-INCONTINENCE, SPINAL-CORD, urethral sphincter, bladder

Published

1999

3. Brain activation during micturition in women

Author

Leontien M. Sturms, Gert Holstege, Bertil F.M. Blok, and Faculteit Medische Wetenschappen/UMCG

Subjects

Adult, Male, media_common.quotation_subject, POSITRON EMISSION TOMOGRAPHY, Urinary Bladder, Urination, Inferior frontal gyrus, Functional Laterality, URETHRAL SPHINCTER, PERIAQUEDUCTAL GRAY, M-region, Prosencephalon, inferior frontal gyrus, L-region, Tegmentum, medicine, Animals, Humans, ULTRASTRUCTURAL EVIDENCE, media_common, PUDENDAL MOTONEURONS, Brain Mapping, LUMBOSACRAL CORD, Urethral sphincter, Brain, pontine micturition centre, Middle Aged, Spinal cord, anterior cingulate gyrus, Pons, pontine storage centre, medicine.anatomical_structure, PREOPTIC AREA, Cerebral blood flow, Anesthesia, CELL GROUPS, Cats, NEURAL CONTROL, Female, Neurology (clinical), Brainstem, SPINAL-CORD, Psychology, Brain Stem, Tomography, Emission-Computed

Abstract

Experiments in the cat have led to a concept of how the CNS controls micturition. In a previous study this concept was tested in a PET study in male volunteers, It was demonstrated that specific brainstem and forebrain areas are activated during micturition, It was unfortunate that this study did not involve women, because such results are important for understanding urge incontinence, which occurs more frequently in women than in men. Therefore, a similar study was done in 18 right-handed women, who were scanned during the following four conditions: (i) 15 min prior to micturition (urine withholding); (ii) during micturition; (iii) 15 min after micturition; and (iv) 30 min after micturition, Of the 18 volunteers, 10 were able to micturate during scanning and eight were not, despite trying vigorously. Micturition appeared to be associated with significantly increased blood flow in the right dorsal pontine tegmentum and the right inferior frontal gyrus, Decreased blood flow was found in the right anterior cingulate gyrus during urine withholding. The eight volunteers who were not able to micturate during scanning did not show significantly increased regional cerebral blood flow in the right dorsal, but did so in the right ventral pontine tegmentum, In the cat this region controls the motor neurons of the pelvic floor. In the same unsuccessful micturition group, increased blood flow was also found in the right inferior frontal gyrus, In all 18 volunteers, decreased blood flow in the right anterior cingulate gyrus was found during the period when they had to withhold their urine prior to the micturition condition. The results suggest that in women rind in men the same specific nuclei exist in the pontine tegmentum responsible for the control of micturition. The results also indicate that the cortical and pontine micturition sites are more active on the right than on the left side.

Published

1998

4. A PET study on brain control of micturition in humans

Subjects

M-REGION, POSITRON EMISSION TOMOGRAPHY, periaqueductal grey, CAT, CEREBRAL BLOOD-FLOW, URETHRAL SPHINCTER, PERIAQUEDUCTAL GRAY, right inferior frontal gyrus, ANTERIOR CINGULATE CORTEX, right anterior cingulate gyrus, PROJECTIONS, right pontine tegmentum, URINARY-INCONTINENCE, hypothalamus, SPINAL-CORD

Abstract

Although the brain plays a crucial role in the control of micturition, little is known about the structures involved. Identification of these areas is important because their dysfunction is thought to cause urge incontinence, a major problem in the elderly. In the cat, three areas in the brainstem and diencephalon are specifically implicated in the control of micturition: the dorsomedial pontine tegmentum, the periaqueductal grey, and the preoptic area of the hypothalamus. PET scans were used to test whether these areas are also involved in human micturition. Seventeen right-handed male volunteers were scanned during the following four conditions: (i) 15 min prior to micturition during urine withholding; (ii) during micturition; (iii) 15 min after micturition; (iv) 30 min after micturition. Ten of the 17 volunteers were able to micturate during scanning. Micturition was associated with increased blood flow in the right dorsomedial pontine tegmentum, the periaqueductal grey, the hypothalamus and the right inferior frontal gyrus. Decreased blood flow was found in the right anterior cingulate gyrus when urine was withheld. The other seven volunteers were not able to micturate during scanning, although they had a full bladder and tried vigorously to do so. In this group, during these unsuccessful attempts to micturate, increased blood pow was Sound in the right ventral pontine tegmentum, which corresponds with the hypothesis, formulated from results in cats, that this area controls the motor neurons of the pelvic poor Increased blood pow was also found in the right inferior frontal gyrus during unsuccessful attempts at micturition, and decreased blood pow in the right anterior cingulate gyrus was found during the withholding of urine. The results suggest that, as that of the cat, the human brainstem contains specific nuclei responsible for the control of micturition, and that the cortical and pontine micturition sites are predominantly on the right side.

Published

1997

5. A PET study on brain control of micturition in humans

Subjects

M-REGION, POSITRON EMISSION TOMOGRAPHY, periaqueductal grey, CAT, CEREBRAL BLOOD-FLOW, URETHRAL SPHINCTER, PERIAQUEDUCTAL GRAY, right inferior frontal gyrus, ANTERIOR CINGULATE CORTEX, right anterior cingulate gyrus, PROJECTIONS, right pontine tegmentum, URINARY-INCONTINENCE, hypothalamus, SPINAL-CORD

Abstract

Although the brain plays a crucial role in the control of micturition, little is known about the structures involved. Identification of these areas is important because their dysfunction is thought to cause urge incontinence, a major problem in the elderly. In the cat, three areas in the brainstem and diencephalon are specifically implicated in the control of micturition: the dorsomedial pontine tegmentum, the periaqueductal grey, and the preoptic area of the hypothalamus. PET scans were used to test whether these areas are also involved in human micturition. Seventeen right-handed male volunteers were scanned during the following four conditions: (i) 15 min prior to micturition during urine withholding; (ii) during micturition; (iii) 15 min after micturition; (iv) 30 min after micturition. Ten of the 17 volunteers were able to micturate during scanning. Micturition was associated with increased blood flow in the right dorsomedial pontine tegmentum, the periaqueductal grey, the hypothalamus and the right inferior frontal gyrus. Decreased blood flow was found in the right anterior cingulate gyrus when urine was withheld. The other seven volunteers were not able to micturate during scanning, although they had a full bladder and tried vigorously to do so. In this group, during these unsuccessful attempts to micturate, increased blood pow was Sound in the right ventral pontine tegmentum, which corresponds with the hypothesis, formulated from results in cats, that this area controls the motor neurons of the pelvic poor Increased blood pow was also found in the right inferior frontal gyrus during unsuccessful attempts at micturition, and decreased blood pow in the right anterior cingulate gyrus was found during the withholding of urine. The results suggest that, as that of the cat, the human brainstem contains specific nuclei responsible for the control of micturition, and that the cortical and pontine micturition sites are predominantly on the right side.

Published

1997

6. The central control of micturition and continence: Implications For Urology

Author

Holstege, G. and Faculteit Medische Wetenschappen/UMCG

Subjects

M-REGION, DIRECT PROJECTIONS, pontine micturition centre, CAT, BLADDER, Barrington's area, BRAIN-STEM, URETHRAL SPHINCTER, pontine storage centre, PERIAQUEDUCTAL GRAY, overactive bladder, ULTRASTRUCTURAL EVIDENCE, URINARY-INCONTINENCE, SPINAL-CORD

Published

1999

7. A PET study on brain control of micturition in humans

Author

Blok, BFM, Willemsen, ATM, and Holstege, G

Subjects

M-REGION, POSITRON EMISSION TOMOGRAPHY, periaqueductal grey, CAT, CEREBRAL BLOOD-FLOW, URETHRAL SPHINCTER, PERIAQUEDUCTAL GRAY, right inferior frontal gyrus, ANTERIOR CINGULATE CORTEX, right anterior cingulate gyrus, PROJECTIONS, right pontine tegmentum, URINARY-INCONTINENCE, hypothalamus, SPINAL-CORD

Abstract

Although the brain plays a crucial role in the control of micturition, little is known about the structures involved. Identification of these areas is important because their dysfunction is thought to cause urge incontinence, a major problem in the elderly. In the cat, three areas in the brainstem and diencephalon are specifically implicated in the control of micturition: the dorsomedial pontine tegmentum, the periaqueductal grey, and the preoptic area of the hypothalamus. PET scans were used to test whether these areas are also involved in human micturition. Seventeen right-handed male volunteers were scanned during the following four conditions: (i) 15 min prior to micturition during urine withholding; (ii) during micturition; (iii) 15 min after micturition; (iv) 30 min after micturition. Ten of the 17 volunteers were able to micturate during scanning. Micturition was associated with increased blood flow in the right dorsomedial pontine tegmentum, the periaqueductal grey, the hypothalamus and the right inferior frontal gyrus. Decreased blood flow was found in the right anterior cingulate gyrus when urine was withheld. The other seven volunteers were not able to micturate during scanning, although they had a full bladder and tried vigorously to do so. In this group, during these unsuccessful attempts to micturate, increased blood pow was Sound in the right ventral pontine tegmentum, which corresponds with the hypothesis, formulated from results in cats, that this area controls the motor neurons of the pelvic poor Increased blood pow was also found in the right inferior frontal gyrus during unsuccessful attempts at micturition, and decreased blood pow in the right anterior cingulate gyrus was found during the withholding of urine. The results suggest that, as that of the cat, the human brainstem contains specific nuclei responsible for the control of micturition, and that the cortical and pontine micturition sites are predominantly on the right side.

Published

1997