Dimitri Laurent1, Olgert Bardhi1, Jason Gregory2, Anthony Yachnis2, Lance S. Governale1- Department of Neurosurgery University of Florida, Gainesville, Florida, United States.
- Department of Pathology, University of Florida, Gainesville, Florida, United States.
Correspondence Address: Lance S. Governale Department of Neurosurgery University of Florida, Gainesville, Florida, United States.
DOI:10.25259/SNI_641_2020 Copyright: © 2020 Surgical Neurology International This is an open-access article distributed under the terms of the Creative Commons Attribution-Non Commercial-Share Alike 4.0 License, which allows others to remix, tweak, and build upon the work non-commercially, as long as the author is credited and the new creations are licensed under the identical terms. How to cite this article: Dimitri Laurent1, Olgert Bardhi1, Jason Gregory2, Anthony Yachnis2, Lance S. Governale1. Pediatric pathology all grown up – An interesting case of adult tethered spinal cord. 29-Oct-2020;11:362 Add to Reading ListRemove from Reading List Date of Submission 14-Sep-2020 Date of Acceptance 02-Oct-2020 Date of Web Publication 29-Oct-2020 Background: Cervical myelopathy in an adult is typically the result of degenerative disease or trauma. Dysraphism is rarely the cause. Case Description: The authors report the case of a 35-year-old male drywall installer who presented with 2 years of progressive left upper extremity weakness, numbness, and hand clumsiness. Only upon detailed questioning did he mention that he had neck surgery just after birth, but he did not know what was done. He then also reported that he routinely shaved a patch of lower back hair, but denied bowel, bladder, or lower extremity dysfunction. Magnetic resonance imaging of the cervical spine demonstrated T2 hyperintensity at C4-C5 with dorsal projection of the neural elements into the subcutaneous tissues concerning for a retethered cervical myelomeningocele. Lumbar imaging revealed a diastematomyelia at L4. He underwent surgical intervention for detethering and repaired of the cervical mye lomeningocele. Four months postoperatively, he had almost complete resolution of symptoms, and imaging showed a satisfactory detethering. The diastematomyelia remained asymptomatic and is being observed. Conclusion: Tethered cervical cord is a rare cause for myelopathy in the adult patient. In the symptomatic patient, surgical repair with detethering is indicated to prevent disease progression and often results in clinical improvement. Keywords: Cervical myelomeningocele, Cervical myelopathy, Diastematomyelia, Spina bifida, Spinal dysraphism, Tethered spinal cord Cervical myelopathy in an adult is typically the result of degenerative disease or trauma.[ 4 ] Dysraphism is rarely the cause. Cervical myelomeningoceles are a rare form of spinal dysraphism, accounting for 5 , 11 ] Patients may present with a myriad of signs and symptoms, including pain, weakness, paresthesia, upper motor neuron signs, muscle wasting, and bowel/bladder dysfunction.[ 1 - 3 , 5 , 12 , 13 ] Unlike myelomeningoceles occurring in the lumbar spine, cervical myelomeningoceles are typically covered by epithelium.[ 11 , 15 ] In the symptomatic patient, surgical repair with detethering is indicated to prevent disease progression and often results in clinical improvement. We present the case of a retethered cervical myelomeningocele in a 35-year-old who also harbored a previously unknown lumbar diastematomyelia. History and examinationA 35-year-old male drywall installer presented with 2 years of progressive left upper extremity weakness, numbness, and hand clumsiness. Neurologic examination demonstrated 4-/5 strength of the left hand intrinsic muscles, decreased sensation to light touch in the left hand, and hyperreflexia of the left upper extremity. Electromyography and nerve conduction testing demonstrated only mild incidental bilateral ulnar neuropathy across the elbow. Magnetic resonance imaging (MRI) of the cervical spine demonstrated cervical spinal cord expansion with T2 hyperintensity at C4-C5. There was an associated defect of the bony posterior elements with projection of the neural elements into the dorsal subcutaneous soft tissue [ Figure 1 ]. At this point, he was referred to our institution where only upon detailed questioning did he mention that he had neck surgery just after birth, but he did not know what was done. This additional history allowed the diagnosis of retethering of a cervical myelomeningocele. A cervical detethering operation was recommended. Figure 1:Preoperative sagittal (a) and axial (b and c) T2 MRI of the cervical spine demonstrating intramedullary T2 signal changes and a small syrinx associated with a dorsally projecting exophytic cervical myelomeningocele terminating in the subcutaneous fat. He then also reported that he routinely shaved a patch of lower back hair, but denied bowel, bladder, or lower extremity dysfunction. This prompted an MRI of the lumbar spine which demonstrated underlying diastematomyelia with a low-lying conus [ Figure 2 ]. His lower extremity and sacral examination were normal. Because the diastematomyelia was asymptomatic in this adult patient at final height, observation was recommended. Figure 2:Preoperative sagittal (left) and axial (right) T2 MRI of the lumbar spine demonstrating a low-lying conus and associated diastematomyelia at L4. OperationAfter satisfactory induction of general endotracheal anesthesia, the patient was positioned prone on gel rolls, and his head was fixed in Mayfield pins in neutral position. Neuromonitoring with somatosensory evoked potentials (SSEP), motor evoked potentials, and electromyography was established. The prior curvilinear midline incision was marked and slightly extended superiorly and inferiorly. The superior portion of the incision over the last rostral intact lamina was opened sharply and carried down to the fascia using blunt dissection. Progressing along the fascia from superior to inferior, the overlying soft tissue was opened. The myelomeningocele sac was identified and dissected circumferentially as it passed through the fascia. The sac was then separated from the overlying soft tissue [ Figure 3a ]. Figure 3:Intraoperative views of the cervical myelomeningocele (cranial at right and caudal at left in each image). (a) Myelomeningocele sac (asterisk) extending through the fascia (f) and terminating in the subcutaneous adipose tissue (a). (b and c) Myelomeningocele emanating from the normal dura (d) and contiguous with it superiorly and inferiorly. (d) Dorsal projection of the neural elements (n) after dissection from the overlying myelomeningocele sac. (e) Pial closure of the dysplastic neural stump. (f) The free dysplastic neural stump at rest before dural closure. The fascia was opened rostral and caudal to the myelomeningocele sac. The rostral (bifid) and caudal (hemi) dysplastic spinal lamina were removed using Kerrison rongeurs. The exposed native dura was contiguous with the myelomeningocele sac [ Figure 3b and c ]. Intraoperative ultrasound was used to confirm adequate bony exposure and identify dorsal subarachnoid space for dural opening. Under microscopic magnification, the spinal cord dura was incised rostral to the myelomeningocele. Progressing caudally, the dorsal spinal cord was found to be tethered to the dura by thick arachnoid bands. These were divided as they were encountered. The dural opening eventually extended into the myelomeningoc ele sac. In the sac was a dorsal projection of the cervical spinal cord approximately the same size as the cervical spinal cord. It was freed circumferentially from its dural attachments. The dorsal projection terminated in dysplastic spinal cord that fused with the overlying dural sac [ Figure 3d ]. At the transition to dysplastic spinal cord, electrical stimulation did not result in a response in the neuromonitoring. The dorsal projection was sectioned at this location and the pial closed [ Figure 3e ]. The detethering was then continued inferiorly to the native spinal cord. Eventually the point of last attachment was sectioned, and the cord was free and lax. The remaining stump of dorsal projection still needed to be addressed. Sectioning the dorsal projection closer to the native spinal cord was avoided due to fear of transiting neural tracts within the projection. Left alone, the stalk came to a resting position along the dorsal surface of the rostral spinal cord [ Figure 3f ]. In this position, there was sufficient redundant dura to close without compressing the projection or the native spinal cord. This was verified with the ultrasound before and after the dura was closed; there was ample subarachnoid space surrounding the neural elements. The dura and overlying soft tissue were closed primarily in a watertight fashion. The neuromonitoring signals at the end of the operation were stable compared to the beginning. In fact, the left arm SSEP was mildly improved. There was no significant neuromonitoring signal change throughout the surgery. Pathological findings The dysplastic portion of the dorsal projection along with its fused overlying dura was examined [ Figure 4 ]. Hematoxylin and eosin stained sections showed band-like collections of neuroglial tissue and meninges within a background of fibrosis, collagen fiber bundles, and disorganized smooth muscle. Scattered dermal appendages were also identified. Figure 4:Hematoxylin and eosin staining of the myelomeningocele at the region of the neural-meningeal attachment. Left: low magnification study revealed fibrosis and collagen fiber bundles with prominent interfiber clefts (arrowhead), likely filled with cerebrospinal fluid. Dura is seen at left (asterisk), leptomeninges at center, and bands of neuroglial tissue (arrow) at right. Right: inspection at high magnification showed the clefts (arrowhead) between collagen fibers at left and bundles of neuroglial tissue (arrow) and meninges (asterisk) at right. Neuropil containing scattered oligodendrocytes with a dark nuclei and slight perinuclear halo is readily identified within the neuroglial tissue. Postoperative courseOn postoperative day 1, the patient reported improvement in his left upper extremity weakness and numbness. At 1 month follow-up, he reported continued improvement in his symptoms. He had some residual altered sensorium of the left hand, but improvement in his intrinsic hand muscle strength and no further pain, paresthesia, or clumsiness. He had returned to work without special accommodation. At 4 months follow-up, he had regained full strength in his left hand, and MRI showed a successful detethering without neural compression [ Figure 5 ]. The diastematomyelia remained asymptomatic and is being observed. Figure 5:Postoperative sagittal (left) and axial (right) T2 MRI of the cervical spine showing successful detethering of the cervical myelomeningocele without neural compression at 4 months follow-up. Cervical myelomeningoceles are a rare form of spinal dysraphism, accounting for 5 , 11 ] As opposed to the classic lumbar myelomeningocele, in which the neural placode is superficially exposed to the environment, the cervical myelomeningocele typically remains covered by full-thickness epithelium.[ 11 , 15 ] Rossi et al. cate gorized these dysraphisms into two types: an abortive nonterminal myelocystocele in which a meningocele is traversed by a fibrovascular stalk; and, a complete nonterminal myelocystocele, in which a hydromyelia expanded cord is dorsally displaced into the dural sac.[ 14 ] In a study of 18 pediatric patients with cervical dysraphisms undergoing operative repair, Salomao et al. identified three subtypes: a fibrovascular stalk projecting from the spinal cord to the dural sac, a myelocystocele, and a meningocele.[ 15 ] In the present case, the myelomeningocele was comprised of a dorsal exophytic extension of native spinal cord that was tethered to the dural sac. As opposed to lumbar myelomeningoceles, the nervous tissue found in cerv ical myelomeningoceles is more frequently nonfunctional.[ 8 ] Regardless, the use of intraoperative neurologic monitoring may decrease the risk of neurologic injury during detethering. Intraoperative ultrasound was also found to be useful. Tethered spinal cord in adults most often presents with pain.[ 9 , 10 ] The pathogenesis of delayed symptoms in adult cervical tethered cord is uncertain. It has been postulated that repeated movements in the setting of a fixed, immobile spinal cord results in ischemic insults and alterations in mitochondrial oxidative metabolism with resultant neuronal damage.[ 16 , 17 ] In a retrospective study of 85 adult patients with tethered cord syndrome, Klekamp et al. found that 61% of surgical patients demonstrated clinical improvement, while 33% reported no change in symptoms. A significant improvement in pain symptoms was not found.[ 10 ] Of 27 adult patients who underwent surgical intervention for tethered cord related to pain symptoms, Iskandar et al. found that at 4 years follow-up, 81% of patients reported an improvement.[ 9 ] Eller et al. observed an immediate increase in the amplitude of SSEP on sectioning the final band of a tethered cervical cord.[ 6 ] Smith et al. described a 33-year-old female with prior cervical myelomeningocele repair who developed neck pain, quadriparesis, and Lhermitte sign as a result of spinal cord tethering from scar tissue. Following detethering, she had significant improvement in her pain symptoms.[ 16 ] It appears that beyond arresting the progression of neurologic deficits, surgical detethering in the adult population often results in symptomatic improvement of pain symptoms. There have been few reports of cervical myelomeningocele in the adult patient. Presentation may include pain, weakness, paresthesia, upper motor neur on signs, muscle wasting, and bowel/bladder dysfunction.[ 1 - 3 , 5 , 12 , 13 ] Detethering of cervical myelomeningocele has been reported to reduce symptoms and, when present, result in decreased syrinx size.[ 3 , 5 , 12 , 13 ] The literature suggests that surgical intervention in the symptomatic adult with tethered cervical myelomeningocele yields beneficial outcomes. In the present case, the patient had significant improvement of his symptoms following surgical detethering. Interestingly, our adult patient also had a previously undiagnosed lumbar diastematomyelia. Other than a patch of lower back hair that was routinely shaved, the lumbar diastematomyelia was asymptomatic. When these lesions are discovered in childhood, surgery is typically recommended to lessen the risk of developing tethering symptoms, which may be irreversible, overtime.[ 7 ] However, when these lesions are discovered in adulthood, observation is typically recommended in the asymptomatic patient.[ 10 ] This raises the question of the true incidence of symptom development in lumbar diastematomyelia, however, natural history studies are lacking. Tethered cervical spinal cord is a rare cause for myelopathy in the adult patient. In the symptomatic patient, surgical repair with detethering is indicated to prevent disease progression and often results in clinical improvement. When asymptomatic, such as with this patient's concurrent lumbar diastematomyelia, observation is prudent. Patient's consent not obtained as patients identity is not disclosed or compromised. Nil. There are no conflicts of interest. 1. Abu-Bonsrah N, Purvis TE, Goodwin CR, Petteys RJ, de la Garza-Ramos R, Sciubba DM. Adult cervicothoracic lipomyelomeningocele. J Clin Neurosci. 2016. 32: 157-9 2. Balachandran G. Klippel-Feil syndrome and anterior cervical meningomyelocele: A rare case report. AJNR Am J Neuroradiol. 2009. 30: E130 3. Brokinkel B, Wiebe K, Hesselmann V, Filler TJ, Ewelt C, Muller-Hofstede C. Surgical treatment in a patient with Klippel-Feil syndrome and anterior cervical meningomyelocele: A case report and review of literature. Eur Spine J. 2013. 22: S517-20 4. Chen YC, Kuo CH, Cheng CM, Wu JC. Recent advances in the management of cervical spondylotic myelopathy: Bibliometric analysis and surgical perspectives. J Neurosurg Spine. 2019. 31: 299-309 5. Denaro L, Padoan A, Manara R, Gardiman M, Ciccarino P, d'Avella D. Cervical myelomeningocele in adulthood: Case report. Neurosurgery. 2008. 62: E1169-71 6. Eller TW, Bernstein LP, Rosenberg RS, McLone DG. Tethered cervical spinal cord. Case report. J Neurosurg. 1987. 67: 600-2 7. Gan YC, Sgouros S, Walsh AR, Hockley AD. Diastematomyelia in children: Treatment outcome and natural history of associated syringomyelia. Childs Nerv Syst. 2007. 23: 515-9 8. Habibi Z, Nejat F, Tajik P, Kazmi SS, Kajbafzadeh AM. Cervical myelomeningocele. Neurosurgery. 2006. 58: 1168-75 9. Iskandar BJ, Fulmer BB, Hadley MN, Oakes WJ. Congenital tethered spinal cord syndrome in adults. Neurosurg Focus. 2001. 10: e7 10. Klekamp J. Tethered cord syndrome in adults. J Neurosurg Spine. 2011. 15: 258-70 11. Meyer-Heim AD, Klein A, Boltshauser E. Cervical myelomeningocele-follow-up of five patients. Eur J paediatr Neurol. 2003. 7: 407-12 12. Perrini P, Scollato A, Guidi E, Benedetto N, Buccoliero AM, di Lorenzo N. Tethered cervical spinal cord due to a hamartomatous stalk in a young adult. Case report. J Neurosurg. 2005. 102: 244-7 13. Raheja A, Gupta DK, Nalwa A, Suri V, Sharma BS. Nonterminal cervical myelocystocele: Unusual cause of spastic quadriparesis in an adult. Neurol India. 2014. 62: 704-8 14. Rossi A, Piatelli G, Gandolfo C, Pavanello M, Hoffmann C, van Goethem JW. Spectrum of nonterminal myelocystoceles. Neurosurgery. 2006. 58: 509-15 15. Salomao JF, Cavalheiro S, Matushita H, Leibinger RD, Bellas AR, Vana zzi E. Cystic spinal dysraphism of the cervical and upper thoracic region. Childs Nerv Syst. 2006. 22: 234-42 16. Smith KA, Rekate HL. Delayed postoperative tethering of the cervical spinal cord. J Neurosurg. 1994. 81: 196-201 17. Yamada S, Zinke DE, Sanders D. Pathophysiology of tethered cord syndrome. J Neurosurg. 1981. 54: 494-503 |
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