Voluntary wheel running preserves lumbar perineuronal nets, enhances motor functions and prevents hyperreflexia after spinal cord injury

Voluntary wheel running preserves lumbar perineuronal nets, enhances motor functions and prevents hyperreflexia after spinal cord injury

Perineuronal nets (PNN) are a promising candidate to harness neural plasticity since their activity-dependent modulation allows to either stabilize the circuits or increase plasticity. Modulation of plasticity is the basis of rehabilitation strategies to reduce maladaptive plasticity after spinal co...

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Bibliographic Details
Published in:Experimental neurology Vol. 336; p. 113533
Main Authors: Sánchez-Ventura, J., Giménez-Llort, L., Penas, C., Udina, E.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-02-2021
Subjects:
Activity-dependent therapy
Hyperreflexia
Motoneurons
Neuropathic pain
Perineuronal nets
Physical activity
Spinal cord injury
Physical activity
Activity-dependent therapy
BMS
CNS
LFB
Iba1
Spinal cord injury
Hyperreflexia
Neuropathic pain
GFAP
Motoneurons
BSA
PNN
PB
RDD
PBST
CSPG
SCI
MEP
IB4
Perineuronal nets
DPI
ChABC
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Summary:Perineuronal nets (PNN) are a promising candidate to harness neural plasticity since their activity-dependent modulation allows to either stabilize the circuits or increase plasticity. Modulation of plasticity is the basis of rehabilitation strategies to reduce maladaptive plasticity after spinal cord injuries (SCI). Hence, it is important to understand how spinal PNN are affected after SCI and rehabilitation. Thus, this work aims to describe functional and PNN changes after thoracic SCI in mice, followed by different activity-dependent therapies: enriched environment, voluntary wheel and forced treadmill running. We found that the contusion provoked thermal hyperalgesia, hyperreflexia and locomotor impairment as measured by thermal plantar test, H wave recordings and the BMS score of locomotion, respectively. In the spinal cord, SCI reduced PNN density around lumbar motoneurons. In contrast, activity-based therapies increased motoneuron activity and reversed PNN decrease. The voluntary wheel group showed full preservation of PNN which also correlated with reduced hyperreflexia and better locomotor recovery. Furthermore, both voluntary wheel and treadmill running reduced hyperalgesia, but this finding was independent of lumbar PNN levels. In the brainstem sensory nuclei, SCI did not modify PNN whereas some activity-based therapies reduced them. The results of the present study highlight the impact of SCI on decreasing PNN at caudal segments of the spinal cord and the potential of physical activity-based therapies to reverse PNN disaggregation and to improve functional recovery. As modulating plasticity is crucial for restoring damaged neural circuits, regulating PNN by activity is an encouraging target to improve the outcome after injury. •Lumbar PNN reduction by a spinal cord injury is reversed by physical activity.•Preservation of PNN correlates with reduced hyperreflexia and better locomotion.•Physical activity reduces PNN in brainstem sensory nuclei after spinal cord injury.
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ISSN:0014-4886
1090-2430
DOI:10.1016/j.expneurol.2020.113533