# Coca (Erythroxylum coca) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/coca-erythroxylum-coca **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-02 **Evidence Score:** 1 / 10 **Category:** South American **Also Known As:** Erythroxylum coca, Bolivian coca, Huanuco coca, mate de coca, cocaine plant ## Overview Coca leaves contain approximately 20 tropane and related alkaloids—principally cocaine (0.13–0.76% dry leaf mass)—which stimulate the central nervous system by blocking dopamine, norepinephrine, and [serotonin reuptake](/ingredients/condition/mood) transporters (DAT, NET, SERT), while co-alkaloids such as trans-cinnamylcocaine modulate cocaine's pharmacokinetics and reduce tolerance development. In rat bioassays, whole coca extract produced an anorexic ED50 of 52.6 mg/kg orally (cocaine-equivalent), compared to 34.6 mg/kg for pure cocaine HCl, yet coca extract showed superior activity over pure cocaine in tolerance-conditioned animals, suggesting the whole-leaf matrix meaningfully alters pharmacodynamic outcomes. ## Health Benefits - **Appetite and Hunger Suppression**: Cocaine and co-alkaloids in whole coca leaf activate central monoaminergic pathways, producing dose-dependent anorexia; rat bioassays established an oral ED50 of 52.6 mg/kg cocaine-equivalent for the extract, demonstrating measurable appetite-suppressing activity via catecholaminergic stimulation. - **Energy and Endurance Enhancement**: Traditional and ethnopharmacological evidence supports that chewing coca leaves delays fatigue and sustains physical output at altitude, attributed to CNS stimulation via elevated synaptic [dopamine](/ingredients/condition/mood) and norepinephrine as well as mild glucose mobilization from leaf sugars (sucrose, glucose, fructose). - **[Cognitive Function](/ingredients/condition/cognitive) and Alertness**: Elevated synaptic monoamine levels resulting from cocaine-mediated reuptake inhibition at DAT and NET improve alertness, attention, and working memory acuity; whole-leaf administration produces peak blood cocaine levels approximately 50-fold lower than isolated cocaine HCl, yielding stimulation without the acute intensity of the purified compound. - **Altitude Sickness (Soroche) Relief**: Centuries of Andean use and modern ethnopharmacological observation support coca leaf's role in mitigating symptoms of acute mountain sickness, plausibly through vasoactive alkaloid effects, mild bronchodilation, and improved oxygen utilization, though controlled clinical trials in humans are absent. - **Digestive Aid**: Traditional preparations, particularly coca tea (mate de coca), are used across the Andes to relieve gastrointestinal discomfort, nausea, and bloating; the leaf's high insoluble dietary fiber content (exceeding 50% of dry mass) supports gut motility, while organic acids such as succinic acid may contribute to digestive secretion stimulation. - **[Antioxidant Activity](/ingredients/condition/antioxidant)**: Polyphenol-rich coca leaf extracts demonstrate measurable DPPH free-radical scavenging capacity of 0.057–0.696 mg Trolox equivalents per gram, with total polyphenol content reaching 142.97 mg gallic acid equivalents per gram in certain extracts, suggesting meaningful antioxidant potential in the whole-leaf matrix. - **[Antimicrobial](/ingredients/condition/immune-support) Properties**: In vitro studies indicate that coca leaf extracts at 50–75% concentration exhibit antibacterial activity against oral pathogens including Streptococcus mutans, with synergistic potential alongside conventional antibiotics, pointing to polyphenol and alkaloid contributions to antimicrobial defense. ## Mechanism of Action The primary pharmacologically active alkaloid, cocaine, functions as a competitive inhibitor of the plasma membrane monoamine transporters DAT (dopamine transporter), NET (norepinephrine transporter), and SERT ([serotonin](/ingredients/condition/mood) transporter), blocking [neurotransmitter](/ingredients/condition/cognitive) reuptake and causing sustained elevation of synaptic dopamine, norepinephrine, and serotonin concentrations in the nucleus accumbens, prefrontal cortex, and peripheral sympathetic synapses. This monoaminergic overflow drives CNS stimulation, appetite suppression, tachycardia, vasoconstriction, and enhanced alertness. Critically, the whole-leaf matrix contains approximately 17–20 co-alkaloids—including trans-cinnamylcocaine (2.1–6.0% of alkaloid fraction), cinnamylcocaine (1.3–2.6%), and benzoylecgonine (10.0–26.6%)—that interact with cocaine's pharmacokinetics, reducing peak absorption rates and attenuating tolerance development more effectively than pure cocaine isolate alone, as demonstrated by smaller ED50 shifts in tolerance-conditioned rat models. Polyphenols and flavonoids (up to 0.213 mg quercetin equivalents per gram) contribute secondary antioxidant effects via hydrogen atom transfer and electron donation to [reactive oxygen species](/ingredients/condition/antioxidant), independent of alkaloid activity. ## Clinical Summary No published human clinical trials with defined sample sizes, randomization, or reported effect sizes specifically examine whole coca leaf supplementation for [cognitive](/ingredients/condition/cognitive), metabolic, or nutritional endpoints. The most controlled experimental data derive from rat bioassays assessing anorexic potency, where whole leaf extract (cocaine-equivalent dosing) demonstrated an oral ED50 of 52.6 mg/kg in drug-naive animals and showed attenuated tolerance development compared to pure cocaine HCl over 30-day chronic dosing protocols, indicating pharmacodynamic modulation by co-alkaloids. Traditional and observational evidence from Andean populations documents practical use for altitude acclimatization, hunger suppression, and [fatigue reduction](/ingredients/condition/energy), but these reports lack control conditions, blinding, or quantified outcome measures. Confidence in coca leaf's efficacy for any specific health outcome in humans remains low by evidence-based medicine standards; the primary alkaloid's Schedule I/controlled status in most jurisdictions has severely constrained human clinical investigation. ## Nutritional Profile Coca leaves are nutritionally dense relative to their mass: dietary fiber constitutes more than 50% of dry leaf weight (predominantly insoluble cellulose and hemicellulose), with stems exceeding 76% fiber. Sugars present include sucrose, glucose, and fructose in modest concentrations. Organic acids, with succinic acid predominating, contribute to the leaf's slightly acidic profile and potential digestive effects. Alkaloid content totals approximately 0.5–1.0% of dry weight across all tropane species, with cocaine comprising the majority (0.13–0.76%), followed by benzoylecgonine (up to 26.6% of the alkaloid fraction by GC-MS relative area), trans-cinnamylcocaine, and cinnamylcocaine. Polyphenol content reaches up to 142.97 mg gallic acid equivalents per gram in concentrated extracts, and flavonoids measure up to 0.213 mg quercetin equivalents per gram. Volatile compounds identified by GC-MS include hexadecanoic acid (1.5–2.7% relative) and phytol (5.09%), suggesting the presence of chlorophyll-related compounds. Bioavailability of cocaine from whole leaf is substantially reduced compared to isolated forms due to matrix binding, alkaline pH dependence for buccal absorption, and co-alkaloid competitive interactions. ## Dosage & Preparation - **Dried Leaf Chewing (Traditional)**: 15–60 g of dried leaves chewed slowly with a small amount of alkaline agent (cal/lime, bicarbonate, or plant ash) to raise buccal pH and facilitate cocaine free-base release; this is the primary traditional method across Andean cultures and results in peak blood cocaine levels approximately 50-fold lower than equivalent oral HCl doses. - **Coca Tea (Mate de Coca)**: One to two commercial tea bags (approximately 1–2 g dried leaf each) steeped in hot water for 5–10 minutes; widely available in Peru and Bolivia as an over-the-counter beverage for altitude sickness and digestive complaints; cocaine content per cup is low (estimated micrograms to low milligrams). - **Ethanolic Extract (Research Form)**: Laboratory preparations have used ethanolic or saline/Tween 80 suspensions standardized to 15–90 mg/kg cocaine-equivalent for animal bioassays; no standardized commercial extract with defined cocaine percentage exists in regulated supplement markets. - **Standardization Note**: No internationally recognized standardization exists for whole coca leaf supplements; cocaine content varies 0.13–0.76% by dry leaf weight depending on variety and growing conditions, making dose consistency difficult to ensure outside of controlled pharmaceutical contexts. - **Regulatory Caveat**: Coca leaf and its alkaloid derivatives are controlled substances in most countries (Schedule I in the United States under the Controlled Substances Act); legal supplemental use is restricted to specific jurisdictions in South America where traditional use is formally protected. ## Safety & Drug Interactions Whole coca leaf carries significant safety concerns primarily attributable to its cocaine content: CNS stimulation, [cardiovascular](/ingredients/condition/heart-health) effects (tachycardia, hypertension, vasoconstriction), and addiction potential are dose-dependent risks even at whole-leaf doses, though the pharmacokinetic matrix effect reduces peak plasma cocaine levels approximately 50-fold versus purified cocaine HCl. Chronic use carries risk of dependence, tolerance development (less pronounced with whole leaf than isolate per rat models, but not eliminated), and cardiovascular strain, particularly in individuals with pre-existing heart conditions, hypertension, or arrhythmias. Drug interaction risks are substantial: co-administration with MAO inhibitors, sympathomimetics, or stimulant medications could produce hypertensive crises or cardiac arrhythmias; cocaine's inhibition of monoamine transporters also potentiates effects of tricyclic antidepressants and adrenergic agents. Coca leaf is absolutely contraindicated in pregnancy and lactation (cocaine crosses the placental barrier and is excreted in breast milk, with well-documented neonatal toxicity), in individuals with cardiovascular disease, and in those with personal or family history of substance use disorders; no safe maximum dose has been established for human supplemental use, and legal restrictions preclude formal dose-safety research in most jurisdictions. ## Scientific Research The evidence base for whole coca leaf is predominantly preclinical, consisting of animal bioassays, in vitro phytochemical analyses, and ethnopharmacological surveys, with no indexed randomized controlled trials in humans reporting sample sizes and effect sizes as of the available literature. Rat anorexia studies comparing coca extract to pure cocaine HCl are the most quantitatively robust data available, establishing oral ED50 values (52.6 mg/kg extract vs. 34.6 mg/kg cocaine HCl in naive animals; shifted to 150+ mg/kg range in tolerant animals for cocaine vs. a smaller shift for extract), but these cannot be directly extrapolated to human supplemental doses. Phytochemical characterization studies using GC-MS, HPLC, and spectrophotometric methods have reliably quantified alkaloid concentrations, polyphenol content, and [antioxidant](/ingredients/condition/antioxidant) capacity across Bolivian and Peruvian leaf varieties, providing a strong chemical evidence base if not a clinical one. In vitro [antimicrobial](/ingredients/condition/immune-support) assays against S. mutans show activity at 50–75% extract concentrations, but these have not been validated in animal infection models or human oral health trials. ## Historical & Cultural Context Coca leaf has been cultivated and used by Andean indigenous peoples for at least 3,000–8,000 years, with archaeological evidence of coca chewing found at sites in Peru and Chile predating the Incan Empire; the plant held sacred status as a gift from Inti (the sun deity) in Inca cosmology and served roles in religious ceremony, labor sustenance, and social exchange. Traditional use centered on chewing dried leaves combined with an alkaline catalyst (cal, a lime preparation) to extract alkaloids transbuccally, a technique refined over millennia to maximize pharmacological effect while minimizing acute toxicity. Spanish colonizers documented and exploited coca use from the 16th century onward, initially suppressing it as pagan practice before permitting and even encouraging its use to sustain the labor capacity of indigenous mine workers. In the 19th century, coca extracts were incorporated into European and North American patent medicines—most famously Vin Mariani (coca wine) and the original Coca-Cola formulation before 1903—until cocaine's addictive properties prompted regulatory controls; today, decocainized coca leaf extract (Merchandise No. 5) remains a flavoring agent in Coca-Cola under DEA license. ## Synergistic Combinations Traditional Andean practice combines coca leaf chewing with alkaline catalysts (cal/lime or plant ash), which raises buccal pH and converts cocaine from its salt form to the free base, dramatically increasing transmucosal absorption—this alkali co-administration is arguably the most pharmacologically significant synergistic pairing documented for this ingredient. In vitro evidence suggests coca leaf extracts may act synergistically with antibiotics against oral bacterial pathogens such as Streptococcus mutans, though the specific compounds mediating this synergy (polyphenols, alkaloids, or both) have not been isolated. From an [antioxidant](/ingredients/condition/antioxidant) standpoint, coca leaf polyphenols theoretically complement other flavonoid-rich botanicals, but no controlled studies have evaluated combined antioxidant stacking with whole coca leaf in human subjects. ## Frequently Asked Questions ### How much cocaine is in a coca leaf? Bolivian Erythroxylum coca leaves contain approximately 0.13–0.76% cocaine by dry weight, with an average around 0.63% in Bolivian varieties. A single coca tea bag containing roughly 1–2 g of dried leaf therefore delivers on the order of 1.3–15 mg of cocaine, though actual absorption is far lower than this figure because whole-leaf matrix effects reduce peak blood cocaine levels approximately 50-fold compared to purified cocaine hydrochloride. ### Is coca leaf the same as cocaine? No—coca leaf is the whole dried plant material containing approximately 20 alkaloids, of which cocaine is only one component averaging 0.63% of dry weight. Cocaine (as cocaine hydrochloride or free base) is an isolated, purified extract of the leaf; the whole leaf matrix, including co-alkaloids like trans-cinnamylcocaine and benzoylecgonine, significantly modulates cocaine's pharmacokinetics and reduces both peak absorption rates and tolerance development compared to the purified compound. ### Does coca tea show up on a drug test? Yes—consumption of coca tea can produce positive urine drug screening results for cocaine metabolites, including benzoylecgonine, because even low-dose exposure from tea delivers detectable cocaine that is metabolized and excreted. Detection windows depend on dose frequency and individual metabolism, but studies have confirmed positive immunoassay results following single-cup coca tea consumption, making it a documented cause of false-positive drug tests in workplace and athletic screening contexts. ### What are the traditional uses of coca leaf in South America? Andean indigenous peoples have used coca leaf for at least 3,000–8,000 years to suppress hunger and thirst, sustain energy during high-altitude labor, alleviate altitude sickness (soroche), and support digestion, primarily by chewing dried leaves with an alkaline catalyst such as cal (lime paste) to release alkaloids transbuccally. Coca also held deep ceremonial and social significance in Inca and pre-Inca cultures, serving as an offering to deities, a currency of social exchange, and a component of medicinal preparations for pain and gastrointestinal complaints. ### Is coca leaf legal to use as a supplement? The legal status of coca leaf varies dramatically by jurisdiction: in Bolivia and Peru, traditional coca leaf chewing and coca tea are legally protected cultural practices, and commercial tea bags are sold openly. In the United States, the European Union, and most other countries, coca leaf is classified as a Schedule I or equivalent controlled substance because of its cocaine content, making importation, possession, and sale illegal regardless of intended use—including as a dietary supplement or herbal tea. ### What is the difference between coca leaf extract and coca leaf powder for appetite suppression? Coca leaf extracts contain concentrated alkaloid levels and demonstrate measurable appetite-suppressing activity in bioassays, with an oral ED50 of 52.6 mg/kg cocaine-equivalent, whereas whole leaf powder provides lower and more variable alkaloid concentrations. Extracts offer more standardized dosing for the active compounds responsible for catecholaminergic stimulation, but whole leaf preparations maintain the full plant matrix with additional phytochemicals. The choice depends on whether standardized potency or traditional whole-plant synergy is prioritized. ### Is coca leaf safe to use if I take stimulant medications or have cardiovascular conditions? Coca leaf alkaloids activate central monoaminergic pathways similarly to prescription stimulants, creating potential for additive cardiovascular and central nervous system effects when combined with medications like amphetamines, methylphenidate, or decongestants. Individuals with hypertension, arrhythmias, or other cardiovascular conditions should avoid coca leaf due to its sympathomimetic properties and potential to elevate heart rate and blood pressure. Consultation with a healthcare provider is essential before use if you take any stimulant-class medications or have a history of heart conditions. ### What clinical evidence supports coca leaf for energy and endurance compared to other herbal stimulants? While traditional ethnobotanical use in high-altitude Andean regions demonstrates established effects on fatigue and endurance, human clinical trials specifically measuring coca leaf's energetic effects against standardized comparators (caffeine, guarana, or other stimulant herbs) remain limited in the published literature. Most mechanistic evidence comes from preclinical studies establishing the alkaloid-dependent monoaminergic pathways; translation to human performance data requires more rigorous randomized controlled trials. Current evidence supports traditional use patterns but lacks the robust comparative clinical data available for more extensively studied stimulant supplements. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*