Background
The overall incidence of postoperative nausea and vomiting (PONV) is around 30% and as great as 70% to 80% in high-risk individuals [
1]. For patients undergoing neurosurgery the PONV incidence is about 50% to 80%. Indicators for increased risk of PONV with craniotomy surgery includes: infratentorial lesion, female gender and children older than 2 years of age [
2]. Although PONV is rarely fatal, it does increase morbidity by threatening wound dehiscence, hematoma formation, aspiration, esophageal rupture, dehydration, and increases in intraocular and intracranial pressures due to acute blood pressure elevations [
1]. In addition, patients in the early postoperative period after craniotomy surgery experiencing hypertension have an increased mortality if they develop intracranial hemorrhage [
3]. Multiple willingness to pay studies have shown that patients desire most to avoid pain and nausea or vomiting, and this has over-ridden even the fear of a catastrophic anesthetic outcome [
4,
5]. Research shows patients are willing to pay $100 out of pocket to prevent nausea and vomiting [
6]. Therefore, PONV results in patient discomfort and dissatisfaction, the need for a larger nurse-to-patient ratio, increased post-anesthesia care unit (PACU) times, unintended admissions, extended postoperative stays and increased overall healthcare costs [
1].
PONV risk can be predicted from three characteristics: the patient, the procedure and the pharmacotherapy/anesthesia technique. The patient qualities that increase PONV risk are: female gender (after puberty), younger age (which tapers after puberty), non-smoking status, obesity, anxiety, and a history of PONV/motion sickness [
1]. Length of surgery increases the incidence by approximately 60% from baseline for each 30 minutes of operative time [
1]. Surgical procedures that increase risk include: plastic surgery/breast augmentation, middle ear, tonsillectomy, strabismus, laparoscopic, gynecological, and neurosurgery (particularly infratentorial craniotomies) [
1,
2]. Anesthesia techniques can augment PONV outcomes. General anesthesia increases risk of PONV 11-fold compared with regional anesthesia [
1]. Likewise, less PONV is associated with awake craniotomy compared to general anesthesia [
7]. Induction and maintenance of anesthesia with propofol and/or avoiding inhalational anesthetics reduces PONV. Presurgical hydration with 15 to 20 ml/kg of crystalloid can reduce the incidence of PONV. Neuromuscular reversal with neostigmine, especially in doses greater than 2.5 mg can cause PONV. Avoiding opioids and using alternative modalities for analgesia (that is, non-steroidal anti-inflammatory drugs (NSAIDs) such as acetaminophen and ibuprofen) can reduce the risk of PONV. Oxygen supplementation during the intraoperative period can cut the risk of PONV by half [
1]. A PONV risk factor chart was developed by Apfel
et al. in 1999, identifying four main risks: female gender, non-smoker, history of PONV, and the use of perioperative opioids [
8]. The presence of zero, one, two, three, or four of these risk factors equates to 10%, 20%, 40%, 60%, and 80% risk of PONV, respectively [
8]. The general consensus is to prophylactically treat those patients with moderate to high risk for PONV [
9].
Despite these findings, PONV is still a common complication of anesthesia and the number one cause of unanticipated admission after surgery [
1,
10]. Emesis pathophysiology is multifactorial, incited by drugs, environment, radiation and disease states [
11,
12]. The act of vomiting is controlled by multiple areas within the central nervous system (CNS), including the medulla, vestibular apparatus, and cerebral cortex [
12]. The medulla contains the area postrema (AP), the dorsal motor nucleus of the vagus, and the nucleus tractussolitarius (NTS), collectively referred to as the ‘emesis center’. Additionally, the vestibular apparatus feeds auditory stimuli and positional changes into the vomiting center, while cortical structures allow emotions, tastes, sights and smells to play a role [
11]. Numerous signals must arrive at the emesis center in an appropriate sequence to stimulate emesis [
12]. When these stimuli converge, outputs activate the lower esophageal sphincter (LES) and stomach, sympathetic ganglia, respiration, swallowing, and baroreceptors. The resulting sensation of nausea is thought to originate in the cerebral cortex. Vomiting is a complex process that empties the gastrointestinal tract by retrograde phasic contractions [
12]. At least 17 neurotransmitters have been detected in the AP and NTS.
Specific receptors including opioid, dopamine, histamine, cannabinoid, serotonin, acetylcholine, and neurokinin 1 (NK-1) are associated with the vomiting reflex [
12]. Therapeutic options have been aimed at blocking or augmenting many of these receptors. The first class of antiemetics is dopamine antagonists of which metoclopramide and droperidol are examples. Metoclopramide (Reglan), a prokinetic agent that increases muscle tone of the lower esophagus sphincter and enhance gastric emptying, is likely to cause nervous system side effects such as jitteriness, insomnia, sedation, or anxiety with large doses. Droperidol, a very effective antiemetic, received a US Food and Drug Administration (FDA) ‘black box’ warning due to potential life threatening arrhythmias and clinically relevant prolongation of the QTc interval at high doses [
1,
13]. Antihistamines (that is, promethazine, cycline, hydroxyzine, and diphenhydramine) block histamine receptors in the vomiting center, but frequently cause sedation and dry mouth. Anticholinergic scopolamine patches have the ability to prevent emesis for up to 72 h, but frequently cause sedation, blurred vision, dry mouth and confusion [
6,
14]. Serotonin antagonists (that is, ondansetron, dolasetron, and granisetron) are most effective when given towards the end of surgery, though rare side effects include headache, constipation and increased liver enzymes [
1,
14]. The anti-inflammatory agent dexamethasone a synthetic adrenocortical steroid, used prophylactically before the induction of anesthesia appears to be an effective antiemetic. Side effects similar to chronic steroid use, adrenal insufficiency and immunosuppression, have not been associated with a single dose [
1,
15].
For those patients at moderate to high risk, combination therapy has shown to be more efficacious for PONV prophylaxis. A common triple therapy regimen includes droperidol, promethazine, and dexamethasone, which allows smaller doses to be as effective when dosed together [
1]. Triple therapy practice was affected by the increased warnings and contraindications for droperidol issued by the FDA. Droperidol is not currently recommended or used in standard combination therapy for PONV. Furthermore, PONV can occur up to 5 days after surgery, and most antiemetic therapy would need frequent redosing [
14].
A future approach to preventing PONV is blockade of substance P and NK-1 receptors. Substance P, named for the powdered product discovered by Gaddum and Schild, has been studied since the early 1900s [
16]. Current research has established substance P as a prominent neurotransmitter released from both the CNS and the peripheral nervous system (PNS) afferent neurons. Substance P interacts with NK receptors, which are rhodopsin-like structures coupled to G-proteins. This interaction of neurotransmitter and receptor is involved in many disease processes including: asthma, chronic bronchitis, inflammatory bowel disease, cystitis, migraines, seizures, pain, depression, and emesis [
16]. Substance P activity occurs at primary sensory neurons in the PNS, and produces an inflammatory reaction referred to as neurogenic inflammation.
More recent research is targeting the relationship between substance P and the CNS. Animal studies demonstrated that application of substance P to the emesis center induced vomiting. Substance P is likely involved in decreasing gastric pressures, slowing antral motility and relaxing the LES, all involved in the act of regurgitation [
12]. Few human trials exist examining NK-1 antagonists in the prevention of PONV, showing a decreased incidence. Of further interest, the NK-1 antagonist aprepitant may have antiemetic effects as far out from surgery as 48 h, important with post-discharge nausea and vomiting and opioid induced emesis [
14,
17]. The FDA-approved aprepitant, an oral NK-1 antagonist, for treatment and prevention of cisplatin-induced nausea and vomiting.
Methods
We conducted a randomized, double-blind, double-dummy, parallel-group, single-center study of high risk for PONV patients to investigate the administration of triple antiemetic prophylactic therapy. The objective of this study was to compare and evaluate the efficacies of aprepitant versus ondansetron for prophylactic combination therapy in preventing nausea and vomiting in neurosurgery patients. The safety of the two triple therapies in these patients was also assessed.
The standard PONV prophylaxis regimen for high-risk patients at Ohio State University Medical Center (OSUMC) consists of dexamethasone, promethazine, and ondansetron. In this study, we used a double-dummy design to substitute aprepitant for ondansetron in a 1:1 ratio to determine the relative efficacies of these two drugs in combination therapy. The study groups were compared for the number of patients that develop PONV, the number and total dose of rescue from PONV medications given postoperatively, and patient satisfaction with their treatment. We hypothesized a significantly greater percentage of neurosurgery patients will experience no vomiting during the immediate 48-h postoperative period in the prophylactic aprepitant triple therapy group.
Adult patients, 18 to 85 years of age, scheduled for neurosurgery requiring opening of the cranium and dura at OSUMC and who consent in writing to participate in this study were eligible. Patients who were (1) prisoners, (2) pregnant women, (3) mentally ill, (4) under the age of 18 or over the age of 85, (5) graded as American Society of Anesthesiologists (ASA) classification V (6) alcohol or drug abusers or (7) had a cerebral perfusion pressure (CPP) greater than 150 mmHg or less than 50 mmHg were excluded from this study.
After receiving approval from The Ohio State University institutional review board, 176 consecutive patients who meet the inclusion and exclusion criteria and who give written informed consent to participate in the study were randomly assigned by the research pharmacist to 1 of 2 experimental groups using a 1:1 ratio. All study personnel were blinded to group assignment. Patients in group I received 25 mg promethazine intravenously, 10 mg dexamethasone intravenously, 4 mg ondansetron intravenously, and an inactive oral dummy pill. Patients in group II received 25 mg promethazine intravenously, 10 mg dexamethasone intravenously, 40 mg aprepitant orally, and an inactive dummy intravenous injection. Thus, all patients received 25 mg promethazine and 10 mg dexamethasone. Because this is a double-blind, double-dummy study and ondansetron was given intravenously whereas aprepitant was given orally, it was necessary to give patients an oral or intravenous placebo, depending on their group assignment, for uniformity and to maintain the double-blindedness. This study does not contain a placebo arm, though dummy treatment using placebo was necessary due to the different routes of medications. Therefore, each patient received the three drugs in the PONV prophylactic triple cocktail, plus an intravenous or oral dummy treatment prior to induction of anesthesia (Table
1). Funding for these medications was provided internally, through the Department of Anesthesiology.and preoperative data about each patient in the two groups were recorded (Table
2). The duration of each surgery (anesthesia time) will be recorded for each patient. Patients were continuously monitored in the PACU, surgical intensive care unit (SICU) and the medical floor for a total of 120 h postoperatively. Episodes of nausea, vomiting and administration of rescue therapy for either nausea or vomiting were recorded and time stamped by blinded personnel. In addition, the severity of the nausea or vomiting was recorded. Nausea will be reported by the patient and evaluated by the blinded personnel utilizing a standard verbal response scale (VRS) ranging from 0 to 10, 0 being no nausea and 10 being severe nausea. Vomiting will be evaluated numerically by the blinded personnel as either 0, no vomiting, 1, mild vomiting, 2, moderate vomiting, or 3, severe vomiting. Rescue therapy for PONV episodes consisted of 4 mg ondansetron. After the first 24 h of starting the triple therapy antiemetic, an electrocardiogram (ECG) was recorded as well as blood drawn for analysis.
Table 1
Postoperative nausea and vomiting (PONV) medications and administration
Preoperative PONV medications: |
4 mg ondansetron intravenously + placebo PO | 40 mg aprepitant PO + intravenous placebo |
25 mg Promethazine intravenous | 25 mg Promethazine intravenous |
10 mg dexamethasone intravenous | 10 mg dexamethasone intravenous |
Postoperative PONV rescue therapy: |
Multiple 4 mg ondansetron | Multiple 4 mg ondansetron |
Table 2
Demographic and preoperative data
Gender | Systolic, diastolic and median blood pressure |
Age | Electrocardiography (ECG) recording |
History of postoperative nausea and vomiting (PONV) | Anesthesia modality |
Surgery | Renal function |
Smoking history | Hepatic function |
Race | Cerebral perfusion pressure (CPP) |
Motion sickness history | |
Past reactions to the study drugs | |
Efficacy variables
Efficacy variables were collected based on previously designed PONV studies [
18,
19]. The primary efficacy variable is the percentage of patients with no vomiting over 0 to 72 h postoperatively across the two treatment groups.
The secondary efficacy variables are as follows: (1) proportion of patients with a complete response during delayed (24 to 120 h; days 2 to 5) and overall (0 to 120 h; days 1 to 5) after neurological surgery and general anesthesia; (2) proportion of patients with complete control, defined as no emetic episode, no need for rescue medication and no more than mild nausea overall (0 to 120 h; days 1 to 5) after neurological surgery and general anesthesia; (3) assessment of the severity of nausea and vomiting during acute (0 to 24 h), delayed (24 to 120 h) and overall (0 to 120 h) intervals after neurological surgery and general anesthesia; (4) assessment of the time to treatment failure (defined as time to first emetic episode and/or to first use of rescue medication); (5) assessment of the time to first emetic episode; (6) assessment the time to significant nausea (defined as nausea rated ≥4 on a 0 to 10 verbal response scale or nausea that required rescue therapy).
The incidence of any adverse reaction to treatment in our two experimental groups was recorded. In the ondansetron-treated patients (group I), all cardiovascular, gastrointestinal, hepatic, integumentary and neurologic postoperative adverse events was recorded and analyzed for cause. For instance, treatment-related diarrhea, headaches, fever, akathisia and acute dystonic reactions was also recorded and analyzed. Similarly, in the aprepitant patients (group II) all adverse events related to the digestive, hemic, lymphatic, nervous, cardiovascular and respiratory systems was recorded and analyzed for cause.
Statistical methods
From Gan
et al. [
18] who compared the use of aprepitant 40 mg to ondansetron 4 mg in a similar PONV study involving patients undergoing open abdominal surgeries and an overnight hospitalization, 85% of the patients experienced no vomiting to aprepitant treatment and 67% to ondansetron treatment. For a two-sided test to compare the two proportions at 0.05 significance level, we need n = 88 per group to achieve 80% power. We sought n = 100 subjects per group to account for screening and attrition in the study.
The efficacy data was analyzed based on the intention-to-treat principal. Demographic and other patient characteristics for all randomized patients were reported by descriptive statistics, such as: mean, standard deviation, and so on. Also, we examined the comparability of the two treatment groups with respect to important preoperative factors. Logistic regression was used to test the primary hypothesis with demographic characteristics as potential covariates in the model. For the number of rescue therapy treatments used during the 120-h postoperative period, Wilcoxon rank sum test was performed. For other secondary endpoints, the analysis plan was similar to the one for the primary endpoint. Standard safety assessments included adverse event reports, physical and laboratory data, awakening time and duration of recovery from anesthesia.
SB received a MD degree from the National University of Cordoba, Argentina in 1988. In 1991, he completed an internship in the Department of Surgery at the Italian Hospital in Cordoba, Argentina. From 1992 to 1997, SB worked as a Research Associate in the Department of Surgery, Division of Transplantation at The Ohio State University where he completed a fellowship in Cellular Immunology and Vascular Biology. He proceeded to do a residency in general surgery, and later completed his residency in the Department of Anesthesia at The Ohio State University. In 2008, he obtained a Certificate of Business Administration. Presently, he is Associate Professor, Director of Neuroanesthesia and the Neuroanesthesia Fellowship, and Director of Clinical and Neurological Research in the Department of Anesthesia at The Ohio State University. SB’s main research interests and expertise are neuroanesthesia, anesthesia monitoring, and mitigation of risks and discomforts associated with anesthesia. As director of a relatively large clinical trials research group, SB has mentored numerous research and neuroanesthesia fellows and currently oversees more than 50 projects in the areas of anesthesia, neurosurgery, general surgery, and critical care. In 2006, he was selected as America’s Top Anesthesiologist. He is an active member of the ASA, SNACC, IARS, SAMBA, and ASRA. SB also serves on the editorial board of several journals including the Journal of Neurosurgical Anesthesiology, World Journal of Anesthesiology and International Journal of Medicine. He has been a faculty at more than 50 national and international meetings, where he has presented over 200 lectures. SB also has over 40 publications and over 150 abstracts presented at national and international conferences.
Competing interests
The authors declare that they have no competing interests to report.
Authors’ contributions
SB, the principal investigator, designed the current study, drafted the manuscript, oversaw revisions, and gave final approval on all aspects of the study. AV, AU, AA, and SF were involved with the acquisition of data, drafting and revision of the manuscript, analysis and interpretation of available results. All authors read and approved the final manuscript