Small dose of propofol combined with dexamethasone for postoperative vomiting in pediatric Moyamoya disease patients: a prospective, observer-blinded, randomized controlled study
Article information
Abstract
Background
For effective postoperative antiemetic management in pediatric moyamoya disease patients receiving fentanyl based postoperative analgesia, a multimodal approach has been recommended. The uncertain efficacy of ondansetron for pediatric neurosurgical patients or the possible antiemetic effect of small dose of propofol motivated us to evaluate the preventive effect of a subhypnotic dose of propofol combined with dexamethasone on postoperative vomiting (POV), especially during immediate postoperative periods.
Methods
In a prospective observer-blind randomized controlled study, we compared dexamethasone 0.15 mg/kg alone (Group D) with dexamethasone combined with propofol of 0.5 mg/kg (Group DP) in 60 pediatric patients, aged 4-17 years, who underwent indirect bypass surgery and received fentanyl-based postoperative analgesia. Occurrence of vomiting and pain score (Wong-Baker facial score) and requirement of rescue analgesic and antiemetic were continually measured (0-2, 2-6, 6-12 and 12-24 postoperative hours). For statistical analysis, in addition to the Fisher's exact test, a generalized linear mixed model (GLMM) and the linear mixed model (LMM) for repeated measures were used for vomiting and pain scores, respectively.
Results
There was no statistical significance of POV incidence, requirement of rescue analgesic and pain score between the two groups at any measured intervals. The incidence of POV was 53.3% during 24 hours in both groups, and was especially 6.7% and 13.3% (P = 0.671) during 0-2 hr and 16.7% and 23.3% (P = 0.748) during 2-6 hr in group D and group DP, respectively.
Conclusions
A small dose of propofol combined with dexamethasone appears ineffective to preventing POV in pediatric moyamoya patients receiving continuous fentanyl infusion.
Introduction
Moyamoya disease is a rare progressive ischemic vascular disorder predominantly in the territory of the anterior and middle cerebral arteries. Neovascularization procedures such as direct or indirect vascular bypass surgery are effectively practiced in most institutes for these patients, and intraoperative and postoperative management strategies are strictly based on hemodynamic stability and normocarbic status. According to the report by Hayash et al. [1], postoperative neurologic deterioration in moyamoya disease patients is often caused by cerebral hemodynamic changes such as a shift of the watershed area or hyperemia in brain regions. Both inadequate postoperative pain control and emesis activate the sympathetic nervous system and increase the intracranial pressure, and the postoperative care for pain and emesis can be very closely related to their morbidity and mortality of pediatric moyamoya patients [2,3]. Continuous intravenous infusion with fentanyl [4] was suggested to be effective for postoperative pain control in pediatric patients, but fentanyl also acts as a risk factor for postoperative nausea and vomiting (PONV) [5,6]. For high risk PONV patients, a multimodal approach is recommended [7] because most antiemetics work independently of each other and of the patient's risk factor [8]. But the antiemetic effect of ondansetron is uncertain in pediatric neurosurgical patients [9-11]. It is widely believed that propofol based anesthesia reduces PONV more compared to volatile anesthesia [12]. Furthermore, even a small dose of propofol was reported to possess direct antiemetic effects [13-15], and an adjuvant subhypnotic dose [16,17] or infusion [18] of propofol to dexamethasone reduced emetic events in surgical or chemotherapy patients. For surgical patients, a small dose of propofol combined with dexamethasone was effective to preventing PONV during immediate postoperative periods without delaying anesthetic recovery [17] and would be valuable to neurosurgical patients.
Therefore, we compared the postoperative anti-vomiting effect between dexamethasone alone and dexamethasone with a small dose of propofol in pediatric moyamoya patients who underwent encephalo-duro-arterio-synangiosis (EDAS) surgery and received continuous infusion of fentanyl for postoperative pain.
Materials and Methods
After approval of the Institutional Review Board and obtaining written informed consent from parents, this study was performed according to the declaration of Helsinki and 67 American Society of Anesthesiologists physical status I or II, diagnosed with moyamoya disease, aged 4-17 year of either sex, scheduled for EDAS surgery were enrolled during May 2009 and May 2010 at a university hospital in this observer-blind prospective, randomized controlled study. Among them, 60 patients were included for data analysis according to our exclusion criteria; presence of neurologic signs or seizure at admission, history of motion sickness or PONV, mental retardation and requirement of postoperative ventilator care (Fig. 1).
Patients fasted for 4-8 hours before surgery according to age. Premedication was not given. As patients arrived at the preinduction room with their parents, thiopental sodium 2 mg/kg was administered to children who were crying or anxious about entering the operating room. Anesthesia was induced with intravenous thiopental sodium 3-5 mg/kg followed by face mask ventilation with sevoflurane in air and oxygen. The trachea was intubated with the aid of rocuronium 0.7 mg/kg. Anesthesia was maintained with sevoflurane (2-4 vol%) in 50% oxygen and remifentanil infusion (0.1-0.4 µg/kg/min), and anesthetic depth was adjusted to changes in the hemodynamic variables within 20% of baseline values. Controlled ventilation was adjusted to maintain end-tidal carbon dioxide partial pressure of 35-40 mmHg. Body temperature was maintained within 36.0-36.7℃ with air heater. Standard anesthetic monitors of ECG, invasive blood pressure, and pulse oximetry were applied continuously. For postoperative pain control, fentanyl i.v. infusion with a rate of 0.5 µg/kg/hr (with the maximum dose of 600 µg/day) began at dural closure and continued for 48 hours postoperatively. At the completion of surgery, residual muscle relaxation was completely reversed with neostigmine 0.02 mg/kg and atropine 0.01 mg/kg after confirming the recovery of neuromuscular function using a nerve stimulator (TOF-Watch SX, Organon Ireland Limited, Dublin, Ireland). After completion of the head dressing, administration of remifentanil and sevoflurane was discontinued. The trachea was extubated by the attending anesthesiologist's assessment that the patient regained spontaneous respiration adequately. Patients stayed in the postoperative care unit (PACU) for at least 1 hour, and were moved to a general ward.
Patients were randomly allocated into two groups with computer-generated random numbers. At dural closure, normal saline and dexamethasone 0.15 mg/kg (group D) or propofol 0.5 mg/kg and dexamethasone 0.15 mg/kg (group DP) were administered. Nursing staffs in PACU and ward, who cared for the patients and knew of this clinical study but were blinded to the patient's group, recorded every episode of vomiting for 24 hours (at intervals of 0-2 hr, 2-6 hr, 6-12 hr and 12-24 hr). Vomiting was defined as forced gastric and esophageal movement with either the expulsion of gastric contents or not. When vomiting occurred more than twice in 30 minutes or patients were intolerant to vomiting, metoclopramide 0.15 mg/kg was administered as a rescue antiemetic. In addition, numeric scaled pain scores (0-5, Wong-Baker's facial expression scale [4,19]) were evaluated. Ketorolac 1 mg/kg was intravenously administered as a rescue analgesic on the basis of the requirements of the children's care giver or pain score of more than 3.
Collected data included gender, age, weight, height, duration of anesthesia and operation, occurrence of postoperative vomiting (POV), pain severity, and number of patients who were administered with rescue antiemetic or analgesic. Recovery time (from discontinuation of anesthetics to awakening or eye opening with physical activities) was recorded.
Statistical analysis
We used the Student t-test and chi-square test or Fisher's exact test for comparison of mean data and dichotomous data, respectively. For further analysis of the incidence of vomiting and pain score by the measuring time (0-2, 2-6, 6-12 and 12-24 hr), we also used a generalized linear mixed model (GLMM) for repeated measure vomiting (applied with binomial response distribution and logit link function) and a linear mixed model (LMM) for a repeated pain measure score. A P value of less than 0.05 was considered significant. Statistical analysis was performed with Sigma stat v3.0 (Systat software, San Jose, Ca, USA) and a proc glimmix and proc mixed program (SAS 9.2 for Windows, SAS Institute Inc., Cary, NC, USA).
Results
In comparison of demographic data between the two groups, patients of Group D weighed less than those of Group DP (27.3 kg vs. 34.7 kg, P = 0.042). Otherwise, there were no differences between the two groups in demographic data. Recovery time from anesthesia, fentanyl consumption dose, and patient number who required rescue analgesic and antiemetic were not different between the two groups (Table 1). No patients showed oxygen desaturation of SpO2 < 90% during the recovery period and at PACU.
The Fisher's exact test showed no difference of incidence of POV between two groups at any measured intervals with the overall incidence of POV of 53.3% in both groups during 24 hours. GLMM analysis revealed that the incidence of vomiting during the postoperative 0-2 hr was lower than that during the 6-12 hr (P < 0.05) as a factor of measured time regardless of group, but the interactive effect between groups and measured time was also insignificant (P > 0.05).
Postoperative pain scores during 0-2 and 2-6 hr were higher than those during 12-24 hr in both groups (P = 0.001) but did not differ between the two groups at measured intervals (Fig. 2).
Discussion
Our study failed to observe that adjuvant use of propofol 0.5 mg/kg would increase the antiemetic effect of dexamethasone in pediatric moyamoya patients who underwent EDAS surgery under intraoperative use of sevoflurane and remifentanil and received fentanyl based postoperative analgesia.
Moyamoya disease is diagnosed with unique cerebral angiographic findings frequently accompanied with transient ischemic attacks or seizures. The nature of this disease is progressive, and neovascularization procedures such as direct or indirect vascular bypass surgery prevent further aggravation and improve the occurrence of neurologic symptoms. Since the postoperative neurologic deterioration may be related with dynamic changes in bypassed vasculatures [1], postoperative care for adequate pain and PONV control is critically important. For high risk patients to PONV, multiple drug combinations with dexamethasone, dimenhydrinate, perphenazine, and serotonin type 3 receptor antagonists has been suggested to prevent postoperative emesis [20]. Nevertheless, ondansetron, a class of serotonin type 3 receptor antagonists, seems to be very effective in non-neurosurgical cases, it is still controversial for neurosurgical patients [9,11]. On the other hand, propofol was suggested as another candidate for drug combinations with dexamethasone to prevent postoperative emesis in some circumstances [16-18], especially during immediate postoperative periods rather than delayed periods. Therefore, we hypothesized that adjuvant use of propofol 0.5 mg/kg to prophylactic dexamethasone might reduce the incidence of POV further, especially during immediate postoperative periods, in pediatric moyamoya disease undergoing bypass surgery. This study must be the first report on the incidence of POV for them. The enrolled patients belong to a very high risk category of POV because of many well known risk factors or conditions; status as children, using sevoflurane and remifentanil in anesthetic maintenance, using fentanyl as postoperative analgesia, and undergoing craniotomy. The overall incidence of POV during 24 hours in our moyamoya patients was 53.3% regardless of groups (Table 2) and was slightly lower than 66% of incidence in children undergoing craniotomy [11] probably due to less severe and shorter surgical procedures in spite of the fact that postoperative use of opioids would affect the incidence of POV in a dose-dependent manner [21]. We found similar requirements of rescue antiemetic and POV incidence at any measured intervals between the two groups with Fisher's exact test. Contrary to previous studies which showed the antiemetic effect of a small dose of propofol combined with dexamethasone [16-18] in some clinical situations, our patients differ from them in some aspects; undergoing neurosurgery, being pediatric patients, and receiving fentanyl as postoperative analgesia. Even though that risk factors of postoperative emesis relating to surgical anesthesia and analgesia such as use of sevoflurane and remifentanil for anesthetic maintenance and fentanyl as postoperative analgesia would contribute independently to postoperative nausea and vomiting according to postoperative periods [5], it is uncertain whether small dose of propofol would potentiate the fentanyl induced vomiting during postoperative 0-6 hours (Table 2) because propofol 0.5 mg/kg combined with dexamethasone 4 mg showed an antiemetic effect during postoperative 0-4 hours but not thereafter after middle ear surgery [17]. But in a later study, they compared propofol and dexamethasone with the placebo group and the patients were neurologically intact adults and had not received fentanyl as postoperative analgesia. With GLMM analysis, in spite of insignificant interaction effects between groups and the time factor, POV occurred less during early postoperative periods. Contrary to our expectations, there was rather a tendency for more patients of group DP than of group D vomited during the postoperative 0-6 hours and reversed thereafter (Table 2). It was hard to explain the reasons behind this postoperative vomiting tendency. Therefore, while seeking multi-antiemetic interventions should be maintained for high risk pediatric neurosurgical patients, the reduction of postoperative opioid doses by adding non-opioids such as non steroidal antiinflammatory agents [22] or by applying scalp nerve blocks [23] also needs to be considered.
Our study has some limitations. First, even though moyamoya disease is uncommon, our sample size may be too small to completely exclude any beneficial effect of small doses of propofol . According to the incidence of POV during early postoperative periods (0-6 hours), a post-hoc power analysis showed 55% power to validate our results and a minimum of 25 patients per group would be required to exclude the possible beneficial effect of propofol (Type II error). Therefore , this study may provide clinical significance as a pilot study. Second, we did not measure the plasma concentration of propofol to show the relationship between plasma concentration of propofol and its antiemetic effect because an antiemetic effect of propofol was shown at a plasma concentration of 343 ng/ml which was possible to reach with a bolus dose of 10 mg followed by an infusion of 10 mg/kg/min in adults [24]. In this study, the dose of propofol might be too small to achieve plasma concentration to show its antiemetic effect because the awakening time was not different between the two groups. But multimodal regimens with a higher bolus dose or infusion of propofol combined with dexamethasome may not be appropriate because the antiemetic effect of subhypnotic propofol was associated with prolonged orientation time [15], Third, we did not measure the effect of propofol on nausea because it is not easy to measure the incidence of nausea in pediatric patients. Because the exact mechanisms of postoperative nausea and vomiting associated with separate risk factors are unclear and unrelated with each other, we could not exclude any favorable effect toward postoperative nausea in these patients. Forth, Lejus et al. [25] recently published three independent risk factors of POV (female, urological surgery and age of older than 3 years) in non-neurosurgical pediatric patients receiving continuous intravenous morphine. In this study, patients of Group D weighed less than those of Group DP (27.3 kg vs. 34.7 kg, P = 0.042), perhaps due to a slightly younger group in D patients (8.1 yr vs. 10.0 yr, P = 0.052). However this would not influence the results. Even though there were no differences in sex distribution and mean age between the two groups in demographic data (Table 1) and similar sexual distribution at each measured interval between groups (Table 2) perhaps due to the small size of enrolled patients, we could not measure the exact impact of the sex distributions of ages over puberty in our results.
In conclusion, the administration of small doses of propofol combined with dexamethasone during dural closure is not more effective than dexamethasone alone for the prevention of postoperative vomiting in pediatric moyamoya surgical patients receiving fentanyl as a postoperative analgesic. However further study with a large sample size may be needed.
Acknowledgments
Authors thanks to Hye Sun Lee, Biostatistician, Biostatistics Collaboration Unit for the assistance of statistical analysis.
Notes
This article is a Master's Thesis by Jeongmin Kim.