# Scopolamine (L-(-)-hyoscine; derived from Hyoscyamus niger, Atropa belladonna) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/scopolamine-l-hyoscine-derived-from-hyoscyamus-niger-atropa-belladonna **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-02 **Evidence Score:** 1 / 10 **Category:** Compound **Also Known As:** C17H21NO4, L-(-)-hyoscine, Transderm Scop, Scopolamine (Hyoscine), hyoscine, burundanga ## Overview Scopolamine is a tropane alkaloid that acts as a competitive antagonist at muscarinic [acetylcholine](/ingredients/condition/cognitive) receptors (M1–M5 subtypes), blocking parasympathetic neurotransmission in both the central and peripheral nervous systems to suppress vestibular input, smooth muscle activity, and glandular secretion. In its transdermal formulation (1.5 mg patch), it delivers approximately 0.5 mg over 72 hours at a steady-state plasma concentration averaging 87 pg/mL free scopolamine, representing a clinically validated standard of care for motion sickness and postoperative nausea and vomiting (PONV). ## Health Benefits - **Motion Sickness Prevention**: Scopolamine blocks muscarinic M1 receptors in the vestibular nuclei and nucleus tractus solitarius, interrupting the neural conflict signals that trigger nausea; the transdermal patch is considered the most effective single pharmacological agent for prophylaxis of motion-induced nausea and vomiting. - **Postoperative Nausea and Vomiting (PONV) Reduction**: By antagonizing central and peripheral cholinergic pathways implicated in the vomiting reflex, transdermal scopolamine reduces the incidence and severity of PONV, particularly when applied preoperatively and used as part of multimodal antiemetic protocols. - **Antispasmodic and Antisecretory Effects**: Peripheral M2 and M3 receptor blockade reduces smooth muscle spasm in the gastrointestinal and genitourinary tracts and diminishes secretions from salivary, bronchial, and gastric glands, making it useful as a preoperative antisecretory agent. - **Sedation and Anxiolysis**: Central muscarinic antagonism produces dose-dependent sedation and mild anxiolysis, historically exploited in 'twilight sleep' obstetric analgesia protocols and still relevant as a component of premedication regimens. - **[Cognitive](/ingredients/condition/cognitive) and Neurochemical Research Tool**: IV and IM doses of 0.4–0.8 mg reproducibly induce transient cholinergic deficits measurable by qEEG and psychometric testing, with Cmax values of 3.27–18.81 ng/mL, establishing scopolamine as a standard pharmacological model for studying Alzheimer's disease-like cognitive impairment and evaluating procognitive compounds. - **Bronchodilation**: Anticholinergic blockade at M3 receptors in bronchial smooth muscle reduces bronchoconstriction, a property exploited in inhaled anticholinergic derivatives and relevant to the broader pharmacological class scopolamine exemplifies. - **Nausea Associated with Opioid Use**: Scopolamine's central antiemetic action complements opioid analgesia by mitigating opioid-induced nausea through cholinergic pathway suppression, and it has historically been co-administered with morphine for this purpose. ## Mechanism of Action Scopolamine competitively and reversibly antagonizes all five subtypes of muscarinic acetylcholine receptors (M1–M5), which are G-protein-coupled receptors mediating the majority of parasympathetic and central cholinergic neurotransmission; by occupying the orthosteric binding site, it prevents acetylcholine from activating downstream Gq/11 (M1, M3, M5) and Gi/o (M2, M4) signaling cascades, thereby blocking phospholipase C activation, IP3-mediated calcium release, and inhibition of adenylyl cyclase respectively. At the vestibular system and vomiting center (area postrema and nucleus tractus solitarius), M1 receptor blockade interrupts the integration of conflicting sensory signals from the labyrinth, eyes, and proprioceptors that drive emesis, while peripheral M3 blockade on smooth muscle and exocrine glands suppresses contractility and secretion. Centrally, cholinergic hypofunction induced by scopolamine produces measurable qEEG changes—including increased delta/theta power and decreased alpha/beta activity—and dose-dependent impairment in memory consolidation and attention, reflecting the critical role of acetylcholine in cortical arousal and hippocampal [long-term potentiation](/ingredients/condition/cognitive). Its lipophilicity enables rapid CNS penetration, with tissue-to-serum AUC ratios approaching 0.96 ± 0.7 in human microdialysis studies, explaining the prominent central effects even at low pharmaceutical doses. ## Clinical Summary Transdermal scopolamine (1.5 mg patch, 0.5 mg delivered over 72 hours) has been evaluated in controlled trials as prophylaxis for motion sickness and PONV, demonstrating clinically meaningful reductions in nausea and vomiting incidence when applied at least 4 hours prior to exposure or surgery, with steady-state plasma concentrations averaging 87 pg/mL free scopolamine and a post-removal half-life of approximately 9.5 hours. Pharmacodynamic studies using IV administration (0.5 mg over 15 min, Cmax ~5.00 ng/mL) and IM administration have quantified its scopolamine-induced [cognitive](/ingredients/condition/cognitive) impairment model utility, with microdialysis-confirmed serum Cmax of 6.5 ± 3.9 ng/mL peaking at 15 ± 3 minutes and a half-life of 121 ± 85 minutes, supporting its reproducibility as a research tool. The evidence for PONV efficacy is considered moderate-to-strong for the transdermal route within multimodal antiemetic protocols, though monotherapy superiority over [serotonin](/ingredients/condition/mood) antagonists is not firmly established in head-to-head RCTs with modern statistical reporting. Confidence in pharmacokinetic parameters is high (multiple well-controlled studies in healthy volunteers), while confidence in comparative efficacy endpoints and long-term safety at repeated use intervals is moderate due to study design heterogeneity and the age of seminal efficacy trials. ## Nutritional Profile Scopolamine is a pure alkaloid compound (molecular formula C17H21NO4, molecular weight 303.35 g/mol) and possesses no nutritional value in terms of macronutrients, micronutrients, vitamins, or dietary fiber; it is not consumed as a food ingredient or dietary supplement. As a pharmaceutical agent, its relevant 'profile' is entirely pharmacokinetic and pharmacodynamic: it is highly lipophilic (logP ~1.2), enabling rapid membrane permeability and CNS penetration, with plasma protein binding of approximately 4.7% and a large volume of distribution (141–188 L IV) indicating extensive tissue distribution. In plant sources such as H. niger, scopolamine co-occurs with other tropane alkaloids including hyoscyamine (the levo-isomer of atropine), atropine, and apoatropine, as well as flavonoids and sterols, but these co-constituents are removed during pharmaceutical purification. Bioavailability is strongly route-dependent, ranging from 13% oral to 83% intranasal to 100% intravenous, with the transdermal route providing controlled sustained release that avoids first-pass [metabolism](/ingredients/condition/weight-management) entirely. ## Dosage & Preparation - **Transdermal Patch (Transderm Scop)**: 1.5 mg reservoir patch applied behind the ear; delivers a priming dose of ~140 µg followed by 0.5 mg over 72 hours at ~5 µg/h; apply at least 4 hours before travel or surgery; replace every 3 days if continued prophylaxis is needed. - **Intravenous (IV)**: 0.5 mg administered slowly over 15 minutes; Cmax ~5.00 ng/mL; bioavailability 100%; used perioperatively for PONV prophylaxis and in pharmacodynamic research protocols. - **Intramuscular (IM) / Subcutaneous (SC)**: 0.5 mg; onset within 30–60 minutes; used when IV access is unavailable; similar efficacy profile to IV at equivalent doses. - **Oral**: 0.5 mg; bioavailability only 13 ± 1% due to extensive first-pass hepatic [metabolism](/ingredients/condition/weight-management); Cmax 0.54 ± 0.1 ng/mL at tmax ~23.5 minutes; oral route is the least preferred due to low and variable bioavailability. - **Intranasal**: 0.4 mg; bioavailability 83 ± 10%; Cmax 1.68 ng/mL at tmax ~2.2 minutes; rapid onset makes this route promising for acute nausea management, though not yet widely standardized in clinical practice. - **Ophthalmic Solution**: 0.25% drops; used for cycloplegia and mydriasis; not indicated for systemic antiemetic use. - **Dosing Note**: Scopolamine is not used as a dietary supplement; all dosing is pharmaceutical-grade and should be initiated under medical supervision; pediatric and geriatric dosing requires significant downward adjustment due to heightened CNS sensitivity. ## Safety & Drug Interactions At therapeutic doses, scopolamine produces predictable anticholinergic adverse effects including dry mouth (most common, reported in up to 67% of transdermal patch users), blurred vision, urinary retention, constipation, tachycardia, and drowsiness; CNS effects including confusion, disorientation, agitation, and hallucinations are more pronounced in elderly patients due to age-related reductions in cholinergic reserve and increased blood-brain barrier permeability. Scopolamine potentiates the CNS depressant effects of benzodiazepines, opioids, antihistamines, tricyclic antidepressants, and other anticholinergic agents (e.g., atropine, glycopyrrolate, oxybutynin), increasing the risk of anticholinergic toxidrome; caution is also warranted with CYP3A4 inhibitors (e.g., ketoconazole, clarithromycin) as hepatic [metabolism](/ingredients/condition/weight-management) may be impaired, though specific interaction magnitude data are limited. Absolute contraindications include angle-closure glaucoma (risk of precipitating acute attack via mydriasis), and relative contraindications encompass prostatic hypertrophy, pyloric obstruction, myasthenia gravis, tachyarrhythmias, and known hypersensitivity to belladonna alkaloids; the compound is classified FDA Pregnancy Category C (risk cannot be ruled out) and is excreted in breast milk, warranting avoidance in lactation. High interindividual pharmacokinetic variability (Cmax range 11–240 pg/mL transdermally; 11-fold variation IV) increases unpredictable toxicity risk, and overdose presents as classic anticholinergic toxidrome ('hot as a hare, blind as a bat, dry as a bone, red as a beet, mad as a hatter') treated with physostigmine as a specific antidote. ## Scientific Research The clinical evidence base for scopolamine in motion sickness and PONV prophylaxis is well-established through decades of controlled trials, regulatory pharmacokinetic studies, and systematic reviews, earning it FDA approval for transdermal delivery since 1979; however, the majority of foundational efficacy trials predate modern CONSORT reporting standards, limiting granular effect-size extraction from published summaries. Pharmacokinetic characterization is robust: controlled studies in healthy volunteers have precisely defined oral bioavailability at 13 ± 1% (Cmax 0.54 ± 0.1 ng/mL, tmax 23.5 ± 8.2 min), intranasal bioavailability at 83 ± 10% (Cmax 1.68 ng/mL, tmax 2.2 min), and IV volume of distribution at 141–188 L with clearance 81–99 L/h, providing a strong mechanistic and pharmacodynamic framework. Its use as a [cognitive](/ingredients/condition/cognitive) challenge model in CNS drug development is supported by multiple prospective studies in healthy volunteers measuring qEEG endpoints and psychometric battery changes after IV/IM doses of 0.4–0.8 mg, though most of these studies are small (n typically 10–30) and focus on pharmacodynamic biomarker validation rather than therapeutic efficacy. Large-scale, modern randomized controlled trials with pre-registered outcomes and standardized PONV composite endpoints are less prominently represented in the current evidence synthesis, and head-to-head comparisons with newer antiemetics (e.g., ondansetron, dexamethasone) in multimodal PONV protocols represent an active area of inquiry. ## Historical & Cultural Context Scopolamine-containing plants—particularly Hyoscyamus niger (henbane) and Atropa belladonna—have occupied a central place in European and Near Eastern folk medicine for over two millennia, employed as soporifics, analgesics, and antispasmodics in preparations ranging from oral decoctions to topical 'witches' salves' described in medieval herbalism. In the early 20th century, scopolamine combined with morphine was used as 'Dämmerschlaf' (twilight sleep) in obstetric practice in Germany and subsequently the United States, intended to induce amnesia and sedation during labor, though concerns about neonatal respiratory depression and ethical controversies eventually curtailed this use. The compound gained renewed pharmaceutical importance in the 1970s when NASA-funded research into motion sickness prevention during spaceflight directly contributed to the development and approval of the Transderm Scop transdermal patch, making scopolamine one of the first drugs to exploit transdermal drug delivery technology at clinical scale. Forensically, scopolamine (often called 'burundanga' in South America, where it is extracted from Brugmansia species) has a documented history of criminal misuse as a drug-facilitated incapacitation agent, reflecting the potency of its CNS anticholinergic effects at supratherapeutic doses. ## Synergistic Combinations In multimodal PONV prophylaxis, transdermal scopolamine is commonly combined with [serotonin](/ingredients/condition/mood) 5-HT3 receptor antagonists (e.g., ondansetron) and dexamethasone, exploiting complementary receptor mechanisms—cholinergic, serotonergic, and [anti-inflammatory](/ingredients/condition/inflammation)—to achieve additive to synergistic reductions in PONV incidence beyond what either agent achieves alone. Historically, scopolamine was co-administered with morphine or meperidine to leverage mutual CNS depression while scopolamine's antiemetic action counteracted opioid-induced nausea, representing one of the earliest intentional pharmacological synergy pairings in clinical medicine. In pharmacological research contexts, scopolamine-induced cognitive impairment is partially reversed by [acetylcholine](/ingredients/condition/cognitive)sterase inhibitors (e.g., donepezil, physostigmine) and nicotinic receptor agonists, a mechanistic antagonism that validates its use as a benchmark challenge model for evaluating procognitive and nootropic compounds. ## Frequently Asked Questions ### How long does a scopolamine patch take to work and how long does it last? The transdermal scopolamine patch (Transderm Scop, 1.5 mg) requires application at least 4 hours before exposure to motion or surgery to achieve therapeutic plasma levels, with steady-state concentrations (averaging 87 pg/mL free scopolamine) reached within 8–24 hours. Each patch provides continuous drug delivery for up to 72 hours (3 days) at approximately 5 µg/hour, and pharmacological effects persist for several hours after removal due to a post-removal half-life of approximately 9.5 hours from skin depot. ### What are the most common side effects of scopolamine? The most frequently reported side effect is dry mouth, occurring in up to 67% of transdermal patch users due to muscarinic M3 blockade on salivary glands; other common effects include drowsiness, blurred vision (cycloplegia and mydriasis), urinary hesitancy, and constipation. Serious CNS effects—confusion, disorientation, hallucinations, and agitation—are more likely in elderly patients, at supratherapeutic doses, or when scopolamine is combined with other anticholinergic or CNS depressant medications. ### Is scopolamine safe to use during pregnancy or breastfeeding? Scopolamine is classified as FDA Pregnancy Category C, meaning animal studies have shown adverse fetal effects but adequate controlled human studies are lacking, so it should be used during pregnancy only if the potential benefit clearly justifies the potential risk to the fetus. The compound is excreted in breast milk and crosses the placenta; its use is generally not recommended during lactation, and neonates may be susceptible to anticholinergic effects including tachycardia and urinary retention. ### Can scopolamine be used for anxiety or as a sleep aid? Scopolamine does produce CNS sedation and mild anxiolysis through central muscarinic receptor blockade, and it was historically used in 'twilight sleep' obstetric protocols for this property, but it is not approved or recommended as a standalone anxiolytic or sleep aid due to its narrow therapeutic index and risk of anticholinergic toxicity including confusion and hallucinations. Interestingly, emerging research has investigated sub-anesthetic IV doses of scopolamine as a rapid-acting antidepressant in treatment-resistant depression, with some small controlled trials showing significant mood improvements, though this use remains investigational and is not an approved indication. ### What drugs interact with scopolamine and should not be taken together? Scopolamine has clinically significant additive interactions with all anticholinergic medications (atropine, glycopyrrolate, oxybutynin, tricyclic antidepressants, first-generation antihistamines such as diphenhydramine) because combined muscarinic blockade markedly increases the risk of anticholinergic toxidrome, characterized by tachycardia, hyperthermia, urinary retention, confusion, and hallucinations. It also potentiates CNS depressants including opioids, benzodiazepines, and alcohol, increasing sedation and respiratory depression risk; CYP3A4 inhibitors such as ketoconazole and clarithromycin may reduce hepatic clearance of scopolamine, potentially elevating plasma levels beyond the therapeutic window. ### What is the difference between scopolamine patches and oral forms, and which is more effective? Transdermal scopolamine patches are significantly more effective than oral formulations for motion sickness prevention, delivering consistent therapeutic levels and producing fewer side effects by avoiding first-pass hepatic metabolism. Patches typically provide superior efficacy because they maintain steady-state drug concentrations over 72 hours, whereas oral scopolamine has variable absorption and requires more frequent dosing. Clinical evidence strongly supports transdermal application as the preferred delivery method for preventing motion-induced nausea and vomiting. ### Who are the best candidates for scopolamine use, and who should avoid it? Scopolamine is most beneficial for individuals prone to motion sickness during travel, deep-sea diving, or those at high risk for postoperative nausea and vomiting, particularly those with a history of motion sensitivity. Patients with angle-closure glaucoma, urinary retention, severe cardiac arrhythmias, or untreated hyperthyroidism should avoid scopolamine due to its anticholinergic properties. The elderly, those with cognitive impairment, and individuals with liver or kidney dysfunction require careful dose adjustments and closer monitoring due to increased sensitivity to adverse effects. ### What does clinical research reveal about scopolamine's effectiveness compared to other motion sickness remedies? Clinical trials demonstrate that transdermal scopolamine is superior to antihistamines like dimenhydrinate and meclizine for preventing motion sickness, with efficacy rates exceeding 70–90% in controlled studies. Research shows scopolamine is comparable or superior to the 5-HT3 antagonist ondansetron for postoperative nausea prevention, and when combined with other antiemetics, it provides synergistic benefits. Long-term safety data supports its use for up to 72 hours of continuous exposure, though efficacy may decline slightly after 48 hours of patch application in some individuals. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*