|Year : 2021 | Volume
| Issue : 1 | Page : 26-32
Predictive value of intraoperative D-wave and m-MEP neurophysiological monitoring in patients with preoperative motor deficits in immediate and late postoperative period
Megha Bir1, Uditi Gupta1, Ashok Kumar Jaryal1, Akanksha Singh1, Ritesh Netam1, Shashank Sharad Kale2, Sarat P Chandra2, Manmohan Singh2, Girija Prasad Rath3
1 Department of Physiology, All India Institute of Medical Sciences, New Delhi, India
2 Department of Neurosurgery, All India Institute of Medical Sciences, New Delhi, India
3 Department of Neuroanaesthesia and Critical Care, All India Institute of Medical Sciences, New Delhi, India
|Date of Submission||30-May-2020|
|Date of Acceptance||26-Dec-2020|
|Date of Web Publication||4-Mar-2021|
Ashok Kumar Jaryal
Department of Physiology, All India Institute of Medical Sciences, Room No. 6015, Convergence Block, Ansari Nagar, New Delhi - 110 029
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Background: Presence of preoperative motor deficits in patients poses a distinct challenge in monitoring the integrity of corticospinal tracts during spinal surgeries. The inconsistency of the motor-evoked potentials is such patients, limits its clinical utility. D-wave is a robust but less utilized technique for corticospinal tract monitoring. The comparative clinical value of these two techniques has not been evaluated in the patients with preoperative deficits.
Objectives: The objective of the study was to compare the predictive utility of myogenic Motor Evoked Potentials (m-MEP) and D-wave in terms of recordability and their sensitivity and specificity in predicting transient and permanent new motor deficits.
Materials and Methods: Thirty-one patients with preoperative motor deficit scheduled to undergo spinal surgery were included in the study. Intraoperative m-MEP and D-wave changes were identified and correlated with postoperative neurology in the immediate postoperative period and at the time of discharge.
Results: The mean preoperative motor power of the patient pool in left and right lower limb was 2.97 ± 1.56 and 3.32 ± 1.49, respectively. The recordability of m-MEPs and D-wave was observed to be 79.4% and 100%, respectively. The m-MEP predicted the motor deterioration in immediate postoperative period with 100% sensitivity and 80% specificity, while D-wave had 14% sensitivity and 100% specificity. At the time of discharge, m-MEPs' specificity reduced to 61%, while D-wave demonstrated 100% specificity.
Conclusions: D-wave has a better recordability than m-MEPs in neurologically compromised patients. D-wave predicts development of long-term deficits with 100% specificity, while m-MEPs have a high sensitivity for transient neurological deficit. A combination of D-wave and m-MEP is recommended for monitoring the integrity of the corticospinal tract in patients with preoperative motor deficits.
Keywords: Corticospinal tract monitoring, D-wave, epidural potentials, intraoperative neurophysiological monitoring, motor evoked potentials
|How to cite this article:|
Bir M, Gupta U, Jaryal AK, Singh A, Netam R, Kale SS, Chandra SP, Singh M, Rath GP. Predictive value of intraoperative D-wave and m-MEP neurophysiological monitoring in patients with preoperative motor deficits in immediate and late postoperative period. J Craniovert Jun Spine 2021;12:26-32
|How to cite this URL:|
Bir M, Gupta U, Jaryal AK, Singh A, Netam R, Kale SS, Chandra SP, Singh M, Rath GP. Predictive value of intraoperative D-wave and m-MEP neurophysiological monitoring in patients with preoperative motor deficits in immediate and late postoperative period. J Craniovert Jun Spine [serial online] 2021 [cited 2023 Feb 9];12:26-32. Available from: https://www.jcvjs.com/text.asp?2021/12/1/26/310746
| Introduction|| |
Intraoperative neuromonitoring techniques are utilized to prevent/limit the risk of development of new neurological deficits during neurosurgical procedures. Monitoring of the motor tract is an important component of the multimodal intraoperative neuromonitoring technique in the context of spinal surgeries.
Physiological differentiation of a transient loss of motor function due to inadvertent handing of the spinal cord from the potentially permanent loss of motor function due to injury to the cord is extremely critical to determine the course of the action during ongoing surgery.
Intraoperatively, the functional integrity of the motor pathways can be assessed by transcranial stimulation of the motor cortex, and recording the evoked potentials at the level of spinal cord (D-wave), or at the level of the muscles (m-MEP). There are only a handful of reports comparing the utility of recording and monitoring D-wave and m-MEP simultaneously.,,,, The presence of preoperative motor deficits has been a limiting factor in the recording and hence monitoring of integrity of motor tracts. The recordability of m-MEP is poor in such patients,,,, while D-wave recordability has been shown to unaffected or poor.,,,
Decrease in the amplitude of m-MEP during the surgery correlates well with the immediate postoperative neurological deficit, but poorly with long-term postoperative neurological status.,, Intact D-wave in the face of decreased m-MEP amplitudes accurately predicts the recoverability of the transient deficits and therefore predicts the long-term neurological status.,, However, most of this information is based on data from patients without any preoperative motor deficits. Most of these studies have included only a small number of patients with preoperative motor deficits while others none at all.,,
Thus, the present study was designed to prospectively study the comparative monitorability of D-wave and m-MEP in patients with preoperative motor deficits undergoing spinal neurosurgical procedures and their relative clinical utility in predicting postoperative new motor deficits in terms of sensitivity and specificity.
| Materials and Methods|| |
After approval by the institute ethics committee, patients scheduled for spinal surgeries requiring intraoperative monitoring of corticospinal tracts were screened. Thirty-one patients (19 males [26.89 ± 14.18 years] and 12 females [35.5 ± 17.95 years]; mean age: 32.2 ± 16.03 years) with preoperative motor deficits were included in the study after exclusion of patients younger than 5 years of age, patients with a history of irradiation, previous spinal surgery, or lesions extending caudal to T9 thoracic spinal segment. Written informed consent was obtained from all the patients or from their legal guardians in case of minors. Etiologic distribution of the patients is presented in [Table 1]. In all patients, the preoperative assessment of the motor power was done, and the m-MEP and D-wave recordings were attempted during the course of the neurosurgery with NIM-ECLIPSE® NS System (Medtronics, USA).
Assessment of motor power
All patients underwent neurological evaluation by attending neurosurgery resident doctor of motor power the day before the surgery, the day after the surgery, and at the time of discharge. The motor power of the patients was graded according to the MRC scale [Medical Research Council, UK, [Table 2]]. Thereafter, each limb was given a separate motor score ranging from 0 to 5 by averaging the power of each joint of the same limb. The average preoperative motor score of the patients is presented in [Table 3].
All the patients were maintained with total intravenous anesthesia using propofol (100–150 μg/kg/min) and fentanyl (1 μg/kg/h) infusions. Short-acting muscle relaxant was used only at the time of induction.
Transcranial muscle motor-evoked potentials (m-MEP)
Transcranial electrical stimulus was delivered through corkscrew electrodes placed at C3' and C4' position (1 cm anterior to C3 and C4 electrode position, respectively) according to the international 10–20 system of electrode placement. Motor cortex was stimulated with a train of 8, 75 μs long biphasic pulses with a frequency of 250–400 Hz. To determine threshold stimulation, voltage was gradually increased from 50 V till m-MEP responses were consistently obtained. This was considered as threshold stimulation, and the same strength was used for subsequent monitoring.
m-MEPs were recorded using dual-twisted needle electrodes placed bilaterally in at least four muscles supplied by motor nerves arising at or caudal to the spinal lesion. The muscles chosen were among brachioradialis, abductor pollicis brevis, abductor digiti minimi, rectus abdominis, vastus lateralis, tibialis anterior, extensor hallucis longus, and abductor hallucis. The m-MEPs were recorded in a 100 ms window with a band pass filter of 30–3000 Hz.
The D-wave was elicited using the same electrode montage that was used for m-MEP. A single pulse of 75 μs was used. The stimulation threshold was determined in the same manner as described for m-MEP. Thereafter, supramaximal stimulation voltage was determined by step-wise increment in the stimulation voltage till no further increase in the amplitude of the D-wave occurred. The D-wave monitoring was done at supramaximal voltage.
The D-wave was recorded using a 2-point semi-rigid catheter type recording electrode with recording points 1.5 cm from each other at the tip (Inomed, Germany). The catheter electrode was inserted in epidural space (25 patients) or in subdural space (six patients) caudal to the lesion after laminectomy and was secured with sutures. The recording window of D-wave was of 20 ms duration and band pass filter of 30–1500 Hz was used. 5–10 sweeps were averaged to improve the signal-to-noise ratio whenever necessary.
The alarm criteria were set at 50% decrease in the peak-to-peak amplitude of the m-MEP record and D-wave record. In cases where the decrease in amplitude showed consistent trend of recovery, such cases were considered as partially recovered.
The distribution of data of each parameter was tested by Shapiro–Wilk test. Parametric data are presented as mean ± standard deviation and nonparametric data are presented as median with interquartile range. The comparison of thresholds of m-MEP and D-wave was done using Mann–Whitney U-test. The association of m-MEP or D-wave alarm with immediate deficit or deficit at the time of patient discharge was evaluated using Fisher' exact test. The level of statistical significance was set at P < 0.05. All statistical analyses were performed using SPSS(Statistical Package for the Social Sciences, version 25, IBM SPSS Statistics).
| Results|| |
Intraoperative neurophysiological monitoring was attempted in 31 patients. m-MEPs could be recorded at the beginning of the surgery in 24 out of 31 patients (79.4%). In one of these 24 patients, monitoring had to be aborted mid-surgery because of occurrence of seizures and was excluded from analysis. In one patient, the m-MEP was recordable only after decompression, and in another patient, m-MEP was recordable only from abductor halluces on the right side. These two patients were also excluded from the analysis for assessing clinical utility.
D-wave baseline could be recorded in all 31 patients (100%). In 17 of these cases, D-wave was monitored throughout the surgery. In the remaining cases, D-wave was not monitored till the end of surgery because the catheter electrode was removed for surgical reasons (10 cases) or was accidentally pulled out mid-surgery (4 cases).
Thresholds for D-wave and m-MEP
The mean threshold stimulation strength required for obtaining D-wave in the patients was 400 ± 137.5 V, which was significantly lower as compared to the mean threshold stimulation strength (700 ± 200 V) required for obtaining m-MEP (P < 0.0001 by Mann–Whitney U-test).
Analyses for clinical utility
The sensitivity, specificity, positive predictive value, and negative predictive value of m-MEP and D-wave alarms were calculated in immediate and late postoperative periods (at the time of discharge). The terminologies used in this section have been described in [Table 4].
Clinical utility of m-MEP and D-wave in predicting new motor deficit in the immediate postoperative period
m-MEPs were monitored till the end of surgery in 23 patients. The alarm was raised in 16 patients. Intraoperative recovery of m-MEP amplitude was observed in five patients (three complete and two partial) and none of them developed any new deficit in the immediate postoperative period. In 11 patients, m-MEP alarm was persistent through the surgery, and of these, eight developed new motor deficit in the immediate postoperative period. The m-MEP monitoring was uneventful in 12 patients and none of them developed any new deficits in the immediate postoperative period. One of these patients died in the postoperative period and was excluded from analysis of long-term postoperative motor status.
D-wave was monitored throughout the surgery in 17 patients. The D-wave alarm was raised only in one patient who had new motor deficit in the immediate postoperative period. In one patient, there was a surgical complication because, of which he underwent a revision surgery which was not supported with neuromonitoring and his data were thus not included in the analysis. Even though D-wave monitoring was uneventful in 15 patients and new motor deficits in immediate postoperative period were noted in six patients. Overall results of clinical utility analysis in the immediate postoperative period are presented in [Table 5].
|Table 5: Clinical utility (sensitivity, specificity, positive, and negative predictive value) of myogenic motor-evoked potential and D-wave for predicting new motor deficits in the immediate postoperative period|
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Clinical utility of m-MEP and D-wave in predicting new motor deficit in the long-term postoperative period
Of 11 patients who had persistent m-MEP alarm, eight had developed new motor deficit in the immediate postoperative motor deficit. Two of these 11 patients who died in the postoperative period were excluded from this analysis. Of the remaining nine patients, two had persistent decrease in motor power as compared to preoperative motor status at the time of discharge.
D-wave amplitude alarm was raised one patient. The patient had persistent motor deficit at the time of discharge. Among the other 15 patients with uneventful D-wave monitoring throughout, two died and were excluded from the analysis at discharge. Of the remaining 13 patients with uneventful D-wave monitoring, one patient had not completely recovered motor from motor deficit time of discharge. Rest 13 recovered to preoperative status while in hospital. Overall results of clinical utility analysis at the time of discharge are presented in [Table 6].
|Table 6: Clinical utility (sensitivity, specificity, positive, and negative predictive value) of amplitude changes in myogenic motor-evoked potential and D-wave for predicting new motor deficits in the long-term postoperative period|
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There were two cases of special interest in whom the amplitude of neurophysiological parameters increased during the course of surgery. Case 1 operated for Pott's spine at D4–D6. Initially, only D-wave was recordable in this case, m-MEPs were not. As the surgery ensued, first, the amplitude of D-wave increased, and after some time, the m-MEPs also appeared in the lower limbs. Case 2 operated for extramedullary tumor at C4–C5. Both D-wave and m-MEPs showed increased amplitudes after resection of tumor. The intraoperative findings in both these patients corroborated with postoperative neurology with both patients showing improvement in motor power.
| Discussion|| |
m-MEP and D-wave are the primary neurophysiological modalities employed for monitoring of corticospinal tracts during spinal surgeries. Patients with preoperative deficits present challenges in recording and interpretation of intraoperative changes in m-MEP and D-wave waveforms. The present study was designed to compare the utility of m-MEPs and D-wave monitoring in predicting immediate and long-term postoperative motor deficit in neurologically compromised patients.
In our study, a reliable m-MEP baseline could be recorded in 79.4% of the patients with preoperative deficits. In previous reports, recordability of m-MEP in patients has shown to range from 82.5% to 97% in group of patients with or without preoperative deficits.,,,,,, All the patients in the present study had preoperative motor deficits, and hence the recordability is lower than previously reported where the patients were included irrespective of preoperative motor deficit.
There is limited literature available on D-wave and most of them have reported a wide range of recordability. In their 1997 study, Morota et al. could record D-wave in 59.3% of their patients undergoing surgery for intramedullary spinal cord tumor at cervical/thoracic levels. Similar results were reported by Kothbauer et al. (68.6%), Sala et al. (70%), and Korn et al., (73%).,,, Costa et al. have reported relatively better recordability of D-wave (94.1%). Ghadirpour et al. have recently reported a recordability of 92.2%. All of them documented significant difficulty in eliciting the D-wave in neurologically compromised patients. Having excluded patients with a history of irradiation, previous spinal surgery, or patients with lesion extending beyond T9 thoracic spinal segment as part of the study protocol we were able to record D-wave successfully in all study participants.
The D-wave is the direct wave elicited by a single stimulation of the motor cortex and is recorded from the spinal cord. The elicitation of the m-MEP, however, requires polysynaptic transmission followed by temporal summation of a volley of 4–8 action potentials (D-wave) at the alpha motor neurons and is recorded from the muscle. For efficient temporal summation at the alpha motor neuron, the D-waves should be temporally coherent and reach the alpha motor neuron at an optimal frequency to generate an action potential. We speculate that, in patients with preoperative motor deficits, the associated spinal pathology alters the conduction velocity of the corticospinal tract fibers affecting the temporal summation, leading to absent/inconsistent m-MEPs. The spinal pathologies, adhesions due to prior surgery/radiotherapy, may cause wide dispersion even of the D-waves such that it may be difficult to record it consistently in such patients.
The clinical utility of an intraoperative neurophysiological monitoring modality is characterized by its ability to predict and prevent new motor deficits. High sensitivity is important for timely identification of an insult/injury to neural tissue, to limit it and early institution of corrective measures. High specificity on the other hand helps discern alarms related to reversible “surgically induced transient paraplegia” from the “real” injury to the motor tract which may lead to persistent deficits. A combination of high sensitivity with high specificity is ideal for maximum safe resection with minimal risk of new neurological deficit.
In the immediate postoperative period, the m-MEP showed 100% sensitivity and a negative predictive value of 1. The specificity of this technique was 80%. The D-wave on the other hand showed high specificity (100%) and positive predictive value but low sensitivity (14.2%) in immediate postoperative period. Thus, intraoperative m-MEP alarms correlated well with the immediate postoperative outcome in terms of sensitivity, but the specificity of D-wave was better.
In the immediate postoperative period, it is not possible to differentiate transient physiological deficit from permanent motor deficit. The distinction between the two manifests later during the follow-up. At the time of discharge in the present study, the m-MEP sensitivity was 100%, but the specificity decreased to 61%. D-wave on the other hand had high specificity (100%). This suggests that the D-wave alarms correlate better in predicting severe motor tract/real anatomical injuries with high specificity, and it has higher sensitivity for detecting severe spinal cord injuries than minor insults which result in only transient changes. Furthermore, it was noted that, overall, m-MEPs were relatively more prone to drop during resection of intramedullary tumors as compared to extramedullary pathologies probably owing to greater degree of cord handling. However, D-wave was stable in such cases, thus allowing the neurophysiological monitoring to continue to ensure maximal resection without compromising the integrity of corticospinal tracts.
These results suggest that, in patients with preoperative motor deficits, the greater sensitivity of m-MEP has importance of alerting surgeon of ongoing insult, thus limiting injury, but the D-wave helps the surgeon distinguish between the severities of insult and take appropriate measures to prevent injury without sacrificing extent of excision of lesion or correction of deformity or malformation.
There are only a few reports which have compared the clinical utility of m-MEP and D-wave and their findings have been presented in [Table 7].,,
|Table 7: Sensitivity and specificity of simultaneous myogenic motor-evoked potential and D-wave monitoring in literature|
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Ghadirpour et al. have reported a sensitivity and specificity of 62.5% and 97.03 for m-MEP and 100% and 98.4% for D-wave, respectively. However, the time point at which these calculations were done is not clear from their report.
| Conclusions|| |
Our results suggest that D-wave can be successfully recorded and monitored in patients with preoperative neurological deficits but without the history of previous surgery, irradiation, and the lesions caudal to T9. A combination of m-MEP and D-wave cater to two distinct requirements of successful monitoring of functional integrity of motor tracts with high sensitivity of m-MEP alerting surgeons so that corrective measures can be taken at the very early stages of injury/insult, while the D-wave helps surgeons differentiate between the severity of injury so that judicious decision can be taken preventing conservative excision of lesion or under-correction of deformity. Therefore, a combination of m-MEP and D-wave is recommended for monitoring the functional integrity of the corticospinal motor tract, especially in patients with preoperative motor deficits.
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Conflicts of interest
There are no conflicts of interest.
| References|| |
Deletis V. Intraoperative neurophysiology and methodologies used to monitor the functional integrity of the motor system. In: Neurophysiology in Neurosurgery. Academic press: Elsevier; 2002. p. 25-51.
Merton PA, Morton HB. Stimulation of the cerebral cortex in the intact human subject. Nature 1980;285:227.
Taniguchi M, Cedzich C, Schramm J. Modification of cortical stimulation for motor evoked potentials under general anesthesia: Technical description. Neurosurgery 1993;32:219-26.
Boyd SG, Rothwell JC, Cowan JM, Webb PJ, Morley T, Asselman P, et al
. A method of monitoring function in corticospinal pathways during scoliosis surgery with a note on motor conduction velocities. J Neurol Neurosurg Psychiatry 1986;49:251-7.
Burke D, Hicks R, Stephen J, Woodforth I, Crawford M. Assessment of corticospinal and somatosensory conduction simultaneously during scoliosis surgery. Electroencephalogr Clin Neurophysiol 1992;85:388-96.
Kothbauer KF, Deletis V, Epstein FJ. Motor-evoked potential monitoring for intramedullary spinal cord tumor surgery: Correlation of clinical and neurophysiological data in a series of 100 consecutive procedures. Neurosurg Focus 1998;4:e1.
Costa P, Peretta P, Faccani G. Relevance of intraoperative D wave in spine and spinal cord surgeries. Eur Spine J 2013;22:840-8.
Korn A, Halevi D, Lidar Z, Biron T, Ekstein P, Constantini S. Intraoperative neurophysiological monitoring during resection of intradural extramedullary spinal cord tumors: Experience with 100 cases. Acta Neurochir (Wien) 2015;157:819-30.
Yamamoto T, Katayama Y, Nagaoka T, Kobayashi K, Fukaya C. Intraoperative monitoring of the corticospinal motor evoked potential (D-wave): Clinical index for postoperative motor function and functional recovery. Neurol Med Chir (Tokyo) 2004;44:170-80.
Ghadirpour R, Nasi D, Iaccarino C, Romano A, Motti L, Sabadini R, et al
. Intraoperative neurophysiological monitoring for intradural extramedullary spinal tumors: Predictive value and relevance of D-wave amplitude on surgical outcome during a 10-year experience. J Neurosurg Spine 2018;30:259-67.
Morota N, Deletis V, Constantini S, Kofler M, Cohen H, Epstein FJ. The role of motor evoked potentials during surgery for intramedullary spinal cord tumors. Neurosurgery 1997;41:1327-36.
Sala F, Palandri G, Basso E, Lanteri P, Deletis V, Faccioli F, et al
. Motor evoked potential monitoring improves outcome after surgery for intramedullary spinal cord tumors: A historical control study. Neurosurgery 2006;58:1129-43.
Quiñones-Hinojosa A, Lyon R, Zada G, Lamborn KR, Gupta N, Parsa AT, et al
. Changes in transcranial motor evoked potentials during intramedullary spinal cord tumor resection correlate with postoperative motor function. Neurosurgery 2005;56:982-92.
Fujiki M, Furukawa Y, Kamida T, Anan M, Inoue R, Abe T, et al
. Intraoperative corticomuscular motor evoked potentials for evaluation of motor function: A comparison with corticospinal D and I waves. J Neurosurg 2006;104:85-92.
Hyun SJ, Rhim SC, Kang JK, Hong SH, Park BR. Combined motor- and somatosensory-evoked potential monitoring for spine and spinal cord surgery: Correlation of clinical and neurophysiological data in 85 consecutive procedures. Spinal Cord 2009;47:616-22.
Wang S, Zhang J, Tian Y, Shen J, Zhao Y, Zhao H, et al
. Intraoperative motor evoked potential monitoring to patients with preoperative spinal deficits: Judging its feasibility and analyzing the significance of rapid signal loss. Spine J 2017;17:777-83.
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6], [Table 7]