Postoperative nausea and vomiting (PONV) is a common adverse effect following surgery and general anesthesia, characterized by nausea (a subjective unpleasant sensation associated with the urge to vomit) and/or vomiting (forceful expulsion of gastric contents) occurring within the first 24 to 48 hours postoperatively.[1] It affects approximately 25-30% of patients overall without prophylaxis and up to 80% in high-risk populations, making it one of the most frequent postoperative complications.[2] PONV not only causes significant patient discomfort and dissatisfaction but also contributes to prolonged recovery times, increased risk of aspiration, dehydration, electrolyte disturbances, and potential surgical complications such as wound dehiscence.[1] Despite advances in antiemetic therapies, it remains a major challenge in perioperative care, with economic implications including higher healthcare costs due to extended hospital stays.[3]The etiology of PONV is multifactorial, involving interactions between the central nervous system, gastrointestinal tract, and vestibular apparatus, primarily triggered by the activation of the chemoreceptor trigger zone in the medulla oblongata.[1] Anesthetic agents such as volatile inhalational anesthetics (e.g., sevoflurane, desflurane) and nitrous oxide, along with postoperative opioids, are key pharmacological contributors, as they stimulate emetogenic pathways via neurotransmitters including serotonin (5-HT3), dopamine, and substance P.[3] Surgical factors, including the type and duration of procedure—such as intra-abdominal, gynecological, or ear-nose-throat surgeries—further exacerbate risk, with longer anesthesia times increasing incidence by about 60% for every additional 30 minutes.[3] Patient-specific elements also play a critical role, with well-established risk factors including female gender, nonsmoker status, younger age (middle-aged adults), history of PONV or motion sickness, and use of postoperative opioids.[1] These factors are often quantified using scoring systems like the Apfel score, which predicts PONV risk based on four independent predictors: female sex, nonsmoking, history of PONV/motion sickness, and opioid use.[4]Prevention and management of PONV emphasize multimodal approaches, as single interventions are often insufficient for high-risk patients.[1] Guidelines from organizations like the Society for Ambulatory Anesthesia and the 2025 Consensus Guidelines recommend risk stratification and prophylactic antiemetics such as 5-HT3 receptor antagonists (e.g., ondansetron), corticosteroids (e.g., dexamethasone), and neurokinin-1 antagonists (e.g., aprepitant), which can reduce incidence by 20-30% when combined.[3][5] Non-pharmacological strategies, including the use of propofol-based total intravenous anesthesia, avoidance of nitrous oxide, and acupressure at the P6 point, further support effective prophylaxis.[1] Ongoing research focuses on personalized medicine and novel agents to minimize PONV, highlighting its persistent relevance in improving surgical outcomes and patient experience.[6]
Overview and Epidemiology
Definition and Clinical Features
Postoperative nausea and vomiting (PONV) is defined as any nausea, retching, or vomiting that occurs within 24 to 48 hours after surgery in patients who have received anesthesia.[7][1] This condition is a frequent postoperative complication that can lead to significant patient discomfort and dissatisfaction.[1]Clinically, PONV manifests through distinct yet interrelated symptoms. Nausea is characterized as a subjective, unpleasant sensation in the back of the throat or epigastric area, often accompanied by an urge to vomit but without actual expulsion of gastric contents; it may also provoke autonomic responses such as pallor, diaphoresis, or salivation.[1][7]Retching involves labored, spasmodic, and involuntary contractions of the abdominal and thoracic muscles in an attempt to vomit, yet without the ejection of stomach contents.[7][8]Vomiting, the most overt feature, entails the forceful expulsion of gastric contents through the mouth, potentially resulting in physiological effects like transient hypertension, tachycardia, or bradycardia due to the Valsalva maneuver.[1] Associated symptoms can include dizziness, anxiety, tachycardia, tachypnea, sweating, and elevated intrathoracic or intracranial pressure.[1]The timing of PONV is classified into early and delayed phases to guide clinical observation. Early PONV arises within the first 6 hours postoperatively, often in the postanesthesia care unit, while delayed PONV emerges beyond 6 hours and may extend up to 48 hours after surgery.[9][8]Diagnosis relies primarily on clinical assessment, including patient self-report of symptoms and direct observation of retching or vomiting; no laboratory tests or imaging are routinely required, though evaluation may involve excluding other causes through history and vital signs monitoring.[1][7]Historically, PONV was first described as a common adverse effect in the mid-19th century, coinciding with the advent of general anesthesia in the 1840s, when ether and chloroform were introduced into surgical practice.[10]
Incidence and Clinical Impact
Postoperative nausea and vomiting (PONV) affects approximately 20-30% of patients undergoing surgery under general anesthesia.[11] In high-risk populations, such as those with multiple predisposing factors, the incidence can rise to as high as 80%.[12] The prevalence varies significantly by surgical procedure; for instance, laparoscopic surgeries are associated with rates of 40-80%, while breast surgeries exhibit incidences around 40-50%.[13][14]PONV is a leading cause of patient dissatisfaction following surgery, often ranked by patients as one of the most undesirable postoperative outcomes, surpassing even pain in some surveys.[15] It contributes to prolonged stays in the post-anesthesia care unit (PACU), with affected patients experiencing an average extension of 20-25% in recovery time, or approximately 25 minutes to one hour longer per episode.[16][17] This delay not only hampers early ambulation and oral intake but also elevates the risk of complications such as aspiration, dehydration, wound dehiscence, and pulmonary issues.[1]Although mortality directly attributable to PONV is rare, severe cases can lead to life-threatening events like aspiration pneumonia.[18] Economically, PONV imposes a substantial burden on healthcare systems, with additional costs per affected patient estimated at $75-100 in the United States, primarily due to extended resource utilization and treatment needs.[19] Furthermore, it is linked to higher readmission rates of 1-2%, particularly in procedures like bariatric surgery, thereby impacting overall quality of life and postoperative recovery trajectories.[20][8]
Etiology and Risk Factors
Primary Causes
Postoperative nausea and vomiting (PONV) arises primarily from direct emetogenic stimuli during the perioperative period, stemming from anesthetic, surgical, and immediate postoperative events. Anesthetic agents are among the most potent triggers, with volatile inhalational anesthetics such as isoflurane, sevoflurane, and desflurane directly stimulating the chemoreceptor trigger zone (CTZ) in the area postrema of the brainstem, thereby activating central emetic pathways.[21] These agents also promote serotonin release from enterochromaffin cells in the gastrointestinal tract, enhancing peripheral inputs to the vomiting center.[1] Opioids, including fentanyl and morphine, contribute significantly by activating mu-opioid receptors in the brainstem and CTZ, which delays gastric emptying, reduces gastrointestinal motility, and heightens vestibular sensitivity to motion.[22]Nitrous oxide further amplifies risk through diffusion into the bowel lumen and middle ear, causing visceral distension and vestibular disturbances that provoke nausea.[21]Surgical interventions introduce additional direct causes by mechanically perturbing emetogenic sites. Manipulation of intra-abdominal viscera, as occurs during laparoscopy or gynecological procedures, irritates the peritoneum and serosal surfaces, stimulating vagal afferent nerves and eliciting reflex emesis.[22] Intraoperative hypotension and hypoxia, often resulting from fluid shifts, blood loss, or ventilatory challenges, are associated with an increased risk of postoperative nausea.[1]Postoperative triggers perpetuate these effects through ongoing physiological stresses. Uncontrolled pain activates nociceptive pathways that converge with emetic circuits in the brainstem, while ambulation induces orthostatic changes and vestibular stimulation, particularly in opioid-exposed patients.[21] Early oral intake can similarly irritate the pharynx and stimulate vagal afferents from the upper gastrointestinal tract, compounding nausea.[22]The multifactorial etiology of PONV reflects the synergistic interaction of these stimuli with both central and peripheral emetic pathways, where anesthetic and surgical insults prime the system for postoperative decompensation, leading to notably higher incidence in prolonged or intra-abdominal operations.[1]
Categories of Risk Factors
Risk factors for postoperative nausea and vomiting (PONV) are typically categorized into patient-related, anesthesia-related, and procedure-related factors, with additional contributions from genetic predispositions. These categories help in identifying patients at elevated risk, allowing for targeted preventive measures.31636-7/fulltext)Patient-related factors include demographic and historical elements that independently increase PONV susceptibility. Female sex is a prominent risk, conferring 2-4 times higher odds compared to males, largely attributed to estrogen fluctuations that enhance emetogenic sensitivity.[23] A history of motion sickness or prior PONV elevates risk approximately threefold, reflecting inherent vulnerability in the vomiting reflex.[24] Non-smoker status roughly doubles the risk (odds ratio ≈2.0), possibly due to lack of nicotine-induced desensitization of emetic pathways.[25] Younger age, particularly under 50 years, is associated with higher incidence, as metabolic and neural responses to anesthetics are more pronounced in this group.[26] Certain comorbidities, such as migraines or pregnancy, further amplify risk through overlapping neurochemical mechanisms like serotonin dysregulation.[9]Anesthesia-related factors stem from agents and techniques that directly provoke emesis. Use of nitrous oxide increases PONV odds by about 1.5 times, linked to its expansion of middle ear pressure and gastrointestinal gases.[27] Administration of long-acting opioids heightens risk in a dose-dependent manner by stimulating mu-opioid receptors in the chemoreceptor trigger zone.[28] In contrast, total intravenous anesthesia (TIVA) with propofol reduces PONV incidence compared to volatile anesthetics, as propofol lacks the emetogenic properties of inhalational agents like isoflurane.[29]Procedure-related factors involve surgical characteristics that influence emetic stimuli. Operations lasting over one hour elevate risk, with each additional hour incrementally heightening exposure to anesthetics and tissue manipulation.[30] Certain surgery types, such as strabismus correction or gynecologic procedures, carry notably higher PONV rates due to direct vestibular or intra-abdominal irritation.[31]The Apfel simplified risk score provides a practical tool for stratifying PONV probability using four key patient- and anesthesia-related predictors: female sex, non-smoker status, history of PONV or motion sickness, and postoperative opioid use. Each factor scores one point; corresponding risks are approximately 10% (0 points), 20% (1 point), 40% (2 points), 60% (3 points), and 80% (4 points).[24]Emerging research highlights genetic factors, particularly polymorphisms in serotonin (5-HT3) receptor genes like HTR3A and HTR3B, which may underlie individual susceptibility to PONV by altering receptor function and antiemetic response.[32]
Pathophysiology
Neural Mechanisms
The vomiting center, located in the medulla oblongata, serves as the primary coordination site for the emetic response in postoperative nausea and vomiting (PONV). It consists of interconnected neurons that form a central pattern generator, integrating sensory inputs to orchestrate the sequential motor actions of vomiting. The nucleus tractus solitarius (NTS), a key component within this center, receives and processes afferent signals from multiple sources, including the chemoreceptor trigger zone (CTZ), vestibular apparatus, and vagal nerves, thereby facilitating the neural coordination of nausea and emesis.[33][7]The area postrema, situated at the floor of the fourth ventricle adjacent to the NTS, functions as the CTZ due to its lack of a robust blood-brain barrier, allowing direct detection of circulating emetogens such as anesthetic agents and toxins. This structure relays emetogenic signals to the NTS and other medullary nuclei, amplifying the central emetic response in PONV. The emetic reflex arc begins with peripheral afferent inputs, primarily via vagal nerve fibers from gastrointestinal mechanoreceptors and chemoreceptors sensing surgical irritation or delayed motility. These signals converge on the NTS, which then activates efferent pathways involving the phrenic nerve for diaphragmatic contraction, cranial nerves V, VII, IX, X, and XII for upper gastrointestinal and oral coordination, and spinal nerves for abdominal muscle engagement, culminating in the expulsive act of vomiting.[34][33][7]Early PONV, occurring within the first 2-6 hours postoperatively, is predominantly mediated by central mechanisms, where volatile anesthetics directly stimulate the CTZ and NTS, triggering rapid emetic activation. In contrast, delayed PONV, occurring 6-24 hours postoperatively, involves more peripheral influences, such as opioid-induced alterations in gut motility that activate vagal afferents, alongside sustained CTZ sensitivity to postoperative analgesics. Animal models, particularly in ferrets and musk shrews, have elucidated these pathways; for instance, ferrets exposed to isoflurane and morphine exhibit emetic behaviors mirroring human PONV, highlighting the role of vagal and hindbrain circuits in anesthetic- and opioid-induced emesis. Similarly, shrew studies demonstrate reproducible vomiting reflexes to surgical stressors, providing insights into NTS integration without a blood-brain barrier confound.[33][35]
Receptor and Pathway Involvement
Serotonin 5-HT3 receptors are pivotal in the pathophysiology of postoperative nausea and vomiting (PONV), predominantly expressed on vagal afferent terminals in the gastrointestinal mucosa and within the chemoreceptor trigger zone (CTZ). These receptors are activated by serotonin release from enterochromaffin cells, which occurs in response to surgical gut distension, anesthetics, or opioids, initiating afferent signals that converge on the nucleus tractus solitarius (NTS) to elicit the emetic reflex.[36][6]Dopamine D2 receptors, located primarily in the CTZ and NTS, mediate emetic signaling by coupling to Gi/o proteins, which inhibit adenylate cyclase and reduce intracellular cyclic AMP levels, thereby disinhibiting neuronal activity in the vomiting center. This pathway is particularly relevant in PONV triggered by central emetogenic stimuli from anesthetics or opioids.[4][6]Histamine H1 receptors, found in the vestibular nucleus and NTS, contribute to nausea signals originating from the inner ear and vestibular system, especially in cases of PONV exacerbated by motion or labyrinthine disturbances during recovery. Complementing this, muscarinic M1 receptors in the area postrema and vestibular apparatus facilitate cholinergic transmission that amplifies central integration of emetic inputs, linking peripheral sensory cues to brainstem coordination.[37]Neurokinin-1 (NK1) receptors, bound by the neuropeptidesubstance P, are densely expressed in the NTS and vagal afferents, playing a critical role in both acute and delayed phases of PONV by propagating prolonged emetic signals through tachykinin pathways in the brainstem.[38]Cannabinoid CB1 receptors modulate emetic responses via inhibitory G-protein signaling in the dorsal vagal complex of the brainstem, where activation suppresses neurotransmitter release from emetogenic neurons, providing a counter-regulatory mechanism against PONV induction. Similarly, GABAergic pathways, involving GABAA and GABAB receptors in the NTS, exert tonic inhibition on emetic circuits, dampening excitability from converging afferent inputs.[39][6]Recent investigations have elucidated the involvement of transient receptor potential vanilloid 1 (TRPV1) channels in visceral afferent neurons, where their activation by inflammatory mediators or surgical trauma sensitizes nociceptive pathways, contributing to the inflammatory subset of PONV through enhanced signaling to the NTS.[40]
Prevention Strategies
Risk Assessment and Stratification
Risk assessment for postoperative nausea and vomiting (PONV) involves evaluating patient-specific, surgical, and anesthetic factors to predict the likelihood of occurrence and guide preventive strategies. Preoperative identification of at-risk individuals is essential, as PONV affects up to 30% of all surgical patients and over 80% in high-risk groups, emphasizing the need for structured tools to stratify risk levels.[41] Widely adopted models, such as the simplified Apfel score, provide a practical framework by assigning points based on key independent predictors, enabling clinicians to estimate baseline risk without complex computations.The Apfel simplified risk score, developed and validated in multicenter cohorts, assigns one point each for four major risk factors: female gender, history of PONV or motion sickness, nonsmoking status, and anticipated postoperative opioid use. The corresponding predicted PONV incidence is approximately 10% with 0 factors, 21% with 1 factor, 39% with 2 factors, 61% with 3 factors, and 79% with 4 factors. This score demonstrates good discriminatory power, with an area under the receiver operating characteristic curve of about 0.7, and has been cross-validated across diverse surgical populations for its reliability in clinical settings.[41]Enhanced risk models build on the Apfel framework by incorporating additional variables for greater precision in specific contexts. The Koivuranta score, for instance, extends the Apfel predictors by adding points for motion sickness (separate from PONV history) and surgical duration exceeding 60 minutes, resulting in risk predictions ranging from 17% (no factors) to 87% (five or more factors). Simplified checklists versus comprehensive models are often compared, with the former favored for routine use due to comparable accuracy and ease of integration into preoperative workflows.[42]Preoperative screening forms the cornerstone of risk stratification, involving targeted history taking to verify smoking status, personal or family history of PONV. This process also includes reviewing anticipated anesthetic plans, such as opioid requirements, to refine predictions. Increasingly, these assessments are integrated into electronic health records (EHRs) for automated scoring and alerts, facilitating consistent application across healthcare systems.[41]Patients with a predicted risk exceeding 40%—typically those scoring 2 or more on the Apfel scale—are classified as high-risk, prompting consideration for intensified preventive measures. Consensus guidelines recommend prophylaxis for such individuals, particularly when multiple risk factors converge, to mitigate the substantial clinical burden of PONV.[41]Despite their utility, risk assessment tools have inherent limitations, including moderate sensitivity and specificity (around 65-70%), which may overlook nuanced interactions among factors or fail to account for emerging variables like genetic predispositions. These scores predict probability but do not obviate the need for multimodal approaches, as over-reliance on any single model can lead to under- or over-treatment in heterogeneous patient populations. Ongoing validation studies underscore the importance of adapting these tools to contemporary practices, such as opioid-sparing anesthesia.[41]
Prophylactic Interventions
Prophylactic interventions for postoperative nausea and vomiting (PONV) aim to prevent its occurrence through a multimodal approach tailored to patient risk levels, incorporating both non-pharmacological and pharmacological strategies. These interventions are guided by evidence-based recommendations that emphasize reducing baselineanesthetic risks and administering antiemetics preemptively. Effective prophylaxis can significantly lower PONV incidence, particularly in moderate- to high-risk patients, by targeting underlying mechanisms such as neurotransmitter release and inflammation.Non-pharmacological strategies focus on optimizing anesthetic and perioperative management to minimize PONV triggers. Total intravenous anesthesia (TIVA) using propofol has been shown to reduce PONV risk by approximately 20-30% compared to inhalational anesthesia, due to propofol's antiemetic properties and avoidance of volatile agents.[43] Avoiding nitrous oxide is recommended, as its use increases PONV risk by about 20% per hour of exposure beyond 45 minutes, primarily through intestinal distension and emetogenic metabolites.[44] Adequate perioperative hydration with liberal fluid regimens decreases PONV incidence by around 15%, likely by improving gastrointestinal perfusion and reducing hypovolemia-related symptoms.[45] Regional anesthesia techniques are preferred over general anesthesia when feasible, as they reduce PONV risk by up to ninefold by eliminating airway manipulation and volatile anesthetics.[22]Pharmacological prophylaxis relies on antiemetics administered intravenously to block key receptors involved in the emetic pathway. First-line agents include 5-HT3 receptor antagonists such as ondansetron at a dose of 4 mg IV, which reduces PONV incidence by about 25% through serotonin blockade in the gut and central nervous system.[46]Dexamethasone, a corticosteroid with anti-inflammatory effects, is commonly used at 4-8 mg IV and achieves a 20-30% reduction in PONV, particularly when given at induction to suppress delayed emesis.[47] For enhanced efficacy, combination therapy is recommended; for example, ondansetron combined with droperidol (a dopamine antagonist) yields 40-50% overall PONV reduction by targeting multiple pathways, outperforming monotherapy in high-risk cases.[48]Timing of administration is critical for optimal prophylaxis, with antiemetics ideally given before anesthesia induction to preempt emetic stimuli. Doses should be adjusted based on risk stratification, using higher or combined regimens for patients with moderate-to-high risk (e.g., Apfel score ≥3). The Fifth Consensus Guidelines for the Management of Postoperative Nausea and Vomiting (2025) advise against routine prophylaxis in low-risk patients to avoid unnecessary medication exposure, while recommending 2 antiemetics for moderate risk (1-2 factors), and 3-4 antiemetics plus non-pharmacological mitigation for high risk (≥3 factors) in adults, achieving up to 50-60% risk reduction.[49]Certain surgical techniques also contribute to prophylaxis by altering procedural factors that provoke PONV. Gasless laparoscopy, which uses mechanical abdominal wall lifting instead of pneumoperitoneum, reduces PONV incidence compared to conventional CO2 insufflation methods, owing to less peritoneal irritation and hemodynamic instability.[50]Antiemetic acupuncture, particularly stimulation of the P6 (Neiguan) point on the wrist, shows limited but promising evidence for reducing PONV, with moderate-quality studies indicating a relative risk reduction of about 50% versus sham treatment, though it is not universally recommended as a standalone intervention.[51]
Management and Treatment
Acute Rescue Therapies
Acute rescue therapies for postoperative nausea and vomiting (PONV) emphasize immediate supportive and non-pharmacological measures to alleviate symptoms while minimizing risks such as aspiration or dehydration. Initial supportive care focuses on ensuring patient safety and comfort. Airway protection is paramount to prevent aspiration during vomiting episodes, achieved through vigilant monitoring and prompt intervention if needed. Intravenous hydration with 1-2 liters of crystalloids, such as normal saline or lactated Ringer's, is recommended for patients showing signs of dehydration, as supplemental perioperative fluids (10-30 mL/kg) have been shown to reduce the incidence of early PONV and the need for rescue antiemetics. Oral intake should be withheld until symptoms resolve to avoid exacerbating nausea, and patients are positioned supine with the head elevated 30 degrees to facilitate drainage and reduce reflux risk.[8][52][53]Non-pharmacological interventions provide adjunctive relief with low risk. Acupressure at the P6 (Neiguan) point on the wrist, applied via bands or manual pressure, offers moderate relief, reducing nausea and vomiting incidence by approximately 20-30% compared to sham treatment, with evidence supporting its use as an alternative or complement to pharmacotherapy. Ginger supplements, administered orally at a dose of 1 g, demonstrate mild efficacy in decreasing nausea severity, though the reduction in overall PONV incidence is modest and dose-dependent.[54]Aromatherapy using essential oils like peppermint or lemongrass, inhaled via cotton balls or diffusers, can shorten nausea duration and decrease the need for additional interventions, with peppermint showing particular promise as an adjunct in postoperative settings.[55][8][56][57]Ongoing monitoring is essential to assess response and detect complications. Dehydration is evaluated through vital signs (e.g., tachycardia, hypotension) and urine output (targeting at least 0.5 mL/kg/hour), with fluid balance tracked to guide rehydration. Other causes, such as ileus or opioid effects, should be ruled out via physical examination and history to ensure appropriate management. Escalation to pharmacological intervention is warranted if symptoms persist beyond two episodes or six hours despite supportive measures, as prolonged PONV increases morbidity risk. Many patients with mild symptoms experience resolution with supportive care alone, avoiding the need for further therapy.[58][8][59]
Pharmacological and Non-Pharmacological Options
Management of postoperative nausea and vomiting (PONV) after prophylaxis failure or onset primarily involves targeted antiemetic therapies from distinct pharmacological classes, alongside strategies to minimize emetogenic contributors like opioids. 5-HT3 receptor antagonists, such as ondansetron, are commonly used for rescue at a dose of 4 mg intravenously, though their efficacy is limited post-onset, with repeat dosing showing no significant benefit over placebo in controlling emesis or nausea severity.[60] Neurokinin-1 (NK1) receptor antagonists like aprepitant, administered orally at 40 mg, are effective for delayed PONV, providing prolonged symptom relief due to their extended half-life.[61] Antihistamines, including promethazine at 6.25-12.5 mg intravenously or intramuscularly, demonstrate superior efficacy for rescue compared to repeating the prophylactic agent, particularly after 5-HT3 failure, though they carry risks of sedation and dry mouth.[62][63] Dopamine antagonists such as amisulpride (5-10 mg IV) are effective for rescue treatment, especially following failure of prophylaxis with other classes, with a favorable safety profile and NNT of approximately 5 for preventing vomiting.[8]To address opioid-induced PONV, alternatives such as reduced opioid dosing combined with multimodal analgesia, or substitution with tramadol and patient-controlled analgesia (PCA) supplemented by antiemetics, help mitigate emetogenic effects while maintaining pain control.[8]Non-pharmacological adjuncts offer supportive benefits, with transcutaneous electrical acupoint stimulation at the P6 (Neiguan) point providing a 10-20% adjunctive reduction in PONV risk, serving as a safe, non-invasive option without sedation risks.[64][65]For refractory PONV, transdermal scopolamine patches (1.5 mg, lasting 72 hours) target muscarinic receptors effectively in persistent cases, while subhypnotic propofol boluses (e.g., 20-30 mg intravenously in the post-anesthesia care unit) offer rapid antiemetic action by modulating GABA receptors.[66][67]Notable side effects include QT interval prolongation with ondansetron, particularly at higher doses or in combination with other QT-prolonging agents, and significant sedation with promethazine, which may impair recovery.[68][63] The 2020 consensus guidelines emphasize selecting rescue antiemetics from a different pharmacological class than those used for prophylaxis to optimize efficacy and avoid tachyphylaxis.[8][69]
Remimazolam, an ultra-short-acting benzodiazepine used in total intravenous anesthesia (TIVA), has emerged as a promising agent for reducing postoperative nausea and vomiting (PONV). A 2025 systematic review and meta-analysis of randomized controlled trials (RCTs) demonstrated that remimazolam significantly lowered PONV incidence compared to inhalational anesthetics, achieving a relative risk reduction of approximately 49% (RR 0.51; 95% CI 0.27–0.96).[70] A subgroup analysis from an earlier meta-analysis confirmed lower PONV with remimazolam versus volatile anesthetics (RR 0.50; 95% CI 0.34–0.73).[71] These benefits stem from its targeted action on GABA_A receptors, potentially modulating the neural pathways involved in emetic signaling without the broader sedativehangover associated with longer-acting benzodiazepines.[72]Olanzapine, an atypical antipsychotic, offers efficacy against breakthrough PONV through its antagonism of dopamine D2, serotonin 5-HT2A, and other receptors implicated in emesis. Low-dose olanzapine (5 mg) has been shown in RCTs to reduce PONV incidence and severity by 38–49% in high-risk patients undergoing laparoscopic procedures.[73] An updated meta-analysis with trial sequential analysis further supported its prophylactic role, reporting a relative risk reduction of 33% (RR 0.67; 95% CI 0.56–0.80), with an approximate absolute risk reduction of 15% depending on baseline incidence, particularly when added to standard antiemetics.[74] This multi-receptor profile addresses both central and peripheral emetic triggers, making it suitable for rescue therapy in refractory cases.Tradipitant, a novel neurokinin-1 (NK1) receptor antagonist, is in late-stage development for motion sickness and gastroparesis, with potential translational applications for managing delayed PONV by blocking substance P-mediated emetic signals in the brainstem. Phase III trials completed in 2024 for motion sickness reported significant reductions in vomiting incidence (up to 50% versus placebo) and nausea severity across varied conditions.[75] A 2024 Phase III RCT in gastroparesis showed mixed results, failing the primary endpoint for nausea reduction (P=0.741) but demonstrating benefits in post-hoc analyses of subgroups with adequate drug exposure, suggesting potential for nausea alleviation. However, the FDA declined the NDA for gastroparesis in September 2024, issuing a proposal to refuse approval in January 2025.[76][77]Dexmedetomidine, an alpha-2 adrenergic agonist, serves as an adjunct infusion to mitigate PONV by decreasing opioid requirements and stabilizing autonomic responses. A 2023 meta-analysis of RCTs indicated it reduces the risk of PONV (RR 0.57; 95% CI 0.47–0.68) and perioperativeopioid consumption.[78] In bariatric surgery contexts, dexmedetomidine infusions lowered postoperative pain scores and PONV incidence without prolonging recovery.[79] Studies in neurosurgical patients have also reported reduced emetic episodes with dexmedetomidine use.[80]Recent RCTs and meta-analyses underscore these agents' roles in PONV prevention, with remimazolam highlighted in a 2025 study for its TIVA-specific advantages.[70] Cost-benefit analyses reveal savings of $50–100 per case through reduced hospital admissions and rescue interventions.[81] However, challenges include limited availability for newer drugs like remimazolam and tradipitant, off-label applications for olanzapine and dexmedetomidine in some regions, and the need for additional long-term safety data in diverse populations.[82]
Updated Guidelines and Consensus
The Fourth Consensus Guidelines for the Management of Postoperative Nausea and Vomiting, published in 2020, emphasize a risk-stratified approach to prophylaxis, recommending no routine antiemetics for low-risk patients (0-1 risk factors per Apfel score), a single agent such as a 5-HT3 antagonist or dexamethasone for moderate-risk patients (2-3 factors), and multimodal therapy with 2-3 agents from different classes (e.g., 5-HT3 antagonist, NK1 antagonist, and dexamethasone) for high-risk patients (≥4 factors).[83] For rescue treatment of established PONV, the guidelines advocate using an antiemetic from a pharmacologic class not administered prophylactically, with close monitoring to avoid over-sedation.[41] These recommendations remain the cornerstone of PONV management as of 2025, with endorsements from organizations including the European Society of Anaesthesiology and Intensive Care (ESAIC), which lists them as a key resource for evidence-based care. No new consensus guidelines have been published as of November 2025.[84]Recent updates integrate these guidelines into quality metrics and emerging technologies. The 2025 Merit-based Incentive Payment System (MIPS) Quality Measure #430 requires reporting the percentage of high-risk surgical patients (aged ≥18 years undergoing procedures under general anesthesia) who receive combination antiemetic prophylaxis (≥2 agents), aiming to promote adherence and reduce PONV incidence through structured performance tracking.[85] Additionally, machine learning models for PONV risk prediction have gained traction, outperforming traditional tools like the Apfel score by incorporating diverse variables such as electronic health record data; for instance, gradient boosting algorithms achieved AUC values of 0.77 in recent validations, enabling more precise patient stratification.[86]Evolving practices focus on ambitious targets and seamless care delivery. In ambulatory surgery centers, protocols aiming for zero PONV incidence employ expanded multimodal regimens, such as a 5-drug prophylaxis (palonosetron, perphenazine, aprepitant, diphenhydramine, dexamethasone) with boosters, demonstrating PONV rates below 10% and cost savings of approximately €1,948 per 1,000 patients compared to standard guidelines.[87] Continuum-based protocols, spanning preoperative risk assessment to postoperative discharge, use checklists to ensure consistent interventions across phases: preoperative Apfel scoring and tailored prophylaxis, intraoperative minimization of volatiles and opioids, and postoperative rescue with hydration and non-overlapping antiemetics, resulting in improved compliance and reduced incidence in real-world implementations.[88]Future directions highlight personalized approaches and regional disparities. Pharmacogenetic testing for variants in genes like HTR3A, HTR3B, and TACR1 shows promise in optimizing antiemetic selection for chemotherapy-induced nausea, with potential translational applications to PONV. Globally, PONV incidence varies by ethnicity, with higher rates observed in non-African populations (up to 40% vs. 25% in Africans), influenced by factors including dietary habits and genetic predispositions, underscoring the need for region-specific adaptations in guidelines.[89]