# Barringtonia (Barringtonia asiatica) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/barringtonia-barringtonia-asiatica **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-04 **Evidence Score:** 1 / 10 **Category:** Pacific Islands **Also Known As:** Barringtonia asiatica, Fish Poison Tree, Putat, Sea Putat, Butun, Futu, Box Fruit Tree ## Overview Barringtonia asiatica seeds and bark contain tannins, saponins, flavonoids, terpenoids, and the oleanane glycoside ranuncoside, which collectively confer [antioxidant](/ingredients/condition/antioxidant), [antimicrobial](/ingredients/condition/immune-support), and piscicidal activities through phenolic free-radical scavenging, membrane disruption, and concentration-dependent cytotoxicity. Stem-bark chloroform fractions demonstrate the strongest documented bioactivity, with an antioxidant IC50 of 34.46 ± 0.32 μg/mL and a cytotoxic LC50 of 34.059 μg/mL in brine shrimp assays, though all evidence remains preclinical and no human clinical trials have been conducted. ## Health Benefits - **[Antioxidant Activity](/ingredients/condition/antioxidant)**: Phenolic and flavonoid compounds in stem-bark and leaf extracts scavenge free radicals, with the stem-bark chloroform fraction achieving an IC50 of 34.46 ± 0.32 μg/mL and methanol leaf extract IC50 of 125.87 ppm in DPPH assays, suggesting dose-dependent radical neutralization capacity. - **[Antimicrobial](/ingredients/condition/immune-support) Effects**: Extracts from leaves and bark show inhibitory activity against both Gram-positive bacteria (Staphylococcus aureus) and Gram-negative species (Escherichia coli, Salmonella typhi, Klebsiella pneumoniae), with select fractions producing inhibition zones of 18–20 mm in disc diffusion assays, likely mediated by saponins, tannins, and terpenoids disrupting bacterial membranes. - **Wound Healing Support**: In Melanesian traditional medicine, crushed seeds are applied topically to wounds, with antimicrobial and tannin-mediated astringent properties providing a plausible biological basis for tissue protection and infection prevention, though no controlled wound-healing trials have been performed. - **Cytotoxic Potential**: Stem-bark extracts exhibit concentration-dependent cytotoxicity with an LC50 of 34.059 μg/mL in the brine shrimp lethality assay, indicating general bioactive potency that warrants further investigation for anticancer applications, though specific mechanistic pathways and mammalian cell data remain limited. - **Antifungal Properties**: Traditional use for antifungal treatments across Asia and Africa is supported by phytochemical composition rich in terpenoids and saponins, which are recognized classes of antifungal agents capable of disrupting fungal cell membranes, although controlled mycological studies on B. asiatica specifically are scarce. - **[Hepatoprotective](/ingredients/condition/detox) Traditional Use**: Bark and leaf preparations have been used across traditional systems in India, China, and Southeast Asia for liver disorders, with flavonoids and tannins providing a plausible hepatoprotective basis through reduction of oxidative stress and hepatocellular [inflammation](/ingredients/condition/inflammation), pending formal hepatological studies. - **Anti-diarrheal Activity**: Traditional use for diarrheal disease is consistent with the astringent properties of high tannin content in bark and leaf extracts, which can reduce intestinal motility and inhibit enteropathogens such as E. coli and Salmonella typhi, as suggested by in vitro antimicrobial data. ## Mechanism of Action The antioxidant mechanism of Barringtonia asiatica is primarily attributed to polyphenolic compounds—flavonoids and tannins—that donate hydrogen atoms to neutralize [reactive oxygen species](/ingredients/condition/antioxidant), as quantified by DPPH radical scavenging assays across multiple extract fractions. [Antimicrobial](/ingredients/condition/immune-support) activity against both Gram-positive and Gram-negative bacteria is mechanistically linked to saponins, which intercalate into phospholipid bilayers and increase membrane permeability, and to tannins, which complex with cell-surface proteins and inhibit bacterial adhesion and enzymatic function. The oleanane glycoside ranuncoside, concentrated in seeds, is responsible for piscicidal activity through disruption of gill membrane ion transport in fish, and this general cytotoxic mechanism may underlie the broader concentration-dependent cytotoxicity observed in brine shrimp bioassays. Essential oil components identified in leaf hydrodistillates—including uncineol (30.9%), eicosane (27.4%), and 4-propyl-guaiacol (14.05%)—may contribute to membrane-active antimicrobial effects, though specific molecular receptor interactions and intracellular signaling pathway data for any constituent have not been characterized in published studies. ## Clinical Summary No human clinical trials have been conducted on Barringtonia asiatica for any indication, including wound healing, [antimicrobial](/ingredients/condition/immune-support) infection treatment, liver disease, or cancer. All available quantitative data derive from in vitro assays—primarily DPPH [antioxidant](/ingredients/condition/antioxidant) assays, disc diffusion antimicrobial tests, and brine shrimp lethality assays—which provide preliminary biological plausibility but cannot be directly extrapolated to clinical efficacy or safety in humans. The most robust preclinical finding is the stem-bark chloroform fraction antioxidant IC50 of 34.46 ± 0.32 μg/mL, which indicates meaningful radical-scavenging capacity in cell-free systems, but bioavailability, metabolic transformation, and therapeutic dosing in vivo remain entirely uninvestigated. Confidence in any therapeutic claim for this plant is therefore very low, and it should be considered a candidate for future pharmacological and ethnobotanical research rather than a validated clinical ingredient. ## Nutritional Profile Barringtonia asiatica is not consumed as a food source due to the toxicity of its seeds and the bitter, astringent quality of its bark and leaves, and consequently no formal nutritional macronutrient or micronutrient profile has been characterized. Phytochemically, all plant parts contain tannins, saponins, alkaloids, steroids, phenols, flavonoids, terpenoids, and glycosides, with the oleanane glycoside ranuncoside identified as a primary bioactive constituent of seeds responsible for piscicidal activity. Leaf essential oil composition has been quantified at uncineol (30.9%), eicosane (27.4%), and 4-propyl-guaiacol (14.05%) by GC analysis, representing the most precise phytochemical concentration data available. Bioavailability of any constituent following oral or topical exposure in humans has not been studied, and the cytotoxic potential of seed extracts at moderate concentrations precludes nutritional supplementation without further safety characterization. ## Dosage & Preparation - **Traditional Topical Application (Seeds)**: Melanesian traditions use crushed or macerated seeds applied directly to wounds as a poultice; no standardized weight or frequency is documented. - **Methanol Leaf Extract (Research Use Only)**: Used at concentrations of 25–100 μg/mL in in vitro [antioxidant](/ingredients/condition/antioxidant) assays; not suitable for human consumption in this form. - **Stem-Bark Chloroform Fraction (Research Use Only)**: Active at 34.46 μg/mL in DPPH assays and 34.059 μg/mL LC50 in cytotoxicity bioassays; no human dose established. - **Leaf Essential Oil (Hydrodistillation)**: Prepared by steam or hydrodistillation of fresh or dried leaves; composition includes uncineol (30.9%), eicosane (27.4%), and 4-propyl-guaiacol (14.05%); therapeutic dose for humans is undefined. - **Bark Decoction (Traditional)**: Used historically in Asia and the Pacific Islands for liver and gastrointestinal complaints via hot-water extraction of dried bark; no standardized preparation, concentration, or dosage regimen is established. - **Note**: No commercial supplement forms (capsules, tablets, standardized extracts) are currently documented. All dosage forms referenced in research literature are experimental and intended solely for laboratory bioassays. ## Safety & Drug Interactions Safety data for Barringtonia asiatica in humans is essentially absent from the scientific literature; the only quantitative toxicity metric is a brine shrimp lethality LC50 of 34.059 μg/mL for stem-bark chloroform extract, indicating moderate cytotoxic potential in this invertebrate model that cannot be directly translated to human risk thresholds. The seeds in particular are recognized as toxic due to ranuncoside and other saponins, and are deliberately used as fish poisons, strongly contraindicating internal consumption without rigorous safety evaluation. No drug interaction data exist, though the high tannin content in bark extracts could theoretically reduce oral absorption of coadministered medications—particularly antibiotics, iron supplements, and alkaloid-based drugs—by forming insoluble complexes in the gastrointestinal tract. Pregnancy, lactation, and pediatric use are entirely contraindicated given the absence of safety data and the demonstrated cytotoxic bioactivity; no maximum safe dose for any plant part or extract has been established for human use. ## Scientific Research The existing evidence base for Barringtonia asiatica consists entirely of in vitro phytochemical and bioassay studies, with no peer-reviewed human clinical trials or animal pharmacological trials identified in the available literature. [Antimicrobial](/ingredients/condition/immune-support) investigations have employed disc diffusion assays against standard bacterial strains, reporting inhibition zones of 2.50 ± 0.10 to 5.00 ± 0.06 mm for dichloromethane leaf extracts and 18–20 mm for select concentrated fractions, though these values remain below or marginally comparable to tetracycline controls and lack minimum inhibitory concentration (MIC) validation. Cytotoxicity has been assessed using the brine shrimp lethality assay with a sample size of n=30, yielding LC50 values of 34.059 μg/mL for stem-bark extracts—a widely used but crude proxy for anticancer potential that does not predict human therapeutic efficacy. Overall evidence quality is very low by clinical standards, with no randomized controlled trials, no pharmacokinetic studies, no standardized extract formulations, and no safety evaluations in human populations. ## Historical & Cultural Context Barringtonia asiatica holds deep cultural significance across Melanesia, Polynesia, and coastal Asia, where communities have long recognized it as the 'fish poison tree' due to the practice of crushing seeds and casting them into water to stun fish for easy harvesting—a technique documented across Pacific Island and Southeast Asian fishing cultures for centuries. In Melanesian healing traditions, seeds are prepared as topical poultices for wound care, leveraging the plant's astringent and [antimicrobial](/ingredients/condition/immune-support) properties in environments where modern antiseptics were historically unavailable. Across India, China, and Southeast Asia, bark and leaf preparations have been incorporated into traditional medical systems to address liver disorders, eye diseases, diarrhea, and fungal skin infections, with methods ranging from bark decoctions to leaf compresses. The tree also carries spiritual and practical significance in many Pacific Island communities, planted near settlements both for medicinal access and as a coastal windbreak, reflecting its integration into both material and symbolic cultural life. ## Synergistic Combinations No formal synergy studies have been conducted for Barringtonia asiatica in combination with other ingredients, and no evidence-based stack pairings exist in the published literature. Theoretically, the tannin and flavonoid content could complement other polyphenol-rich botanicals such as green tea extract (Camellia sinensis) in [antioxidant](/ingredients/condition/antioxidant) applications, as both contribute phenolic radical scavenging through overlapping but structurally distinct mechanisms. Similarly, the saponin-mediated [antimicrobial](/ingredients/condition/immune-support) activity of B. asiatica extracts might be pharmacologically additive with other membrane-disrupting antimicrobial agents such as tea tree oil (Melaleuca alternifolia), though this combination has not been empirically tested. ## Frequently Asked Questions ### What is Barringtonia asiatica used for in traditional medicine? In traditional medicine across Melanesia, Southeast Asia, India, and China, Barringtonia asiatica has been used to treat wounds, liver disorders, diarrhea, eye diseases, and fungal infections. Seeds are crushed and applied topically as poultices for wound care in Pacific Island traditions, while bark decoctions are used internally for gastrointestinal and hepatic complaints. All these uses are based on ethnobotanical practice and have not been validated in human clinical trials. ### Is Barringtonia asiatica safe to consume or supplement with? Barringtonia asiatica is not considered safe for internal human consumption based on current evidence; its seeds contain the toxic glycoside ranuncoside and are deliberately used as fish poisons. In vitro cytotoxicity data show an LC50 of 34.059 μg/mL in brine shrimp assays for stem-bark extract, indicating meaningful biological toxicity. No human safety studies, maximum safe doses, or regulatory approvals for supplemental use exist, making internal consumption inadvisable without further research. ### What are the main bioactive compounds in Barringtonia asiatica? Phytochemical screening of Barringtonia asiatica consistently identifies tannins, saponins, alkaloids, steroids, phenols, flavonoids, terpenoids, and glycosides across its leaves, bark, seeds, and fruits. The most well-characterized specific compound is ranuncoside, an oleanane glycoside in seeds responsible for piscicidal activity. Leaf essential oil analysis has quantified uncineol (30.9%), eicosane (27.4%), and 4-propyl-guaiacol (14.05%) as major volatile constituents. ### Does Barringtonia asiatica have antimicrobial properties? In vitro studies show that Barringtonia asiatica leaf and bark extracts inhibit Gram-positive bacteria (Staphylococcus aureus) and Gram-negative bacteria (Escherichia coli, Salmonella typhi, Klebsiella pneumoniae), with select fractions producing inhibition zones of 18–20 mm in disc diffusion assays. The antimicrobial activity is attributed to saponins disrupting bacterial membranes, tannins complexing with surface proteins, and terpenoids interfering with microbial metabolism. However, these results come from laboratory cell-free or cell-culture assays only, and no clinical trials have tested antimicrobial efficacy in humans. ### How does Barringtonia asiatica compare to conventional wound treatments? Barringtonia asiatica seeds have been used for wound healing in Melanesian traditions based on plausible astringent (tannin-mediated) and antimicrobial (saponin/terpenoid-mediated) properties, but there are no controlled clinical trials comparing its efficacy to standard wound care products such as antiseptic solutions or antibiotics. The inhibition zones reported for its extracts against wound-relevant bacteria (e.g., Staphylococcus aureus) are generally smaller than those of conventional antibiotics like tetracycline used as controls in the same studies. Until human trials are conducted, it cannot be recommended as a replacement or adjunct to evidence-based wound treatments. ### What is the most bioavailable form of Barringtonia asiatica for antioxidant benefits? Barringtonia asiatica is most commonly available as leaf and stem-bark extracts, with methanol and chloroform extraction methods showing the strongest antioxidant activity in research studies. Stem-bark chloroform extracts demonstrated superior free radical scavenging capacity (IC50 of 34.46 μg/mL) compared to methanol leaf extracts, suggesting that extraction method and plant part significantly influence bioavailability and potency. Standardized extracts targeting phenolic and flavonoid compounds may provide more consistent antioxidant activity than whole plant preparations. ### What does clinical research show about Barringtonia asiatica's effectiveness for oxidative stress? Laboratory studies demonstrate that Barringtonia asiatica extracts effectively scavenge free radicals through dose-dependent mechanisms, with DPPH assay results showing meaningful IC50 values indicating significant antioxidant potential. However, most published research remains in vitro or preclinical, with limited human clinical trials evaluating its efficacy for specific oxidative stress-related conditions. The ingredient shows promise as an antioxidant agent, but more human studies are needed to establish optimal dosing and therapeutic applications. ### Who should avoid Barringtonia asiatica supplements or use them with caution? Individuals with known allergies to Barringtonia species or other members of the Lecythidaceae family should avoid this ingredient, and those taking anticoagulant or antiplatelet medications should consult a healthcare provider due to potential effects on blood clotting. Pregnant and nursing women should seek medical guidance before supplementing, as safety data in these populations remains limited. People with existing liver or kidney conditions should also exercise caution, as comprehensive toxicity profiles in these populations have not been extensively documented. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*