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Retinyl acetate

Retinyl acetate, also known as retinol acetate or acetate, is an derivative of () formed by the esterification of with acetic acid, serving as an essential for human health. It has the molecular formula C₂₂H₃₂O₂ and a molecular weight of 328.49 g/mol, typically appearing as a light yellow to dark yellow viscous liquid or solid with a of 51–58 °C. As a fat-soluble compound, it is soluble in organic solvents like , , and but has limited in , and it is sensitive to light and air, requiring storage at -20 °C under inert conditions to maintain stability. In biological systems, retinyl acetate acts as a precursor to and , supporting key physiological functions such as vision (particularly through formation), epithelial cell growth and differentiation, immune response, and reproduction. It is commonly used as a to prevent and treat , with potency standardized at approximately 2,800,000 international units () per gram, and is incorporated into fortified foods, multivitamins, and animal feeds. In cosmetics and , it is a mild topical applied in anti-aging formulations to promote production, reduce wrinkles, improve skin elasticity, and treat , though it is less irritating than but requires conversion in the skin for full activity. Medically, retinyl acetate exhibits potential antineoplastic and chemopreventive properties, with studies exploring its role in treating conditions like through intravaginal application and in media for mammalian growth. However, excessive intake can lead to , causing toxicity symptoms such as liver damage, birth defects, and skin irritation, necessitating careful dosing—recommended daily allowances are 700–900 μg retinol activity equivalents (RAE) for adults, with upper limits at 3,000 μg RAE to avoid adverse effects.

Chemical Properties

Molecular Structure

Retinyl acetate possesses the chemical formula C_{22}H_{32}O_{2} and a molecular weight of 328.49 g/mol. This compound is the acetate ester of all-trans-retinol, formed through the esterification of the hydroxyl group on retinol with acetic acid. Its core structure features a β-ionone ring—a cyclohexene ring with geminal methyl groups and a methyl substituent—attached to an 11-carbon polyene side chain containing four conjugated double bonds in the all-trans configuration. The acetate moiety (-OCOCH_{3}) is linked via an ester bond at the terminal C-15 position of the polyene chain, enhancing its stability compared to the parent alcohol while maintaining the conjugated system responsible for its biological activity. The predominant form of retinyl acetate is the all-trans , where all exocyclic double bonds exhibit ; isomers, such as 13-cis or 9-cis variants, exist but are less common in commercial preparations and differ in the configuration around specific double bonds in the polyene chain. In comparison to related retinoids, retinyl acetate differs from by the replacement of the free hydroxyl (-OH) group at C-15 with an , and from by having a shorter two-carbon acetyl chain instead of the 16-carbon palmitoyl , which affects and .

Physical and Chemical Characteristics

Retinyl acetate is a yellow to yellow crystalline solid at , often appearing as greasy or sticky prisms with a mild characteristic . It melts at 57-58°C and has a of approximately 0.98 g/cm³ at 25°C. The compound decomposes upon heating above 230°C without a defined , as it is thermally unstable under such conditions. Retinyl acetate exhibits low in , with values below 0.1 mg/mL, rendering it practically insoluble in aqueous environments. In contrast, it is highly soluble in fats and oils (up to 750 g/100 mL) as well as in organic solvents such as , , acetone, and isopropanol, reflecting its lipophilic nature. Chemically, retinyl acetate is sensitive to , , oxygen, and alkaline conditions, which can induce or oxidative degradation, though the acetate provides greater stability compared to free . It remains relatively stable in neutral to slightly acidic environments but undergoes bond rearrangement in strong acids or bases. The compound displays a characteristic absorption maximum at 325 nm in , facilitating its identification and in spectroscopic methods. This absorption arises from the conjugated polyene system in its structure, contributing to its .

Biological Role

Metabolism

Retinyl acetate, a common dietary form of , is primarily absorbed in the , where it undergoes by pancreatic enzymes such as carboxylester lipase and intestinal brush border esterases to yield free prior to cellular uptake. This process is facilitated by formation with dietary , enabling the retinyl ester to interact with the intestinal mucosa; approximately 70-90% of ingested retinyl esters are absorbed under normal conditions. Once inside enterocytes, the free is re-esterified primarily by :retinol acyltransferase (LRAT) into retinyl esters, which are then incorporated into chylomicrons for lymphatic transport to the bloodstream and delivery to the liver. Following absorption, retinyl esters are transported to the liver via remnants, where they are stored or mobilized for systemic distribution. In the liver, these esters accumulate in hepatic stellate cells as droplets, comprising 70-90% of total body reserves, again mediated by LRAT. For circulation, stored retinyl esters are hydrolyzed by retinyl ester hydrolases (such as hormone-sensitive ) to , which binds to retinol-binding protein 4 (RBP4) in hepatocytes and forms a complex with to prevent renal filtration and ensure delivery to peripheral tissues. This holo-RBP complex maintains plasma levels at 2-4 μM in humans during fasting states. Excretion of retinyl acetate-derived vitamin A is limited, with minimal urinary loss due to the RBP-transthyretin binding; instead, excess is primarily eliminated via feces through biliary secretion of polar metabolites. In the liver, surplus retinol is oxidized by enzymes (e.g., CYP26 family) to water-soluble derivatives, which are conjugated with and excreted in , or further metabolized for renal elimination. The efficiency of retinyl acetate metabolism is influenced by nutritional status, particularly dietary , , and protein availability. Adequate dietary (at least 3-5 g per meal) is essential for and optimal , while deficiencies reduce uptake significantly. and protein support RBP synthesis and overall transport, with their deficiencies impairing mobilization from hepatic stores and leading to functional shortages despite adequate intake.

Biochemical Functions

Retinyl acetate, an form of , undergoes in the intestinal mucosa and liver by retinyl ester hydrolases to yield , the primary form of the . This is then sequentially oxidized: first to retinaldehyde () by alcohol dehydrogenases (such as ADH1, ADH3, and ADH4) or specific retinol dehydrogenases, and subsequently to by retinal dehydrogenases (RALDH enzymes, including RALDH1, RALDH2, and RALDH3). These conversions are essential for activating retinyl acetate's metabolites, with serving as the primary bioactive form that exerts genomic effects. In terms of activity, 1 mg of retinyl acetate corresponds to approximately 0.872 mg of retinol activity equivalents (RAE), accounting for the molecular weight difference between the ester and free . Retinoic acid functions as a ligand for nuclear receptors, specifically retinoic acid receptors (RARs) and retinoid X receptors (RXRs), forming heterodimers that bind to retinoic acid response elements in DNA to regulate gene transcription. This signaling pathway governs critical cellular processes, including cell , , and , particularly in epithelial tissues where it maintains integrity and barrier function. In vision, (derived from ) is isomerized to 11-cis-retinal, which binds to in rod cells to form , the light-sensitive pigment essential for phototransduction and low-light detection. Retinoic acid also modulates immune responses by promoting of immune cells and regulating production, while supporting reproduction through roles in and fetal implantation. In embryonic development, retinoic acid gradients orchestrated by RALDH enzymes pattern the anterior-posterior axis, influencing in structures like the heart, limbs, and ; however, excessive levels can lead to teratogenic effects such as craniofacial and cardiac malformations. Additionally, derived from retinyl acetate exhibits properties by scavenging free radicals and inhibiting , complementing its role in cellular protection. Impairments in these metabolic pathways due to manifest as night blindness from reduced rhodopsin regeneration and , characterized by corneal drying and ulceration from disrupted epithelial maintenance.

Production and Stability

Industrial Synthesis

Retinyl acetate is primarily produced industrially through the esterification of with or , typically in the presence of a base catalyst such as . This reaction converts the alcohol group of retinol to the acetate ester, enhancing stability for commercial applications, and achieves yields exceeding 90%. The process is conducted under controlled conditions to minimize and ensure high purity, often followed by purification via (HPLC) or to attain greater than 95% purity suitable for pharmaceutical grades. Scale-up involves batch or continuous reactors, with considerations for handling light-sensitive intermediates to prevent degradation. Synthetic routes to retinyl acetate dominate modern production, beginning with total synthesis from β-ionone as the key starting material. The polyene chain is constructed via coupling reactions, such as the Wittig reaction in BASF's C15 + C5 process or the Julia olefination in Rhône-Poulenc's variant, followed by reduction to retinol and subsequent acetylation. Historical development traces to the 1940s, with the first industrial synthesis achieved by Isler et al. at Hoffmann-La Roche in 1947 using a C14 + C6 Grignard-based route, enabling commercial production by 1948 at scales initially yielding 168 kg annually and expanding to thousands of tons by the 1970s. These methods, refined by companies like DSM and BASF, now produce multi-ton quantities annually, prioritizing the all-trans isomer for bioactivity. Natural sourcing of , though less prevalent today due to the cost and scalability advantages of synthesis, involves extraction of retinyl esters (primarily palmitate) from animal livers or . These can be hydrolyzed to and then esterified to retinyl acetate if needed, but retinyl acetate itself is predominantly synthetic and not commonly used in "natural" labeled products, which typically retain longer-chain esters like palmitate. This extraction approach was historically significant before widespread synthetic adoption in the mid-20th century. Emerging biotechnological methods offer sustainable alternatives to traditional . As of 2024, processes using engineered oleaginous yeasts, such as lipolytica, enable microbial production of retinyl acetate through , potentially reducing environmental impact and reliance on feedstocks. Industrial processes manage byproducts and waste through recovery techniques, such as acetic acid from esterification and recycling of triphenylphosphine oxide from Wittig reactions. Volatile solvents like or are captured via columns, with environmental controls including catalytic optimizations to reduce emissions and . These measures align with principles, minimizing the of large-scale production.

Stability Factors

Retinyl acetate is susceptible to several degradation mechanisms that compromise its potency, primarily due to its polyene structure. Photo-oxidation occurs under ultraviolet irradiation, where the molecule undergoes ionic , leading to into cis forms and formation of byproducts such as anhydroretinol, with contributing to oxidation of the conjugated double bonds. Thermal can also shift the all-trans configuration to less active cis isomers, particularly at elevated temperatures, while degrades the ester linkage in moist or aqueous environments, accelerating in alkaline conditions where the acetate group is cleaved. Compared to free , retinyl acetate exhibits enhanced stability owing to the protective acetate group, which shields the reactive hydroxyl functionality from rapid oxidation and isomerization. This results in a significantly longer in the presence of air and light—typically on the order of months for retinyl acetate versus mere days for retinol under similar exposure. The form reduces sensitivity to environmental stressors, making it preferable for formulations requiring prolonged shelf presence. Optimal storage conditions are essential to minimize degradation, with recommendations including packaging in amber glass to block penetration, maintenance under an inert atmosphere such as or to prevent oxidation, and temperatures below 25°C to limit thermal effects. Incorporation of antioxidants like (BHT) or tocopherols further stabilizes the compound by scavenging free radicals and inhibiting auto-oxidation during storage. In formulations for foods and supplements, using materials such as or matrices provides a physical barrier against oxygen, , and , thereby enhancing retention of bioactivity during and . Retinyl acetate demonstrates optimal within a pH range of 4 to 7, where acidic to neutral environments minimize hydrolytic breakdown, though deviations can accelerate cleavage. Under these controlled conditions, typically extends to 2-3 years, monitored through potency assays that quantify retention of the active all-trans .

Applications

Food Fortification

Retinyl acetate serves as a key fortificant for enhancing the content in staple foods, particularly in , , cereals, and formulas, where it is added at levels typically ranging from 500 to 3000 per serving to meet a significant portion of daily requirements. This form is preferred for its compatibility with lipid-rich matrices, ensuring even distribution during manufacturing. The rationale for using retinyl acetate in lies in its as an oil-soluble retinol , which resists degradation in oil-based vehicles and delivers bioavailable preformed to populations at risk of deficiency, especially in developing regions where dietary intake from natural sources is often inadequate. Its high , comparable to other forms, supports efficient absorption in the intestine following to retinol. Incorporation of retinyl acetate involves emulsification for aqueous products like and formulas to create stable dispersions, or dry blending for powdered cereals and milk to achieve uniform mixing without altering texture. During thermal processing, such as for cereals or for fortified products, retention rates often exceed 80%, with losses minimized through protection and controlled conditions. Integration of retinyl acetate fortification aligns with WHO and global initiatives to combat deficiencies, including standards for mandatory addition to edible oils, , and staples in countries like and several African nations since the early 2000s. These programs target high-burden areas, promoting widespread access through national policies and partnerships. Efficacy evaluations of retinyl acetate-fortified foods indicate substantial impacts, with studies reporting significant improvements in serum retinol levels (standardized mean difference of 0.31) and protection of approximately 2.7 million children from , along with decreased clinical symptoms.

Dietary Supplements

Retinyl acetate is a common form of preformed found in dietary supplements, available in capsules, tablets, and liquid formulations with typical dosages ranging from 5,000 to 25,000 international units () per serving. These supplements are frequently incorporated into products, where they may be combined with other nutrients like to support activity or for overall bone and immune health. The primary target uses of retinyl acetate supplements include preventing , which can lead to impaired and increased risk, as well as supporting eye health by aiding retinal for and color . Additionally, it bolsters immune by maintaining epithelial and promoting T-cell activity, making it a standard component in multivitamins for general wellness. Bioavailability of retinyl acetate is high, with absorption rates of 70-90% when consumed alongside dietary fats, which facilitate its uptake in the intestines as a fat-soluble compound. This direct provision of makes it preferable to beta-carotene supplements, which exhibit only 10-30% and require enzymatic , potentially limiting in individuals with conversion impairments. The global market for , including dietary supplements featuring retinyl acetate, exceeded USD 540 million in 2022 and continues to grow, driven by demand for nutritional support in developed and developing regions. Synthetic retinyl acetate provides a vegan-friendly alternative to animal-derived forms, appealing to plant-based consumers seeking preformed without relying solely on provitamin . Clinical trials have shown retinyl acetate supplementation's efficacy in reducing measles-related mortality and complications in children under two years, with megadoses lowering overall death rates by up to 30% in deficient populations. In anemic children, supplementation has improved hemoglobin levels by approximately 7 g/L and decreased anemia prevalence from 54% to 38%, particularly when combined with iron therapy in those with concurrent deficiencies.

Cosmetics

Retinyl acetate serves as a stable of in formulations, providing mild activity that stimulates production and epidermal cell turnover to address signs of , such as fine lines, wrinkles, and uneven texture. Unlike , which can cause significant irritation, retinyl acetate exhibits lower potential for redness and dryness, positioning it as a gentler option for over-the-counter anti-aging products. This pro-vitamin A compound is enzymatically converted to active in the skin, supporting gradual improvements in skin firmness and smoothness without the intensity of prescription-strength . In skincare applications, retinyl acetate is commonly formulated into creams, serums, and sunscreens at concentrations of 0.1% to 1%, often expressed in equivalents to ensure safety and efficacy; regulatory guidelines limit it to 0.3% equivalents in leave-on facial products like moisturizers and 0.05% in body lotions to minimize systemic absorption risks. These levels allow for effective dermal delivery while combined with emollients and antioxidants to counteract potential dryness. Clinical evidence from combination studies demonstrates its role in enhancing plumping and smoothing, with formulations containing retinyl acetate alongside polyhydroxy acids showing statistically significant anti-aging effects on photoaged after regular use. Formulation challenges for retinyl acetate include its sensitivity to light, oxygen, and heat, necessitating opaque, airless to preserve potency and prevent degradation during storage and application. As an , it offers inherent slow-release properties for sustained activity, reducing peak irritation compared to free , though stabilizers like are frequently added to enhance longevity in emulsions. This stability advantage has facilitated its inclusion in diverse products since the , contributing to the growth of the cosmetics segment, valued at approximately $900 million globally in and projected to exceed $1 billion by in key markets like the and . Representative products featuring retinyl acetate include A313 Vitamin A Pommade for targeted repair, Infadolan Cream for moisturizing with anti-aging support, and Cosmedix Timeless Peel for exfoliating treatments, often from brands emphasizing accessible innovation. Studies on similar retinoid esters report 20-30% improvements in photoaged parameters, such as depth and elasticity, after 12 weeks of twice-daily application, underscoring its practical value in cosmetic routines despite limited standalone trials.

Safety and Regulation

Toxicity and Health Effects

Retinyl acetate, as a form of preformed , exhibits low , with an oral LD50 greater than 2,000 mg/kg body weight in rats, indicating it is not highly hazardous in single high-dose exposures. High single doses may cause symptoms such as , , vertigo, and due to rapid onset of A-like effects. Chronic overexposure to retinyl acetate, typically exceeding 3,000 mcg retinol activity equivalents (RAE) per day (equivalent to about 10,000 ), can lead to , resulting in liver damage such as , , and , as well as bone loss through increased resorption and reduced formation, potentially contributing to . Teratogenic risks are particularly notable, with intakes above 10,000 per day during associated with congenital malformations including craniofacial, cardiac, and defects in the . Vulnerable populations include pregnant women, who should limit intake to no more than 3,000 mcg RAE daily to avoid these risks; children, who may experience amplified effects due to lower body mass and developing systems; and individuals with pre-existing , where impaired metabolism heightens susceptibility to accumulation and toxicity. Interactions with other substances can exacerbate retinyl acetate toxicity; concurrent use with may intensify liver strain and damage, while combination with , a synthetic , heightens the risk of , manifesting in symptoms such as dry, scaly , , and brittle nails. A 2021 review has cited evidence from prior studies linking high supplemental intakes of preformed , such as retinyl acetate, to an elevated risk of hip fractures in adults, particularly postmenopausal women, due to adverse effects on .

Regulatory Standards

Retinyl acetate, as a form of preformed , is subject to international guidelines established by bodies such as the Commission and the (WHO). The provides specific maximum levels for in targeted products, including up to 1.2 mg per 100 g in ready-to-use therapeutic foods to prevent deficiency while avoiding excess intake. The WHO sets the tolerable upper intake level (UL) for preformed at 3000 mcg retinol activity equivalents (RAE) per day for adults, applicable to total intake from all sources including supplements and fortified foods. In the United States, the (FDA) affirms retinyl acetate as (GRAS) for use as a in foods, with limitations based on current good manufacturing practices. It is commonly labeled as "vitamin A acetate" in dietary , where content must be declared in mcg RAE on the Supplement Facts panel. High-dose formulations carry warnings due to teratogenic risks when exceeding recommended levels during . European Union regulations, guided by the (EFSA), maintain a UL of 3000 equivalents (RE) per day for preformed from supplements for adults. In , the Scientific Committee on Consumer Safety (SCCS) deems retinyl acetate safe at concentrations up to 0.3% RE in leave-on products excluding body lotions (limited to 0.05% RE), following revisions to ensure systemic exposure remains below the UL. Labeling requirements across jurisdictions mandate expression of content in RAE or RE to reflect accurately, as updated in FDA rules effective 2020-2021 and aligned standards. Warnings for high-dose products, introduced or strengthened in the , advise against exceeding the UL; the 's 2024 Regulation (EU) 2024/996 further requires cosmetic labels to warn that additional from food or supplements may surpass safe limits. Compliance and monitoring involve post-market surveillance by agencies like the FDA to identify adulteration, such as undeclared excesses or contaminants in vitamin A-fortified products and supplements.

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