A spatio-temporal analysis of motoneuron survival, axonal regeneration and neurotrophic factor expression after lumbar ventral root avulsion and implantation

A spatio-temporal analysis of motoneuron survival, axonal regeneration and neurotrophic factor expression after lumbar ventral root avulsion and implantation

Reimplantation of avulsed rat lumbar spinal ventral roots results in poor recovery of function of the denervated hind limb muscles. In contrast, reimplantation of cervical or sacral ventral roots is a successful repair strategy that results in a significant degree of regeneration. A possible explana...

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Bibliographic Details
Published in:Experimental neurology Vol. 223; no. 1; pp. 207 - 220
Main Authors: Eggers, R., Tannemaat, M.R., Ehlert, E.M., Verhaagen, J.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-05-2010
Subjects:
Animals
Axonal regeneration
Axotomy
Brachial plexus
Cell Survival - physiology
Choline O-Acetyltransferase - metabolism
Denervation
Disease Models, Animal
Enzyme-Linked Immunosorbent Assay - methods
Female
Gene Expression Regulation - physiology
Hindlimb - pathology
Lumbosacral Plexus - pathology
Lumbosacral Plexus - physiopathology
Motoneuron
Motor Neurons - pathology
Muscle, Skeletal - physiopathology
Nerve Growth Factors - genetics
Nerve Growth Factors - metabolism
Nerve Regeneration - physiology
Neurotrophic factors
Peripheral nerve injury
Radiculopathy - pathology
Radiculopathy - physiopathology
Radiculopathy - surgery
Rats
Rats, Wistar
Replantation - methods
Sciatic Nerve - metabolism
Sciatic Nerve - pathology
Time Factors
Ventral root avulsion
Axotomy
Brachial plexus
Axonal regeneration
Peripheral nerve injury
Ventral root avulsion
Motoneuron
Neurotrophic factors
Denervation
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Summary:Reimplantation of avulsed rat lumbar spinal ventral roots results in poor recovery of function of the denervated hind limb muscles. In contrast, reimplantation of cervical or sacral ventral roots is a successful repair strategy that results in a significant degree of regeneration. A possible explanation for this difference could be that following lumbar root avulsion, axons have to travel longer distances towards their target muscles, resulting in prolonged denervation of the distal nerve and a diminished capacity to support regeneration. Here we present a detailed spatio-temporal analysis of motoneuron survival, axonal regeneration and neurotrophic factor expression following unilateral avulsion and implantation of lumbar ventral roots L3, L4, and L5. Reimplantation prolongs the survival of motoneurons up to one month post-lesion. The first regenerating motor axons entered the reimplanted ventral roots during the first week and large numbers of fibers gradually enter the lumbar plexus between 2 and 4 weeks, indicating that axons enter the reimplanted roots and plexus over an extended period of time. However, motor axon counts show that relatively few axons reach the distal sciatic nerve in the 16 week post-lesion period. The observed initial increase and subsequent decline in expression of glial cell line-derived neurotrophic factor and brain-derived neurotrophic factor correlate with the apparent spatio-temporal decline in the regenerative capacity of motor axons, indicating that the distal nerve is losing its capacity to support regenerating motor axons following prolonged denervation. These findings have important implications for future strategies to promote long-distance regeneration through distal, chronically denervated peripheral nerves.
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ISSN:0014-4886
1090-2430
DOI:10.1016/j.expneurol.2009.07.021