Impaired efficacy of spinal presynaptic mechanisms in spastic stroke patients

Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have revealed abnormalities in many spinal pathways controlling motoneurone discharge. Unfortunately, the pathophysiological mechanisms responsible...

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Published inBrain (London, England : 1878) Vol. 132; no. 3; pp. 734 - 748
Main Authors Lamy, Jean-Charles, Wargon, Isabelle, Mazevet, Dominique, Ghanim, Zaïd, Pradat-Diehl, Pascale, Katz, Rose
Format Journal Article
LanguageEnglish
Published Oxford Oxford University Press 01.03.2009
Oxford Publishing Limited (England)
Subjects
Adult
Biological and medical sciences
Chronic Disease
Female
Humans
Long-Term Synaptic Depression - physiology
Male
Medical sciences
Middle Aged
Muscle Spasticity - pathology
Muscle Spasticity - physiopathology
Neural Inhibition - physiology
Neural Pathways - physiopathology
Neurology
post-activation depression
presynaptic Ia inhibition
Presynaptic Terminals - physiology
Severity of Illness Index
spasticity
Spinal Cord - physiopathology
stroke
Stroke - pathology
Stroke - physiopathology
upper and lower limbs
Vascular diseases and vascular malformations of the nervous system
Young Adult
presynaptic Ia inhibition
spasticity
upper and lower limbs
post-activation depression
stroke
Mood disorder
Human
Stroke
Nervous system diseases
presynaptic la inhibition
Spasticity
Lower limb
Cardiovascular disease
Muscle tonus alteration
Depression
Presynaptic inhibition
Cerebral disorder
Vascular disease
Striated muscle disease
Central nervous system disease
Upper limb
Neurological disorder
Cerebrovascular disease
Presynaptic
Online AccessGet full text
ISSN0006-8950
1460-2156
1460-2156
DOI10.1093/brain/awn310

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Abstract Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have revealed abnormalities in many spinal pathways controlling motoneurone discharge. Unfortunately, the pathophysiological mechanisms responsible for the development of spasticity remains nevertheless largely unknown since most of the previous studies failed to reveal a link between the characteristics of spasticity (severity, time course) and that of the dysfunction of a given perturbed spinal pathway. In the present series of experiments, we focused on the study of presynaptic mechanisms acting at the synapse fibre Ia—motoneurone since monosynaptic reflexes are enhanced in spasticity. Two presynaptic mechanisms have been described in both animals and humans: presynaptic Ia inhibition and post-activation depression. By increasing the number of subjects in comparison with previous studies (87 patients and 42 healthy controls) we have been able to show that these two mechanisms are unequally impaired in stroke patients depending on (i) the duration of the disease (acute, defined as less than 3 months after the causal lesion, or chronic, defined as more than 9 months after the causal lesion), (ii) the side considered (affected or unaffected) and (iii) the severity of spasticity. In this respect, only post-activation depression amount was found to be highly correlated with the severity of spasticity. Although not a definitive proof, this correlation between severity of spasticity and changes in a given spinal pathway lead us to conclude that the impairment of post-activation depression is likely one of the mechanisms underlying spasticity. On the contrary, changes in presynaptic Ia inhibition appear to be a simple epiphenomenon, i.e. a basic correlate of the brain lesions. It is argued that plastic changes develop from the disuse due to motor command impairment in both pathways.
AbstractList Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have revealed abnormalities in many spinal pathways controlling motoneurone discharge. Unfortunately, the pathophysiological mechanisms responsible for the development of spasticity remains nevertheless largely unknown since most of the previous studies failed to reveal a link between the characteristics of spasticity (severity, time course) and that of the dysfunction of a given perturbed spinal pathway. In the present series of experiments, we focused on the study of presynaptic mechanisms acting at the synapse fibre Ia-motoneurone since monosynaptic reflexes are enhanced in spasticity. Two presynaptic mechanisms have been described in both animals and humans: presynaptic Ia inhibition and post-activation depression. By increasing the number of subjects in comparison with previous studies (87 patients and 42 healthy controls) we have been able to show that these two mechanisms are unequally impaired in stroke patients depending on (i) the duration of the disease (acute, defined as less than 3 months after the causal lesion, or chronic, defined as more than 9 months after the causal lesion), (ii) the side considered (affected or unaffected) and (iii) the severity of spasticity. In this respect, only post-activation depression amount was found to be highly correlated with the severity of spasticity. Although not a definitive proof, this correlation between severity of spasticity and changes in a given spinal pathway lead us to conclude that the impairment of post-activation depression is likely one of the mechanisms underlying spasticity. On the contrary, changes in presynaptic Ia inhibition appear to be a simple epiphenomenon, i.e. a basic correlate of the brain lesions. It is argued that plastic changes develop from the disuse due to motor command impairment in both pathways.Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have revealed abnormalities in many spinal pathways controlling motoneurone discharge. Unfortunately, the pathophysiological mechanisms responsible for the development of spasticity remains nevertheless largely unknown since most of the previous studies failed to reveal a link between the characteristics of spasticity (severity, time course) and that of the dysfunction of a given perturbed spinal pathway. In the present series of experiments, we focused on the study of presynaptic mechanisms acting at the synapse fibre Ia-motoneurone since monosynaptic reflexes are enhanced in spasticity. Two presynaptic mechanisms have been described in both animals and humans: presynaptic Ia inhibition and post-activation depression. By increasing the number of subjects in comparison with previous studies (87 patients and 42 healthy controls) we have been able to show that these two mechanisms are unequally impaired in stroke patients depending on (i) the duration of the disease (acute, defined as less than 3 months after the causal lesion, or chronic, defined as more than 9 months after the causal lesion), (ii) the side considered (affected or unaffected) and (iii) the severity of spasticity. In this respect, only post-activation depression amount was found to be highly correlated with the severity of spasticity. Although not a definitive proof, this correlation between severity of spasticity and changes in a given spinal pathway lead us to conclude that the impairment of post-activation depression is likely one of the mechanisms underlying spasticity. On the contrary, changes in presynaptic Ia inhibition appear to be a simple epiphenomenon, i.e. a basic correlate of the brain lesions. It is argued that plastic changes develop from the disuse due to motor command impairment in both pathways.
Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have revealed abnormalities in many spinal pathways controlling motoneurone discharge. Unfortunately, the pathophysiological mechanisms responsible for the development of spasticity remains nevertheless largely unknown since most of the previous studies failed to reveal a link between the characteristics of spasticity (severity, time course) and that of the dysfunction of a given perturbed spinal pathway. In the present series of experiments, we focused on the study of presynaptic mechanisms acting at the synapse fibre Ia-motoneurone since monosynaptic reflexes are enhanced in spasticity. Two presynaptic mechanisms have been described in both animals and humans: presynaptic Ia inhibition and post-activation depression. By increasing the number of subjects in comparison with previous studies (87 patients and 42 healthy controls) we have been able to show that these two mechanisms are unequally impaired in stroke patients depending on (i) the duration of the disease (acute, defined as less than 3 months after the causal lesion, or chronic, defined as more than 9 months after the causal lesion), (ii) the side considered (affected or unaffected) and (iii) the severity of spasticity. In this respect, only post-activation depression amount was found to be highly correlated with the severity of spasticity. Although not a definitive proof, this correlation between severity of spasticity and changes in a given spinal pathway lead us to conclude that the impairment of post-activation depression is likely one of the mechanisms underlying spasticity. On the contrary, changes in presynaptic Ia inhibition appear to be a simple epiphenomenon, i.e. a basic correlate of the brain lesions. It is argued that plastic changes develop from the disuse due to motor command impairment in both pathways.
Author Pradat-Diehl, Pascale
Lamy, Jean-Charles
Wargon, Isabelle
Mazevet, Dominique
Ghanim, Zaïd
Katz, Rose
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  email: rose.katz@upmc.fr
  organization: 1 Inserm, U731, F-75013, Paris, France
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https://www.ncbi.nlm.nih.gov/pubmed/19036767$$D View this record in MEDLINE/PubMed
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ContentType Journal Article
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ISSN 0006-8950
1460-2156
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Issue 3
Keywords presynaptic Ia inhibition
spasticity
upper and lower limbs
post-activation depression
stroke
Mood disorder
Human
Stroke
Nervous system diseases
presynaptic la inhibition
Spasticity
Lower limb
Cardiovascular disease
Muscle tonus alteration
Depression
Presynaptic inhibition
Cerebral disorder
Vascular disease
Striated muscle disease
Central nervous system disease
Upper limb
Neurological disorder
Cerebrovascular disease
Presynaptic
Language English
License CC BY 4.0
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Oxford Publishing Limited (England)
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Snippet Pathophysiological mechanisms underlying spasticity have been the subject of many studies. These studies performed in various kinds of spastic patients have...
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StartPage 734
SubjectTerms Adult
Biological and medical sciences
Chronic Disease
Female
Humans
Long-Term Synaptic Depression - physiology
Male
Medical sciences
Middle Aged
Muscle Spasticity - pathology
Muscle Spasticity - physiopathology
Neural Inhibition - physiology
Neural Pathways - physiopathology
Neurology
post-activation depression
presynaptic Ia inhibition
Presynaptic Terminals - physiology
Severity of Illness Index
spasticity
Spinal Cord - physiopathology
stroke
Stroke - pathology
Stroke - physiopathology
upper and lower limbs
Vascular diseases and vascular malformations of the nervous system
Young Adult
Title Impaired efficacy of spinal presynaptic mechanisms in spastic stroke patients
URI https://api.istex.fr/ark:/67375/HXZ-DPBPMHR5-2/fulltext.pdf
https://www.ncbi.nlm.nih.gov/pubmed/19036767
https://www.proquest.com/docview/195417227
https://www.proquest.com/docview/20588046
https://www.proquest.com/docview/67111768
Volume 132
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