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Raspberry ketone

Raspberry ketone, chemically known as 4-(4-hydroxyphenyl)butan-2-one, is a naturally occurring ketone responsible for the characteristic fruity aroma of red raspberries () and present in smaller amounts in other fruits such as , peaches, and apples. This aromatic compound has been utilized since the as a synthetic agent in foods, beverages, and , where it is classified by the U.S. (FDA) as (GRAS) for such purposes when used in appropriate concentrations. In recent years, raspberry ketone has gained prominence as a key ingredient in over-the-counter dietary supplements, primarily marketed for its purported role in supporting and , drawing from animal studies suggesting it may increase and reduce accumulation. However, clinical evidence remains limited and inconclusive, with small-scale trials showing mixed results on body weight reduction and potential adverse effects at higher doses, particularly in individuals with compromised health. Ongoing research explores its additional biological activities, including properties and potential metabolic benefits, though these are primarily demonstrated in preclinical models.

Chemical characteristics

Structure and physical properties

Raspberry ketone, systematically named 4-(4-hydroxyphenyl)butan-2-one, is a characterized by a benzene ring substituted with a hydroxyl group at the para position and attached to a butan-2-one chain. Its molecular formula is C₁₀H₁₂O₂, with a of 164.20 g/mol. The presence of a (–C=O) at the 2-position of the butanone chain and a hydroxyl group (–OH) on the phenyl ring imparts specific reactivity, including potential for hydrogen bonding and . In its pure form, raspberry ketone appears as white needles or a crystalline powder, often described as white to off-white. It has a melting point of 82–84 °C. The boiling point is approximately 140–146 °C at reduced pressure (0.5 mmHg), though it may decompose at atmospheric pressure; computed values suggest around 287 °C at 760 mmHg. Raspberry ketone exhibits limited solubility in water, approximately 0.05 M (8.2 g/L) at 25 °C, classifying it as slightly soluble, while it is readily soluble in organic solvents such as ethanol (up to 50 mg/mL in 95% ethanol) and diethyl ether. This solubility profile arises from its amphiphilic nature, with the polar hydroxyl and ketone groups enabling interactions in protic solvents, balanced by the hydrophobic alkyl chain. The compound is renowned for its distinctive aroma, a sweet, fruity scent evocative of fresh raspberries, which stems from the synergistic interaction of its phenolic and ketonic moieties in olfactory perception. This odor profile contributes to its natural occurrence as a trace component in raspberry fruit, enhancing the overall flavor complexity.

Chemical synthesis

Raspberry ketone is primarily produced through traditional chemical synthesis involving a two-step process: the base-catalyzed aldol condensation of 4-hydroxybenzaldehyde with acetone to form the α,β-unsaturated ketone intermediate (4-(4-hydroxyphenyl)but-3-en-2-one), followed by selective hydrogenation of the double bond. The aldol condensation typically employs aqueous sodium hydroxide as the base catalyst at moderate temperatures (around 20–40°C), favoring the crossed condensation due to the activated aromatic aldehyde. The subsequent hydrogenation uses molecular hydrogen under mild conditions (1–5 atm, 50–80°C) with palladium on carbon (Pd/C) as the catalyst, achieving clean reduction without affecting the phenolic or carbonyl groups. The overall reaction sequence is as follows: \ce{4-(HO)C6H4CHO + CH3COCH3 ->[NaOH] 4-(HO)C6H4CH=CHCOCH3 + H2O} \ce{4-(HO)C6H4CH=CHCOCH3 + H2 ->[Pd/C] 4-(HO)C6H4CH2CH2COCH3} This method yields 70–90% overall, depending on purification steps, and is scalable for industrial production due to inexpensive starting materials. Recent chemical advances focus on one-pot processes to streamline and reduce waste, such as the use of bifunctional Pd/Zn-La catalysts that integrate and in a single reactor at 160°C with a 1:20 molar ratio of to acetone, achieving near-complete conversion (99%) and high selectivity. These catalysts, prepared via combustion , exhibit thermal stability up to 700°C and reusability for multiple cycles, enhancing efficiency. Biosynthetic methods represent a sustainable alternative, employing metabolically engineered or to express key phenylpropanoid pathway enzymes, including 4-coumarate:CoA ligase (4CL) for activation of and benzalacetone synthase (BAS) for condensation with , followed by reduction via raspberry ketone synthase (RZS) or benzalacetone reductase (BAR). Strains are often optimized with fed-batch fermentation using glucose or fatty acids as feedstocks, incorporating cofactor regeneration systems like glucose dehydrogenase for NADH supply. Research from 2020–2023 has demonstrated titers up to 9.89 g/L in whole-cell E. coli systems from 4-hydroxybenzylideneacetone. As of 2024, production from glucose and in engineered E. coli has achieved 0.416 g/L. These biosynthetic routes achieve over 95% product purity through inherent pathway specificity and simple downstream processing, offering lower environmental impact via renewable feedstocks and milder conditions compared to chemical synthesis.

Natural sources

Primary occurrence in raspberries

Raspberry ketone, chemically known as 4-(4-hydroxyphenyl)butan-2-one, is biosynthesized in red raspberries (Rubus idaeus) through the phenylpropanoid pathway. This process begins with the amino acid phenylalanine, which is deaminated to form trans-cinnamic acid, followed by subsequent hydroxylations and condensations leading to the key intermediate 4-hydroxybenzaldehyde. From this intermediate, raspberry ketone is formed via a polyketide synthase-like enzyme, such as the recently identified RinPKS4, which catalyzes the final steps in the accumulation of the compound within the fruit's glandular trichomes. In fresh red raspberries, raspberry ketone concentrations typically range from 1 to 4 /, with levels peaking in fully ripe where it serves as the primary contributor to the fruity aroma, accounting for a major portion of the scent profile. This compound imparts sweet, floral, and raspberry-like notes, detectable at very low thresholds around 0.004 in , making it a potent odorant even at trace amounts. Concentrations vary by ; for instance, varieties like 'Willamette' exhibit higher levels compared to others, while 'Meeker' shows distinct aroma profiles influenced by regional growth. Additionally, environmental factors such as increased exposure during can elevate raspberry ketone by enhancing through the phenylpropanoid pathway. To obtain natural raspberry ketone for flavor applications, it is extracted from primarily via or solvent-based methods like extraction under ultrasonic assistance. These techniques isolate volatile fractions from the pulp or juice, but due to the low inherent concentration, the yield of pure raspberry ketone remains below 1% of the extract, necessitating large volumes of starting material for commercial isolation.

Presence in other plants and foods

Raspberry ketone occurs in trace amounts in various berries beyond raspberries, including blackberries (), cranberries (), and kiwifruit (), typically at concentrations ranging from 0.00081 to 0.7 mg/kg. These levels contribute minimally to the overall volatile profile of these fruits compared to their primary aroma compounds. The compound is also present in other plants, such as rhubarb (Rheum rhabarbarum) stems at approximately 0.5 mg/kg and in traces within peaches (Prunus persica) and passionfruit (Passiflora edulis). In peaches and kiwifruit, it forms part of the natural phenolic volatile fraction, though at concentrations far lower than in red raspberries. In processed foods derived from these sources, raspberry ketone appears at low levels, such as in raspberry jams, wines, and essential oils, where it arises from the natural content of the raw materials. However, commercial products often incorporate synthetic raspberry ketone to enhance intensity, as natural extraction yields insufficient quantities. Ecologically, raspberry ketone serves as a volatile signal in certain , functioning as a synomone to attract pollinators like fruit flies in species such as the Bulbophyllum apertum, or potentially as a in plant-insect interactions, though it is not a primary defense compound. Detection of raspberry ketone in these plants and foods is commonly achieved through gas chromatography-mass spectrometry (GC-MS) analysis, which confirms its presence among other volatiles, typically comprising less than 5% of the total volatile fraction in non-raspberry sources. This method allows for precise quantification of trace levels without interference from dominant compounds.

Industrial applications

Flavoring and fragrance industry

Raspberry ketone serves as a key flavoring agent in the food industry, where it is approved by the U.S. Food and Drug Administration (FDA) as generally recognized as safe (GRAS) under 21 CFR 172.515 for direct addition to food products. It imparts a characteristic fruity, raspberry-like aroma and taste, typically incorporated at low concentrations of 1–10 ppm in items such as beverages, candies, baked goods, and dairy products. For instance, reported usage levels in baked goods reach up to 13.05 ppm, enhancing the sensory profile without altering other product attributes. Global annual production is estimated at approximately 100–200 tons, reflecting its established role in creating authentic berry notes in processed foods. Recent reports indicate production capacities have expanded, with some manufacturers reaching 1,200–2,500 tons annually as of 2023, driven by broader industrial demands. In the fragrance sector, raspberry ketone contributes sweet, fruity notes to perfumes and soaps, employed at levels of 0.1–1% to evoke raspberry accords. It is frequently blended with ionones to develop synthetic raspberry profiles, a practice prominent in 20th-century perfumery for floral-fruity compositions like and . This compound's powdery, jam-like scent profile makes it versatile for enhancing sweet floral and oriental fragrances, where it acts as a and . Cosmetic formulations incorporate raspberry ketone primarily for its aromatic properties, adding it to lip balms, lotions, and other personal care items at concentrations up to 0.5% to provide a pleasant fruity scent. Its mild solubility in alcohol and oils supports even distribution in emulsions, contributing to the overall sensory appeal without dominating other ingredients. Approximately 95% of raspberry ketone used industrially is produced synthetically, driven by the low natural yields from (1–4 mg/kg fruit), which make inefficient for large-scale needs. versions, derived from raspberry distillates, command premium prices exceeding $1,000 per kg, compared to synthetic raspberry ketone at $10–50 per kg. Historically, raspberry ketone was first isolated in 1903, with its structure elucidated in 1951, enabling commercial synthesis that scaled in the 1950s to meet post-World War II demands in the expanding and fragrance markets.

Other uses

Raspberry ketone serves as a key intermediate in the synthesis of , a β-adrenergic agonist used as a veterinary pharmaceutical to promote lean muscle growth in . This role leverages its phenolic structure, enabling efficient coupling reactions with other precursors like p-hydroxyacetophenone through processes such as or multi-step . Additionally, it has been incorporated into the preparation of mycophenolic acid aryl esters, derivatives of the mycophenolic acid, which exhibit enhanced properties. In , raspberry ketone functions as a potent insect attractant, particularly for fruit flies such as the melon fly () and Queensland fruit fly (Bactrocera tryoni), which pose significant threats to crops. Its kairomone-like activity draws pests into traps for and mass trapping in programs, thereby reducing crop damage without broad-spectrum insecticides. Derivatives like raspberry ketone trifluoroacetate have shown even higher efficacy in field trials for applications. As a standard reference compound in , raspberry ketone is routinely employed in gas chromatography-mass spectrometry (GC-MS) for volatile profiling and authenticity verification of products and supplements. It enables detection of adulteration in raspberry-derived flavors or weight-loss supplements by comparing retention times and mass spectra against known profiles, ensuring compliance with quality standards. In emerging biotechnology, raspberry ketone acts as a substrate and reporter molecule in enzyme assays studying the phenylpropanoid pathway, which governs secondary metabolite production in plants. Researchers engineer microbial and plant hosts, such as Saccharomyces cerevisiae and Nicotiana benthamiana, to overproduce it via heterologous pathways involving benzalacetone synthase and reductase enzymes, facilitating insights into metabolic flux redirection. This approach supports sustainable bioproduction of high-value phenolics beyond natural extraction limits.

Biological and pharmacological effects

Mechanism of action

Raspberry ketone has been observed to increase levels in preclinical models, potentially contributing to improved , though the exact mechanism remains unclear. This effect has been noted using differentiated 3T3-L1 adipocytes and with 1–2% raspberry ketone supplementation in the diet of high-fat-fed models, elevating in without altering food intake or energy expenditure. Raspberry ketone promotes in adipocytes by stimulating of hormone-sensitive (HSL) via the cyclic AMP ()/ (PKA) signaling pathway, facilitating the breakdown of triglycerides into free fatty acids and . This effect is mediated upstream by increased norepinephrine release, which activates β-adrenergic receptors to elevate intracellular levels and subsequently trigger PKA-dependent HSL at key serine residues (Ser563, Ser660). In differentiated 3T3-L1 adipocytes, 10 μM raspberry ketone treatment enhanced HSL and overall lipolytic activity, leading to reduced accumulation. The compound exhibits antioxidant activity primarily through its phenolic hydroxyl (OH) group, which donates hydrogen atoms to neutralize free radicals such as DPPH, with an IC50 value of approximately 50 μM in cell-free assays. This scavenging capacity helps mitigate oxidative stress by upregulating endogenous antioxidants like superoxide dismutase and glutathione in hepatic and cardiac tissues. Raspberry ketone exerts anti-inflammatory effects by inhibiting the nuclear factor κB (NF-κB) signaling pathway in hepatic cells, thereby suppressing the transcription and release of pro-inflammatory cytokines such as tumor necrosis factor-α (TNF-α). Pretreatment with raspberry ketone in rodent models of chemically induced liver injury reduced NF-κB nuclear translocation and TNF-α protein levels.

Research on health benefits

Research on raspberry ketone's potential health benefits has primarily focused on its anti-obesity and hepatoprotective properties, with most evidence derived from preclinical models. Early rodent studies from 2005 to 2010 demonstrated that oral administration of raspberry ketone at doses of 0.5–2% in high-fat diets led to 10–20% reductions in visceral fat accumulation and body weight gain in mice and rats, attributed to enhanced lipid metabolism. Human randomized controlled trials remain limited; for example, a 2013 small-scale RCT (n=45) involving a multi-ingredient supplement with 100–200 mg raspberry ketone daily reported improvements in body composition when combined with diet and exercise. A 2021 review of available data concluded limited evidence for raspberry ketone's efficacy in weight management in humans due to scarce clinical trials and methodological limitations. As of 2025, no large-scale RCTs have confirmed benefits, with evidence remaining inconclusive. In models of liver injury, raspberry ketone exhibited hepatoprotective effects. A 2024 study published in the Journal of Agricultural and Food Chemistry demonstrated that raspberry ketone attenuated thioacetamide (TAA)-induced liver fibrosis in mice via regulation of FXR and PGC-1α signaling, reducing accumulation and inflammatory markers in hepatic tissue. These outcomes were observed over several weeks, highlighting potential therapeutic value against fibrotic liver conditions. Regarding anti-obesity mechanisms, data indicate that raspberry ketone promotes norepinephrine-induced in by upregulating uncoupling protein 1 () expression and suppressing in 3T3-L1 adipocytes, leading to increased oxidation and energy expenditure. Preliminary research has explored additional benefits, including potential anti-diabetic and neuroprotective effects in preclinical models. Despite these findings, the majority of research remains preclinical, with human data confined to small-scale trials (n<50) lacking long-term follow-up. Reviews emphasize significant evidence gaps and call for larger, well-controlled RCTs to validate therapeutic claims.

Commercial aspects

Marketing as a dietary supplement

Raspberry ketone gained significant popularity as a dietary supplement following its endorsement by television host Dr. Mehmet Oz in 2012, during which he described it as "the No. 1 in a bottle to burn your fat." This promotion led to a sharp increase in sales shortly after the episode aired, with raspberry ketone products becoming one of the top-selling supplements in the U.S. market. It is commonly marketed as a " fat-burner" in pill form, with typical doses ranging from 100 to 200 mg per serving, often recommended once or twice daily. Supplements containing raspberry ketone are available in various forms, including capsules and, less commonly, gummies, and are frequently combined with other ingredients such as extract or cambogia to enhance claimed effects. Leading brands like Nature's Bounty dominate the market, offering products such as 100 mg raspberry ketone capsules positioned for support. Advertising for raspberry ketone supplements often emphasizes its origin as a "natural raspberry extract," despite the fact that most commercial products use synthetically produced versions due to the low natural yield from raspberries. In recent years, influencers have played a key role in driving trends, promoting these supplements through fitness-focused content on platforms like in 2024 and 2025. The primary consumer demographic for raspberry ketone supplements includes individuals seeking non-prescription aids, with marketing heavily targeting women interested in metabolism-boosting products. Online sales of these supplements have surged post-2020, fueled by the growth of channels amid increased demand for and wellness items during the . Marketing efforts have faced controversies, including FTC enforcement actions from 2014 onward against deceptive weight loss claims in dietary supplements, some of which involved raspberry ketone promotions. Class-action lawsuits have also targeted misleading "natural" labeling, such as a 2019 suit against RK Pure Raspberry Ketone Capsules alleging synthetic content despite natural claims.

Regulatory status and market trends

Raspberry ketone holds (GRAS) status from the U.S. () for use as a flavoring agent in in accordance with , under 21 CFR 172.515 since 1965. The () has also evaluated it as safe for use in food flavorings at specified levels, with no consumer safety concerns identified in animal feed applications up to 25 mg/kg. In the context of dietary supplements, raspberry ketone is classified as a new dietary ingredient in the U.S., requiring manufacturers to notify the of its intended use and report any adverse events, though it remains largely unregulated for efficacy claims. Authenticity issues persist in the market, where synthetic versions are often misrepresented as extracts. A 2025 study published in the Journal of A introduced a multi-analytical method using gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-mass spectrometry (LC-MS) to assess quality and authenticity, finding that 60% of tested supplements showed discrepancies between labeled and measured raspberry ketone content, with some indicating potential synthetic origins through identification of impurities and absence of markers. The global raspberry ketone market was valued at approximately $50 million in 2024, with projections indicating a (CAGR) of 8% through 2034, primarily fueled by rising demand for natural flavors in the region. Trade regulations further shape its distribution: the prohibits synthetic raspberry ketone in certified products under Regulation (EC) No 1334/2008, mandating natural or biosynthetic origins for labeling as such. Looking ahead, market trends point to a shift toward sustainable biosynthetic production methods, accelerated by 2025 supply chain disruptions affecting synthetic precursors due to raw material shortages and geopolitical tensions.

Safety profile

Toxicology in food and cosmetic use

Raspberry ketone exhibits low , with an oral LD50 of 1.32 g/kg body weight in rats, indicating minimal risk at typical exposure levels in and . At concentrations used as a flavoring agent or fragrance (typically <1 mg/kg body weight daily), no adverse effects are observed, supporting its classification as (GRAS) by the U.S. (FDA) for these applications. assessments, including the Ames bacterial reverse mutation test, show negative results up to 5000 μg/plate, with no evidence of mutagenic potential under standard conditions. In chronic exposure studies, a (NOAEL) of 70 mg/kg body weight per day was established in a 90-day oral study in rats, based on the absence of systemic at this dose. Evaluations for reproductive and developmental reveal no impacts, with safe margins at levels relevant to food and cosmetic use. Allergenicity concerns are minimal, though rare cases of have been reported due to its phenolic structure in cosmetic formulations. Additionally, raspberry ketone has been associated with chemical leukoderma () in cases of repeated dermal , particularly in occupational and cosmetic settings. sensitization tests, including guinea pig maximization assays, confirm low potential for allergic reactions at use concentrations up to 1%. Raspberry ketone is rapidly absorbed following oral or dermal exposure and metabolized primarily through conjugation with or , leading to excretion via urine as inactive conjugates. This efficient metabolic clearance supports its safety profile in low-dose applications. Regulatory bodies affirm its safety for food and cosmetic use: the FDA permits unlimited addition as a synthetic under GRAS status when compliant with good manufacturing practices, while the (EFSA) concludes no safety concern at estimated dietary exposures of 1–111 μg/kg body weight per day from flavorings. For non-food uses like , maximum concentrations are set at 1% in leave-on products to ensure dermal safety.

Risks associated with supplements

High doses of raspberry ketone in dietary supplements, often exceeding 200 mg per day, have been associated with cardiovascular risks, including elevated and , as reported in isolated case studies from 2015 to 2024. For instance, one case documented leading to and shortly after ingestion, while another described resistant polymorphic in a patient using the supplement for . These effects are attributed to the compound's stimulation of norepinephrine release, which can mimic or exacerbate activity. Raspberry ketone may interact adversely with stimulant drugs, such as , by enhancing norepinephrine-mediated effects, potentially leading to jitteriness, rapid heartbeat, and . Common gastrointestinal side effects, including and , have been noted in user reports, particularly when taken on an empty or in combination with other ingredients, though prevalence is not well-quantified in and appears anecdotal. The supplement is contraindicated for pregnant and lactating women due to insufficient safety data, with no reliable studies establishing its effects on fetal or development. Individuals with hormone-sensitive conditions, such as , should avoid it, as assays indicate weak estrogenic activity through potential binding to receptors in cell lines. Long-term use raises concerns due to limited data on potential hepatic accumulation and other chronic effects, with animal models showing no clear disruption but evidence absent. A 2025 analysis highlights the need for monitoring, as only one small exists, underscoring major gaps in long-term amid increasing popularity.