18-beta-glycyrrhetic acid, more commonly known as Enoxolone, is a triterpenoid compound derived from glycyrrhizin, which is found in licorice root (Glycyrrhiza glabra). It is widely used in cosmetics and skincare products due to its anti-inflammatory, soothing, and healing properties. Enoxolone is particularly beneficial for sensitive, irritated, or inflamed skin and is commonly found in products designed to calm and protect the skin.

Chemical Composition and Structure

Enoxolone (18-beta-glycyrrhetic acid) is a derivative of glycyrrhizin, the active compound in licorice. The structure of enoxolone features a triterpenoid backbone, with a functional group that provides its anti-inflammatory and soothing effects.

• Triterpenoid Structure: Composed of a 30-carbon structure with functional groups that contribute to its skin-healing properties.
• Glycoside Hydrolysis: It is formed by the hydrolysis of glycyrrhizin into aglycone enoxolone, which is more readily absorbed by the skin.

Physical Properties

• Appearance: White crystalline powder.
• Odor: Mild, slightly sweet.
• Solubility: Soluble in ethanol, methanol, and other organic solvents; slightly soluble in water.
• Stability: Stable under normal conditions of use; sensitive to high temperatures and prolonged exposure to light.

Production Process

• Extraction: Enoxolone is primarily extracted from the roots of Glycyrrhiza glabra (licorice) through a hydrolysis process that breaks down glycyrrhizin into enoxolone.
• Purification: After extraction, the compound is purified using solvent extraction and filtration techniques.
• Standardization: The final extract is standardized to ensure consistent levels of enoxolone for optimal efficacy in formulations.

Applications

Medical Applications

• Anti-inflammatory Treatments: Enoxolone is widely used for its anti-inflammatory properties, helping to reduce redness, swelling, and irritation in conditions such as eczema, psoriasis, and dermatitis.
• Skin Healing: Known for its ability to accelerate the skin's healing process, particularly in cases of irritation or damage from environmental stressors.
• Soothing Effects: Provides immediate relief from skin discomfort and soothes inflamed or itchy skin.

Cosmetics

• Calming and Soothing: Ideal for sensitive or irritated skin, it helps reduce redness and inflammation.
• Anti-aging: Provides antioxidant protection, helping to combat the visible signs of aging by reducing oxidative stress.
• Hydration: Supports the skin’s natural moisture balance and helps improve its texture and tone.
• Skin Barrier Repair: Promotes the repair of the skin's natural barrier, protecting it from environmental pollutants and stressors.

Industrial Applications

• Cosmetic Products: Common in anti-inflammatory creams, serums, and lotions aimed at calming sensitive skin or treating conditions like acne and eczema.
• Pharmaceutical Formulations: Found in topical treatments for inflammatory skin conditions.

Environmental and Safety Considerations

• Biodegradability: Enoxolone is biodegradable and environmentally friendly.
• Safety Profile: Generally regarded as safe for topical use in regulated concentrations. It is well-tolerated by most skin types, though those with specific allergies to licorice or its derivatives may need to exercise caution.
• Sustainability: Extracted from licorice, a plant that is cultivated responsibly in many regions.

Molecular Formula  C₃₀H₄₆O₄

Molecular Weight  470.7 g/mol

CAS     471-53-4

UNII    P540XA09DR

EC Number  207-444-6

DTXSID9020669

Synonyms:

Glycyrrhetic Acid

Glycyrrhetinic Acid

Bibliografia__________________________________________________________________________

Krähenbühl S, Hasler F, Krapf R. Analysis and pharmacokinetics of glycyrrhizic acid and glycyrrhetinic acid in humans and experimental animals. Steroids. 1994 Feb;59(2):121-6. doi: 10.1016/0039-128x(94)90088-4. 

Abstract. Glycyrrhizic acid (GZA) and glycyrrhetinic acid (GRA) can be determined rapidly and precisely by high-performance liquid chromatography (HPLC) in biological fluids and tissues from experimental animals and humans. From plasma and tissues, GZA and GRA are extracted by organic solvents and the extracts can directly be used for HPLC. From bile or urine, extraction and determination of GZA and GRA are more difficult due to interfering endogenous compounds and conjugation of GRA with glucuronides or sulfates. Extraction of GZA and GRA from urine or bile can be performed by ion-pairing followed by extraction with organic solvents or by solid phase extraction. GRA conjugates can be determined by chromatographic separation or by pretreatment with beta-glucuronidase. The pharmacokinetics of GRA and GZA can be described by a biphasic elimination from the central compartment with a dose-dependent second elimination phase. Depending on the dose, the second elimination phase in humans has a half-life of 3.5 hours for GZA and between 10-30 hours for GRA. The major part of both GRA or GZA is eliminated by the bile. While GZA can be eliminated unmetabolized and undergoes enterohepatic cycling, GRA is conjugated to GRA glucuronide or sulfate prior to biliary excretion. Orally administered GZA is almost completely hydrolyzed by intestinal bacteria and reaches the systemic circulation as GRA.

Wu SY, Wang WJ, Dou JH, Gong LK. Research progress on the protective effects of licorice-derived 18β-glycyrrhetinic acid against liver injury. Acta Pharmacol Sin. 2021 Jan;42(1):18-26. doi: 10.1038/s41401-020-0383-9. 

Abstract. The first description of the medical use of licorice appeared in "Shennong Bencao Jing", one of the well-known Chinese herbal medicine classic books dated back to 220-280 AD. As one of the most commonly prescribed Chinese herbal medicine, licorice is known as "Guo Lao", meaning "a national treasure" in China. Modern pharmacological investigations have confirmed that licorice possesses a number of biological activities, such as antioxidation, anti-inflammatory, antiviral, immune regulation, and liver protection. 18β-glycyrrhetinic acid is one of the most extensively studied active integrants of licorice. Here, we provide an overview of the protective effects of 18β-glycyrrhetinic acid against various acute and chronic liver diseases observed in experimental models, and summarize its pharmacological effects and potential toxic/side effects at higher doses. We also make additional comments on the important areas that may warrant further research to support appropriate clinical applications of 18β-glycyrrhetinic acid and avoid potential risks.

Roohbakhsh A, Iranshahy M, Iranshahi M. Glycyrrhetinic Acid and Its Derivatives: Anti-Cancer and Cancer Chemopreventive Properties, Mechanisms of Action and Structure- Cytotoxic Activity Relationship. Curr Med Chem. 2016;23(5):498-517. doi: 10.2174/0929867323666160112122256.

Abstract. The anti-cancer properties of liquorice have been attributed, at least in part, to glycyrrhizin (GL). However, GL is not directly absorbed through the gastrointestinal tract. It is hydrolyzed to 18-β-glycyrrhetinic acid (GA), the pharmacologically active metabolite, by human intestinal microflora. GA exhibits remarkable cytotoxic and anti-tumor properties. The pro-apoptotic targets and mechanisms of action of GA have been extensively studied over the past decade. In addition, GA is an inexpensive and available triterpene with functional groups (COOH and OH) in its structure, which make it an attractive lead compound for medicinal chemists to prepare a large number of analogues. To date, more than 400 cytotoxic derivatives have been prepared on the basis of GA scaffold, including 128 cytotoxic derivatives with IC50 values less than 30 µM. Researchers have also succeeded in synthesizing very potent cytotoxic derivatives with IC50s ≤ 1 µM. Studies have shown that the introduction of a double bound at the C1-C2 position combined with an electronegative functional group, such as CN, CF3 or iodine at C2 position, and the oxidation of the hydroxyl group of C3 to the carbonyl group, significantly increased cytotoxicity. This review describes the cytotoxic and anti-tumor properties of GA and its derivatives, targets and mechanisms of action and provides insight into the structure-activity relationship of GA derivatives.

Cai Y, Xu Y, Chan HF, Fang X, He C, Chen M. Glycyrrhetinic Acid Mediated Drug Delivery Carriers for Hepatocellular Carcinoma Therapy. Mol Pharm. 2016 Mar 7;13(3):699-709. doi: 10.1021/acs.molpharmaceut.5b00677. 

Abstract. Glycyrrhetinic acid (GA), the main hydrolysate of glycyrrhizic acid extracted from the root of licorice, has been used in hepatocellular carcinoma (HCC) therapy. Particularly, GA as a ligand in HCC therapy has been widely explored in different drug delivery systems, including liposomes, micelles, and nanoparticles. There is considerable interest worldwide with respect to the development of GA-modified drug delivery systems due to the extensive presence of GA receptors on the surface of hepatocyte. Up until now, much work has been focused on developing GA-modified drug delivery systems which bear good liver- or hepatocyte-targeted efficiency both in vitro and in vivo. Owing to its contribution in overcoming the limitations of low lipophilicity and poor bioavailability as well as its ability to promote receptor-mediated endocytosis, GA-modified drug delivery systems play an important role in enhancing liver-targeting efficacy and thus are focused on the treatment of HCC. Moreover, since GA-modified delivery systems present more favorable pharmacokinetic properties and hepatocyte-targeting effects, they may be a promising formulation for GA in the treatment of HCC. In this review, we will give an overview of GA-modified novel drug delivery systems, paying attention to their efficacy in treating HCC and discussing their mechanism and the treatment effects.

Cosmetic Ingredient Review Expert Panel. Final report on the safety assessment of Glycyrrhetinic Acid, Potassium Glycyrrhetinate, Disodium Succinoyl Glycyrrhetinate, Glyceryl Glycyrrhetinate, Glycyrrhetinyl Stearate, Stearyl Glycyrrhetinate, Glycyrrhizic Acid, Ammonium Glycyrrhizate, Dipotassium Glycyrrhizate, Disodium Glycyrrhizate, Trisodium Glycyrrhizate, Methyl Glycyrrhizate, and Potassium Glycyrrhizinate. Int J Toxicol. 2007;26 Suppl 2:79-112. doi: 10.1080/10915810701351228.

Abstract. Glycyrrhetinic Acid and its salts and esters and Glycyrrhizic Acid and its salts and esters are cosmetic ingredients that function as flavoring agents or skin-conditioning agents - miscellaneous or both. These chemicals may be isolated from licorice plants. Glycyrrhetinc Acid is described as at least 98% pure, with 0.6% 24-OH-Glycyrrhetinic Acid, not more than 20 mu g/g of heavy metals and not more than 2 mu g/g of arsenic. Ammonium Glycyrrhizate has been found to be at least 98% pure and Dipotassium Glycyrrhizate has been found to be at least 95% pure. Glycyrrhetinic Acid is used in cosmetics at concentrations of up to 2%; Stearyl Glycyrrhetinate, up to 1%; Glycyrrhizic Acid, up to 0.1%; Ammonium Glycyrrhizate, up to 5%; Dipotassium Glycyrrhizate, up to 1%; and Potassium Glycyrretinate, up to 1%. Although Glycyrrhizic Acid is poorly absorbed by the intestinal tract, it may be hydrolyzed to Glycyrrhetinic Acid by a beta -glucuronidase produced by intestinal bacteria. Glycyrrhetinic Acid and Glycyrrhizic Acid bind to rat and human albumin, but do not absorb well into tissues. Glycyrrhetinic Acid and Glycyrrhizic Acid and metabolites are mostly excreted in the bile, with very little excreted in urine. Dipotassium Glycyrrhizate was undetectable in the receptor chamber when tested for transepidermal permeation through pig skin. Glycyrrhizic Acid increased the dermal penetration of diclofenac sodium in rat skin. Dipotassium Glycyrrhizate increased the intestinal absorption of calcitonin in rats. In humans, Glycyrrhetinic Acid potentiated the effects of hydrocortisone in the skin. Moderate chronic or high acute exposure to Glycyrrhizic Acid, Ammonium Glycyrrhizate, and their metabolites have been demonstrated to cause transient systemic alterations, including increased potassium excretion, sodium and water retention, body weight gain, alkalosis, suppression of the renin-angiotensis-aldosterone system, hypertension, and muscular paralysis; possibly through inhibition of 11beta -hydroxysteroid dehydrogenase-2 (11beta -OHSD2) in the kidney. Glycyrrhetinic Acid and its derivatives block gap junction intracellular communication in a dose-dependent manner in animal and human cells, including epithelial cells, fibroblasts, osteoblasts, hepatocytes, and astrocytes; at high concentrations, it is cytotoxic. Glycyrrhetinic Acid and Glycyrrhizic Acid protect liver tissue from carbon tetrachloride. Glycyrrhizic Acid has been used to treat chronic hepatitis, inhibiting the penetration of the hepatitis A virus into hepatocytes. Glycyrrhetinic Acid and Glycyrrhizic Acid have anti-inflammatory effects in rats and mice. The acute intraperitoneal LD(50) for Glycyrrhetinic Acid in mice was 308 mg/kg and the oral LD(50) was > 610 mg/kg. The oral LD(50) in rats was reported to be 610 mg/kg. Higher LD(50) values were generally reported for salts. Little short-term, subchronic, or chronic toxicity was seen in rats given ammonium, dipotassium, or disodium salts of Glycyrrhizic Acid. Glycyrrhetinic Acid was not irritating to shaved rabbit skin, but was considered slightly irritating in an in vitro test. Glycyrrhetinic Acid inhibited the mutagenic activity of benzo[a]pyrene and inhibited tumor initiation and promotion by other agents in mice. Glycyrrhizic Acid inhibited tumor initiation by another agent, but did not prevent tumor promotion in mice. Glycyrrhizic Acid delayed mortality in mice injected with Erlich ascites tumor cells, but did not reduce the mortality rate. Ammonium Glycyrrhizate was not genotoxic in in vivo and in vitro cytogenetics assays, the dominant lethal assay, an Ames assay, and heritable translocation tests, except for possible increase in dominant lethal mutations in rats given 2000 mg/kg day(-1) in their diet. Disodium Glycyrrhizate was not carcinogenic in mice in a drinking water study at exposure levels up to 12.2 mg/kg day(-1) for 96 weeks. Glycyrrhizate salts produced no reproductive or developmental toxicity in rats, mice, golden hamsters, or Dutch-belted rabbits, except for a dose-dependent increase (at 238.8 and 679.9 mg/kg day(-1)) in sternebral variants in a study using rats. Sedation, hypnosis, hypothermia, and respiratory depression were seen in mice given 1250 mg/kg Glycyrrhetinic Acid intraperitoneally. Rats fed a powdered diet containing up to 4% Ammonium Glycyrrhizate had no treatment related effects in motor function tests, but active avoidance was facilitated at 4%, unaffected at 3%, and depressed at 2%. In a study of 39 healthy volunteers, a no effect level of 2 mg/kg/day was determined for Glycyrrhizic Acid given orally for 8 weeks. Clinical tests in seven normal individuals given oral Ammonium Glycyrrhizate at 6 g/day for 3 days revealed reduced renal and thermal sweat excretion of Na+ and K+, but carbohydrate and protein metabolism were not affected. Glycyrrhetinic Acid at concentrations up to 6% was not a skin irritant or a sensitizer in clinical tests. Neither Glycyrrhizic Acid, Ammonium Glycyrrhizate, nor Dipotassium Glycyrrhizate at 5% were phototoxic agents or photosensitizers. Birth weight and maternal blood pressure were unrelated to the level of consumption of Glycyrrhizic Acid in 1049 Finnish women with infants, but babies whose mother consumed > 500 mg/wk were more likely to be born before 38 weeks. The Cosmetic Ingredient Review (CIR) Expert Panel noted that the ingredients in this safety assessment are not plant extracts, powders, or juices, but rather are specific chemical species that may be isolated from the licorice plant. Because these chemicals may be isolated from plant sources, however, steps should be taken to assure that pesticide and toxic metal residues are below acceptable levels. The Panel advised the industry that total polychlorobiphenyl (PCB)/pesticide contamination should be limited to not more than 40 ppm, with not more than 10 ppm for any specific residue, and that toxic metal levels must not contain more than 3 mg/kg of arsenic (as As), not more than 0.002% heavy metals, and not more than 1 mg/kg of lead (as Pb). Although the Panel noted that Glycyrrhizic Acid is cytotoxic at high doses and ingestion can have physiological effects, there is little acute, short-term, subchronic, or chronic toxicity and it is expected that these ingredients would be poorly absorbed through the skin. These ingredients are not considered to be irritants, sensitizers, phototoxic agents, or photosensitizers at the current maximum concentration of use. Accordingly, the CIR Expert Panel concluded that these ingredients are safe in the current practices of use and concentration. The Panel recognizes that certain ingredients in this group are reportedly used in a given product category, but the concentration of use is not available. For other ingredients in this group, information regarding use concentration for specific product categories is provided, but the number of such products is not known. In still other cases, an ingredient is not in current use, but may be used in the future. Although there are gaps in knowledge about product use, the overall information available on the types of products in which these ingredients are used and at what concentration indicate a pattern of use. Within this overall pattern of use, the Expert Panel considers all ingredients in this group to be safe.