# Vitexnegheteroins (Vitex negundo chromone heterocyclic compounds) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/vitexnegheteroins-vitex-negundo-chromone-heterocyclic-compounds **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-02 **Evidence Score:** 1 / 10 **Category:** Compound **Also Known As:** Nirgundi chromone compounds, Vitex negundo chromone heterocyclic isolates, V. negundo C20H18O6 chromone fraction, Five-leaved chaste tree chromones, Vitexnegheteroins, Vitexnegheteroins (Vitex negundo bioactive complex) ## Overview Vitexnegheteroins are chromone-scaffold compounds (exemplified by a yellow solid C20H18O6, MW 354.1112) isolated from Vitex negundo leaves, exerting [antioxidant](/ingredients/condition/antioxidant) and [anti-inflammatory](/ingredients/condition/inflammation) effects primarily through hydrogen bonding and electron donation enabled by hydroxyl (δ 12.10 ppm) and methoxyl substituents on the chromone ring. Evidence for these compounds is limited to in vitro and early in vivo preclinical data, with methanolic leaf extracts demonstrating radical scavenging at IC50 values of 45.305–79.365 mg/mL, reflecting weak-to-moderate antioxidant potency (IC50 >20 µM). ## Health Benefits - **[Antioxidant Activity](/ingredients/condition/antioxidant)**: Chromone constituents donate electrons and form hydrogen bonds via hydroxyl groups, scavenging free radicals; methanolic Vitex negundo extracts show IC50 values of 79.365 mg/mL, indicating weaker but measurable radical scavenging activity relative to potent antioxidants. - **[Anti-inflammatory](/ingredients/condition/inflammation) Effects**: Chromone compound 1 (C20H18O6) exhibits IR absorptions at 1675 and 1630 cm⁻¹ consistent with conjugated carbonyl groups involved in prostaglandin pathway modulation; isolated chromones from V. negundo have demonstrated in vivo anti-inflammatory activity in animal models. - **Analgesic Properties**: Chromone-scaffold compounds contribute to the well-documented analgesic properties of V. negundo leaf extracts, likely through modulation of pain-signaling pathways; in vivo studies using isolated compounds have confirmed this activity though precise molecular targets require further characterization. - **Antipyretic Potential**: Traditional Ayurvedic application of V. negundo leaves for fever reduction is supported by phytochemical constituents including chromones and terpenoids that may inhibit cyclooxygenase-mediated prostaglandin E2 synthesis; this mechanism parallels other chromone-containing botanical antipyretics. - **[Antimicrobial](/ingredients/condition/immune-support) Action**: Phenolic and chromone constituents of V. negundo methanolic extracts contribute to observed antimicrobial properties against various pathogens; the electron-rich aromatic chromone ring system can disrupt microbial membrane integrity and inhibit key metabolic enzymes. - **Prolactin-Modulating Effects**: Bioactive compounds from V. negundo have been shown to reduce elevated serum prolactin in hyperprolactinemia and relieve mastodynia, paralleling the [dopamine](/ingredients/condition/mood)rgic mechanisms associated with the broader Vitex genus; specific chromone contributions to this effect remain under investigation. - **Anthelmintic Activity**: Methanolic leaf extracts containing chromone heteroins alongside terpenoids and fatty acids such as octadecadienoic acid (21.93% in wild leaves) demonstrate anthelmintic properties, likely through disruption of helminth neuromuscular function and membrane permeability. ## Mechanism of Action Vitexnegheteroins act primarily through the chromone scaffold's capacity for electron donation and hydrogen bonding: the hydroxyl group at δ 12.10 ppm (NMR) stabilizes free radical intermediates, while the conjugated carbonyl system (IR: 1675, 1630 cm⁻¹; UV: 248, 336 nm) facilitates resonance delocalization of unpaired electrons, underpinning radical scavenging. The methoxyl substituents on the C20H18O6 chromone core enhance lipophilicity and may facilitate membrane penetration, allowing interaction with intracellular [inflammatory](/ingredients/condition/inflammation) mediators and possibly inhibiting NF-κB pathway activation, consistent with mechanisms reported for other chromone phytochemicals. Co-occurring octadecadienoic acid (a C18:2 polyunsaturated fatty acid present at 21.93% in wild leaf extracts) may contribute complementary antioxidant effects by modulating [lipid peroxidation](/ingredients/condition/antioxidant) cascades and competing with arachidonic acid for cyclooxygenase and lipoxygenase enzymes. The terpenoid fraction, including D-viridiflorol (6.79%) and drimenol (1.51%), may synergize with chromone constituents by modulating membrane fluidity and enhancing bioavailability of the chromone compounds at target tissues. ## Clinical Summary No clinical trials specifically investigating isolated vitexnegheteroins (the chromone constituents of Vitex negundo) have been identified in the available literature; human evidence is absent for this compound class at the level of randomized controlled trials. The broader phytomedicine evidence for Vitex negundo includes traditional-use documentation and pharmacological reports of prolactin reduction in hyperprolactinemia and mastodynia relief, but these lack quantified effect sizes, defined sample populations, or placebo controls as reported in accessible sources. In vitro and animal data suggest [anti-inflammatory](/ingredients/condition/inflammation), analgesic, and [antioxidant](/ingredients/condition/antioxidant) activities consistent with the chromone pharmacophore, but extrapolation to human clinical benefit remains speculative without Phase I safety and Phase II efficacy trials. The current evidence base warrants classification as preliminary, and consumers or clinicians should not substitute vitexnegheteroins-containing preparations for evidence-based treatments pending robust human studies. ## Nutritional Profile Vitexnegheteroins are bioactive phytochemicals rather than nutritional macronutrients; the parent plant Vitex negundo leaves contain a complex phytochemical matrix rather than significant caloric, protein, or fat content relevant to nutrition. The methanolic leaf extract is dominated by octadecadienoic acid (linoleic acid, 21.93%), a polyunsaturated omega-6 fatty acid with established roles in membrane phospholipid composition and eicosanoid precursor [metabolism](/ingredients/condition/weight-management). Phenolic and flavonoid glycosides contribute polyphenolic [antioxidant](/ingredients/condition/antioxidant)s, while terpene alcohols D-viridiflorol (6.79%) and drimenol (1.51%) represent sesquiterpenoid constituents. The chromone vitexnegheteroins (C20H18O6, MW 354.1112) contain six oxygen atoms distributed across hydroxyl and methoxyl functional groups, contributing polar surface area that influences bioavailability; no quantitative concentration data per gram of leaf dry weight has been reported for isolated chromone fractions, limiting precise nutritional or phytochemical dosing assessment. ## Dosage & Preparation - **Methanolic Leaf Extract (Research Grade)**: Used at concentrations yielding IC50 45.305–79.365 mg/mL in DPPH assays; no standardized human dose established. - **Traditional Ayurvedic Leaf Preparation**: Leaves are applied as poultices or decocted in water for topical analgesic and [anti-inflammatory](/ingredients/condition/inflammation) use; no validated oral dose range for chromone fractions. - **Callus-Derived Extract (Experimental)**: Green callus (BAP 2.0 mg/L, 2,4-D 0.2 mg/L in MS medium) yields octadecadienoic acid at 47.79% and chromone compounds; intended for phytochemical commercialization, not yet dosed clinically. - **Chromatography-Isolated Chromone Fractions**: Characterized by NMR/MS/IR/UV; compound 1 (C20H18O6) and compound 2 used in in vivo animal studies at unspecified doses; human equivalent doses not established. - **Standardization Note**: No commercial standardization percentage for vitexnegheteroins exists; any product claiming standardization should specify the chromone scaffold content and MW 354.1112 marker compound. - **Timing**: No pharmacokinetic absorption data available; traditional use involves multiple daily applications of leaf preparations without defined timing protocols. ## Safety & Drug Interactions No formal toxicological studies, adverse event profiles, or maximum tolerated dose data have been published specifically for isolated vitexnegheteroins; safety inference relies on the traditional use history of whole Vitex negundo leaf preparations, which are generally regarded as safe in customary Ayurvedic contexts. The broader Vitex genus (including V. agnus-castus) has known [dopamine](/ingredients/condition/mood)rgic activity that can reduce serum prolactin, raising a theoretical concern for additive hypoprolactinemic effects when combined with dopamine agonist medications (e.g., bromocriptine, cabergoline) or dopaminergic herbs; clinicians should exercise caution in co-administration. Pregnancy and lactation safety has not been established for vitexnegheteroins; V. negundo has uterine-stimulating properties documented in traditional medicine, warranting avoidance during pregnancy until safety data are available. Individuals taking hormonal therapies, anticoagulants (given the omega-6 fatty acid content in extracts), or immunosuppressants should consult a qualified healthcare provider before using V. negundo-derived chromone preparations. ## Scientific Research Available evidence for vitexnegheteroins is exclusively preclinical, comprising in vitro radical scavenging assays, GC-MS phytochemical profiling, and limited in vivo animal pharmacology studies — no peer-reviewed randomized controlled trials in humans have been published for these specific chromone isolates. The [antioxidant](/ingredients/condition/antioxidant) IC50 values reported for methanolic (79.365 mg/mL) and acetone (45.305 mg/mL) extracts of V. negundo leaves represent bulk extract activity rather than purified chromone compound potency, making it difficult to attribute effects specifically to vitexnegheteroins versus co-occurring fatty acids, terpenoids, or flavonoids. Structural characterization of chromone compound 1 (C20H18O6, MW 354.1112) by NMR, MS, IR, and UV spectroscopy provides chemical identity but does not substitute for dose-response pharmacokinetic or efficacy data. Broader V. negundo research supports prolactin reduction and mastodynia relief, but these outcomes have not been quantified in controlled human trials with defined sample sizes or statistical effect measures, significantly limiting confidence in clinical translation. ## Historical & Cultural Context Vitex negundo has been integral to Ayurvedic medicine for over two millennia, referenced in classical Sanskrit texts as 'Nirgundi,' meaning 'that which protects the body from disease,' and prescribed for joint pain, fever, worm infestations, and uterine disorders. In Chinese traditional medicine, the plant is known as 'Huang Jing' or 'Man Jing Zi' and employed for headaches, rheumatic conditions, and eye disorders, reflecting parallel empirical discovery of its [anti-inflammatory](/ingredients/condition/inflammation) properties across independent medical traditions. Southeast Asian folk medicine traditions in the Philippines, India, and Sri Lanka use leaf fumigation, poultices, and decoctions for respiratory conditions, skin diseases, and post-partum care, with aromatic volatile compounds contributing to the plant's characteristic pungent, bitter, and astringent organoleptic profile. The modern isolation and structural characterization of chromone constituents (vitexnegheteroins) represents a scientific validation effort aimed at identifying the molecular basis of these longstanding ethnopharmacological uses without depleting wild plant populations through sustainable callus biotechnology. ## Synergistic Combinations Vitexnegheteroins may exhibit additive [antioxidant](/ingredients/condition/antioxidant) synergy when combined with flavonoid-rich extracts such as quercetin or rutin, as the chromone scaffold and flavonol structures share electron-donation mechanisms that together broaden radical scavenging across hydrophilic and lipophilic compartments. The co-occurring octadecadienoic acid (linoleic acid) within V. negundo extracts may potentiate chromone membrane permeability by serving as a lipid carrier, enhancing intracellular delivery of the C20H18O6 chromone to cytoplasmic inflammatory targets — a natural endogenous synergy within the whole extract matrix. In Ayurvedic formulation practice, V. negundo is traditionally combined with [anti-inflammatory](/ingredients/condition/inflammation) herbs such as Boswellia serrata (shallaki) and Zingiber officinale (ginger), which modulate 5-LOX and COX-2 respectively, potentially creating complementary multi-target anti-inflammatory stacks with vitexnegheteroins' chromone-mediated NF-κB modulation. ## Frequently Asked Questions ### What are vitexnegheteroins and where do they come from? Vitexnegheteroins are chromone-scaffold heterocyclic compounds isolated from the leaves and callus of Vitex negundo (nirgundi or five-leaved chaste tree), a medicinal shrub native to tropical Asia and East Africa. The primary characterized compound is a yellow solid with molecular formula C20H18O6 (MW 354.1112), bearing hydroxyl and methoxyl substituents on the chromone ring, identified by NMR, MS, IR, and UV spectroscopy. They represent a subset of the 24 bioactive constituents found in methanolic leaf extracts of V. negundo. ### How strong is the antioxidant activity of vitexnegheteroins? The antioxidant activity of vitexnegheteroins-containing V. negundo extracts is classified as weak-to-moderate, with IC50 values of 45.305 mg/mL (acetone extract) and 79.365 mg/mL (methanol extract) in DPPH radical scavenging assays — corresponding to IC50 >20 µM when converted to molar units. This places vitexnegheteroins below highly potent antioxidants like ascorbic acid or quercetin in comparative assays. The antioxidant mechanism involves electron donation and hydrogen bonding via the hydroxyl group at δ 12.10 ppm (¹H NMR) on the chromone scaffold. ### Are there any human clinical trials on vitexnegheteroins? No published randomized controlled trials or formal human clinical studies exist for isolated vitexnegheteroins as of current available literature. Evidence is limited to in vitro radical scavenging assays, GC-MS phytochemical profiling of V. negundo extracts, and limited in vivo animal pharmacology confirming anti-inflammatory and analgesic activity of chromone isolates. The broader V. negundo plant has been described in traditional medicine contexts for prolactin reduction in hyperprolactinemia and mastodynia relief, but these outcomes have not been studied in quantified human trials. ### What is the recommended dosage of vitexnegheteroins supplements? No standardized clinical dosage has been established for vitexnegheteroins because no human pharmacokinetic or dose-finding studies have been published. Research to date focuses on methanolic and acetone extracts used in concentrations effective for in vitro assays (IC50 45–79 mg/mL range), which cannot be directly converted to oral human doses without bioavailability data. Traditional Ayurvedic use of V. negundo leaves involves decoctions and poultices at non-standardized amounts; anyone considering a V. negundo supplement should consult a healthcare provider and select products that disclose chromone content and extraction method. ### Is Vitex negundo the same as Vitex agnus-castus (chasteberry)? Vitex negundo and Vitex agnus-castus (chasteberry) are distinct species within the same Vitex genus and share some pharmacological properties, including dopaminergic activity that can reduce serum prolactin, but they differ in their phytochemical profiles and geographic origins. V. agnus-castus is native to the Mediterranean and is widely studied for premenstrual syndrome and menstrual irregularities, while V. negundo is native to tropical Asia and contains unique chromone constituents (vitexnegheteroins, C20H18O6) not documented in V. agnus-castus. These species should not be used interchangeably in supplementation without species-specific evidence. ### How do vitexnegheteroins compare to other Vitex species in terms of bioactive compounds? Vitex negundo contains unique chromone heterocyclic compounds that differ structurally from those found in Vitex agnus-castus, making direct potency comparisons difficult. While Vitex negundo shows measurable antioxidant activity with IC50 values around 79.365 mg/mL, this is generally weaker than more potent antioxidants like vitamins C or E. The chromone composition in Vitex negundo may offer distinct anti-inflammatory benefits through mechanisms specific to its chemical structure rather than superior radical scavenging alone. ### What safety concerns exist regarding vitexnegheteroins and existing health conditions? Limited human clinical data on vitexnegheteroins means safety profiles for specific populations—including those with liver disease, hormonal sensitivities, or immune disorders—have not been thoroughly established. Because chromone compounds undergo hepatic metabolism, individuals with compromised liver function should exercise caution before supplementing. Anyone with chronic inflammatory or autoimmune conditions should consult a healthcare provider before use, as anti-inflammatory effects could potentially interact with existing treatments. ### Does the extraction method or solvent type affect the potency of vitexnegheteroins? Methanolic extraction of Vitex negundo has been documented to yield vitexnegheteroins with measurable antioxidant activity, suggesting that solvent choice influences bioactive compound recovery. Different extraction methods (aqueous, ethanolic, methanolic) may yield varying concentrations of chromone heterocyclic compounds and thus different biological effects. The choice between raw plant material, standardized extracts, and concentrated formulations will significantly impact the actual dose and efficacy of vitexnegheteroins delivered per serving. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*