# Miconia crenata (Miconia crenata) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/miconia-crenata-miconia-crenata **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-03 **Evidence Score:** 1 / 10 **Category:** Amazonian **Also Known As:** Miconia crenata (Vahl) Michelang., Melastomataceae shrub, Amazonian Miconia, Crenate Miconia ## Overview Miconia crenata leaves and fruits contain high concentrations of flavonoids (508.84 ± 154.42 mg/mg total flavonoid content) and phenolic compounds that scavenge [free radical](/ingredients/condition/antioxidant)s and disrupt bacterial cell growth through membrane-active mechanisms. Methanol leaf extracts exhibit a DPPH radical scavenging IC50 of 40.54 μg/mL and demonstrated antibacterial activity against Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa at MIC values of 10.4–21.6 mg/mL in vitro, with phenolic fractions shown to synergize with conventional antibiotics including ampicillin and tetracycline. ## Health Benefits - **Free Radical Scavenging and Antioxidant Protection**: Leaf methanol extracts yield a DPPH IC50 of 40.54 μg/mL, driven by high flavonoid and phenolic content that donate hydrogen atoms to neutralize [reactive oxygen species](/ingredients/condition/antioxidant) and interrupt lipid peroxidation chain reactions. - **Antibacterial Activity Against Pathogenic Bacteria**: Phenolic fractions from M. crenata inhibit growth of E. coli (largest inhibition zone, lowest MIC), S. aureus, and P. aeruginosa in vitro, with activity enhanced when combined with ampicillin or tetracycline, suggesting membrane-disrupting and antibiotic-potentiating mechanisms. - **Anti-inflammatory Potential via Genus-Level Triterpenoids**: Related Miconia species contribute ursolic acid and oleanolic acid that suppress [pro-inflammatory cytokine](/ingredients/condition/inflammation)s IL-1β, IL-6, and TNF-α and inhibit prostaglandin synthesis, pathways plausibly shared by M. crenata based on genus-wide phytochemical profiles. - **Antiparasitic Activity Against Trypanosoma cruzi**: Triterpenoids identified across the Miconia genus, including ursolic acid (IC50 12.8 μM) and oleanolic acid (IC50 17.1 μM), reduced T. cruzi parasitemia by 70.4–75.7% in animal models, highlighting potential for Chagas disease-relevant applications within this botanical family. - **Antimutagenic and Cytoprotective Effects**: Related species such as M. latecrenata demonstrate reduction of reactive oxygen species and antimutagenic activity, effects plausibly attributable to the shared flavonoid glycosides and phenolic acids documented across the genus. - **Synergistic Antibiotic Potentiation**: Phenolic fractions from M. crenata have been shown in vitro to act synergistically with standard antibiotics including ampicillin and tetracycline, lowering effective inhibitory concentrations and potentially addressing [antimicrobial](/ingredients/condition/immune-support) resistance mechanisms. - **Chlorophyll-Rich Nutritional Bioactivity**: Fruits of M. crenata contain chlorophyll and derivatives up to 45.0 mg/100 g dry weight, contributing to antioxidant and potentially [photoprotect](/ingredients/condition/skin-health)ive bioactivities consistent with chlorophyll's known roles in reducing oxidative stress markers. ## Mechanism of Action The primary [antioxidant](/ingredients/condition/antioxidant) mechanism involves hydrogen atom transfer and single electron donation by phenolic hydroxyl groups in flavonoids such as quercetin, kaempferol, and matteucinol, which quench DPPH and superoxide radicals, interrupting oxidative chain reactions at the molecular level. Antibacterial action is mediated by phenolic compounds that disrupt bacterial cell membrane integrity and inhibit essential enzymatic functions, with phenolic fractions potentiating ampicillin and tetracycline by impairing efflux pump activity or compromising cell wall biosynthesis. Triterpenoids documented across the Miconia genus—specifically ursolic acid and oleanolic acid—inhibit cyclooxygenase and lipoxygenase pathways to suppress prostaglandin synthesis and block NF-κB-driven transcription of IL-1β, IL-6, and TNF-α, constituting a multi-target [anti-inflammatory](/ingredients/condition/inflammation) mechanism. Glycosylated flavonoids at C3 and C7 positions and tannins further contribute to antioxidant and [antimicrobial](/ingredients/condition/immune-support) activity through metal chelation and protein precipitation, respectively, creating a polypharmacological bioactive profile consistent with the 148 compounds identified across the Miconia genus. ## Clinical Summary No human clinical trials have been conducted specifically on Miconia crenata, and the clinical evidence base is entirely absent at this time. Preclinical data—restricted to cell-free DPPH assays, bacterial inhibition zone measurements, and rodent models of parasitemia using genus-related extracts—provide mechanistic rationale for [antioxidant](/ingredients/condition/antioxidant) and [antimicrobial](/ingredients/condition/immune-support) applications but do not establish human efficacy, effective dose ranges, or pharmacokinetic parameters. Effect sizes from animal models (e.g., 75.7% parasitemia reduction with genus triterpenoids) are promising but are derived from studies with incompletely reported methodologies and sample sizes, limiting confidence in extrapolation. Until Phase I and Phase II clinical trials are completed for M. crenata extracts, any claim of clinically meaningful benefit in humans remains speculative. ## Nutritional Profile Miconia crenata leaves contain exceptionally high total flavonoid content measured at 508.84 ± 154.42 mg/mg at a 0.02 mg/mL extract concentration via aluminum chloride colorimetric assay, alongside significant total phenolic content attributable to quercetin, kaempferol, matteucinol glycosides, phenolic acids, and tannins. Fruits contain chlorophyll and chlorophyll derivatives at up to 45.0 mg/100 g dry weight, contributing to both pigment content and [antioxidant](/ingredients/condition/antioxidant) capacity. Across the Miconia genus, triterpenoids including ursolic acid, oleanolic acid, α-amyrin, and β-amyrin are structurally characterized, with 148 total compounds identified at genus level. Bioavailability of phenolic glycosides is expected to be moderate and highly dependent on gut microbial deconjugation of glycosidic bonds; lipophilic triterpenoids likely require formulation with lipid carriers for meaningful oral absorption, though no human bioavailability studies for M. crenata specifically have been conducted. ## Dosage & Preparation - **Methanol Leaf Extract (Laboratory Grade)**: Used in research at concentrations of 0.02 mg/mL for flavonoid quantification and at MIC ranges of 10.4–21.6 mg/mL for antibacterial testing; no human supplemental dose established. - **Aqueous Leaf Infusion (Traditional-Style Preparation)**: Hot water extracts have been prepared in lab settings for screening purposes; no standardized preparation protocol or human dose guideline exists. - **Hexane Fruit Extract**: Used in preclinical studies for isolation of lipophilic compounds including chlorophyll derivatives (up to 45.0 mg/100 g DW); not available in commercial supplement form. - **Standardized Extract (Theoretical)**: Given genus-level phytochemistry, standardization to total flavonoid content (e.g., quercetin equivalents) or total phenolic content (gallic acid equivalents) would be logical endpoints, but no commercial standardized product has been validated. - **Timing and Formulation Notes**: No human pharmacokinetic data exist; bioavailability of phenolic glycosides would theoretically depend on [gut microbiome](/ingredients/condition/gut-health) deglycosylation, food matrix effects, and first-pass hepatic [metabolism](/ingredients/condition/weight-management), all of which remain unstudied for this species. ## Safety & Drug Interactions Miconia crenata and related Miconia genus species have demonstrated low acute toxicity in limited laboratory assessments, with genus extracts considered safe at high concentrations in preliminary acute toxicity screens; however, dose-dependent cytotoxicity has been noted at very high polyphenol concentrations in cell-based assays. No specific adverse effects, drug interactions, or contraindications have been formally documented for M. crenata in humans, and the absence of clinical trial data means the full safety profile in therapeutic contexts remains unknown. Given the genus-level evidence of cytotoxicity at concentrated extract doses and the presence of bioactive tannins, caution is warranted regarding high-dose or long-term consumption, and individuals taking anticoagulants, immunosuppressants, or broad-spectrum antibiotics should consult a healthcare provider before use due to theoretical polyphenol-mediated drug interaction risks. No safety data exist for use during pregnancy or lactation, and use in these populations cannot be recommended in the absence of controlled safety studies. ## Scientific Research The available evidence base for Miconia crenata consists exclusively of in vitro assays and limited in vivo animal studies on closely related Miconia genus species, with no published human clinical trials identified as of current literature. Key in vitro findings include a DPPH IC50 of 40.54 μg/mL for leaf methanol extracts, antibacterial MIC values of 10.4–21.6 mg/mL against E. coli, S. aureus, and P. aeruginosa, and genus-level triterpenoid IC50 values of 12.8 μM (ursolic acid) and 17.1 μM (oleanolic acid) against T. cruzi. In vivo animal studies on Miconia genus triterpenoids report 70.4–75.7% reductions in T. cruzi parasitemia, though sample sizes and methodological details remain incompletely reported in available literature. The overall evidence quality is preliminary; results cannot be extrapolated to human supplemental efficacy or safety without controlled clinical investigation. ## Historical & Cultural Context Miconia crenata does not have a well-documented individual ethnobotanical record in published literature, and no specific traditional medicine system has been formally documented as utilizing this species by name. Within the broader Miconia genus, species such as M. albicans and M. rubiginosa have been employed in Brazilian folk medicine for the management of pain and [inflammatory](/ingredients/condition/inflammation) conditions, typically as leaf decoctions or poultices applied topically or consumed as teas. The Melastomataceae family more broadly represents a significant source of medicinal plants across Amazonian indigenous communities, where species richness is high and plant-based remedies for infection and fever are culturally integral. The absence of a distinct traditional use record for M. crenata specifically may reflect taxonomic complexity within the genus, limited ethnobotanical survey coverage in its native range, or overlap with more commonly studied congeners. ## Synergistic Combinations Phenolic fractions of Miconia crenata have demonstrated in vitro synergy with conventional antibiotics ampicillin and tetracycline against E. coli, S. aureus, and P. aeruginosa, suggesting that co-administration could lower effective antibiotic concentrations and potentially mitigate resistance, though this has not been validated in vivo or in humans. At the genus level, ursolic acid and oleanolic acid exhibit complementary [anti-inflammatory](/ingredients/condition/inflammation) mechanisms—COX/LOX pathway inhibition and cytokine suppression—that may synergize with other anti-inflammatory botanicals such as boswellic acids (Boswellia serrata) or curcuminoids (Curcuma longa) when combined in multi-botanical formulations. Pairing polyphenol-rich M. crenata extracts with lipid-based delivery systems or piperine (from black pepper) could theoretically enhance absorption of poorly bioavailable triterpenoids and flavonoid aglycones, a strategy well-supported for structurally analogous phytochemicals. ## Frequently Asked Questions ### What are the main bioactive compounds in Miconia crenata? Miconia crenata leaves are rich in flavonoids—including quercetin, kaempferol, and matteucinol glycosides—and phenolic acids, with total flavonoid content measured at 508.84 ± 154.42 mg/mg at 0.02 mg/mL extract concentration. Fruits contain chlorophyll derivatives up to 45.0 mg/100 g dry weight, and the broader Miconia genus contributes triterpenoids such as ursolic acid, oleanolic acid, α-amyrin, and β-amyrin, totaling 148 identified compounds across the genus. ### Does Miconia crenata have proven antibacterial effects? In vitro studies show that phenolic fractions from M. crenata inhibit Escherichia coli (showing the largest inhibition zones and lowest MIC values), Staphylococcus aureus, and Pseudomonas aeruginosa at MIC values ranging from 10.4 to 21.6 mg/mL. These phenolic fractions have also demonstrated synergy with conventional antibiotics ampicillin and tetracycline in laboratory assays, though no human clinical trials have confirmed these effects in vivo. ### Is Miconia crenata safe to consume? Limited acute toxicity assessments on M. crenata and related Miconia genus species suggest low toxicity at moderate concentrations, but dose-dependent cytotoxicity has been observed at high polyphenol extract concentrations in cell-based assays. No human safety data, established maximum safe doses, or guidance for special populations such as pregnant or lactating individuals have been published, so consumption beyond culinary amounts is not currently supported by evidence. ### What is the antioxidant potency of Miconia crenata? Methanol leaf extracts of Miconia crenata demonstrate a DPPH radical scavenging IC50 of 40.54 μg/mL, indicating moderate to good antioxidant potency compared to standard botanical antioxidants in analogous assay conditions. This activity is primarily attributed to the high flavonoid and phenolic content of leaf tissue, which donates hydrogen atoms to neutralize free radicals through well-characterized chemical mechanisms. ### Are there any human clinical trials on Miconia crenata? No human clinical trials on Miconia crenata have been published as of current available literature; all evidence is limited to in vitro biochemical assays and preclinical animal studies conducted on closely related Miconia genus species. While triterpenoids from the genus have shown 70.4–75.7% reductions in T. cruzi parasitemia in animal models, these findings have not been translated into human studies, and no supplemental dose, bioavailability data, or clinical efficacy endpoint has been established for M. crenata specifically. ### What forms of Miconia crenata are most effective for antioxidant benefits? Leaf methanol extracts and standardized phenolic fractions of Miconia crenata demonstrate the highest antioxidant potency, with DPPH IC50 values as low as 40.54 μg/mL. Whole leaf extracts tend to preserve the synergistic effects of multiple flavonoids and phenolic compounds better than isolated fractions. Standardized extracts are generally preferred in supplements to ensure consistent bioactive compound levels across batches. ### Who should consider taking Miconia crenata supplements? Individuals seeking natural antioxidant support and those interested in botanicals with documented free radical scavenging properties may benefit from Miconia crenata. People concerned with oxidative stress-related conditions and those preferring plant-based alternatives to synthetic antioxidants are potential candidates. However, consult a healthcare provider before use, especially if you have existing health conditions or are taking medications. ### How does Miconia crenata compare to other herbal antioxidants in potency? Miconia crenata's DPPH IC50 of 40.54 μg/mL indicates strong free radical scavenging ability, positioning it competitively among herbal antioxidants, though direct comparative studies with other commonly used herbs remain limited. Its potency is driven by exceptionally high flavonoid and phenolic content relative to many traditional antioxidant botanicals. More head-to-head clinical comparisons are needed to definitively establish its ranking among commercial antioxidant ingredients. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*