Evidence that impaired motor conduction in the bilateral ulnar and tibial nerves underlies cervical spondylotic amyotrophy in patients with unilateral deltoid muscle atrophy
Introduction: The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear.Methods: We assessed electrophysi...
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| Published in | Spine Surgery and Related Research Vol. 2; no. 1; pp. 23 - 29 |
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| Main Authors | , , , , , |
| Format | Journal Article |
| Language | English |
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Japan
The Japanese Society for Spine Surgery and Related Research
01.01.2018
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| Online Access | Get full text |
| ISSN | 2432-261X 2432-261X |
| DOI | 10.22603/ssrr.2017-0012 |
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| Abstract | Introduction: The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear.Methods: We assessed electrophysiological motor conduction through the corticospinal tract and ulnar and tibial nerves, which do not supply the deltoid or biceps muscles, of 18 patients with CSA, 12 patients with compressive cervical myelopathy, and 18 control subjects with cervical spondylotic radiculopathy. Motor evoked potentials following transcranial magnetic stimulation and M-waves and F-waves following electrical stimulation were measured from the bilateral abductor digiti minimi muscles (ADMs) and abductor hallucis muscles (AHs). The peripheral conduction time (PCT) was calculated from the latencies of the CMAPs and F-waves as follows: (latency of CMAPs + latency of F-waves - 1) / 2. The central motor conduction time (CMCT) was calculated by subtracting the PCT from the onset latency of the MEPs.Results: The M-wave (M) latency and minimum F-wave (Fmin) latency from the ADM, and Fmin-M latency from the ADM/AH were significantly longer in the CSA group than in the other groups, on both the affected (p = 0.000-0.007) and unaffected sides (p = 0.000-0.033). F-wave persistence from the bilateral ADMs was significantly lower in the CSA group than in the other groups (p = 0.000-0.002). Among the CSA patients, there were no significant differences in these parameters between the affected and unaffected sides. The CMCT showed no significant differences between the CSA and control groups, but significant differences between the CSA and CCM groups (p = 0.000-0.004).Conclusions: CSA patients with unilateral deltoid muscle atrophy had subclinical impairments of lower motor neurons and/or peripheral axons in the ulnar nerve, and subclinical impairments of peripheral axons in the tibial nerve. These motor impairments may have originally existed in these individuals before the onset of CSA. |
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| AbstractList | Introduction: The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear. Methods: We assessed electrophysiological motor conduction through the corticospinal tract and ulnar and tibial nerves, which do not supply the deltoid or biceps muscles, of 18 patients with CSA, 12 patients with compressive cervical myelopathy, and 18 control subjects with cervical spondylotic radiculopathy. Motor evoked potentials following transcranial magnetic stimulation and M-waves and F-waves following electrical stimulation were measured from the bilateral abductor digiti minimi muscles (ADMs) and abductor hallucis muscles (AHs). The peripheral conduction time (PCT) was calculated from the latencies of the CMAPs and F-waves as follows: (latency of CMAPs + latency of F-waves - 1) / 2. The central motor conduction time (CMCT) was calculated by subtracting the PCT from the onset latency of the MEPs. Results: The M-wave (M) latency and minimum F-wave (Fmin) latency from the ADM, and Fmin-M latency from the ADM/AH were significantly longer in the CSA group than in the other groups, on both the affected (p = 0.000-0.007) and unaffected sides (p = 0.000-0.033). F-wave persistence from the bilateral ADMs was significantly lower in the CSA group than in the other groups (p = 0.000-0.002). Among the CSA patients, there were no significant differences in these parameters between the affected and unaffected sides. The CMCT showed no significant differences between the CSA and control groups, but significant differences between the CSA and CCM groups (p = 0.000-0.004). Conclusions: CSA patients with unilateral deltoid muscle atrophy had subclinical impairments of lower motor neurons and/or peripheral axons in the ulnar nerve, and subclinical impairments of peripheral axons in the tibial nerve. These motor impairments may have originally existed in these individuals before the onset of CSA. The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear. We assessed electrophysiological motor conduction through the corticospinal tract and ulnar and tibial nerves, which do not supply the deltoid or biceps muscles, of 18 patients with CSA, 12 patients with compressive cervical myelopathy, and 18 control subjects with cervical spondylotic radiculopathy. Motor evoked potentials following transcranial magnetic stimulation and M-waves and F-waves following electrical stimulation were measured from the bilateral abductor digiti minimi muscles (ADMs) and abductor hallucis muscles (AHs). The peripheral conduction time (PCT) was calculated from the latencies of the CMAPs and F-waves as follows: (latency of CMAPs + latency of F-waves - 1) / 2. The central motor conduction time (CMCT) was calculated by subtracting the PCT from the onset latency of the MEPs. The M-wave (M) latency and minimum F-wave (Fmin) latency from the ADM, and Fmin-M latency from the ADM/AH were significantly longer in the CSA group than in the other groups, on both the affected ( = 0.000-0.007) and unaffected sides ( = 0.000-0.033). F-wave persistence from the bilateral ADMs was significantly lower in the CSA group than in the other groups ( = 0.000-0.002). Among the CSA patients, there were no significant differences in these parameters between the affected and unaffected sides. The CMCT showed no significant differences between the CSA and control groups, but significant differences between the CSA and CCM groups ( = 0.000-0.004). CSA patients with unilateral deltoid muscle atrophy had subclinical impairments of lower motor neurons and/or peripheral axons in the ulnar nerve, and subclinical impairments of peripheral axons in the tibial nerve. These motor impairments may have originally existed in these individuals before the onset of CSA. The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear.INTRODUCTIONThe clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory deficits in patients with cervical spondylosis. However, the pathogenesis of CSA is still unclear.We assessed electrophysiological motor conduction through the corticospinal tract and ulnar and tibial nerves, which do not supply the deltoid or biceps muscles, of 18 patients with CSA, 12 patients with compressive cervical myelopathy, and 18 control subjects with cervical spondylotic radiculopathy. Motor evoked potentials following transcranial magnetic stimulation and M-waves and F-waves following electrical stimulation were measured from the bilateral abductor digiti minimi muscles (ADMs) and abductor hallucis muscles (AHs). The peripheral conduction time (PCT) was calculated from the latencies of the CMAPs and F-waves as follows: (latency of CMAPs + latency of F-waves - 1) / 2. The central motor conduction time (CMCT) was calculated by subtracting the PCT from the onset latency of the MEPs.METHODSWe assessed electrophysiological motor conduction through the corticospinal tract and ulnar and tibial nerves, which do not supply the deltoid or biceps muscles, of 18 patients with CSA, 12 patients with compressive cervical myelopathy, and 18 control subjects with cervical spondylotic radiculopathy. Motor evoked potentials following transcranial magnetic stimulation and M-waves and F-waves following electrical stimulation were measured from the bilateral abductor digiti minimi muscles (ADMs) and abductor hallucis muscles (AHs). The peripheral conduction time (PCT) was calculated from the latencies of the CMAPs and F-waves as follows: (latency of CMAPs + latency of F-waves - 1) / 2. The central motor conduction time (CMCT) was calculated by subtracting the PCT from the onset latency of the MEPs.The M-wave (M) latency and minimum F-wave (Fmin) latency from the ADM, and Fmin-M latency from the ADM/AH were significantly longer in the CSA group than in the other groups, on both the affected (p = 0.000-0.007) and unaffected sides (p = 0.000-0.033). F-wave persistence from the bilateral ADMs was significantly lower in the CSA group than in the other groups (p = 0.000-0.002). Among the CSA patients, there were no significant differences in these parameters between the affected and unaffected sides. The CMCT showed no significant differences between the CSA and control groups, but significant differences between the CSA and CCM groups (p = 0.000-0.004).RESULTSThe M-wave (M) latency and minimum F-wave (Fmin) latency from the ADM, and Fmin-M latency from the ADM/AH were significantly longer in the CSA group than in the other groups, on both the affected (p = 0.000-0.007) and unaffected sides (p = 0.000-0.033). F-wave persistence from the bilateral ADMs was significantly lower in the CSA group than in the other groups (p = 0.000-0.002). Among the CSA patients, there were no significant differences in these parameters between the affected and unaffected sides. The CMCT showed no significant differences between the CSA and control groups, but significant differences between the CSA and CCM groups (p = 0.000-0.004).CSA patients with unilateral deltoid muscle atrophy had subclinical impairments of lower motor neurons and/or peripheral axons in the ulnar nerve, and subclinical impairments of peripheral axons in the tibial nerve. These motor impairments may have originally existed in these individuals before the onset of CSA.CONCLUSIONSCSA patients with unilateral deltoid muscle atrophy had subclinical impairments of lower motor neurons and/or peripheral axons in the ulnar nerve, and subclinical impairments of peripheral axons in the tibial nerve. These motor impairments may have originally existed in these individuals before the onset of CSA. |
| Author | Nakanishi, Kazuyoshi Kamei, Naosuke Kotaka, Shinji Adachi, Nobuo Ochi, Mitsuo Tanaka, Nobuhiro |
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| Keywords | cervical spondylotic amyotrophy cervical spondylotic radiculopathy F-wave central motor conduction time motor evoked potentials |
| Language | English |
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| References | 9. Di Lazzaro V, Restuccia D, Colosimo C, et al. The contribution of magnetic stimulation of the motor cortex to the diagnosis of cervical spondylotic myelopathy. Correlation of central motor conduction to distal and proximal upper limb muscles with clinical and MRI findings. Electroencephalogr Clin Neurophysiol. 1992;85 (5):311-20. 15. King D, Ashby P. Conduction velocity in the proximal segments of a motor nerve in the Guillain-Barré syndrome. J Neurol Neurosurg Psychiatr. 1976;39 (6):538-44. 17. Mills KR, Nithi KA. Peripheral and central motor conduction in amyotrophic lateral sclerosis. J Neurol Sci. 1998;159 (1):82-7. 6. Abbed KM, Coumans J-VCE. Cervical radiculopathy: pathophysiology, presentation, and clinical evaluation. Neurosurgery. 2007;60 (1 Supp1 1):S28-34. 19. Bradley WG. Recent views on amyotrophic lateral sclerosis with emphasis on electrophysiological studies. Muscle Nerve. 1987;10 (6):490-502. 2. Shinomiya K, Komori H, Matsuoka T, et al. Neuroradiologic and electrophysiologic assessment of cervical spondylotic amyotrophy. Spine. 1994;19 (1):21-5. 3. Ebara S, Yonenobu K, Fujiwara K, et al. Myelopathy hand characterized by muscle wasting. A different type of myelopathy hand in patients with cervical spondylosis. Spine. 1988;13 (7):785-91. 11. Nakanishi K, Tanaka N, Fujiwara Y, et al. Corticospinal tract conduction block results in the prolongation of central motor conduction time in compressive cervical myelopathy. Clin Neurophysiol. 2006;117 (3):623-7. 12. Nakanishi K, Tanaka N, Kamei N, et al. Significant correlation between corticospinal tract conduction block and prolongation of central motor conduction time in compressive cervical myelopathy. J Neurol Sci. 2007;256 (1-2):71-4. 13. Conrad B, Aschoff JC, Fischler M. [The diagnostic value of the F wave latency (author's transl) ]. J Neurol. 1975;210 (3):151-9. 16. Panayiotopoulos CP, Scarpalezos S, Nastas PE. F-wave studies on the deep peroneal nerve. J Neurol Sci. 1977;31 (3):319-29. 23. Dietz V, Curt A. Neurological aspects of spinal-cord repair: promises and challenges. Lancet Neurol. 2006;5 (8):688-94. 25. Puksa L, Stålberg E, Falck B. Reference values of F wave parameters in healthy subjects. Clin Neurophysiol. 2003;114 (6):1079-90. doi:10.1016/S1388-2457 (03) 00028-2. 5. Mizuno J, Nakagawa H, Hashizume Y. Cervical amyotrophy caused by hypertrophy of the posterior longitudinal ligament. Spinal Cord. 2002;40 (9):484-8. 14. Kimura J. Principles and pitfalls of nerve conduction studies. Ann Neurol. 1984;16 (4):415-29. 1. Keegan JJ. The cause of dissociated motor loss in the upper extremity with cervical spondylosis. J Neurosurg. 1965;23 (5):528-36. 21. Hiersemenzel LP, Curt A, Dietz V. From spinal shock to spasticity: neuronal adaptations to a spinal cord injury. Neurology. 2000;54 (8):1574-82. 8. Maertens de Noordhout A, Remacle JM, Pepin JL, et al. Magnetic stimulation of the motor cortex in cervical spondylosis. Neurology. 1991;41 (1):75-80. 24. Shibuya R, Yonenobu K, Yamamoto K, et al. Acute arm paresis with cervical spondylosis: three case reports. Surg Neurol. 2005;63 (3):220-28. 7. Kimura J, Yamada T, Stevland NP. Distal slowing of motor nerve conduction velocity in diabetic polyneuropathy. J Neurol Sci. 1979;42 (2):291-302. 20. Curt A, Keck ME, Dietz V. Clinical value of F-wave recordings in traumatic cervical spinal cord injury. Electroencephalogr Clin Neurophysiol. 1997;105 (3):189-93. 4. Kameyama T, Ando T, Yanagi T, et al. Cervical spondylotic amyotrophy. Magnetic resonance imaging demonstration of intrinsic cord pathology. Spine. 1998;23 (4):448-52. 18. Argyropoulos CJ, Panayiotopoulos CP, Scarpalezos S. F- and M-wave conduction velocity in amyotrophic lateral sclerosis. Muscle Nerve. 1978;1 (6):479-85. 22. Mangold S, Keller T, Curt A, et al. Transcutaneous functional electrical stimulation for grasping in subjects with cervical spinal cord injury. Spinal Cord. 2005;43 (1):1-13. 10. Kaneko K, Taguchi T, Morita H, et al. Mechanism of prolonged central motor conduction time in compressive cervical myelopathy. Clin Neurophysiol. 2001;112 (6):1035-40. 22 23 24 25 10 11 12 13 14 15 16 17 18 19 1 2 3 4 5 6 7 8 9 20 21 |
| References_xml | – reference: 3. Ebara S, Yonenobu K, Fujiwara K, et al. Myelopathy hand characterized by muscle wasting. A different type of myelopathy hand in patients with cervical spondylosis. Spine. 1988;13 (7):785-91. – reference: 20. Curt A, Keck ME, Dietz V. Clinical value of F-wave recordings in traumatic cervical spinal cord injury. Electroencephalogr Clin Neurophysiol. 1997;105 (3):189-93. – reference: 6. Abbed KM, Coumans J-VCE. Cervical radiculopathy: pathophysiology, presentation, and clinical evaluation. Neurosurgery. 2007;60 (1 Supp1 1):S28-34. – reference: 14. Kimura J. Principles and pitfalls of nerve conduction studies. Ann Neurol. 1984;16 (4):415-29. – reference: 19. Bradley WG. Recent views on amyotrophic lateral sclerosis with emphasis on electrophysiological studies. Muscle Nerve. 1987;10 (6):490-502. – reference: 15. King D, Ashby P. Conduction velocity in the proximal segments of a motor nerve in the Guillain-Barré syndrome. J Neurol Neurosurg Psychiatr. 1976;39 (6):538-44. – reference: 16. Panayiotopoulos CP, Scarpalezos S, Nastas PE. F-wave studies on the deep peroneal nerve. J Neurol Sci. 1977;31 (3):319-29. – reference: 21. Hiersemenzel LP, Curt A, Dietz V. From spinal shock to spasticity: neuronal adaptations to a spinal cord injury. Neurology. 2000;54 (8):1574-82. – reference: 11. Nakanishi K, Tanaka N, Fujiwara Y, et al. Corticospinal tract conduction block results in the prolongation of central motor conduction time in compressive cervical myelopathy. Clin Neurophysiol. 2006;117 (3):623-7. – reference: 12. Nakanishi K, Tanaka N, Kamei N, et al. Significant correlation between corticospinal tract conduction block and prolongation of central motor conduction time in compressive cervical myelopathy. J Neurol Sci. 2007;256 (1-2):71-4. – reference: 5. Mizuno J, Nakagawa H, Hashizume Y. Cervical amyotrophy caused by hypertrophy of the posterior longitudinal ligament. Spinal Cord. 2002;40 (9):484-8. – reference: 23. Dietz V, Curt A. Neurological aspects of spinal-cord repair: promises and challenges. Lancet Neurol. 2006;5 (8):688-94. – reference: 1. Keegan JJ. The cause of dissociated motor loss in the upper extremity with cervical spondylosis. J Neurosurg. 1965;23 (5):528-36. – reference: 10. Kaneko K, Taguchi T, Morita H, et al. Mechanism of prolonged central motor conduction time in compressive cervical myelopathy. Clin Neurophysiol. 2001;112 (6):1035-40. – reference: 25. Puksa L, Stålberg E, Falck B. Reference values of F wave parameters in healthy subjects. Clin Neurophysiol. 2003;114 (6):1079-90. doi:10.1016/S1388-2457 (03) 00028-2. – reference: 2. Shinomiya K, Komori H, Matsuoka T, et al. Neuroradiologic and electrophysiologic assessment of cervical spondylotic amyotrophy. Spine. 1994;19 (1):21-5. – reference: 24. Shibuya R, Yonenobu K, Yamamoto K, et al. Acute arm paresis with cervical spondylosis: three case reports. Surg Neurol. 2005;63 (3):220-28. – reference: 22. Mangold S, Keller T, Curt A, et al. Transcutaneous functional electrical stimulation for grasping in subjects with cervical spinal cord injury. Spinal Cord. 2005;43 (1):1-13. – reference: 4. Kameyama T, Ando T, Yanagi T, et al. Cervical spondylotic amyotrophy. Magnetic resonance imaging demonstration of intrinsic cord pathology. Spine. 1998;23 (4):448-52. – reference: 8. Maertens de Noordhout A, Remacle JM, Pepin JL, et al. Magnetic stimulation of the motor cortex in cervical spondylosis. Neurology. 1991;41 (1):75-80. – reference: 13. Conrad B, Aschoff JC, Fischler M. [The diagnostic value of the F wave latency (author's transl) ]. J Neurol. 1975;210 (3):151-9. – reference: 7. Kimura J, Yamada T, Stevland NP. Distal slowing of motor nerve conduction velocity in diabetic polyneuropathy. J Neurol Sci. 1979;42 (2):291-302. – reference: 17. Mills KR, Nithi KA. Peripheral and central motor conduction in amyotrophic lateral sclerosis. J Neurol Sci. 1998;159 (1):82-7. – reference: 9. Di Lazzaro V, Restuccia D, Colosimo C, et al. The contribution of magnetic stimulation of the motor cortex to the diagnosis of cervical spondylotic myelopathy. Correlation of central motor conduction to distal and proximal upper limb muscles with clinical and MRI findings. Electroencephalogr Clin Neurophysiol. 1992;85 (5):311-20. – reference: 18. Argyropoulos CJ, Panayiotopoulos CP, Scarpalezos S. F- and M-wave conduction velocity in amyotrophic lateral sclerosis. 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| Snippet | Introduction: The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with... The clinical entity of cervical spondylotic amyotrophy (CSA) is characterized by severe muscle atrophy in the upper extremities with insignificant sensory... |
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| SubjectTerms | central motor conduction time cervical spondylotic amyotrophy cervical spondylotic radiculopathy F-wave motor evoked potentials Original |
| Title | Evidence that impaired motor conduction in the bilateral ulnar and tibial nerves underlies cervical spondylotic amyotrophy in patients with unilateral deltoid muscle atrophy |
| URI | https://www.jstage.jst.go.jp/article/ssrr/2/1/2_2017-0012/_article/-char/en https://www.ncbi.nlm.nih.gov/pubmed/31440642 https://www.proquest.com/docview/2281103148 https://pubmed.ncbi.nlm.nih.gov/PMC6698543 https://doaj.org/article/06f7059fbefb486ea1dc3a2cb21f1b23 |
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| ispartofPNX | Spine Surgery and Related Research, 2018/01/20, Vol.2(1), pp.23-29 |
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