Evaluation of the lower motor neuron integrity of upper extremity muscles in high level spinal cord injury

Mulcahey, M. J.; Bt, Smith; Rr, Betz

doi:10.1038/sj.sc.3100889

Cited by 76 publications

(40 citation statements)

References 31 publications

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“…For example, various muscles innervated from the lesion epicenter have been unresponsive to electrical stimulation of their peripheral nerves, consistent with complete muscle denervation. [14][15][16][17][18] Other studies have shown signs of partial denervation (low motor unit counts, positive sharp waves, small amplitude compound muscle action potentials, muscle weakness that exceeds that expected from disuse atrophy, atrophied and angular muscle fibers), including indications of intramuscular motor axon sprouting, an important compensatory mechanism for recovery of muscle innervation after death of some motoneurons in a motor pool (large polyphasic motor unit potentials, stronger than usual motor unit forces, increased motor unit fiber density, increased jitter in re-innervated muscle fibers). 12,[19][20][21][22][23] In this study, we address an important and often overlooked aspect of SCI-the effect of injury on the lesioned spinal cord segment and denervation of skeletal muscle as a contributor to muscular weakness.…”

Section: Introductionmentioning

confidence: 99%

Motoneuron Death after Human Spinal Cord Injury

Grumbles

Thomas

2017

Journal of Neurotrauma

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The severe muscle weakness and atrophy measured after human spinal cord injury (SCI) may relate to chronic muscle denervation due to motoneuron death and/or altered muscle use. The aim of this study was to estimate motoneuron death after traumatic human SCI. The diameter and number of myelinated axons were measured in ventral roots post-mortem because ventral roots contain large diameter (> 7 lm) myelinated axons that typically arise from motoneurons and innervate skeletal muscle. In four cases (SCI levels C7, C8, T4, and L1) involving contusion (n = 3) or laceration (n = 1), there was a significant reduction in the number of large diameter myelinated axons at the lesion epicenter (mean -standard error [SE]: 45 -11% Uninjured), one level above (51 -14%), and one (27 -12%), two (45 -40%), and three (54 -23%) levels below the epicenter. Reductions in motoneuron numbers varied by side and case. These deficits result from motoneuron death because the gray matter was destroyed at and near the lesion epicenter. Muscle denervation must ensue. In seven cases, ventral roots at or below the epicenter had large diameter myelinated axons with unusually thin myelin, a sign of incomplete remyelination. The mean -SE g ratio (axon diameter/fiber diameter) was 0.60 -0.01 for axons of all diameters in five above-lesion ventral roots, but increased significantly for large diameter fibers ( ‡ 12 lm) in three roots at the lesion epicenter. Motoneuron death after human SCI will coarsen muscle force gradation and control, while extensive muscle denervation will stifle activity-based treatments.

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Section: Introductionmentioning

confidence: 99%

Motoneuron Death after Human Spinal Cord Injury

Grumbles

Thomas

2017

Journal of Neurotrauma

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“…If a muscle responded weakly to surface stimulation, strength duration testing was performed to that muscle to determine if the muscle should be classified as innervated, denervated, or partially denervated. A full description of performing and interpreting strength duration curves is identified in Mulcahey et al 21 Data analysis Subjects were grouped according to levels of injury (Table 2). These groupings were based upon the authors' hypotheses about potential sources of denervation due to clinical experience and anatomy.…”

Section: Data Collectionmentioning

confidence: 99%

“…The literature presents mixed findings in regard to mechanism of injury and innervation. Doherty et al 1 found no relationship between mechanism of injury and innervation, while Mulcahey et al 21 anecdotally reported increased LMN damage in the upper extremities of children whose cervical SCI had viral, vascular, or iatrogenic causes, and Triolo et al 23 reported a relationship between SCI due to transverse myelitis and denervation. Despite anatomical differences reported in the spines of children less than 10 years of age, we found no relationship between age at injury and innervation status, indicating that the anatomical differences in children likely do not impact innervation status.…”

Section: A Negative Odds Ratiomentioning

confidence: 99%

“…Studies have attempted to predict whether the neurological level will correspond to the type of lesion in the lower extremities, 1 upper extremities, 21 and the bladder. 22 Doherty et al 1 found a significant trend that the incidence of LMN lesions affecting the lower extremities decreased as the level of injury progressed in a cephalad manner in adults with SCI, using reflex testing to distinguish those with UMN and LMN lesions.…”

Section: Introductionmentioning

confidence: 99%

“…25,26 Viral, vascular, and iatrogenic causes of SCI have also been linked to LMN damage. 21,23 Differences may exist in patterns of UMN and LMN lesions between injuries sustained by children and by adults. Injuries to the spinal cord can differ in presentation between adults and children.…”

Section: Introductionmentioning

confidence: 99%

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Patterns of lower extremity innervation in pediatric spinal cord injury

et al. 2005

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Study design: Retrospective review. Objectives: To identify relationships between lower extremity innervation and level of injury, mechanism of injury, and age at injury in a pediatric population with spinal cord injury (SCI). Secondarily, relationships between innervation and completeness of injury, time since injury, race, and sex were evaluated. Setting: Pediatric orthopedic referral hospital, Philadelphia, Pennsylvania. Methods: Records of 190 subjects, ages 1-21 years, were reviewed. Data collected from the medical record included lower extremity muscle innervation, American Spinal Injury Association (ASIA) level and class, mechanism of injury, age at injury, time since injury, race, and sex. To determine innervation, lower extremity muscles had been tested using surface electrical stimulation and identified as being innervated or denervated. If a muscle responded weakly, strength duration testing was performed. For analysis via logistic regression, subjects were grouped based upon level and mechanism of injury. Results: A relationship (Po0.0001) was found between ASIA level and lower extremity innervation of all muscles and between length of time since injury and lower extremity innervation for some muscles. Following multiple logistic regression, only ASIA level remained as an independent predictor of lower extremity innervation status. Conclusion: Our results show that lower extremity innervation does differ based on the level of the injury. Denervation began to be seen with injuries in the lower thoracic region and more predominantly with injuries in the lumbar region. This supports our hypothesis that the incidence of lower motor neuron injuries would increase as injuries became more caudal. Our hypotheses of a relationship between innervation status and mechanism of injury and age at injury were not supported. This information is important in determining treatment strategies, eligibility for electrical stimulation techniques, and potential regenerative strategies.

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Diffusion tensor magnetic resonance imaging in spinal cord injury

Ellingson¹,

Schmit²,

Ulmer³

et al. 2008

Concepts Magnetic Resonance

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Noninvasive assessment of spinal cord integrity following injury is critical for precise diagnosis, prognosis, and surgical intervention strategies. Diffusion weighted imaging and diffusion tensor imaging are more sensitive to the underlying spinal cord microstructure than traditional imaging techniques. As a result, diffusion imaging is emerging as the clinical technique for imaging the spinal cord after trauma, surgery or during progressive degenerative diseases. This review describes the basic physics of diffusion imaging using magnetic resonance, techniques used to visualize diffusion measurements, and expected changes in diffusion measurements following spinal cord injury.

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Evaluation of the lower motor neuron integrity of upper extremity muscles in high level spinal cord injury

Cited by 76 publications

References 31 publications

Motoneuron Death after Human Spinal Cord Injury

Motoneuron Death after Human Spinal Cord Injury

Patterns of lower extremity innervation in pediatric spinal cord injury

Diffusion tensor magnetic resonance imaging in spinal cord injury

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