Keywords intradural extramedullary spinal cord tumor - intraoperative neurophysiological monitoring
- IONM - modified McCormick scale - motor evoked potential - somatosensory evoked
potential
Introduction
Spinal cord tumor (SCT) surgery intrinsically involves manipulation of neural structures.
Intraoperative neurological injury manifesting as postoperative sensory/motor deterioration
is an unnerving event for surgeons. Quench for a device, which can monitor the integrity
of neuraxis in real time during spine surgery, was met by intraoperative neurophysiological
monitoring (IONM) system in the second half of twentieth century. Over the period
it evolved and the latest system incorporates different modalities, namely evoked
potentials including somatosensory evoked potential (SSEP), motor evoked potential
(MEP), brainstem auditory evoked potential, visual evoked potential, electroencephalography,
electromyography (EMG), to monitor specific neural pathway.[1 ] Its importance, especially in spine surgery, was acknowledged by the American Academy
of Neurology and the American Clinical Neurophysiology Society a decade back (2012)
and they recommended that: “Intraoperative monitoring using SSEPs and transcranial
MEPs be established as an effective means of predicting an increased risk of adverse
outcomes, such as paraparesis, paraplegia, and quadriplegia, in spinal surgery.”[2 ]
Effectiveness of IONM in intramedullary spinal cord tumor (IMSCT) surgery is well
established; however, its role in resection of intradural extramedullary spinal cord
tumor (IDEMSCT) is still controversial. Though 6 to 7% patients of IDEMSCT postoperatively
develop permanent neurological deficits,[3 ]
[4 ] the opponents expostulate its use by citing factors like extra-axial location of
lesion, low canal occupancy, increased surgical duration, and higher cost of surgery/anesthesia.[5 ]
In this era of evidence, an unambiguous knowledge of precision of IONM is needed while
defining its niche in SCT surgery, especially IDEMSCTs. Indexed study focuses on sensitivity,
specificity, positive predictive value (PPV), negative predictive value (NPV), and
overall diagnostic accuracy of SSEP and transcranial MEP individually in detection
of intraoperative neurological injury in patients undergoing IDEMSCT resection for
oncological cure.
Materials and Methods
The proposed prospective study was conducted in the Department of Neurosurgery, Institute
of Medical Sciences, Banaras Hindu University, Varanasi, Uttar Pradesh, India, in
collaboration with Department of Physiology over a period of 24 months (January 2021–December
2022). Study protocol was approved by Institutional Ethics Committee. Patients presenting
in outpatient department with IDEMSCT were selected on the basis of clinical history,
physical examination, and contrast-enhanced magnetic resonance imaging (MRI) of spine.
All patients were informed about the benefits/risks of surgery under IONM and written
consent was taken. Limb-specific neurological deficit was measured using modified
McCormick (mMC) scale ([Table 1 ]).[6 ]
Table 1
Integrated table showing clinical, radiological, and surgical profile of patients
included in the study
Sl. no.
Age
Sex
Baseline mMC grade
IDEMSCT location
Tumor location with respect to cord
SSEP recordable
SSEP drop (>50%)
MEP drop (>50%)
Tumor resection
New deficit
1
27
F
3
D
Lt
NR
NA
Y
STR
Y
2
26
M
2
D
Lt
R
N
N
GTR
N
3
22
M
2
C
Lt
R
N
N
GTR
N
4
12
F
1
C
Lt
R
N
N
GTR
N
5
18
M
3
L
Co
NR
NA
N
GTR
N
6
45
F
3
D
Lt
NR
NA
N
GTR
N
7
23
F
3
D
Lt
NR
NA
N
GTR
N
8
22
M
3
L
P
NR
NA
N
GTR
N
9
46
F
2
D
P
R
N
N
GTR
N
10
65
F
3
L
Lt
NR
NA
N
GTR
N
11
14
M
3
D
Lt
NR
NA
N
GTR
N
12
39
M
2
C
P
R
N
N
GTR
N
13
28
M
2
D
P
R
N
N
GTR
N
14
47
M
2
D
Lt
R
N
N
GTR
N
15
17
M
4
L
Lt
NR
NA
N
GTR
N
16
59
F
3
D
Lt
NR
NA
N
GTR
N
17
45
F
2
D
A
R
Y
Y
STR
Y
18
16
F
3
L
P
NR
NA
N
GTR
N
19
52
M
3
L
Co
NR
NA
N
GTR
N
20
13
F
1
C
Lt
R
N
N
GTR
N
21
46
F
2
D
P
R
N
N
GTR
N
22
65
M
4
D
Lt
NR
NA
N
GTR
Y
23
40
F
3
C
Lt
NR
NA
N
GTR
N
24
23
F
1
D
Lt
R
N
N
GTR
N
25
28
F
3
D
A
NR
NA
Y
STR
Y
26
54
F
3
D
P
NR
NA
N
GTR
N
27
60
F
3
D
Lt
NR
NA
N
GTR
N
28
45
F
2
C
Lt
R
N
N
GTR
N
29
27
M
2
C
Lt
R
Y
Y
STR
Y
30
60
F
3
D
P
NR
NA
N
GTR
N
31
50
M
4
C
Lt
NR
NA
N
GTR
N
32
45
M
3
L
Co
NR
NA
N
GTR
N
Abbreviations: A, anterior; C, cervical; D, dorsal; F, female; GTR, gross total resection;
L, lumbar; Lt, lateral; M, male; N, no; NA, not applicable; MEP, motor evoked potential;
mMC, modified McCormick scale; NR, not recordable; P, posterior; R, recordable; SSEP,
somatosensory evoked potential; STR, subtotal resection; Y, yes.
Inclusion Criteria
Exclusion Criteria
IDEMSCT patients with other spinal compressive lesions
IDEMSCT patients with mMC grade V neurological deficit
Pregnant patients
Patients on treatment for seizure/ movement disorders
History of deep venous thrombosis
For statistical ease, IDEMSCTs of junctional region of spine (namely cervicodorsal/dorsolumbar)
were placed in cervical/ dorsal/lumbar group, on the basis of major regional occupancy
(>50%) in longitudinal axis on MRI. Limb-specific neurological deficit using mMC scale
was assessed preoperatively (baseline), on the day of surgery after 4 hours of reversal
from general anesthesia (postoperative day [POD] 0), on POD 1, 7, and 30. MRI spine
was carried out in all patients on POD-0.
Anesthesia for surgery under IONM: Following preoxygenation for 3 to 5 minutes general anesthesia was induced with fentanyl
(2 μg/kg) and propofol (titrated to loss of consciousness) by neuroanesthesiologist.
After adequate mask ventilation, vecuronium (0.1 mg/kg) was administered and patients
were intubated with appropriate-sized endotracheal tube. Temperature probe was attached.
Body temperature was maintained throughout the procedure between 36 and 37°C. Bite
block was placed between the jaws. Ventilation was adjusted to obtain a stable airway
pressure with end-tidal carbon dioxide levels between 30 and 40 mm Hg (adjusted after
obtaining an arterial blood gas to correlate with a partial pressure of carbon dioxide
between 35 and 45 mm mercury). In all cases, bispectral index (BIS) was used to monitor
the depth of anesthesia, with BIS maintained between 40 and 60. Wearing-off effect
of vecuronium was confirmed with the ulnar nerve stimulation. Baseline MEPs (transcranial)
were recorded. Anesthesia was maintained by intravenous propofol (2%) infusion at
50 to 100 μg/kg/min with fentanyl infusion at 1 to 2 μg/kg/hour. It was occasionally
supplemented with inhalational anesthetic agents, that is, air-nitrous oxide in 1:1
ratio and isoflurane at permissible low minimal alveolar concentration (MAC) 0.4 to
0.5, when plane of anesthesia was not maintained. At this time, neurophysiologist
was informed and IONM waveform changes were closely monitored. At the time of skin
closure, anesthetic agents were stopped. Inhalational anesthetic drugs were stopped
at approximately 10 minutes prior to end of surgery. Reversal of residual neuromuscular
blockade was done with intravenous neostigmine 50µg/kg and glycopyrrolate 10µg/kg
drugs. If criteria were met, patient was extubated.
Surgery under IONM
: A standardized workflow was followed in the study ([Fig. 1 ]). “Medtronic NIM – Eclipse system 68L2128-C” was used as neurophysiological detector.
After cleaning of the local sites with chlorhexidine and 70% ethyl alcohol solution,
electrodes were fixed on patient. Cork-screw electrodes were applied over scalp at
standard sites (FZ , CZ , C3 , C3′ , C4 , C4' ) of international 10 to 20 system ([Fig. 2A ]). In upper extremities, SSEP stimulating electrodes were placed over median nerve
at the wrist ([Fig. 2B ]), while in the lower extremities, they were placed over posterior tibial nerve ([Fig. 2C ]). Invasive subdermal needle electrodes were inserted at target muscles of upper
and/or lower limbs for recording of trans cranial MEP ([Fig. 2D ]). All electrodes were secured using adhesive plasters.
Fig. 1 Outline of the standardized workflow of this study. CEMRI, contrast-enhanced computed
tomography; IONM, Intraoperative neuromonitoring; MEP, motor evoked potential; mMC,
modified McCormick scale; SSEP, somatosensory evoked potential.
Fig. 2 Preoperative patient with multiple electrodes for spinal cord tumor surgery under
intraoperative neuromonitoring (A ) Cork-screw electrodes fixed over scalp according to international 10-20 system.
(B ) Sticky electrodes attached over both fore arms near wrist (arrow marked) for somatosensory
evoked potential (SSEP) recording from median nerve of upper limbs. (C ) Sticky electrodes attached over both legs near ankle (arrow marked) for SSEP recording
from posterior tibial nerve of lower limbs. (D ) Invasive subdermal needle electrodes for motor evoked potential recording inserted
in target muscles of both lower limbs, namely vastus medialis of thigh, tibialis anterior
of leg, flexor halluces longus of foot during dorsal intradural extramedullary spinal
cord tumor surgery with control electrodes inserted in abductor pollicis brevis muscle
of hand.
Patients were positioned prone on table over bolsters. Distal ends of electrodes were
inserted in data acquisition modules that were in continuation with IONM system. Baseline
SSEP and MEP waveforms ([Fig. 3A, B ]) were recorded. Weaned-off effect of muscle relaxant was ensured. Surgery was proceeded.
SSEP and/or MEP were recorded at multiple phases of surgery (namely laminectomy, durotomy,
tumor decompression, and resection). More than 50% decrease in amplitude of waveform
was considered as “warning sign” ([Fig. 3C, D ]).
Fig. 3 Somatosensory evoked potential (SSEP) and motor evoked potential (MEP) waveforms
(A ) Typical baseline SSEP waveform recording from upper and lower limbs while operating
cervical intradural extramedullary spinal cord tumor (IDEMSCT). (B ) Typical baseline MEP waveform recording while operating cervical IDEMSCT. (C ) Waveform showing drop in SSEP amplitude by more than 50% in both upper and lower
limb recordings while resecting cervical IDEMSCT. (D ) Red-flagged MEP waveform readings due to more than 50% drop in amplitude of most
target muscles while resecting cervical IDEMSCT; however, left abductor pollicis brevis
MEP amplitude has improved. (E ) Most MEP recordings improved while some remained red flagged after following rescue
protocol. (F ) Baseline SSEP waveform recording from a patient with dorsal IDEMSCT who had Nurick
grade IV deficit. NB, here amplitude is very small which is in contrast with [Fig. 2A ].
At such instances, surgery was withheld temporarily when MEP amplitude decreased by
more than 50%. Cord was irrigated with warm saline; mean arterial pressure, MAC of
isoflurane, patient's body temperature (to rule out hypothermia), and BIS were checked.
It was resumed on improvement of amplitude. “Unilateral or bilateral disappearance
of waveform (especially MEP) as well as lack of restoration of amplitude by more than
50%” were considered red flag. Correctable parameters were rechecked and needful adjustments
were done. Subject to normalization of waveform, surgery was further proceeded, else
aborted ([Fig. 3E ]). After tumor resection, watertight duraplasty was performed and checked on-table
by “induced Valsalva maneuver”. Anatomical closure of surgical site was done. Excised
specimen was sent for histopathological examination. Neurological status was of limb
was reassessed using mMC scale, after 4 hours of extubation (i.e., POD 0), POD 1,
7, and 30. Clinical change in mMC value was considered “reference standard” and diagnostic
accuracy of SSEP and MEP was compared with respect to it.
Statistical Analysis
Data was fed in Microsoft EXCEL spreadsheet and analyzed using Statistical Package
for Social Sciences (SPSS) software, IBM manufacturer, Chicago, United States, version
25.0. Presentation of “Categorical variables” was done in form of number and percentage
(%). On the other hand, “quantitative data” were presented as “mean ± SD” (standard
deviation) and as “median with 25th and 75th percentiles” (interquartile range). Following
statistical tests were applied for results:
Association of variables, which were quantitative in nature, was analyzed using analysis
of variance. Paired t -test was used for comparison across follow-up.
Association of variables, which were qualitative in nature, was analyzed using Fisher's
exact test, as at least one cell had an expected value of less than 5.
Receiver-operating characteristic (ROC) curve was used to find cutoff point of mMC
for SSEP being recordable in patients with higher neurological deficit along with
calculation of sensitivity, specificity, PPV, NPV, and diagnostic accuracy of SSEP.
Sensitivity, specificity, PPV, and NPV of SSEP and MEP were calculated for predicting
intraoperative neurological injury/new motor deficit.
Statistically, p -value of less than 0.05 was considered significant.
Results
Between January 2021 and December 2022, 35 patients with IDEMSCT were enrolled and
underwent surgery under IONM, at our institution. Three patients were lost to follow-up
at 30 days. Finally, the cohort comprised of 32 patients ([Table 1 ]). All patients had varying degree of neurological deficits. Mean age of presentation
was 36.84 years. There was female preponderance with female: male ratio: 1.28:1. Preoperative/baseline
sensory-motor deficit in limbs was measured on mMC ([Table 2 ]) and mean mMC value was 2.59. Most of these spinal tumors (53.13%) were located
in dorsal vertebral region. Within thecal sac, the commonest site (59.38%) was “lateral”
to cord. Mean duration of surgery was 222.34 minutes. Duration of surgery was significantly
dependent on tumor location within thecal sac. It was minimum (mean: 186.67 minutes)
for tumors at conus and maximum (mean: 295 minutes) for tumors ventral to cord. Gross
total resection (GTR) was achieved in 28 (87.5%) patients, while it was “subtotal”
in four (12.5%) patients due to persistent warning changes in MEP waveform.
Table 2
Modified McCormick scale (mMC) scale
Functional grade
Clinical prerequisites
I
Neurologically intact, normal ambulation, minimal dysesthesia
II
Mild sensory or motor deficit, functional independence
III
Moderate deficit, limitation of function, independent with external aid
IV
Severe sensory or motor deficit, limitation of function, dependent
V
Paraplegia or quadriplegia, even with flickering movement
SSEP with typical waveform ([Fig. 3A ]) was recordable in 13 (40.63%) patients. Patients with high neurological deficit
had very small amplitude SSEP waves ([Fig. 3F ]), where tracking 50% amplitude drop was elusive. In our study, majority of patients
(19/32, 59.37%) had this very type of small amplitude SSEP recordings. On application
of statistical ROC curve, we found that standard SSEP waves were recordable in subset
of patients who had mMC score less than or equal to2 ([Fig. 4 ]). Since authors could not reliably notice “more than 50% drop in amplitude” in such
small waves, so further SSEP analysis was carried out in 13 patients who displayed
typical waveforms. Among these 13 patients, SSEP showed intraoperative drops (>50%)
in amplitude in two cases that did not recover despite rescue protocol of optimizing
blood pressure, core temperature, local irrigation with warm saline, etc. Their “post-operative”
MRI spine had no radiological signs of cord parenchyma injury. Both cases had temporary
sensory-motor deterioration from baseline, which were found recovered on POD 7 follow-up.
Nurick grade further continued to improve. In this subset of study cohort, statistically
SSEP had 100% sensitivity, 100% specificity, 100% PPV, and 100% negative predictive
value in identification of neurological injury ([Table 3 ]).
Fig. 4 Receiver-operating characteristic curve showing 100% sensitivity and specificity
of somatosensory evoked potential in subset of intradural extramedullary spinal cord
tumor patients whose neurological deficit on modified McCormick scale (mMC) is less
than or equal to 2.
Table 3
Statistical description of ROC curve of SSEP
Variables
mMC at baseline
Area under the ROC curve (AUC)
1
Standard error
0
95% CI
0.891–1.000
p -Value
<0.0001
Cutoff
≤2
Sensitivity (95% CI)
100% (75.3–100.0%)
Specificity (95% CI)
100% (82.4–100.0%)
PPV (95% CI)
100% (75.3–100.0%)
NPV (95% CI)
100% (82.4–100.0%)
Diagnostic accuracy
100.00%
Abbreviations: AUC, area under the curve; CI, confidence interval; IDEMSCT, intradural
extramedullary spinal cord tumor; MEP, motor evoked potential; mMC, modified McCormick
scale; NPV, negative predictive value; PPV, positive predictive value; ROC, receiver-operating
characteristic; SSEP, somatosensory evoked potential.
In the indexed study SSEP had 100% diagnostic accuracy for the subset of IDEMSCT patients
whose mMC value was less than or equal to 2.
MEP was recordable in all 32 patients. Authors noticed an inverse relationship between
neurological deficit of limb muscle group and corresponding amplitude of MEP wave.
Four patients (12.5%) showed intraoperative more than 50% drop in waveform amplitude,
which translated into their postoperative motor deficit. However, at POD-7 follow-up,
deficits were recovered. In one patient (3.13%), there was no intraoperative significant
change in MEP waveform ([Fig. 5A ]), but there was postoperative deterioration of motor power. Preoperative MRI of
this patient had left laterally located contrast enhancing D10 D11 IDEMSCT that was severely compressing the cord parenchyma ([Fig. 5B, C ]). Intraoperative MEP tracing had differential amplitude in waveform for both lower
limbs. On affected (left) side there were smaller amplitude waves; though there were
no intraoperative significant fluctuations in MEP, still patient had drop in motor
power of limb after surgery. Postoperative MRI spine showed GTR of tumor ([Fig. 5D ]); however, there were radiological features of focal cord contusion ([Fig. 5E ]). Statistically MEP had 80% sensitivity, 100% specificity, 100% PPV, and 96.43%
NPV. Its diagnostic accuracy was 96.88% in detection of intraoperative neurological
injury ([Table 4 ]).
Fig. 5 Motor evoked potential (MEP) recordings and radiological details of the patient whose
neurophysiological monitoring was false negative. (A ) Control MEP from abductor pollicis brevis has the highest amplitude. Waveform gets
progressively smaller in lower limb recordings. Left foot, ipsilateral to tumor, has
the smallest waves. (B ) Sagittal contrast-enhanced magnetic resonance imaging (MRI) spine of the indexed
patient has D10 D11 contrast avid intradural extramedullary spinal cord tumor measuring 3.7 × 2.5 × 2.3 cm.
(C ) Corresponding axial section shows anterolaterally located tumor occupying approximately
65% of thecal space causing significant mass effect on cord. (D ) T2 sequence sagittal MRI spine after gross total resection of tumor with postoperative
artifacts. (E ) Corresponding axial section has areas of hyperintensity, suggestive of cord contusion.
Table 4
Statistical description of ROC curve of MEP
Variables
Values
Sensitivity (95% CI)
80% (28.36–99.49%)
Specificity (95% CI)
100% (87.23–100.00%)
AUC (95% CI)
0.9 (0.74–0.98)
Positive predictive value (95% CI)
100% (39.76–100.00%)
Negative predictive value (95% CI)
96.43% (81.65–99.91%)
Diagnostic accuracy
96.88%
Abbreviations: AUC, area under the curve; CI, confidence interval; MEP, motor evoked
potential; ROC, receiver-operating characteristic;
Patients were clinically assessed at POD 0, 1, 7, and 30. Mean mMC value was higher
than baseline on POD 0, but it improved subsequently at every follow-up, that is,
POD 1, POD 7, and POD 30. Statistically significant improvement was noticed on POD
7 and POD 30 ([Fig. 6 ]).
Fig. 6 Graph showing changes in mean modified McCormick value (mMC) of the study group.
Statistically significant improvement is noticeable at postoperative day (POD) 7 and
POD 30.
Discussion
SCTs comprise approximately 15% of all central nervous system neoplasms, which include
extradural and intradural tumors.[7 ] Intradural spinal cord tumors (IDSCTs) can be extramedullary or intramedullary.
IDEMSCTs constitute about 35 to 40% of all SCTs.[8 ] Usual presentations of SCTs are pain and progressive sensory-motor deficits with/without
bladder-bowel symptoms. Surgical resection is the cornerstone in the management. Chief
complications of IDSCT surgeries are surgical site infections, cerebrospinal fluid
(CSF)-related complications (namely pseudomeningocele and CSF leak) and new onset/worsening
of neurological deficits. Despite incorporation of latest microneurosurgical techniques,
3.7 to 7.5% of postoperative patients endure the torment of neurological deterioration.[3 ]
[4 ]
[9 ] This deterioration may occur due to direct maneuvers being performed on to cord
(tumor-cord interface delineation), secondary to systemic blood pressure changes leading
to cord hypoperfusion or by traction injury of cord while contemplating tumor debulking/resection.
The never-ending quench of achieving maximum possible safe tumor resection has driven
the intraoperative monitoring technique for integrity of neuraxis during spine surgery,
from crude “wake up” test to modern sophisticated multimodal IONM system.[9 ] SSEP and MEP have been extensively used in IONM during SCT surgeries. SSEP monitors
the dorsal column and medial lemniscus pathways, while MEP monitors the motor pathways.
MEP is the most dependable modality in monitoring conus medullaris and cauda equina
motor integrity. The major limitation of SSEP is that it requires averaging that prolongs
acquisition time. MEP has overcome this limitation and it does not require averaging,
but it has variable morphology. Fifty percent drop in latency and/or a 10% prolongation
in latency are accepted as warning criteria in SSEP monitoring; while owing to its
variable morphology, the warning criteria during MEP monitoring are absence of waves,
change in waveform or more than 50% drop in amplitude. There is a consensus to continue
the surgery, as long as MEP recordings are stable.[9 ]
[10 ] The role of IONM in IMSCT surgeries has been highlighted in various studies; however,
its routine use in IDEMSCT and extradural SCT is still under debate.[5 ]
[10 ]
In this study, the mean duration of surgery under IONM was 222.34 minutes. Operative
time was minimum for IDEMSCTs located at conus medullaris or cauda equina, while it
was maximum for tumors located ventral to cord. In our study since there was no control
group of patients undergoing surgery without IONM (ethical committee did not approve),
so authors cannot opine whether use of IONM and its warnings lead to a statistically
significant increase in the surgical duration or not. Siller et al in their study
had mean operative time of 200 minutes while performing resection of IDEMSCTs using
IONM.[11 ]
SSEP with typical waveform was recordable in 40.63% patients. In patients with higher
deficit, amplitude was very small, where tracking of further decrease by more than
50% was difficult. Baig Mirza et al faced similar difficulty while recording SSEP
and MEP in his subset of IDEMSCT patients who had greater baseline neurological deficit.
SSEP was recordable in 68% patients with ASIA E and 62% patients with ASIA D impairment.
They had to preclude patients with higher impairment where no successful readings
were obtained.[5 ] In our study, we found that patients whose neurological status on mMC scale was
up 1 or 2; SSEP had 100% recordability (95% confidence interval). In this subset of
patients (13/32), SSEP showed 100% sensitivity, specificity, PPV, NPV, and diagnostic
accuracy in prediction of intraoperative neurological injury.
MEP was recordable in all patients of our study, but amplitudes were smaller in the
muscle groups with higher deficit. In four (12.5%) patients, it showed more than 50%
drop in amplitude in some target muscles, which did not recover to 50% of baseline
value. These patients showed temporary motor worsening. However, in one patient (3.12%),
there was deterioration without significant MEP amplitude change during surgery. In
literature, there is wide variation in the false-negative reporting of transcranial
MEP. Historically, Kurokawa et al have reported 7% false-negative transcranial MEP
recordings in his study group of 59 SCT surgeries,[12 ] while Tamkus et al cite false-negative IONM findings in spine surgery as rare (0.04%)
event.[13 ] Baig Mirza et al have mentioned in their research about patients who did not exhibit
intraoperative change in MEP, but later developed neurological deficits.[5 ] Elwakil et al have reported one false-negative case out of 24 patients who underwent
spine surgery under transcranial MEP monitoring.[14 ] Thus, in our study MEP had 80% sensitivity, 100% specificity, 96.43% negative predictive
value, 100% PPV, and overall 96.88% diagnostic accuracy. Point to ponder over here
is that SSEP had 100% diagnostic accuracy, but it was recordable in a small subset
of our study group who had minimal neurological deficits, while transcranial MEP was
recordable in all patients of our cohort (mMC grade I to grade IV) and it delivered
good diagnostic accuracy. Literature has paucity of studies citing the sensitivity,
specificity, PPV, NPV, and diagnostic accuracy for individual modalities of IONM,
that is, SSEP and MEP in IDEMSCT surgeries. Niljianskul and Prasertchai in their study
on IDSCT (IDEMSCT and IMSCT) patients have reported 66.7% sensitivity, 88.7% specificity,
22.2% PPV, and 98.2% NPV when they used multimodal (SSEP, MEP, EMG) IONM.[15 ] Siller et al in their retrospective study on elderly patients (≥ 65-year age) with
IDEMSCT who underwent IONM (SSEP and transcranial MEP) guided resection found 42.9%
sensitivity, 98,2% specificity, 75.0% PPV, and 93.3% NPV of IONM as a composite modality.[11 ] van der Wal et al have cited 73% sensitivity and 78% specificity of multimodal IONM
(SSEP, MEP) when used in IDEMSCT surgery.[8 ]
In our study, persistent warning changes in SSEP/MEP waveform led to change of tumor
resection plan (gross total to subtotal) in four (12.5%) patients. All were neurologically
preserved postoperatively. Ghadirpour et al described a series of 68 patients who
underwent multimodal IONM (SSEP and MEP) guided IDEMSCT surgery, during which significant
IONM changes occurred in 7.35% of patients, inducing a modification of the surgical
strategy which prevented and mitigated postoperative neurological sequelae.[16 ] Baig Mirza et al have reported 17% subtotal resection in IONM-IDEMSCT surgical subgroup
and this resection was comparable (15%) to non-IONM IDEMSCT surgical subgroup.[5 ]
Authors noticed higher mean mMC value on POD 0 than baseline that improved subsequently
at every follow-up, that is, POD 1, POD 7, and POD 30. This transient worsening could
have been due to postoperative edema and microinsults to neuraxis.
The plan of anesthesia is very important in such cases and cannot be overlooked in
discussion. Team work and close communication between neurosurgeons, neuroanesthesiologists,
and neurophysiologists are must for better outcomes. But there is paucity of ideal
anesthetic technique, which can be universally applied for the optimal generation
of evoked potentials. A low-dose inhalational anesthetic agent (up to 0.5 MAC) and
low-to-medium dose propofol (50–100 μg/kg/min intravenous) with infusion of opioid
(fentanyl, remifentanil) offers a balanced anesthesia approach, which can be modified
as per the changes in IONM waveforms.[17 ]
This study has some limitations like small sample size, lack of control arm in design
(not approved by ethics committee), and short duration of follow-up. Still the results
were encouraging. Studies with larger number of patients and longer follow-up will
further strengthen defining the role of IONM in IDEMSCT surgeries.
Conclusion
The two most frequently used modalities of IONM, namely, SSEP and MEP, individually
carry high diagnostic accuracy in detection of intraoperative neurological injuries
in patients undergoing IDEMSCT surgery. MEP continues to monitor the spinal cord,
even in those subset of patients where SSEP fails to record. In opinion of authors,
neurological integrity of patients must be respected and in this context SSEP and/or
transcranial MEP serve(s) as a reliable adjunct to the dexterity of surgeon while
addressing IDEMSCTs.
