# Baccharis incarum (Baccharis incarum Wedd.) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/baccharis-incarum-baccharis-incarum-wedd **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-02 **Evidence Score:** 1 / 10 **Category:** South American **Also Known As:** Baccharis incarum Wedd., Inca baccharis, Puna baccharis, Asteraceae Andean shrub, Chilca (regional Andean term for Baccharis spp.) ## Overview Baccharis incarum contains phenolic compounds and flavonoids—including chlorogenic acid and 4',5-dihydroxy-3',3,6,7,8-pentamethoxyflavone—that exert antioxidant activity via [free radical scaveng](/ingredients/condition/antioxidant)ing (ABTS SC50 1.6–4.0 µg GAE/mL) and [antimicrobial](/ingredients/condition/immune-support) activity against antibiotic-resistant Gram-positive bacteria. Ethanol extracts demonstrate minimum inhibitory concentrations of 40–80 µg GAE/mL against methicillin-resistant Staphylococcus aureus and Enterococcus faecalis in vitro, representing the most quantified pharmacological activity reported to date. ## Health Benefits - **[Antioxidant Activity](/ingredients/condition/antioxidant)**: Standardized ethanol extracts of Baccharis incarum demonstrate potent ABTS radical scavenging capacity with SC50 values of 1.6–4.0 µg GAE/mL, attributed to the phenolic compounds and flavonoids concentrated in the plant's aerial tissues as an adaptive response to high-altitude UV stress. - **[Antimicrobial](/ingredients/condition/immune-support) Effects Against Resistant Pathogens**: In vitro assays show MIC values of 40–80 µg GAE/mL against methicillin-resistant Staphylococcus aureus (MRSA) and antibiotic-resistant Enterococcus faecalis, suggesting utility against Gram-positive nosocomial pathogens where conventional antibiotics are failing. - **Topical Anti-infective Potential**: A phytopharmaceutical hydrogel formulation incorporating 60° ethanol tincture with Carbopol® 934 demonstrates controlled in vitro release of chlorogenic acid and the isolated flavone via Franz diffusion cell studies, supporting potential topical application for skin and wound infections. - **Gastrointestinal Support (Traditional)**: Andean traditional medicine employs Baccharis incarum preparations for gastrointestinal complaints including in[digestion](/ingredients/condition/gut-health), nausea, and abdominal discomfort, consistent with the known carminative and antimicrobial properties of related Baccharis species used throughout the altiplano. - **Non-Genotoxic Safety Profile**: Salmonella-based genotoxicity assays on both the crude extract and formulated hydrogel showed no mutagenic activity, providing a preliminary safety signal for topical and potentially oral preparations, though this does not substitute for comprehensive toxicological evaluation. - **Phenolic-Driven [Anti-inflammatory](/ingredients/condition/inflammation) Potential**: Chlorogenic acid, one of the identified bioactives, is well-characterized in broader botanical literature as an inhibitor of NF-κB signaling and cyclooxygenase pathways; its presence in Baccharis incarum suggests plausible anti-inflammatory mechanisms, though direct studies on this species are lacking. - **Formulation Stability for Phytopharmaceutical Development**: The ethanol tincture-based hydrogel demonstrated microbiological, chemical, physical, and functional stability under room-temperature storage conditions, making Baccharis incarum a viable candidate for standardized topical phytomedicines in resource-limited Andean healthcare contexts. ## Mechanism of Action The primary antioxidant mechanism involves electron donation and hydrogen atom transfer by phenolic hydroxyl groups—particularly those of chlorogenic acid and the identified pentamethoxyflavone—to neutralize ABTS radical cations and likely other [reactive oxygen species](/ingredients/condition/antioxidant) such as superoxide and hydroxyl radicals. The [antimicrobial](/ingredients/condition/immune-support) mechanism against Gram-positive bacteria including MRSA and E. faecalis is attributed to flavonoid and phenolic acid disruption of bacterial cell membrane integrity, inhibition of membrane-associated ATPases, and potential interference with bacterial cell wall synthesis, although specific molecular targets such as penicillin-binding proteins or topoisomerases have not yet been identified for this species. Chlorogenic acid, present in quantifiable amounts in Franz cell release studies, is known from broader pharmacological literature to modulate NF-κB nuclear translocation, suppress [pro-inflammatory cytokine](/ingredients/condition/inflammation) expression (IL-1β, TNF-α), and inhibit glucose-6-phosphatase activity, providing a mechanistic basis for the plant's traditional gastrointestinal applications. The extremophile adaptation of Baccharis incarum to high-altitude UV and oxidative stress environments likely upregulates the biosynthesis of these phenolic secondary metabolites via the phenylpropanoid pathway, resulting in relatively high concentrations of bioactives compared to lowland congeners. ## Clinical Summary No human clinical trials have been conducted on Baccharis incarum, and no animal in vivo studies with pharmacokinetic or efficacy endpoints have been identified in available literature. The entirety of quantified evidence derives from in vitro [antimicrobial](/ingredients/condition/immune-support) (MIC/MBC assays), [antioxidant](/ingredients/condition/antioxidant) (ABTS), genotoxicity (Salmonella), and formulation release (Franz diffusion cell) studies. While these preclinical results are promising—particularly the activity against antibiotic-resistant MRSA and E. faecalis—effect sizes cannot be extrapolated to human clinical outcomes without dose-response data in living systems. Confidence in any therapeutic claim for Baccharis incarum remains very low by evidence-based medicine standards, and the ingredient should be regarded as a candidate for future investigation rather than a clinically validated therapeutic agent. ## Nutritional Profile Baccharis incarum is not consumed as a food or nutritional supplement in the conventional sense, and systematic macronutrient or micronutrient profiling has not been reported in available literature. The pharmacologically relevant nutritional-phytochemical constituents identified include phenolic acids (notably chlorogenic acid, a hydroxycinnamic acid derivative) and flavonoids (including the polymethoxylated flavone 4',5-dihydroxy-3',3,6,7,8-pentamethoxyflavone), which are released from ethanol extracts in quantities detectable by HPLC. Total phenolic content is quantified in gallic acid equivalents (GAE) for research purposes, with [antioxidant](/ingredients/condition/antioxidant) SC50 values of 1.6–4.0 µg GAE/mL suggesting a relatively concentrated phenolic load compared to many temperate medicinal herbs. Bioavailability of these compounds from oral preparations has not been studied; however, chlorogenic acid as a class is known to undergo partial hydrolysis in the small intestine and subsequent colonic fermentation, yielding caffeic acid and quinic acid as bioavailable metabolites—this extrapolation from related botanical sources has not been validated specifically for B. incarum. ## Dosage & Preparation - **Ethanol Tincture (60° ethanol)**: The most pharmacologically studied form; used as both a standalone preparation and as the active component in hydrogel formulations; no standardized oral dose established—traditional Andean use likely involves decoctions of aerial parts but exact volumes are undocumented. - **Ethanol Tincture (80° ethanol)**: Higher-proof extraction yielding comparable [antimicrobial](/ingredients/condition/immune-support) and [antioxidant activity](/ingredients/condition/antioxidant); studied in parallel with 60° preparations in Franz cell release studies; no clinical dosing guidelines available. - **Topical Hydrogel (Phytopharmaceutical Formulation)**: Prepared by incorporating 60° ethanol tincture into a Carbopol® 934 gel matrix; demonstrated stable release of chlorogenic acid and 4',5-dihydroxy-3',3,6,7,8-pentamethoxyflavone in vitro; no approved clinical dosing regimen established. - **Aqueous Decoction (Traditional)**: Aerial parts of the plant boiled in water; consistent with general Andean phytomedicine practice for gastrointestinal complaints; no standardized preparation ratio or dose documented in peer-reviewed sources. - **Methanolic Extract (Research Use)**: Used in the 2009 antimicrobial study for phytochemical characterization; not appropriate for human consumption; referenced here for pharmacological completeness. - **Standardization Note**: No commercially standardized extracts with defined phenolic or flavonoid percentages are currently established; researchers have used gallic acid equivalents (GAE) as the reference standard for total phenolic content quantification. ## Safety & Drug Interactions Baccharis incarum extracts and hydrogel formulations tested negative for genotoxicity in Salmonella mutagenicity (Ames) assays, providing a preliminary indicator of genetic safety, but this single assay type does not constitute a complete toxicological profile and cannot be used to establish safe dosing limits for human use. No data on acute or chronic oral toxicity, hepatotoxicity, nephrotoxicity, reproductive toxicity, or carcinogenicity are available for this species, and no adverse event reports or drug interaction studies have been published. Given the complete absence of human pharmacokinetic data, potential interactions with cytochrome P450 enzymes, P-glycoprotein transporters, or specific drug classes (anticoagulants, immunosuppressants, [antimicrobial](/ingredients/condition/immune-support)s) cannot be assessed, and caution is warranted in polypharmacy contexts. Use during pregnancy and lactation is not supported by any evidence and should be avoided; individuals with known hypersensitivity to Asteraceae family plants face theoretical cross-reactivity risk and should exercise particular caution. ## Scientific Research The available evidence for Baccharis incarum is limited exclusively to in vitro preclinical studies, with no published human clinical trials, animal pharmacokinetic studies, or randomized controlled trials identified in the literature. A key published study investigated standardized 60° and 80° ethanol tinctures and a Carbopol® 934 hydrogel formulation, quantifying [antioxidant activity](/ingredients/condition/antioxidant) (ABTS SC50 1.6–4.0 µg GAE/mL), [antimicrobial](/ingredients/condition/immune-support) activity (MIC 40–80 µg GAE/mL against resistant S. aureus and E. faecalis), bioactive release via HPLC-coupled Franz diffusion cells, and genotoxicity via Salmonella assays—representing the most comprehensive pharmacological characterization available. A 2009 study cited in related Baccharis research confirmed phenolic acid and flavonoid richness with antimicrobial effects against methicillin-resistant strains using aqueous and methanolic extracts, corroborating the primary findings but without providing full quantitative concentration data. The overall evidence base is sparse and methodologically restricted to bench-level assays, meaning all potential health applications remain speculative pending in vivo validation, pharmacokinetic profiling, and clinical investigation. ## Historical & Cultural Context Baccharis incarum occupies the Andean Puna, a region with a continuous human habitation history stretching back thousands of years, where indigenous Quechua and Aymara communities have developed extensive ethnobotanical knowledge of high-altitude flora for medicinal, ritual, and nutritional purposes. Within Bolivian traditional medicine, preparations from Baccharis species—including B. incarum—have been employed for gastrointestinal ailments, febrile conditions, and as topical [antimicrobial](/ingredients/condition/immune-support)s, consistent with the plant's documented pharmacological properties, though species-specific ethnographic records for B. incarum in particular remain sparse in academic literature. The genus Baccharis, comprising over 500 species across the Americas, holds broad cultural significance in Andean healing traditions, with multiple species appearing in the materia medica of colonial-era Andean chroniclers and in contemporary folk pharmacopeias from Argentina, Bolivia, Peru, and Chile. The extremophile ecology of B. incarum—surviving at altitudes above 3,500 meters under intense UV radiation and freeze-thaw cycles—has historically positioned it as a resilient and potent medicinal resource in environments where alternative medicinal plants are scarce. ## Synergistic Combinations No formal synergy studies have been conducted for Baccharis incarum in combination with other ingredients; however, chlorogenic acid—one of its identified bioactives—is documented in broader pharmacological literature to exhibit additive or synergistic [antimicrobial](/ingredients/condition/immune-support) effects when combined with conventional antibiotics such as ampicillin against resistant Gram-positive organisms, suggesting potential adjunctive utility that warrants direct investigation in this species. The flavonoid constituents of Baccharis incarum may theoretically complement the [antioxidant activity](/ingredients/condition/antioxidant) of other high-phenolic Andean botanicals such as muña (Minthostachys mollis) or coca leaf (Erythroxylum coca) in traditional polyherbal preparations, consistent with the widespread Andean practice of combining multiple puna-adapted plants. Formulation with Carbopol® 934 hydrogel has been empirically demonstrated to maintain bioactive stability and controlled release, suggesting that excipient-level synergy with appropriate pharmaceutical carriers is a practical consideration for topical product development. ## Frequently Asked Questions ### What is Baccharis incarum used for traditionally? In Andean traditional medicine across Bolivia and northwestern Argentina, Baccharis incarum has been used primarily for gastrointestinal complaints including indigestion, nausea, and abdominal discomfort, prepared as aqueous decoctions of the aerial parts. Its use is consistent with broader ethnobotanical applications of the Baccharis genus across South American highland communities, though species-specific clinical documentation remains limited in peer-reviewed literature. ### Does Baccharis incarum have antimicrobial properties? Yes, in vitro studies demonstrate that standardized ethanol extracts of Baccharis incarum exhibit antimicrobial activity against antibiotic-resistant Gram-positive bacteria, including methicillin-resistant Staphylococcus aureus (MRSA) and Enterococcus faecalis, with minimum inhibitory concentration (MIC) values of 40–80 µg GAE/mL. These effects are attributed to phenolic compounds and flavonoids, including the identified 4',5-dihydroxy-3',3,6,7,8-pentamethoxyflavone, though no human clinical trials have confirmed these effects in vivo. ### What are the main bioactive compounds in Baccharis incarum? The primary identified bioactive compounds in Baccharis incarum are phenolic acids—most notably chlorogenic acid—and flavonoids, including the polymethoxylated flavone 4',5-dihydroxy-3',3,6,7,8-pentamethoxyflavone. These compounds are released from 60° and 80° ethanol tinctures and have been quantified by HPLC in in vitro Franz diffusion cell studies, with total phenolic content expressed in gallic acid equivalents (GAE). ### Is Baccharis incarum safe to use? Preliminary safety data show that Baccharis incarum extracts and hydrogel formulations tested negative for genotoxicity in Salmonella mutagenicity assays, which is an encouraging but incomplete safety signal. No human toxicology studies, oral safety data, drug interaction assessments, or pregnancy safety data exist, so the ingredient cannot currently be considered fully evaluated for safe human consumption; use should be approached with caution and under the guidance of a qualified healthcare provider. ### What is the effective dose of Baccharis incarum? No standardized or clinically validated dosing regimen has been established for Baccharis incarum in any form, as all pharmacological research to date is limited to in vitro studies without human pharmacokinetic data. Research preparations have used 60° and 80° ethanol tinctures with antimicrobial activity quantified at MIC values of 40–80 µg GAE/mL in cell-based assays, but translating these concentrations to human oral or topical doses requires in vivo studies that have not yet been conducted. ### How does high-altitude cultivation affect the potency of Baccharis incarum? Baccharis incarum grows in high-altitude Andean environments where intense UV exposure triggers adaptive phenolic and flavonoid production as a protective mechanism. This environmental stress concentrates bioactive compounds in the plant's aerial tissues, resulting in extracts with superior antioxidant capacity (SC50 values of 1.6–4.0 µg GAE/mL). Plants cultivated at lower altitudes or in controlled conditions typically show lower concentrations of these protective compounds, making source and growing conditions a significant quality differentiator. ### What is the difference between Baccharis incarum extract and whole plant preparations? Standardized ethanol extracts of Baccharis incarum concentrate phenolic compounds and flavonoids primarily in the aerial tissues, delivering measurable antioxidant potency with documented SC50 values. Whole plant preparations contain these active compounds at lower concentrations and may include less bioactive root or stem material, resulting in variable potency between batches. Standardized extracts offer consistent dosing and research-backed efficacy, while whole plant forms provide a broader spectrum of constituents that may have synergistic effects not yet fully characterized. ### Does Baccharis incarum retain its antioxidant properties in different extraction methods? Ethanol extraction has been shown to effectively preserve and concentrate the phenolic compounds and flavonoids responsible for Baccharis incarum's potent ABTS radical scavenging capacity. Other extraction methods (water, glycerin, or CO2) may yield different bioactive profiles and varying antioxidant potency depending on solvent polarity and extraction parameters. The choice of extraction solvent directly impacts which compounds are isolated and the resulting antioxidant strength, making extraction method an important consideration for supplement efficacy. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*