J Neurosurg Pediatrics 13:355–361, 2014 ©AANS, 2014

Intraoperative neurophysiological monitoring in patients undergoing tethered cord surgery after fetal myelomeningocele repair Clinical article Eric M. Jackson, M.D.,1 Daniel M. Schwartz, Ph.D., 2,3 Anthony K. Sestokas, Ph.D., 2,3 Deborah M. Zarnow, M.D., 4 N. Scott Adzick, M.D., 5 Mark P. Johnson, M.D., 5 Gregory G. Heuer, M.D., Ph.D., 6,7 and Leslie N. Sutton, M.D.6,7 Department of Neurosurgery, Johns Hopkins University, Baltimore, Maryland; 2Department of Neurosurgery, Drexel University, Philadelphia; 4Department of Radiology, 7Division of Neurosurgery, and 5 The Center for Fetal Diagnosis and Treatment, The Children’s Hospital of Philadelphia; 6Department of Neu355rosurgery, University of Pennsylvania, Philadelphia; and 3Surgical Monitoring Associates, Bala Cynwyd, Pennsylvania 1

Object. Fetal myelomeningocele closure has been shown to be advantageous in a number of areas. In this study, the authors report on neural function in patients who had previously undergone fetal myelomeningocele repair and returned to the authors’ institution for further surgery that included intraoperative neurophysiological monitoring. Methods. The authors retrospectively reviewed data obtained in 6 cases involving patients who underwent fetal myelomeningocele repair and later returned to their institution for spinal cord untethering. (In 4 of the 6 cases, the patients also underwent removal of a dermoid cyst [3 cases] or removal of an epidermoid cyst [1 case] during the untethering procedure.) Records and imaging studies were reviewed to identify the anatomical level of the myelomeningocele as well as the functional status of each patient. Stimulated electromyography (EMG) and transcranial motor evoked potential (tcMEP) recordings obtained during surgery were reviewed to assess the functional integrity of the nerve roots and spinal cord. Results. During reexploration, all patients had reproducible signals at or below their anatomical level on stimulated EMG and tcMEP recordings. Corresponding to these findings, prior to tethering, all patients had antigravity muscle function below their anatomical level. Conclusions. All 6 patients had lower-extremity function and neurophysiological monitoring recording signals at or below their anatomical level. These cases provide direct evidence of spinal cord and nerve root conductivity and functionality below the anatomical level of the myelomeningocele, further supporting that neurological status improves with fetal repair. (http://thejns.org/doi/abs/10.3171/2014.1.PEDS11336)

Key Words      •      electromyography      •      fetal surgery      •      intraoperative monitoring      •    motor evoked potentials      •      myelomeningocele      •      craniofacial

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yelomeningocele is a severe form of spina bifida characterized by failure of closure of the neural tube.28 Patients with this condition have long-term disability associated with structural brain abnormalities, bowel and bladder dysfunction, and paralysis below the spinal cord level of the lesion. Serial imaging studies of patients with myelomeningocele have demon-

Abbreviations used in this paper: CMAP = compound muscle action potential; EMG = electromyography; IONM = intraoperative neurophysiological monitoring; MOMS = Management of Myelomeningocele Study; SSEP = somatosensory evoked potential; tcMEP = transcranial motor evoked potential.

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strated progression in a number of areas as these children develop in the womb.16,25 Early experimental studies on animal models and then in patients supported a “two-hit” hypothesis that the paralysis in patients with myelomeningocele results from the congenital myelodysplasia and from spinal cord injury from the intrauterine environment.7,8,10,11,18–20,26 Prenatal myelomeningocele closure was first successfully performed in patients in 1997.1,30 This procedure resulted in improvement in a number of clinical variables, including a decreased shunt requirement and a decreased incidence of hindbrain herniation.4,5,27,32–34 Some patients also had improved lower-extremity function.13 355

E. M. Jackson et al. In 2011 the results of the Management of Myelomeningocele Study (MOMS) were published.2 This study was a randomized trial comparing outcomes after prenatal versus postnatal myelomeningocele closure. Among other variables this study compared the need for a shunt, the rate of hindbrain herniation, and motor function in patients. The investigators found a reduced need for a shunt and a reduction in the rate of hindbrain herniation. Regarding motor function, children who had undergone prenatal myelomeningocele repair were more likely to have a level of function 2 or more levels better than expected and were more likely to be able to ambulate at 30 months of age. Spinal cord retethering has been well documented in patients with myelomeningocele with late progressive decline in function.3,12,22 Intraoperative neurophysiological monitoring (IONM) is used as an adjunct to prevent iatrogenic neurological injury across the entire spectrum of spinal surgeries. Particularly relevant here is the use of IONM during spinal cord untethering.17,21,23,28,35 Recording of compound muscle action potentials (CMAPs) elicited in response to direct bipolar stimulation of spinal nerve roots (stimulated electromyography [EMG]) has proven valuable for identifying nerve root location and verifying functional neural integrity. The more recent advent and use of transcranial motor evoked potential (tcMEP) monitoring has added further information about the integrity of the corticospinal tracts including alpha motor neurons and motor spinal nerve roots.9 Accordingly, these IONM modalities can provide objective evidence of the extent of neural function relative to the anatomical level of a myelomeningocele. For this study we analyzed a subset of cases involving patients who had undergone fetal myelomeningocele repair at our institution and returned for spinal cord untethering. Using the intraoperative neurophysiological monitoring data from the untethering surgery, we set out to investigate and document the neurophysiological conductivity and functionality of the spinal cord and nerve roots distal to the anatomical defect in these patients as a further means of investigating lower-extremity function.

Methods

A retrospective chart review was conducted for all patients who had fetal repair of a myelomeningocele performed at the Children’s Hospital of Philadelphia (prior to MOMS) and later returned for additional surgery for spinal cord untethering. At the time of repeat surgery for untethering, multimodality intraoperative neurophysiological monitoring consisting of spontaneous and stimulated EMG and tcMEP and posterior tibial nerve somatosensory evoked potential (SSEP) recordings was performed as per the standard of care for spinal cord untethering at the Children’s Hospital of Philadelphia. All neuromonitoring was accomplished with one of two 16-channel neurophysiology workstations (Axon Epoch XP, Axon Systems; Nicolet Endeavor, Viasys Healthcare). EMG and tcMEP monitoring was performed with a 10-channel recording from 5 bipolar subdermal needle electrode pairs inserted into the left and right adductor, 356

quadriceps, tibialis anterior, gastrocnemius, and external anal sphincter muscles. This electrode montage provided adequate nerve root coverage from the L2–S4 segments. At times, a sixth recording channel from rectus abdominis–iliopsoas muscle combinations was added when it was necessary to monitor T12–L1 nerve roots. For stimulated EMG monitoring, a sterile, hand-held concentric bipolar stimulator was used for neural depolarization. The stimulus was a 50- to 100-μsec squarewave electric pulse delivered at a rate of 3.1 pulses per second at progressively increasing intensity levels until either a CMAP was recorded from the respective myotome or the level reached or exceeded 10 mA, suggesting the absence of functional neural elements. Transcranial motor evoked potentials were recorded bilaterally from the same myotomes used to record EMG. These myogenic responses were elicited using a commercially available transcranial electrical stimulator (Digitimer D185, Digitimer Corp.), that delivered a brief (50 μsec), high voltage (250–500 V) anodal pulse train (number of pulses 2–5, interstimulus interval 1–3 msec) between 2 subdermal needle electrodes inserted subcutaneously over motor cortex regions C1 and C2 (International 10–20 system). Stimulation parameters of output voltage, number of pulses in the stimulus train, and interstimulus interval were all optimized to elicit maximal response amplitudes for each individual patient. Subcortical posterior tibial nerve SSEPs were elicited in response to a 300-μsec square-wave electrical pulse. Stimulation intensity levels ranged from 25 to 30 mA, with intensity selected to achieve response amplitude within the asymptotic portion of the SSEP intensity versus amplitude curve for each individual patient. Cortical potentials were recorded from subdermal needle electrodes (Rochester Electro-Medical, Inc.; Axon Systems, Inc.) placed over the surface of the second or third cervical vertebra and referenced to Fpz (forehead) (International 10–20 system). Both the initial fetal repair of the myelomeningocele and the surgical untethering were performed by a single senior surgeon (L.N.S.), while all of the IONM was carried out by a board-certified surgical neurophysiologist. The intraoperative neurophysiological records were reviewed to assess the lumbosacral nerve root signals. Hospital and office records as well as available radiographic images were analyzed to assess the anatomical level of the myelomeningocele and the functional status. Neuromotor functional level was determined by the best functional myotome as documented in the medical record by a specialist physical therapist. Muscle strength was graded on the Medical Research Council (MRC) scale. A muscle strength score of at least 3/5 in the lower extremity was required for a myotome level to be assigned.14 For patients with different neuromotor levels on the left and right, the higher (worse) level was assigned. Testing was performed on all children who could follow commands and actively participate in the testing process. For newborns, clinical observation was used to determine which muscle groups were functional. Anatomical level by ultrasound was defined as the first level with abnormal-appearing posterior elements. J Neurosurg: Pediatrics / Volume 13 / April 2014

IONM after fetal myelomeningocele repair The MRI defect was defined as the first level with loss of posterior elements. On radiographs, the anatomical level was considered to be the first level noted to have widening of the interpedicular space.

Results

Six patients were identified and reviewed for the study. These 6 patients represent all of the patients who underwent fetal repair and returned to the Children’s Hospital of Philadelphia for untethering. Fetal repair was performed in these patients at 21–25 weeks’ gestation (mean 23 weeks). At the time of tethered cord surgery, the patients were 6 months, 15 months, and 2, 3, 4, and 5 years of age. Indications for tethered cord surgery included: 1) worsening of gait/loss of foot function, 2) increasing back and leg pain, and 3) significant lesion progression (Fig. 1). Four of the 6 patients had an untethering with removal of a lesion—3 patients with dermoid cysts and 1 with an epidermoid cyst. The 2 remaining patients had untethering performed without a discrete lesion. At the time of surgery, the general impression of the senior surgeon was that the nerve roots appeared to have a more normal appearance than is often seen at or below the level of a myelomeningocele (Fig. 2). At the time of chart review, all patients were ambulatory with pre-tethering neuromotor functional levels of L-5 or S-1. Anatomical levels across all evaluated imaging modalities as well as pre-tethering neuromotor functional levels are presented in Table 1. As far as imaging

Fig. 1. Sagittal T2-weighted MR image demonstrating the presence of a dermoid cyst causing spinal cord tethering. The lesion had increased in size from the previous scan.

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Fig. 2.  Intraoperative photograph obtained at the time of spinal cord untethering. The arrow points to the epidermoid, which is at the rostral aspect of the opening. The nerve roots were felt to be more normal appearing as they exited toward the foramen than may be expected in patients with myelomeningocele.

modalities are concerned, there were some differences noted across modalities, most notably in Case 3. Of note, with one exception the neuromotor functional level was consistently below the anatomical level for all patients across all imaging modalities. The exception was Case 6; in this patient, the MRI defect level was the same as the functional level. As of this writing, the modality most predictive of the functional level is currently under investigation, and there is no standard in the literature. For consistency in this study, we chose to use prenatal ultrasound as our modality for assessing anatomical level, as it is commonly cited and was the most uniformly obtained. At the time of surgery, stimulated EMG and tcMEP recordings were suggestive of robust lumbosacral spinal nerve root function at or below the level of the myelomeningocele (Figs. 3 and 4). Although they were recorded at the time of surgery, SSEP data did not yield any additional information in this patient population. A summary of the neurophysiological data comparing the presence of signals for both stimulated EMG and tcMEP with the anatomical level is depicted in Fig. 5. All patients who underwent fetal repair had signals below their anatomical level. As some patients had weak, inconsistent signals that may not be consistent with normal function at some levels, the lowest level with consistent, reproducible neurophysiological responses across both modalities was noted as well (Fig. 6). Five of the patients had functional signals definitively below the anatomical level. One patient had functional signals at or slightly below the anatomical level (L-3 in a patient with an L2–3 anatomical level). No patient demonstrated loss of signals above the anatomical level. Our patients who undergo postnatal myelomeningocele repair typically do not have significant function below the level of the lesion and uncommonly undergo untethering procedures related to progressive decline or pain. During this study period, one patient who had undergone postnatal myelomeningocele repair presented with a symptomatic tethered cord. This patient had a repair of a low lumbosacral myelomeningocele 2 days after birth with an 357

E. M. Jackson et al. TABLE 1: Anatomic myelomeningocele level in prenatal closed patients according to different imaging modalities and pre-tethering neuromotor functional level Case No.

Prenatal Ultrasound

Postnatal MRI Defect

Postnatal MRI Bony Dysplasia

Postnatal Radiograph

Pre-Tethering Motor Functional Level

1 2 3 4 5 6

L-4 L2–3 L-2 L4–5 L4–5 L-4

L-4 L-4 T-12 L-5 L-4 L-5

L2–3 L2–3 T-11 L-4 L-3 L3–4

L-4 NA* L-4 L-4 L-3 L-3

L-5 S-1 L-5 S-1 S-1 L-5

*  Radiograph was not available (NA); level was L2–3 based on note.

MRI level of L-5. At 15 years of age, the patient presented with decreased sensation in his feet and legs and deterioration of his foot and leg function. An untethering procedure was performed. Transcranial MEPs were recorded over the course of surgery from myotomes innervated by the L2–S4 nerve roots (Fig. 7). The tcMEPs demonstrated left versus right amplitude asymmetry at baseline. The responses from the tibialis anterior muscle on the left side were attenuated compared with those on the right, and there were only trace responses from the left gastrocnemius, left abductor hallucis, and bilateral external anal sphincter muscles. Overall, these data are consistent with preexisting left lower-extremity weakness. The data also are suggestive of weakness in muscles innervated by the lower sacral nerve roots.

Discussion

We document here the use of intraoperative moni-

toring in patients undergoing tethered cord release after fetal myelomeningocele repair. This study provides direct evidence of intact neural pathways below the anatomical level of the myelomeningocele in patients who have undergone fetal repair. All 6 patients in this retrospective study showed both neurophysiological and physical evidence of neural function at and below (1 patient) or below (5 patients) the anatomical level of the myelomeningocele defect as defined by prenatal ultrasound. In 3 cases (Cases 3, 4, and 5), the level of lowest consistent signals mirrored the pre-tethering neuromotor functional level. In 2 cases (Cases 1 and 6), the consistent monitoring signals were below the pre-tethering neuromotor level. As was noted in Figs. 3 and 4, this finding can be explained by the fact that patients may have some demonstrable function but if the strength is not antigravity, that myotome is not included in their functional level. (For example, the patient in Case 6 had good signals at S-1 but was given

Fig. 3.  A stack display of tcMEPs recorded over the course of surgery in Case 6 (L-4 level) from myotomes innervated by the L-2 through S-4 nerve roots. The first MEP column in each panel represents controls recorded from the intrinsic hand muscles. The following columns represent recordings from the hip adductors, quadriceps, tibialis anterior, gastrocnemius, and anal sphincter, in that order. Note the clear presence of repeatable tcMEPs from external anal sphincter muscles bilaterally (arrows). While responses from the low sacral nerve roots on the right are smaller in amplitude than those on the left, they are clearly present and reproducible nonetheless.

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IONM after fetal myelomeningocele repair

Fig. 6.  Chart demonstrating the level of consistent, reproducible signals across both modalities in comparison with the anatomical level for each case. Fig. 4.  Stimulated electromyogram obtained in Case 6 (L-4) showing evidence of a functional S-1 nerve root. Robust CMAPs in response to direct bipolar stimulation of the nerve root can be seen from the right gastrocnemius (arrow) with no contaminating crossover on the left side. Here again, the neurophysiological finding of functional neural elements is below the anatomical level. Of note, although the patient had a reported functional level of L-5 (lowest antigravity level), she did have 2/5 gastrocnemius function, consistent with finding a CMAP with stimulation.

an L-5 neuromotor function level due to a gastrocnemius strength of 2/5 rather than 3 or greater.) In only 1 case (Case 2) was the pre-tethering functional level below the level of consistent signals. In this case, signals were present throughout, but reproducible signals were only found at or slightly below the anatomical level (L-3 in L2–3 level); the pre-tethering neuromotor function level had been approximately 2 levels lower (L-5). As this patient presented for untethering with a worsening gait, a possible explanation for this discrepancy includes decreased signals at the time of surgery due to the functional loss from spinal cord tethering (her function was worse than at the time of physical therapy examination to determine the functional level). Although not perfectly predictive in all cases, these data suggest that the EMG and tcMEP data can provide an objective measure of function for comparison across patients. The SSEP data, on the other hand, are not felt to be useful for comparison in studies like this one, as

Fig. 5.  Chart demonstrating the presence of signals for each patient on both tcMEP and stimulated EMG by level in comparison with the anatomical level. Note: Transcranial MEP recording was not performed in Case 1.

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SSEPs are based on mixed-nerve conduction rather than specific nerves and tracts like EMG and tcMEPs. Therefore they are less sensitive to focal injury and less able to provide specific localization for comparison. The presence of function below the anatomical level differs from previous data obtained in patients with postnatally treated myelomeningocele, which suggests that most patients with myelomeningocele function at levels at or above their anatomical level.6,15,24 Previous reports on lower-extremity function in patients who underwent prenatal myelomeningocele repair were inconsistent, some showing improved function and others showing no difference.13,29,31 However, the MOMS trial provided evidence in the form of a randomized trial indicating that fetal surgery does improve motor function.2 We believe this study provides the electrophysiological evidence of neural function below the anatomical level of the myelomeningocele in patients who have undergone fetal repair. This report, along with the MOMS trial, provides further support that fetal surgery provides some protection of the neural elements from exposure to the neurotoxic intrauterine environment. There are a number of limitations in this study. The conclusions are drawn from a limited and restricted patient sample from before the MOMS trial. Therefore, there may be some element of selection bias to this population that skews the results. It will be important to determine if similar findings with regard to direct multimodality neurophysiological monitoring data are observed in the patients within the MOMS trial, as these patients are being followed in a more controlled and screened environment. Secondly, only 1 patient with postnatal myelomeningocele repair underwent a similar operation at our institution during the same time period for comparison, and we did not have a large sample of age-matched controls for this study. Our patients who have undergone postnatal myelomeningocele repair do not have function below the level of the lesion, and thus we are not able to make direct comparison between prenatal and postnatal closure with respect to neurophysiological testing.

Conclusions

We feel that the results of this study and the larger 359

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Fig. 7.  A stack display of tcMEPs recorded over the course of surgery from myotomes innervated by the L2–S4 nerve roots in a patient who had undergone postnatal myelomeningocele repair. (See Fig. 3 for recording sites.) The tcMEPs demonstrated left versus right amplitude asymmetry at baseline. The responses from the tibialis anterior muscle on the left side are attenuated compared with those on the right. Note the lack of responses from the left gastrocnemius, left abductor hallucis, and bilateral external anal sphincter muscles (arrows).

MOMS trial provide strong evidence that prenatal closure protects the spinal cord from continued injury in the uterine environment. This study also provides an interesting area of investigation in the MOMS patients as they get older. Acknowledgments We thank the staff of The Center for Fetal Diagnosis and Treatment at the Children’s Hospital of Philadelphia for their care of the patients in this study, with special thanks to Enrico Danzer, Jamie Koh, and Jeanne Melchionni for assistance with obtaining data. Disclosure Dr. Jackson received salary support from the Neurosurgery Research and Education Foundation. Author contributions to the study and manuscript preparation include the following. Conception and design: Jackson, Adzick, Sutton. Acquisition of data: all authors. Analysis and interpretation of data: all authors. Drafting the article: all authors. Critically revising the article: all authors. Reviewed submitted version of manuscript: all authors. Approved the final version of the manuscript on behalf of all authors: Heuer. References   1.  Adzick NS, Sutton LN, Crombleholme TM, Flake AW: Successful fetal surgery for spina bifida. Lancet 352:1675–1676, 1998   2.  Adzick NS, Thom EA, Spong CY, Brock JW III, Burrows PK, Johnson MP, et al: A randomized trial of prenatal versus postnatal repair of myelomeningocele. N Engl J Med 364:993– 1004, 2011   3.  Bowman RM, McLone DG, Grant JA, Tomita T, Ito JA: Spina bifida outcome: a 25-year prospective. Pediatr Neurosurg 34: 114–120, 2001   4.  Bruner JP, Tulipan N, Paschall RL, Boehm FH, Walsh WF, Silva SR, et al: Fetal surgery for myelomeningocele and the incidence of shunt-dependent hydrocephalus. JAMA 282: 1819–1825, 1999   5.  Bruner JP, Tulipan N, Reed G, Davis GH, Bennett K, Luker KS, et al: Intrauterine repair of spina bifida: preoperative predictors of shunt-dependent hydrocephalus. Am J Obstet Gynecol 190:1305–1312, 2004   6.  Coniglio SJ, Anderson SM, Ferguson JE II: Functional motor outcome in children with myelomeningocele: correlation

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with anatomic level on prenatal ultrasound. Dev Med Child Neurol 38:675–680, 1996   7.  Correia-Pinto J, Reis JL, Hutchins GM, Baptista MJ, EstevãoCosta J, Flake AW, et al: In utero meconium exposure increases spinal cord necrosis in a rat model of myelomeningocele. J Pediatr Surg 37:488–492, 2002   8.  Drewek MJ, Bruner JP, Whetsell WO, Tulipan N: Quantitative analysis of the toxicity of human amniotic fluid to cultured rat spinal cord. Pediatr Neurosurg 27:190–193, 1997   9.  Fan D, Schwartz DM, Vaccaro AR, Hilibrand AS, Albert TJ: Intraoperative neurophysiologic detection of iatrogenic C5 nerve root injury during laminectomy for cervical compression myelopathy. Spine (Phila Pa 1976) 27:2499–2502, 2002 10.  Heffez DS, Aryanpur J, Hutchins GM, Freeman JM: The paralysis associated with myelomeningocele: clinical and experimental data implicating a preventable spinal cord injury. Neurosurgery 26:987–992, 1990 11.  Heffez DS, Aryanpur J, Rotellini NA, Hutchins GM, Freeman JM: Intrauterine repair of experimental surgically created dys­­raphism. Neurosurgery 32:1005–1010, 1993 12.  Hudgins RJ, Gilreath CL: Tethered spinal cord following repair of myelomeningocele. Neurosurg Focus 16(2):E7, 2004 13.  Johnson MP, Sutton LN, Rintoul N, Crombleholme TM, Flake AW, Howell LJ, et al: Fetal myelomeningocele repair: shortterm clinical outcomes. Am J Obstet Gynecol 189:482–487, 2003 14.  Kendall FP, Provance P, McCreary EK: Muscles, Testing and Function: With Posture and Pain, ed 4. Baltimore: Lippincott Williams & Wilkins, 1993 15.  Kollias SS, Goldstein RB, Cogen PH, Filly RA: Prenatally detected myelomeningoceles: sonographic accuracy in estimation of the spinal level. Radiology 185:109–112, 1992 16.  Korenromp MJ, van Gool JD, Bruinese HW, Kriek R: Early fetal leg movements in myelomeningocele. Lancet 1:917–918, 1986 17.  Kothbauer KF, Novak K: Intraoperative monitoring for tethered cord surgery: an update. Neurosurg Focus 16(2):E8, 2004 18.  Meuli M, Meuli-Simmen C, Hutchins GM, Yingling CD, Hoffman KM, Harrison MR, et al: In utero surgery rescues neurological function at birth in sheep with spina bifida. Nat Med 1:342–347, 1995 19.  Meuli M, Meuli-Simmen C, Yingling CD, Hutchins GM, Timmel GB, Harrison MR, et al: In utero repair of experimental myelomeningocele saves neurological function at birth. J Pediatr Surg 31:397–402, 1996 20.  Michejda M: Intrauterine treatment of spina bifida: primate model. Z Kinderchir 39:259–261, 1984 21.  Paradiso G, Lee GY, Sarjeant R, Hoang L, Massicotte EM,

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IONM after fetal myelomeningocele repair Fehlings MG: Multimodality intraoperative neurophysiologic monitoring findings during surgery for adult tethered cord syndrome: analysis of a series of 44 patients with long-term follow-up. Spine (Phila Pa 1976) 31:2095–2102, 2006 22.  Phuong LK, Schoeberl KA, Raffel C: Natural history of tethered cord in patients with meningomyelocele. Neurosurgery 50:989–995, 2002 23.  Quiñones-Hinojosa A, Gadkary CA, Gulati M, von Koch CS, Lyon R, Weinstein PR, et al: Neurophysiological monitoring for safe surgical tethered cord syndrome release in adults. Surg Neurol 62:127–135, 2004 24.  Rintoul NE, Sutton LN, Hubbard AM, Cohen B, Melchionni J, Pasquariello PS, et al: A new look at myelomeningoceles: functional level, vertebral level, shunting, and the implications for fetal intervention. Pediatrics 109:409–413, 2002 25.  Sival DA, Begeer JH, Staal-Schreinemachers AL, Vos-Niël JM, Beekhuis JR, Prechtl HF: Perinatal motor behaviour and neurological outcome in spina bifida aperta. Early Hum Dev 50:27–37, 1997 26.  Stiefel D, Copp AJ, Meuli M: Fetal spina bifida in a mouse model: loss of neural function in utero. J Neurosurg 106 (3 Suppl):213–221, 2007 27.  Sutton LN, Adzick NS, Bilaniuk LT, Johnson MP, Crombleholme TM, Flake AW: Improvement in hindbrain herniation demonstrated by serial fetal magnetic resonance imaging following fetal surgery for myelomeningocele. JAMA 282:1826– 1831, 1999 28.  Sutton LN, Schwartz DM: Congenital anomalies of the spinal cord, in Herkowitz HN, Garfin SR, Balderston RA, et al (eds): Rothman-Simeone, The Spine, ed 4. Philadelphia: WB Saunders, 1999, Vol 1, pp 267–302 29.  Tubbs RS, Chambers MR, Smyth MD, Bartolucci AA, Bruner JP, Tulipan N, et al: Late gestational intrauterine myelome-

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ningocele repair does not improve lower extremity function. Pediatr Neurosurg 38:128–132, 2003 30.  Tulipan N, Bruner JP: Myelomeningocele repair in utero: a report of three cases. Pediatr Neurosurg 28:177–180, 1998 31.  Tulipan N, Bruner JP, Hernanz-Schulman M, Lowe LH, Walsh WF, Nickolaus D, et al: Effect of intrauterine myelomeningocele repair on central nervous system structure and function. Pediatr Neurosurg 31:183–188, 1999 32.  Tulipan N, Hernanz-Schulman M, Bruner JP: Reduced hindbrain herniation after intrauterine myelomeningocele repair: a report of four cases. Pediatr Neurosurg 29:274–278, 1998 33.  Tulipan N, Hernanz-Schulman M, Lowe LH, Bruner JP: Intrauterine myelomeningocele repair reverses preexisting hindbrain herniation. Pediatr Neurosurg 31:137–142, 1999 34.  Tulipan N, Sutton LN, Bruner JP, Cohen BM, Johnson M, Adzick NS: The effect of intrauterine myelomeningocele repair on the incidence of shunt-dependent hydrocephalus. Pediatr Neurosurg 38:27–33, 2003 35.  von Koch CS, Quinones-Hinojosa A, Gulati M, Lyon R, Peacock WJ, Yingling CD: Clinical outcome in children undergoing tethered cord release utilizing intraoperative neurophysiological monitoring. Pediatr Neurosurg 37:81–86, 2002

Manuscript submitted September 26, 2013. Accepted January 6, 2014. Please include this information when citing this paper: published online February 7, 2014; DOI: 10.3171/2014.1.PEDS11336. Address correspondence to: Gregory Heuer, M.D., Ph.D., Division of Neurosurgery, Children’s Hospital of Philadelphia, Wood Center, 6th Floor, 34th and Civic Center Blvd., Philadelphia, PA 19104. email: [email protected].

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Intraoperative neurophysiological monitoring in patients undergoing tethered cord surgery after fetal myelomeningocele repair.

Fetal myelomeningocele closure has been shown to be advantageous in a number of areas. In this study, the authors report on neural function in patient...
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