Prospective, randomized, placebo-controlled, double-blind exploratory study.
To compare effects of dexmedetomidine or a subanesthetic dose of ketamine on the amplitude and latency of transcranial electrically generated motor evoked potentials.
Total intravenous anesthesia (TIVA) is a standard anesthesia technique for transcranial electrical motor evoked potential monitoring in spine surgery. We aimed to determine whether the use of dexmedetomidine and ketamine as a component of TIVA exerted any beneficial effect on the quality of monitoring.
A total of 90 American Society of Anesthesiologist grade I–III patients, aged 18–65 years, with a motor power of ≥4/5 grade as per the Medical Research Council Scale in all four limbs who were scheduled for elective spine surgery under transcranial electrical motor evoked potential monitoring were enrolled. The subjects were randomly allocated into the following three groups: group PD who received 0.5 μg/kg/hr dexmedetomidine infusion, group PK who received 0.5 mg/kg/hr ketamine infusion, and group PS who received normal saline infusion, along with standard propofol–fentanyl based TIVA regime. Amplitude and latency of bilateral motor evoked potentials of the tibialis anterior and abductor halluces muscle were recorded at Ti (at train-of-four ratio >90%), T30 (30 minutes post-Ti), T60 (60 minutes post-Ti), and Tf (at the end of spine manipulation).
Baseline median amplitudes were comparable among the study groups. In group PK, we noted a gradually enhanced response by 24%–100% from the baseline amplitude. The median amplitudes of all the muscles were higher in group PK than those in groups PS and PD at time points T60 and Tf (
The present study demonstrated that compared with dexmedetomidine and control treatment, a subanesthetic dose of ketamine caused gradual improvement in amplitudes without affecting the latency.
Transcranial electrical motor evoked potential (TceMEP) monitoring has gained prominence as an integral modality of monitoring in the field of spine surgery. It monitors the functional integrity of the motor cortex, corticospinal tract, α-motor neuron, peripheral nerve, and neuromuscular junction. TceMEP monitoring has high sensitivity and specificity in the detection of postoperative new-onset motor deficits and is currently considered the gold standard with 91% sensitivity and 96% specificity [
The American Society of Neurophysiological Monitoring recommends propofol–opioid based total intravenous anesthesia (TIVA) as the ideal regime for MEP monitoring [
The modified Delphi consensus recommendations advocate the use of TIVA with adjuvant (ketamine, dexmedetomidine, and lidocaine) along with standard TIVA regime without affecting MEP signals [
Ketamine is used as either an infusion or intermittent boluses in nitrous oxide or opioid-based anesthetic regimens with or without neuromuscular blockade [
Dexmedetomidine, an α2 agonist that possesses analgesic, sedative, and sympatholytic properties, has recently been explored as an adjunct to TIVA for MEP monitoring in spine surgery. This agent has demonstrated compatibility with intraoperative MEP monitoring along with the lower intraoperative requirement of opioids and propofol [
Hence, the present study was designed to evaluate and compare the effects of fixed doses of dexmedetomidine or ketamine as adjuvant therapy to propofol–fentanyl based TIVA in adult patients undergoing elective spine surgery under neuromonitoring.
The study was conducted after obtaining approval from the Institutional Ethics Committee of All India Institute of Medical Sciences, Rishikesh, India (ECR/736/Inst/UK/2015/RR-18) and getting written informed consent from 90 patients of either sex with a motor power of ≥4/5 grade as per the Medical Research Council Scale in all four limbs and American Society of Anesthesiologist physical status I–III scheduled for elective spine surgery under TceMEP between August 2019 and 2020. Patients with significant cardiovascular (uncontrolled hypertension, heart block, and heart failure), pulmonary, renal, hepatic, psychiatric, or neuromuscular disease; those with a history of chronic alcohol use or allergy to study drugs; those with hemoglobin ≤10 g/dL; those with body mass index >30 kg/m2; and those with contraindications to MEP monitoring (epilepsy, cortical lesion, raised intracranial tension, pacemaker, intracranial electrodes, or vascular clips), and acute spinal cord injury were excluded from the study. The trial was registered with the Clinical Trials Registry India (CTRI/2019/08/020645).
Patients were randomly allocated to the groups to receive 0.5 μg/kg/hr dexmedetomidine (group PD), 0.5 mg/kg/hr ketamine (group PK), and normal saline (group PS). Computer-generated table of random numbers was used for the random allocation of the subjects in the study groups. The random numbers were placed in opaque and sealed envelopes. An anesthesiologist who was not involved in the study prepared the study drug, as per group allocation, in 50 mL syringes as infusate with normal saline (concentration of dexmedetomidine and ketamine was 4 μg/mL and 4 mg/mL, respectively). Patients, anesthesiologists, neurophysiologists, and surgeons were blinded to the group allocation of patients throughout the study.
All the eligible patients were kept nil per oral for solid food for 6 hours and clear fluids for 2 hours. Sedative premedication was omitted. After shifting to the operating room and initiating intravenous access, pulse oximeter, electrocardiography, noninvasive blood pressure, and noninvasive Bispectral index (BIS) monitors were attached. Anesthesia induction in all the patients was achieved with injection of 2 μg/kg fentanyl, 2.5 mg/kg propofol, and 1.2 mg/kg rocuronium to facilitate tracheal intubation with an appropriately sized endotracheal tube. Anesthesia was maintained with infusions of propofol (50–150 μg/kg/hr) and fentanyl (0.5–2 μg/kg/hr) with 50% oxygen in air. Study drugs as per group allotment were started after securing the airway. Ventilation was adjusted to maintain end-tidal carbon dioxide between 35 mm Hg and 45 mm Hg and the BIS between 40 and 60. The temperature was monitored using a nasopharyngeal temperature probe and maintained at >34°. The left radial artery was cannulated for invasive blood pressure monitoring, and the neuromuscular blockade was monitored using a train-of-four (TOF) recovery ratio (assessed using a TOF stimulation of the ulnar nerve at the left wrist). A dedicated neurophysiologist who used the NIM–Eclipse (Medtronic, Minneapolis, MN, USA) neurophysiologic monitoring system conducted TceMEP monitoring. Paired subdermal needle electrodes were used bilaterally in the tibialis anterior and abductor halluces muscles. The stimulating corkscrew electrodes were placed at the C3 and C4 sites (international 10–20 system). A train of six pulses (0.5 ms pulse duration, 2 ms interstimulus interval) at 250–500 volts was utilized for electrical stimulus. Baseline pulses and voltage were established and maintained throughout the surgery.
Surgeries were performed with the patient in the prone position with protection of eyes and pressure points. Muscle paralysis was allowed to wear off, as evident by the TOF ratio. The baseline MEP (Ti) was recorded on achieving TOF ratio of >90%, and subsequent recordings were noted at 30 and 60 minutes after Ti (T30 and T60); the final recording was made immediately after the surgical procedure was completed (Tf).
Fentanyl and study drug infusions were stopped at the commencement of skin closure, whereas propofol infusion was stopped at the end of skin closure. The trachea was extubated after placing the patient in the supine position, with the BIS between 80 and 100. The immediate recovery (duration from discontinuation of propofol infusion to eye opening on verbal command) and extubation time (discontinuation of propofol and extubation) were recorded. The patients were transferred to the post-anesthesia care unit (PACU) and were discharged when they achieved a Modified Aldrete Score of ≥9. Pain was assessed using a Numerical Rating Scale (NRS) on arrival to the PACU, on discharge from the PACU, and 24 hours postoperatively. Postoperative pain was managed with intravenous injections of tramadol 2 mg/kg and paracetamol 15 mg/kg that were administered every 8 hours. If the NRS score was >6, an intravenous injection of 75 mg diclofenac was administered.
There is a paucity of related literature; hence, no prior formal power calculation was undertaken. For sample size calculation we used the “Pilot Study Sample Size Rules of Thumb” procedure of PASS ver. 16.0 sample size software (NCSS, Kaysville, UT, USA); the calculated sample size was 83.5 [
Statistical analyses were performed using IBM SPSS ver. 26.0 (IBM Corp., Armonk, NY, USA). Categorical variables are presented as frequencies or proportions and were analyzed using the chi-square test or Fisher’s exact test. Quantitative data were analyzed for normal distribution using the Shapiro-Wilk test. Normally distributed data are presented as mean±standard deviation values, and data with non-normal distribution are presented as median with 25th and 75th percentile values (interquartile range). For normally distributed data, the means were compared using one-way analysis of variance after testing for the homogeneity of variance; post hoc analysis was conducted using Tukey’s test for variables with significant
Patient flow and randomization assignment are presented in the CONSORT (Consolidated Standards of Reporting Trials) flow diagram (
The average time to achieve TOF >90% after the administration of rocuronium was comparable (
Changes in intraoperative hemodynamic parameters (heart rate and mean arterial pressure [MAP]) are shown in
Our study demonstrated progressive and sustained improvement in the amplitudes without any change in the latency of MEPs with subanesthetic ketamine (0.5 mg/kg/hr) infusion in comparison with that with dexmedetomidine infusion.
Subanesthetic dose of ketamine acts on the non-N-methyl-D-aspartate (NMDA) receptors (AMPA [α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid] and kainate receptor) and releases endogenous excitatory amino acids, glutamate, and aspartate, resulting in excitability of the motor cortex [
Our results are in agreement with those of various other authors. Kalkman et al. [
Few studies have reported on the use of dexmedetomidine as a component of TIVA and its effect on MEP. Tobias et al. [
To our knowledge, only a retrospective study by Lam et al has compared the effects of ketamine and dexmedetomidine on MEPs during TIVA; no significant difference in amplitudes were observed with ketamine (0.5 mg/kg followed by 0.2–0.5 mg/kg/hr) and dexmedetomidine (0.1–0.4 μg/kg/hr without a loading dose) [
In our study, we used higher, fixed dosages of dexmedetomidine and ketamine in infusion; this could be the reason for the significant difference in amplitudes between the study groups. We also avoided nitrous oxide for the maintenance of anesthesia; this might be responsible for the MEP response-enhancing effect of ketamine in our study. Propofol infusion is stated as a reason for the dose-dependent decrease in amplitude by several researchers [
The drugs used in our study did not significantly affect the latency. The nonsignificant effects of dexmedetomidine, ketamine, or anesthetic agents on the latency of MEP have been recorded in the literature [
Combining dexmedetomidine with propofol infusion in TIVA is advantageous. The proposed advantages are reduced intraoperative consumption of propofol and opioids, intraoperative hemodynamic stability, and postoperative pain relief. We observed lower intraoperative consumption of propofol with dexmedetomidine; various studies have reported reduced propofol usage with 0.3–0.8 μg/kg/hr dexmedetomidine infusion [
Loftus et al. [
The total duration of postoperative analgesia as assessed using the NRS score was higher in the dexmedetomidine group than in the ketamine group.
The use of dexmedetomidine or ketamine was associated with contradictory effects on hemodynamic variables. Heart rate and MAP were lower in the dexmedetomidine group, whereas they were higher in the ketamine group. This difference in heart rate and MAP became significant after 60 minutes and 75 minutes of starting the drug infusion, respectively. Dexmedetomidine decreased the MAP and heart rate by reducing norepinephrine release, and ketamine caused tachycardia and hypertension because of catecholamine release [
The BIS was higher with the use of ketamine infusion than with dexmedetomidine; this difference became significant within 30 minutes of starting the infusion. This increase in BIS may reflect the desynchronization of the electroencephalography signal resulting from the dissociative action of ketamine rather than from the decrease in anesthetic depth [
The use of ketamine was associated with a significantly higher prevalence of complications. Dysphoria or disorientation was observed only with ketamine use. In our study, only one incidence of tongue bite was recorded in the ketamine group. This incident occurred owing to the displacement of the bite block during positioning.
Our study has certain limitations. First, our sample size was relatively small. Second, we could not measure the plasma concentration of dexmedetomidine and ketamine; thus, a fixed-dose regime may be associated with a variable plasma level. Third, the use of the analgesia nociception index would have demonstrated a better intraoperative requirement of opioids and would have inferred the opioid-sparing effect of the study drugs more precisely. Further studies on a larger sample are warranted to confirm our findings.
In conclusion, in this study, compared with dexmedetomidine, a subanesthetic dose of ketamine achieved gradual improvement in amplitudes without affecting the latency of the MEPs. However, this effect was not associated with a reduction in the perioperative dosage of propofol.
No potential conflict of interest relevant to this article was reported.
Roshan Andleeb: data collection, analysis of data, drafting and review of manuscript; Sanjay Agrawal: study design, data collection, drafting and critical review of manuscript; and Priyanka Gupta: study design, critical review of manuscript.
CONSORT (Consolidated Standards of Reporting Trials) flow diagram. Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine.
Secondary outcomes: HR
Demographic profile and perioperative profile of patients
Characteristic | Group PS (n=30) | Group PD (n=30) | Group PK (n=30) | |
---|---|---|---|---|
Age (yr) | 39.83±14.14 | 42.73±14.86 | 43.77±14.56 | 0.557 |
Sex (female/male) | 16/14 | 09/21 | 15/15 | 0.244 |
Weight (kg) | 57.97±12.74 | 61.13±14.26 | 57.37±11.41 | 0.478 |
American Society of Anesthesiologist status (I/II) | 26/4 | 23/7 | 22/8 | 0.186 |
Diagnosis | 0.918 | |||
Traumatic fracture | 13 | 15 | 13 | |
Pott’s spine | 8 | 5 | 5 | |
Prolapsed intervertebral disc | 3 | 2 | 3 | |
Canal stenosis | 2 | 3 | 3 | |
Spinal tumor | 2 | 4 | 3 | |
Scoliosis/kyphosis | 1 | 1 | 3 | |
Atlanto-axial dysplasia | 1 | 0 | 0 | |
Surgery | 0.072 | |||
Anterior cervical corpectomy and fusion | 1 | 1 | 0 | |
Anterior cervical discectomy and fusion | 6 | 4 | 1 | |
Posterior C1C2 fixation | 0 | 1 | 2 | |
Deformity correction | 1 | 1 | 3 | |
Laminectomy and tumor excision | 2 | 3 | 3 | |
Minimal invasive surgery | 1 | 1 | 2 | |
Odontoid surgery and foramen magnum decompression | 1 | 0 | 0 | |
Posterior decompression and instrumentation | 10 | 13 | 11 | |
Transforaminal lumbar interbody fixation | 8 | 6 | 8 | |
Duration of anesthesia (min) | 310.17±77.99 | 314.14±111.54 | 329.83±95.94 | 0.705 |
Duration of surgery (min) | 230.83±78.84 | 245.17±108.82 | 256.83±91.89 | 0.564 |
Baseline heart rate (/min) | 89.40±15.87 | 89.07±10.68 | 89.97±17.58 | 0.973 |
Baseline mean arterial pressure (mm Hg) | 101.50±7.59 | 100.23±9.09 | 96.87±8.31 | 0.091 |
Time to achieve train of four >90% (min) | 45.87±6.40 | 49.30±7.0 | 48.30±6.61 | 0.129 |
Values are presented as mean±standard deviation or number.
Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine.
Intergroup analysis of amplitudes of motor evoked potentials at different time intervals in the study groups
Amplitude (μV) | Time (min) | Group PS (n=30) | Group PD (n=30) | Group PK (n=30) | Post hoc analysis ( | |
---|---|---|---|---|---|---|
Right tibialis anterior | Ti | 563 (313–940) | 408 (190–660) | 587 (289–847) | 0.183 | |
T30 | 578 (340–1,043) | 567 (225–730) | 742 (455–945) | 0.181 | ||
T60 | 569 (290–988) | 587 (235–961) | 948 (475–1,406) | 0.048 |
PS vs. PK (0.047) | |
Tf | 497 (248–854) | 506 (313–901) | 950 (593–1,630) | 0.019 |
PS vs. PK (0.032) | |
Left tibialis anterior | Ti | 665 (389–1,020) | 409 (250–694) | 527 (289–988) | 0.204 | |
T30 | 664 (409–1,077) | 684 (285–1,058) | 715 (429–1,593) | 0.653 | ||
T60 | 590 (398–1,130) | 747 (426–1,183) | 757 (579–1,664) | 0.163 | ||
Tf | 588 (396–950) | 824 (452–1,295) | 1,003 (558–1,717) | 0.048 |
PS vs. PK (0.042) | |
Right abductor halluces | Ti | 811 (451–1,083) | 511 (309–1,226) | 782 (439–1,009) | 0.654 | |
T30 | 809 (441–1,005) | 570 (337–1,231) | 973 (554–1,211) | 0.512 | ||
T60 | 706 (418–1,113) | 638 (326–1,333) | 1,197 (677–1,783) | 0.025 |
PS vs. PK (0.046) | |
Tf | 818 (420–996) | 604 (283–1,920) | 1,401 (579–1,996) | 0.033 |
PS vs. PK (0.049) | |
Left abductor halluces | Ti | 762 (486–990) | 556 (287–1,319) | 713 (347–989) | 0.751 | |
T30 | 749 (498–891) | 559 (277–1,110) | 987 (622–1,249) | 0.122 | ||
T60 | 678 (458–944) | 565 (217–1,459) | 1,140 (599–1,732) | 0.023 |
PS vs. PK (0.042) | |
Tf | 683 (391–1,021) | 709 (296–1,385) | 1,432 (809–2,025) | 0.003 |
PS vs. PK (0.006) |
Values are presented as median (25th–75th quartile interquartile range).
Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine; Ti, time taken to achieve train of four ratio >90% after starting the study drug infusion; T30, 30 minutes after Ti; T60, 60 minutes after Ti; Tf, at the end of spine instrumentation/manipulation.
Change (%) in the median amplitudes from baseline in study groups
Groups | Muscle groups | % Change | ||
---|---|---|---|---|
at T30 | at T60 | at Tf | ||
PS | Right tibialis anterior | +2.7 | +1 | −11 |
Left tibialis anterior | −0.1 | −11 | −12 | |
Right abductor halluces | −0.2 | −12 | +0.9 | |
Left abductor halluces | −2 | −11 | −10 | |
PD | Right tibialis anterior | +39 | +44 | +24 |
Left tibialis anterior | +67 | +82 | +101 | |
Right abductor halluces | +11 | +25 | +18 | |
Left abductor halluces | +0.5 | +62 | +27 | |
PK | Right tibialis anterior | +26 | +60 | +62 |
Left tibialis anterior | +36 | +53 | +90 | |
Right abductor halluces | +24 | +44 | +79 | |
Left abductor halluces | +38 | +62 | +100 |
Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine; Ti, time taken to achieve train of four ratio >90% after starting the study drug infusion; T30, 30 minutes after Ti; T60, 60 minutes after Ti; Tf, at the end of spine instrumentation/manipulation.
Latency at different time interval in study groups
Latency (msec) | Time | Group PS | Group PD | Group PK | |
---|---|---|---|---|---|
Right tibialis anterior | Ti | 29.29±2.61 | 30.77±3.15 | 29.33±2.66 | 0.073 |
T30 | 29.41±2.34 | 31.11±2.96 | 29.88±3.07 | 0.060 | |
T60 | 30.57±2.27 | 31.06±2.36 | 29.47±3.12 | 0.061 | |
Tf | 30.41±2.91 | 30.86±2.86 | 30.59±2.92 | 0.826 | |
Left tibialis anterior | Ti | 29.81±2.59 | 31.48±2.87 | 30.53±2.49 | 0.056 |
T30 | 30.05±2.59 | 31.48±2.87 | 30.53±2.49 | 0.076 | |
T60 | 31.25±2.44 | 31.80±2.17 | 31.33±3.04 | 0.653 | |
Tf | 30.59±2.89 | 31.86±2.39 | 31.03±2.61 | 0.177 | |
Right abductor halluces | Ti | 46.13±3.68 | 49.09±5.89 | 47.99±4.98 | 0.069 |
T30 | 46.88±3.74 | 49.40±6.03 | 49.07±4.38 | 0.135 | |
T60 | 46.59±3.66 | 49.02±5.86 | 47.38±4.74 | 0.148 | |
Tf | 61.97±4.3 | 48.52±5.20 | 47.84±4.89 | 0.470 | |
Left abductor halluces | Ti | 46.18±3.79 | 49.17±5.80 | 48.79±5.58 | 0.054 |
T30 | 46.36±4.23 | 48.89±5.09 | 48.77±5.45 | 0.088 | |
T60 | 47.10±4.04 | 48.84±4.96 | 48.66±4.48 | 0.265 | |
Tf | 47.67±4.03 | 49.05±4.55 | 48.84±4.96 | 0.449 |
Values are presented as mean±standard deviation.
Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine; Ti, time taken to achieve train of four ratio >90% after starting the study drug infusion; T30, 30 minutes after Ti; T60, 60 minutes after Ti; Tf, at the end of spine instrumentation/manipulation.
Secondary outcomes
Variable | Group PS (n=30) | Group PD (n=30) | Group PK (n=30) | Significant post hoc analysis | |
---|---|---|---|---|---|
Intraoperative drugs usage | |||||
Propofol (mg) | 2,174.67±400.9 | 1,799.33±622.5 | 2,021.67±692 | 0.049 | PS vs. PD |
Fentanyl (μg) | 485.67±113.2 | 455.50±155.29 | 466.33±125.46 | 0.674 | |
Study drugs | 31.00±9.21 mL | 146.50±68.85 μg | 136±59.62 mg | - | |
Recovery profiles (min) | |||||
Time (eye opening on command) | 18.30±6.76 | 14.67±4.66 | 19.63±7.66 | 0.011 | PD vs. PK, PS vs. PD |
Time (extubation) | 18.57±6.70 | 14.00±4.52 | 17.73±8.06 | 0.020 | PS vs. PD |
Complications | 0.045 | ||||
Shivering | 1 | 0 | 1 | 0.599 | |
Delayed extubation | 2 | 0 | 1 | 0.355 | |
Facial blisters | 1 | 1 | 1 | 0.999 | |
Delirium/disorientation | 0 | 0 | 6 | 0.006 | |
Tongue bite | 0 | 0 | 1 | 0.364 | |
Postoperative pain score | |||||
NRS arrival in PACU | 2.3 (2–4) | 0 (0–2) | 1.5 (0–2) | 0.00 | PS vs. PD, PK vs. PS |
NRS on discharge from PACU | 5 (2.75–5) | 2 (2–3) | 3.5 (2.75–5) | 0.00 | PS vs. PD, PK vs. PD |
NRS at 24 hr | 7 (5.75–8) | 6 (4–7) | 7 (6–7) | 0.06 | |
Incidence of rescue analgesic requirement (yes/no) | 23/7 | 16/14 | 27/3 | 0.05 | PD vs. PK |
Values are presented as mean±standard deviation, number, or median (25th–75th interquartile range).
Group PS, patients to receive normal saline; group PD, patients to receive 0.5 μg/kg/hr dexmedetomidine; group PK, patients to receive 0.5 mg/kg/hr ketamine; NRS, Numerical Rating Scale; PACU, post-anesthesia care unit.