# Linarin (acacetin-7-O-rutinoside) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/linarin-acacetin-7-o-rutinoside **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-05 **Evidence Score:** 1 / 10 **Category:** Compound **Also Known As:** acacetin-7-O-rutinoside, acacetin-7-rutinoside, 7-O-rutinosyl acacetin, linarine, buddleoside ## Overview Linarin is a glycosylated flavonoid (acacetin-7-O-rutinoside) that exerts anxiolytic, [anti-inflammatory](/ingredients/condition/inflammation), and [neuroprotective effect](/ingredients/condition/cognitive)s by inhibiting NF-κB and MAPK signaling, modulating acetylcholinesterase activity, and binding the sulfonylurea receptor-1 (SUR1) to reduce oxidative neuronal stress. All documented pharmacological evidence derives from preclinical in vitro and animal models—including 50 mg/kg oral dosing reversing cytokine-driven lethality in mice—with no human clinical trial data currently available to confirm efficacy or safe dosing in humans. ## Health Benefits - **[Anti-Inflammatory](/ingredients/condition/inflammation) Activity**: Linarin suppresses LPS-induced production of nitric oxide, TNF-α, IL-1β, IL-6, and PGE2 in RAW264.7 macrophages at concentrations of 2.5–20 μg/mL by co-inhibiting NF-κB nuclear translocation and MAPK (ERK, JNK, p38) phosphorylation, also reducing vascular permeability and tissue edema in rodent models. - **[Hepatoprotect](/ingredients/condition/detox)ion**: At 50 mg/kg in galactosamine/LPS-induced acute liver failure mouse models, linarin attenuated hepatocyte apoptosis by suppressing the TLR4/IRAK cascade, downregulating caspase-3 and cytochrome c release, and upregulating anti-apoptotic Bcl-xL and p-STAT3/STAT3 ratios. - **Neuroprotection and Anxiolytic Potential**: Linarin binds the sulfonylurea receptor-1 (SUR1) to mitigate ATP-depletion-induced [oxidative stress](/ingredients/condition/antioxidant) in neurons, and its 4'-methoxyl group and 7-O-rutinoside moiety inhibit [acetylcholine](/ingredients/condition/cognitive)sterase (AChE), potentially preserving cholinergic neurotransmission relevant to anxiety and cognitive decline. - **Insulin Resistance and Antidiabetic Effects**: In palmitate-treated HepG2 hepatocytes and high-fat diet obese mouse models, linarin improved glucose uptake and [insulin sensitivity](/ingredients/condition/weight-management) by targeting c-FOS/ARG2 signaling, reducing ARG2 expression and hepatic inflammation, and lowering body weight and fat mass accumulation. - **Anticancer Properties**: Preclinical data demonstrate linarin induces apoptosis, oxidative stress, and genotoxic effects while inhibiting proliferation and migration/invasion in lung, prostate, glioma, and brain cancer cell lines, suggesting broad cytotoxic activity not yet characterized in human tissue. - **[Cardiovascular](/ingredients/condition/heart-health) and Vascular Effects**: Linarin modulates Akt signaling and suppresses iNOS/COX-2 expression in human umbilical vein endothelial cells (HUVECs), reducing endothelial inflammatory activation that underlies atherosclerotic plaque formation. - **Sedative and Sleep-Supporting Context**: As a constituent of Valeriana officinalis, linarin contributes to the sedative pharmacology of valerian root preparations, though its isolated contribution to GABAergic or adenosine receptor modulation relative to other valerian constituents (valerenic acid, isovaltrate) has not been fully delineated. ## Mechanism of Action Linarin's [anti-inflammatory](/ingredients/condition/inflammation) mechanism centers on dual inhibition of NF-κB (preventing IκB degradation and p65 nuclear translocation) and the MAPK cascade (blocking phosphorylation of ERK1/2, JNK, and p38), thereby suppressing transcription of iNOS, COX-2, and proinflammatory cytokine genes in macrophages and hepatocytes. Its [hepatoprotective](/ingredients/condition/detox) effect is mediated through interference with TLR4/IRAK1/4 signaling, reduction of [mitochondrial](/ingredients/condition/energy) apoptotic signaling (↓cytochrome c release, ↓caspase-3 activation), upregulation of Bcl-xL, and activation of the JAK/STAT3 survival pathway. [Neuroprotective](/ingredients/condition/cognitive) activity involves direct binding to SUR1 on neurons and astrocytes, attenuating ATP-sensitive potassium channel dysregulation during ischemic or [oxidative stress](/ingredients/condition/antioxidant), while the aglycone acacetin backbone and 7-O-rutinoside substituent sterically inhibit acetylcholinesterase at the active site gorge. Antidiabetic effects are mechanistically linked to transcriptional suppression of c-FOS and ARG2, two nodes implicated in hepatic [insulin resistance](/ingredients/condition/weight-management) and inflammatory lipid metabolism, improving downstream insulin receptor substrate (IRS-1) phosphorylation and GLUT2-mediated glucose uptake. ## Clinical Summary No human clinical trials evaluating isolated linarin have been conducted or reported in the peer-reviewed literature to date, meaning there are no clinical effect sizes, patient populations, primary endpoints, or safety outcomes from which to draw translatable conclusions. Relevant evidence is entirely extrapolated from preclinical models: 50 mg/kg oral linarin reversed GalN/LPS-induced lethality and normalized TNF-α/IL-6 in mice, and high-fat diet obese mice showed improved glucose tolerance, reduced [insulin resistance](/ingredients/condition/weight-management) index, and decreased fat mass following linarin treatment. These animal-derived findings, while pharmacologically coherent and mechanistically well-characterized, cannot reliably predict effective or safe human doses due to unknown oral bioavailability, first-pass metabolism, and species-specific pharmacokinetic differences. Confidence in linarin as a clinically actionable intervention is currently very low, and its use in humans should be considered experimental pending Phase I/II trial data. ## Nutritional Profile Linarin is a pure flavonoid glycoside molecule (molecular formula C₂₈H₃₂O₁₄, molecular weight 592.54 g/mol) and does not contribute macronutrients, vitamins, or minerals as a dietary constituent. Its structure consists of the flavone aglycone acacetin (5,7-dihydroxy-4'-methoxyflavone) glycosylated at the C-7 hydroxyl position with the disaccharide rutinose (6-O-α-L-rhamnopyranosyl-β-D-glucopyranoside). Phytochemically, it belongs to the flavone subclass of flavonoids, sharing structural and bioactivity overlap with apigenin, acacetin, and luteolin. Bioavailability is expected to be moderate and dependent on [gut microbiome](/ingredients/condition/gut-health)-mediated deglycosylation to release the acacetin aglycone, which is more lipophilic (logP ~2.8) and membrane-permeable; no quantitative human absorption studies (Cmax, Tmax, AUC) have been published for linarin specifically. ## Dosage & Preparation - **Isolated Compound (Research Grade)**: Used at 5–160 μM in in vitro studies; 50 mg/kg oral gavage in mouse models—no direct human dose equivalent established - **Valerian Root Extracts (Indirect Source)**: Standardized valerian preparations (0.3–0.8% valerenic acids) containing unquantified linarin; typical anxiolytic/sleep doses of 300–600 mg dried root extract taken 30–60 minutes before sleep - **Lycii Cortex (Di Gu Pi) Decoctions (Indirect Source)**: Traditional TCM preparations use 6–15 g dried root bark per decoction, with linarin present among multiple glycosides; concentration not standardized - **Standardization**: No commercial supplement is currently standardized to a defined linarin percentage; linarin content in source herbs varies by plant part, harvest season, and extraction solvent (methanol/ethanol most efficient) - **Bioavailability Consideration**: As a flavonoid glycoside, linarin likely undergoes intestinal deglycosylation to acacetin prior to absorption, but oral bioavailability data in humans are unavailable; lipophilic delivery vehicles or piperine co-administration are theoretical enhancers - **Timing**: No clinically validated timing recommendations exist; preclinical sedative data from valerian context suggest evening administration for CNS-related applications ## Safety & Drug Interactions No adverse effects have been reported in preclinical models at in vitro concentrations up to 160 μM or oral doses of 50 mg/kg in rodents, suggesting low acute toxicity in animal systems, but human safety data are entirely absent and no maximum tolerated dose, NOAEL, or LOAEL has been established for human exposure to isolated linarin. Because linarin inhibits NF-κB, COX-2, and [inflammatory pathway](/ingredients/condition/inflammation)s, theoretical pharmacodynamic interactions exist with NSAIDs, corticosteroids, and immunosuppressive drugs where additive immunosuppression could increase infection risk or impair wound healing. The parent herb Valeriana officinalis has documented sedative interactions with benzodiazepines, barbiturates, and CNS depressants that may be partially attributable to flavonoid constituents including linarin, warranting caution in co-administration. No pregnancy or lactation safety data exist for isolated linarin; given the general precautionary principle applied to uncharacterized phytochemicals and the lack of teratogenicity or embryotoxicity studies, use during pregnancy or breastfeeding cannot be recommended. ## Scientific Research The entire body of evidence for linarin is preclinical, comprising in vitro cell-based assays and small animal in vivo studies with no registered or published human clinical trials identified as of 2024. In vitro studies have used standardized macrophage (RAW264.7), hepatocyte (HepG2), endothelial (HUVEC), and cancer cell line models at well-defined concentrations (5–160 μM), providing mechanistic clarity but limited translational certainty. Animal studies have employed mouse and rat models of acute liver failure, high-fat diet obesity, and neurological injury, with linarin administered orally at approximately 50 mg/kg, yielding statistically significant improvements in survival, [cytokine](/ingredients/condition/inflammation) profiles, glucose tolerance, and histopathological endpoints—though sample sizes are typically small and not always reported. The evidence base is insufficient to establish human efficacy, optimal bioavailable dose, pharmacokinetic parameters, or comparative effectiveness versus approved therapeutics, and the compound should be regarded as investigational. ## Historical & Cultural Context Linarin was first isolated and chemically characterized from Linaria vulgaris (common toadflax, family Plantaginaceae) in the mid-twentieth century, from which its name derives, and has since been identified across dozens of plant genera used in Ayurvedic, Traditional Chinese, and European herbal medicine. In Traditional Chinese Medicine, its source plant Lycium chinense root bark (Di Gu Pi) has been prescribed for over two millennia to clear heat, cool blood, and manage febrile conditions associated with what modern medicine recognizes as [inflammatory](/ingredients/condition/inflammation) and metabolic disorders including diabetes. Valeriana officinalis, another linarin-containing plant, has been documented in European herbalism since at least the ancient Greeks (Dioscorides, 1st century CE) and was widely employed in medieval European and later Eclectic American medicine for nervousness, [insomnia](/ingredients/condition/sleep), and hysteria, with valerian preparations appearing in the British Pharmacopoeia through the 20th century. The specific pharmacological role of linarin within these multi-constituent traditional preparations was not distinguishable from whole-plant activity until modern phytochemical fractionation techniques enabled its isolation and individual bioassay in the late 20th and early 21st centuries. ## Synergistic Combinations Linarin from Valeriana officinalis is likely synergistic with valerenic acid and isovaltrate—the primary sesquiterpenoids in valerian—since valerenic acid modulates GABA-A receptor activity while linarin contributes AChE inhibition and SUR1 binding, potentially creating complementary anxiolytic and [neuroprotective](/ingredients/condition/cognitive) coverage across distinct receptor systems. In the context of metabolic syndrome, preclinical logic supports combining linarin-containing lycium bark extract with berberine, which independently activates AMPK and suppresses hepatic gluconeogenesis via a distinct pathway from linarin's c-FOS/ARG2 target, producing additive insulin-sensitizing effects observed in HFD models using multi-herb TCM formulas. For [anti-inflammatory](/ingredients/condition/inflammation) stacking, co-administration with curcumin (NF-κB inhibitor via IKK suppression) and quercetin (MAPK modulator) could theoretically produce additive pathway inhibition, though no direct in vivo linarin combination studies have been published. ## Frequently Asked Questions ### What is linarin and what plants does it come from? Linarin is a flavonoid glycoside (acacetin-7-O-rutinoside) consisting of the flavone acacetin attached to the disaccharide rutinose. It is found naturally in Valeriana officinalis (valerian root), Lycium chinense root bark (Di Gu Pi), Chrysanthemum indicum, Linaria vulgaris, and Buddleja species, among others. It is not available in significant amounts in common dietary foods and is primarily obtained through phytochemical extraction from these medicinal plants. ### Does linarin have anxiolytic or sleep-promoting effects? Linarin is a constituent of Valeriana officinalis and contributes to its sedative pharmacology through acetylcholinesterase inhibition and SUR1 binding, but no human clinical trials have specifically tested isolated linarin for anxiety or sleep. All evidence supporting an anxiolytic effect is preclinical or inferred from whole-plant valerian studies. Clinicians typically attribute valerian's sleep effects to valerenic acid and isovaltrate rather than to linarin specifically. ### What is the mechanism of action of linarin's anti-inflammatory effects? Linarin inhibits inflammation by simultaneously blocking two major inflammatory signaling cascades: NF-κB (preventing IκB phosphorylation and p65 nuclear translocation) and the MAPK pathway (suppressing phosphorylation of ERK1/2, JNK, and p38 kinases). This dual inhibition reduces transcription of iNOS, COX-2, TNF-α, IL-1β, IL-6, and PGE2 in LPS-stimulated macrophages at concentrations of 2.5–20 μg/mL. These effects have been demonstrated in RAW264.7 macrophage cell cultures and confirmed in rodent models of acute inflammation, though human pharmacological validation is lacking. ### Are there any human clinical trials on linarin? As of 2024, no published human clinical trials have evaluated isolated linarin for any health indication, including its anti-inflammatory, neuroprotective, antidiabetic, or anxiolytic properties. All available pharmacological data come from in vitro cell studies (RAW264.7 macrophages, HepG2 hepatocytes, cancer cell lines) and small animal models (mice and rats). Linarin should be considered an investigational compound, and any health benefits attributed to it in commercial products are not supported by clinical evidence. ### What is the safe dose of linarin for humans? No safe or effective human dose for isolated linarin has been established because no human pharmacokinetic, dose-escalation, or clinical efficacy studies have been conducted. In animal research, 50 mg/kg oral dosing in mice was used without reported toxicity, but direct extrapolation to human doses is unreliable without allometric scaling data and human bioavailability studies. Individuals consuming linarin-containing plants like valerian root (typically 300–600 mg extract) are exposed to small, unquantified amounts of linarin as part of a complex phytochemical mixture, which is the only contextually established human exposure pattern. ### Does linarin have cardiovascular or heart health benefits? Linarin may support cardiovascular health through its anti-inflammatory effects, particularly by reducing vascular permeability and tissue edema in animal models, which can help maintain healthy blood vessel function. Its inhibition of inflammatory mediators like TNF-α and IL-6 suggests potential benefits for endothelial health, though human clinical trials specifically evaluating cardiovascular outcomes are currently lacking. Most evidence remains limited to in vitro and rodent studies, so broader human research is needed to confirm these effects. ### How does linarin compare to other flavone glycosides for inflammation? Linarin is a flavone glycoside (specifically acacetin-7-O-rutinoside) that works through dual NF-κB and MAPK pathway inhibition, a mechanism shared with other anti-inflammatory flavonoids but with potentially distinct potency depending on its rutinoside glycosylation pattern. While other flavone glycosides like hesperidin and diosmin also target similar inflammatory pathways, direct comparative studies between linarin and these compounds are limited, making it difficult to establish clear superiority. The rutinoside sugar moiety may enhance intestinal absorption and bioavailability compared to some other flavonoid forms. ### Is linarin effective for liver protection beyond the galactosamine model? Linarin demonstrated hepatoprotective effects in a galactosamine/LPS-induced liver injury model at 50 mg/kg in animal studies, suggesting potential benefits against multiple forms of hepatic stress through its anti-inflammatory mechanism. However, most evidence is limited to acute injury models in rodents, and whether linarin protects against chronic liver disease, viral hepatitis, or metabolic fatty liver disease remains unclear. Translation to human hepatoprotection requires additional mechanistic research and clinical validation. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*