Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve

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Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve. / Moldovan, Mihai; Sørensen, Jesper; Krarup, Christian.

In: Brain, Vol. 129, No. Pt 9, 2006, p. 2471-2483.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Moldovan, M, Sørensen, J & Krarup, C 2006, 'Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve', Brain, vol. 129, no. Pt 9, pp. 2471-2483. https://doi.org/10.1093/brain/awl184

APA

Moldovan, M., Sørensen, J., & Krarup, C. (2006). Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve. Brain, 129(Pt 9), 2471-2483. https://doi.org/10.1093/brain/awl184

Vancouver

Moldovan M, Sørensen J, Krarup C. Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve. Brain. 2006;129(Pt 9):2471-2483. https://doi.org/10.1093/brain/awl184

Author

Moldovan, Mihai ; Sørensen, Jesper ; Krarup, Christian. / Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve. In: Brain. 2006 ; Vol. 129, No. Pt 9. pp. 2471-2483.

Bibtex

@article{68f83e606c3811dcbee902004c4f4f50,
title = "Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve",
abstract = "Functional outcome after peripheral nerve regeneration is often poor, particularly involving nerve injuries far from their targets. Comparison of sensory and motor axon regeneration before target reinnervation is not possible in the clinical setting, and previous experimental studies addressing the question of differences in growth rates of different nerve fibre populations led to conflicting results. We developed an animal model to compare growth and maturation of the fastest growing sensory and motor fibres within the same mixed nerve after Wallerian degeneration. Regeneration of cat tibial nerve after crush (n = 13) and section (n = 7) was monitored for up to 140 days, using implanted cuff electrodes placed around the sciatic and tibial nerves and wire electrodes at plantar muscles. To distinguish between sensory and motor fibres, recordings were carried out from L6-S2 spinal roots using cuff electrodes. The timing of laminectomy was based on the presence of regenerating fibres along the nerve within the tibial cuff. Stimulation of unlesioned tibial nerves (n = 6) evoked the largest motor response in S1 ventral root and the largest sensory response in L7 dorsal root. Growth rates were compared by mapping the regenerating nerve fibres within the tibial nerve cuff to all ventral or dorsal roots and, regardless of the lesion type, the fastest growth was similar in sensory and motor fibres. Maturation was assessed as recovery of the maximum motor and sensory conduction velocities (CVs) within the tibial nerve cuff. Throughout the observation period the CV was approximately 14% faster in regenerated sensory fibres than in motor fibres in accordance with the difference observed in control nerves. Recovery of amplitude was only partial after section, whereas the root distribution pattern was restored. Our data suggest that the fastest growth and maturation rates that can be achieved during regeneration are similar for motor and sensory myelinated fibres.",
author = "Mihai Moldovan and Jesper S{\o}rensen and Christian Krarup",
year = "2006",
doi = "10.1093/brain/awl184",
language = "English",
volume = "129",
pages = "2471--2483",
journal = "Brain",
issn = "0006-8950",
publisher = "Oxford University Press",
number = "Pt 9",

}

RIS

TY - JOUR

T1 - Comparison of the fastest regenerating motor and sensory myelinated axons in the same peripheral nerve

AU - Moldovan, Mihai

AU - Sørensen, Jesper

AU - Krarup, Christian

PY - 2006

Y1 - 2006

N2 - Functional outcome after peripheral nerve regeneration is often poor, particularly involving nerve injuries far from their targets. Comparison of sensory and motor axon regeneration before target reinnervation is not possible in the clinical setting, and previous experimental studies addressing the question of differences in growth rates of different nerve fibre populations led to conflicting results. We developed an animal model to compare growth and maturation of the fastest growing sensory and motor fibres within the same mixed nerve after Wallerian degeneration. Regeneration of cat tibial nerve after crush (n = 13) and section (n = 7) was monitored for up to 140 days, using implanted cuff electrodes placed around the sciatic and tibial nerves and wire electrodes at plantar muscles. To distinguish between sensory and motor fibres, recordings were carried out from L6-S2 spinal roots using cuff electrodes. The timing of laminectomy was based on the presence of regenerating fibres along the nerve within the tibial cuff. Stimulation of unlesioned tibial nerves (n = 6) evoked the largest motor response in S1 ventral root and the largest sensory response in L7 dorsal root. Growth rates were compared by mapping the regenerating nerve fibres within the tibial nerve cuff to all ventral or dorsal roots and, regardless of the lesion type, the fastest growth was similar in sensory and motor fibres. Maturation was assessed as recovery of the maximum motor and sensory conduction velocities (CVs) within the tibial nerve cuff. Throughout the observation period the CV was approximately 14% faster in regenerated sensory fibres than in motor fibres in accordance with the difference observed in control nerves. Recovery of amplitude was only partial after section, whereas the root distribution pattern was restored. Our data suggest that the fastest growth and maturation rates that can be achieved during regeneration are similar for motor and sensory myelinated fibres.

AB - Functional outcome after peripheral nerve regeneration is often poor, particularly involving nerve injuries far from their targets. Comparison of sensory and motor axon regeneration before target reinnervation is not possible in the clinical setting, and previous experimental studies addressing the question of differences in growth rates of different nerve fibre populations led to conflicting results. We developed an animal model to compare growth and maturation of the fastest growing sensory and motor fibres within the same mixed nerve after Wallerian degeneration. Regeneration of cat tibial nerve after crush (n = 13) and section (n = 7) was monitored for up to 140 days, using implanted cuff electrodes placed around the sciatic and tibial nerves and wire electrodes at plantar muscles. To distinguish between sensory and motor fibres, recordings were carried out from L6-S2 spinal roots using cuff electrodes. The timing of laminectomy was based on the presence of regenerating fibres along the nerve within the tibial cuff. Stimulation of unlesioned tibial nerves (n = 6) evoked the largest motor response in S1 ventral root and the largest sensory response in L7 dorsal root. Growth rates were compared by mapping the regenerating nerve fibres within the tibial nerve cuff to all ventral or dorsal roots and, regardless of the lesion type, the fastest growth was similar in sensory and motor fibres. Maturation was assessed as recovery of the maximum motor and sensory conduction velocities (CVs) within the tibial nerve cuff. Throughout the observation period the CV was approximately 14% faster in regenerated sensory fibres than in motor fibres in accordance with the difference observed in control nerves. Recovery of amplitude was only partial after section, whereas the root distribution pattern was restored. Our data suggest that the fastest growth and maturation rates that can be achieved during regeneration are similar for motor and sensory myelinated fibres.

U2 - 10.1093/brain/awl184

DO - 10.1093/brain/awl184

M3 - Journal article

C2 - 16905553

VL - 129

SP - 2471

EP - 2483

JO - Brain

JF - Brain

SN - 0006-8950

IS - Pt 9

ER -

ID: 1121129