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Cinnamic acid

Cinnamic acid is an with the molecular C₉H₈O₂, consisting of a monocarboxylic acid derived from with a phenyl at the 3-position, specifically the (E)- known as (E)-3-phenylprop-2-enoic acid. It appears as a white to light yellow crystalline solid and occurs naturally as a plant metabolite in sources such as Cinnamomum cassia (), storax, balsam of Peru, and leaves. This compound plays a central role in plant metabolism as a precursor to phenylpropanoids and lignins, and it is widely utilized in the production of flavors, fragrances, , and pharmaceuticals due to its aromatic properties and chemical versatility. Physically, cinnamic acid has a melting point of 133 °C and a boiling point of 298–300 °C at 760 mm Hg, with low solubility in water (approximately 0.546 mg/mL at 25 °C) but good solubility in ethanol, chloroform, and other organic solvents. It exhibits a pKa of 4.46, indicating moderate acidity, and is stable under normal conditions but can undergo reactions typical of α,β-unsaturated acids, such as Michael additions. Cinnamic acid is generally recognized as safe for use as a flavoring agent in food products, though it may cause mild skin irritation in concentrated forms. Cinnamic acid is commonly synthesized industrially via the Perkin condensation, which involves the base-catalyzed reaction of with , or through the using , both yielding high-purity trans-isomer products. In applications, it serves as a key intermediate for synthesizing various pharmaceuticals, including local anesthetics, as well as for producing esters used in perfumery and as UV absorbers in . Additionally, its derivatives demonstrate biological activities including , , , and anticancer effects, making it valuable in and agricultural formulations.

Chemical structure and properties

Molecular structure

Cinnamic acid has the molecular formula C_9H_8O_2, which can also be represented as C_6H_5CH=CHCOOH. Its IUPAC name is (E)-3-phenylprop-2-enoic acid, reflecting the specific configuration and substitution pattern of the molecule. The molecular weight is 148.16 g/mol. The core structure consists of a benzene ring directly attached to a propenoic acid chain, forming an α,β-unsaturated . The in the propene chain adopts a predominantly (E) configuration, which positions the and the group on opposite sides of the . This arrangement is the most common and naturally occurring form of the compound. Cinnamic acid exhibits geometric isomerism due to the , resulting in and forms. The isomer, known as (Z)-3-phenylprop-2-enoic acid or , is less than the isomer and is less prevalent in . The form's greater thermodynamic arises from reduced steric hindrance between the bulky phenyl and groups. A key structural feature is the extended conjugated π-system, which spans the aromatic ring of the , the carbon-carbon double bond of the , and the of the . This conjugation delocalizes electrons across the molecule, influencing its electronic properties and reactivity.

Physical properties

Cinnamic acid appears as a white to pale yellow crystalline solid with a characteristic honey-like . It has a melting point of 133 °C and a boiling point of 300 °C, at which it decomposes. The density is 1.248 g/cm³ at 20 °C. Cinnamic acid exhibits low solubility in water, approximately 500 mg/L at 20 °C, but is soluble in organic solvents such as , , and . The compound crystallizes in a . Due to its conjugated π-system, cinnamic acid shows strong ultraviolet absorption with a maximum wavelength (λ_max) around 273 nm in ethanol.

Chemical properties

Cinnamic acid exhibits the characteristic acidity of an α,β-unsaturated carboxylic acid, with a pKa value of approximately 4.44 for the dissociation of the carboxylic proton. Under normal ambient conditions, cinnamic acid is chemically stable, showing no significant decomposition at room temperature and standard pressure. However, it decomposes upon heating to elevated temperatures, with thermal gravimetric analysis indicating onset of degradation around 250–300°C depending on the heating rate, primarily via decarboxylation and fragmentation pathways. The compound is sensitive to ultraviolet light, undergoing [2+2] photodimerization to form cyclobutane derivatives such as α-truxillic acid when exposed to UV irradiation in the solid state or solution. Additionally, it is susceptible to slow oxidation in the presence of air, particularly under prolonged exposure, leading to partial degradation of the side chain. The chemical reactivity of cinnamic acid is dominated by its α,β-unsaturated functionality, enabling reactions at both the and the carboxylic group. The conjugated undergoes , such as catalytic to yield hydrocinnamic acid (3-phenylpropanoic acid), typically using metal catalysts like or under mild conditions. The carboxylic group readily participates in esterification reactions with alcohols, forming cinnamate esters via acid-catalyzed or enzymatic methods, which are widely used in fragrance and pharmaceutical applications. As an activated , cinnamic acid serves as a dienophile in Diels-Alder cycloadditions with dienes, producing derivatives due to the electron-withdrawing effect of the carboxylic group enhancing the 's reactivity toward nucleophilic partners. The extended conjugation between the phenyl ring, the C=C , and the delocalizes electrons across the system, reducing the at the β-carbon compared to the isolated in . This effect lowers the reactivity of the toward relative to , while enhancing its susceptibility to nucleophilic attack in conjugate additions. Under strong oxidizing conditions, such as treatment with , cinnamic acid undergoes oxidative cleavage of the side-chain , primarily yielding as the major product along with smaller carboxylic fragments like or . Milder oxidants may form epoxides or other cinnamic acid derivatives without full chain scission.

Natural occurrence and biosynthesis

Biosynthesis in plants

Cinnamic acid is primarily biosynthesized in plants via the phenylpropanoid pathway, a major secondary metabolic route that branches from the primary metabolism of L-phenylalanine derived from the . This pathway serves as the entry point for producing a diverse array of phenylpropanoid compounds essential for structure, defense, and signaling. The initial and committed step in this is catalyzed by the (PAL), which L-phenylalanine to yield trans-cinnamic acid and . This non-oxidative reaction proceeds without cofactors, relying on a 4-methylideneimidazole-5-one (MIO) formed autocatalytically within the . The reaction can be represented as: \ce{L-phenylalanine ->[PAL] trans-cinnamic acid + NH3} PAL exists as a multigene family in , with isoforms exhibiting tissue-specific expression and substrate preferences, ensuring efficient flux into downstream branches of the pathway. PAL activity and are tightly regulated, particularly in response to environmental es. Exposure to UV or pathogen attack, such as fungal elicitors, rapidly induces PAL transcription and mRNA accumulation, often within hours, enhancing phenylpropanoid production for . This involves cis-acting elements in PAL promoters, such as conserved motifs responsive to and elicitors, and post-transcriptional mechanisms like and feedback inhibition by pathway metabolites. Seminal studies in demonstrated that UV irradiation and fungal elicitors increase PAL mRNA levels by up to 50-fold, highlighting the enzyme's role in . Trans-cinnamic acid produced by PAL is rapidly metabolized further by enzymes like cinnamate 4-hydroxylase (C4H) and 4-coumarate:CoA ligase (4CL) to form p-coumaroyl-CoA, a central hub intermediate. This precursor directs flux toward the of for reinforcement, for UV protection and pigmentation, and coumarins for activity, underscoring cinnamic acid's foundational role in .

Sources in nature

Cinnamic acid occurs naturally in various plant sources, primarily as a component of essential oils, resins, and fats. It is most abundantly found in the bark of Cinnamomum cassia (cassia cinnamon), where it is present in the essential oil, often alongside derivatives like cinnamaldehyde. The resin from Liquidambar orientalis (oriental sweetgum), known as storax or styrax, is another rich source, containing 7.03% free cinnamic acid and up to 25.26% in hydrolyzable forms within the gum. In shea butter extracted from Vitellaria paradoxa kernels, cinnamic acid appears as esters within the unsaponifiable fraction, contributing to its phenolic profile. Balsam of Peru, derived from Myroxylon pereirae, includes cinnamic acid as a key constituent in its aromatic balsam, forming part of the 60-70% cinnamein fraction that also encompasses cinnamyl esters and benzoic acid derivatives. Trace amounts of cinnamic acid are also found in coca leaves (Erythroxylum coca). Trace amounts of cinnamic acid and its hydroxycinnamic derivatives are present in various fruits, such as apricots (Prunus armeniaca) and cherries (Prunus avium), where they contribute to the outer peel's phenolic content, typically at concentrations below 200 mg per 100 g of fresh weight in stone fruit varieties. These compounds also appear in low levels in beverages like wines and teas; for instance, red wines contain approximately 100 mg/L of total hydroxycinnamic acids, while green and black teas harbor them as part of their polyphenol matrix, often in the range of 10-50 mg/L depending on processing. Extraction from these natural sources commonly involves for volatile-rich materials like bark oil or solvent-based methods such as or extraction for resins like storax and , where higher yields are achieved through . Microwave-assisted extraction has been optimized for powder, enhancing recovery of cinnamic acid while minimizing solvent use compared to traditional or techniques. These methods derive from the phenylpropanoid pathway in plants but focus on harvesting rather than biosynthetic details.

Synthesis and production

Laboratory synthesis

Cinnamic acid is commonly synthesized in the laboratory via the , which involves the base-catalyzed condensation of with in the presence of . This method selectively produces the of cinnamic acid and is typically conducted under conditions for several hours. The reaction proceeds through the formation of an from , followed by aldol-type addition to the and subsequent elimination. A representative equation for the process is: \ce{C6H5CHO + (CH3CO)2O ->[NaOAc] C6H5CH=CHCOOH + CH3COOH} Yields for the Perkin reaction generally range from 70% to 80%, though modifications such as the addition of pyridine as a co-catalyst can increase them to up to 85%. Another established laboratory route is the Knoevenagel condensation, where benzaldehyde reacts with malonic acid in the presence of a basic catalyst like piperidine, followed by thermal decarboxylation of the intermediate to afford cinnamic acid. This method is often performed in a solvent such as ethanol or under solvent-free conditions at elevated temperatures (around 100–120°C), making it suitable for green chemistry approaches. The condensation step generates a benzylidene malonic acid intermediate, which upon heating loses CO₂ to yield the α,β-unsaturated acid. Overall yields typically reach 60–80%, with high purity achievable through simple recrystallization. Modern laboratory syntheses include the palladium-catalyzed , which couples an such as iodobenzene with to form cinnamic acid, often in the presence of a base and ligands under mild heating (80–100°C). This cross-coupling method provides stereoselective access to the trans product with yields of 70–90% in optimized microscale setups. These methods highlight the versatility of laboratory-scale preparations, emphasizing control over and efficiency.

Industrial production

Cinnamic acid is primarily produced industrially via synthetic chemical routes such as the Perkin condensation of benzaldehyde with acetic anhydride or the Doebner modification of the Knoevenagel condensation using malonic acid and pyridine, often adapted for continuous flow reactors to enhance throughput and reduce reaction times. An alternative method involves the oxidation of synthetic cinnamaldehyde with molecular oxygen in an aromatic hydrocarbon solvent at temperatures between 30°C and 80°C, yielding high selectivity and efficiency. Natural sources, such as oxidation of cinnamaldehyde from cinnamon essential oil, contribute minimally due to high costs. High-purity grades for pharmaceuticals and specialties rely on synthetic methods, achieving 98-99% purity through . Annual global output is estimated in the thousands of tons, driven by demand in flavors, fragrances, and other sectors. Recent advancements emphasize , with a growing shift toward bio-based production via enzymatic of renewable using engineered microorganisms such as glutamicum, offering an alternative to traditional chemical syntheses reliant on fossil-derived precursors. As of 2024, such biotechnological approaches remain emerging and not yet dominant commercially.

Metabolism and biological role

Metabolism in organisms

In humans, cinnamic acid undergoes hepatic metabolism primarily through β-oxidation, where it is converted to , which is subsequently conjugated with to form for urinary . This process occurs in hepatocytes, with the final metabolite being rather than free in some cases. Additionally, cinnamic acid can be detoxified via conjugation to glucuronides or sulfates in the liver, facilitating its elimination. The of cinnamic acid in hepatic is short, typically less than 1 hour, reflecting its rapid . The β-oxidative conversion of cinnamic acid to benzoic acid involves enzymatic steps, including activation to cinnamoyl-CoA, followed by hydration, dehydrogenation, and thiolysis, ultimately yielding benzoyl-CoA, which is then hydrolyzed to benzoic acid: \text{Cinnamic acid} \xrightarrow{\text{cinnamate:CoA ligase}} \text{cinnamoyl-CoA} \xrightarrow{\text{enoyl-CoA hydratase}} 3\text{-hydroxy-3-phenylpropanoyl-CoA} \xrightarrow{\text{3-hydroxyacyl-CoA dehydrogenase}} 3\text{-oxo-3-phenylpropanoyl-CoA} \xrightarrow{\text{3-oxoacyl-CoA thiolase}} \text{benzoyl-CoA + acetyl-CoA} \xrightarrow{\text{hydrolysis}} \text{benzoic acid} This pathway is conserved across organisms and does not involve as a primary mechanism. In plants and microbes, cinnamic acid participates in phenylpropanoid , where it can be further hydroxylated to , serving as an in the degradation to compounds like . This step, catalyzed by cinnamate 4-hydroxylase, integrates catabolic turnover with broader phenylpropanoid pathways, though it is more prominently associated with . Microbial degradation of cinnamic acid, particularly by soil bacteria such as those in the genera and , proceeds via a coenzyme A-dependent β-oxidative pathway, enabling the use of cinnamoyl-CoA esters as energy sources through complete mineralization to CO₂ and biomass. Aerobic and anaerobic routes have been identified, with enzymes like cinnamoyl-CoA hydratase facilitating the breakdown in cell-free extracts of cinnamic acid-grown cultures.

Biological activities

Cinnamic acid exhibits notable properties, primarily attributed to its phenolic-like conjugated structure, which enables it to scavenge free radicals effectively. In radical scavenging assays, it demonstrates potent activity with an value of approximately 76.46 μg/mL, highlighting its capacity to neutralize . This involves electron donation from the hydroxyl group and the extended π-conjugation in the , contributing to its role in mitigating in biological systems. The compound also displays antimicrobial effects, particularly against such as , by disrupting integrity and inhibiting growth. Representative (MIC) values range from 0.65 to 0.70 mg/mL against E. coli, underscoring its potential as a natural or therapeutic agent. These effects are linked to interference with bacterial and enzyme activity, without significant to host cells at these concentrations. In terms of activity, cinnamic acid inhibits (COX-2) expression, reducing pro-inflammatory mediators like prostaglandins. Studies in periodontal models show it decreases COX-2 levels and associated tissue damage, promoting resolution of . Furthermore, its properties support by enhancing migration and modulating synthesis, accelerating tissue repair processes. Ecologically, cinnamic acid serves as a key compound, secreted by roots in response to stresses to deter and pathogens. Trans-cinnamic acid is rapidly biosynthesized and exuded to inhibit microbial and herbivore feeding, illustrating its role in belowground chemical signaling and protection. Recent research since 2010 has explored cinnamic acid's anticancer potential, particularly its ability to induce in various cancer cell lines. For instance, it triggers in human cells by altering mitochondrial function and activation, suggesting mechanisms involving imbalance and arrest. These findings position it as a promising lead for further chemotherapeutic development, though clinical translation remains pending.

Applications and derivatives

Industrial and commercial uses

Cinnamic acid serves as a key component in the production of flavorings and fragrances, imparting a balsamic, cinnamon-like aroma essential to various consumer products. It is incorporated into chewing gums, beverages, and items at low concentrations, typically ranging from trace amounts to 400 , depending on the product type, to enhance sensory profiles without overpowering other notes. In the polymer industry, cinnamic acid acts as a precursor for synthesizing cinnamate esters, which function as (UV) stabilizers in plastics and personal care formulations. These esters absorb UV radiation, preventing degradation of materials exposed to , and are commonly found in products where they provide effective UVB protection. Cinnamic acid has been utilized as an intermediate in dye production, particularly in the synthesis of synthetic through derivatives of the . This historical application dates back to the late 19th century, when it served as a starting material in early efforts to produce the commercially. Additionally, cinnamic acid is employed as an additive in active materials, where it inhibits bacterial growth to extend the of perishable goods. Its integration into biodegradable films, such as those based on sodium caseinate, leverages its natural properties for solutions. The global market for cinnamic acid, driven by these industrial applications, was valued at approximately USD 45 million in the mid-2020s. Historically, in the early , cinnamic acid derivatives like were foundational bases in perfumery, contributing to the development of complex floral and oriental scents (detailed further in the section on derivatives and related compounds).

Derivatives and related compounds

Cinnamic acid derivatives encompass a range of compounds modified through esterification, , or other substitutions, often enhancing specific properties such as , bioactivity, or reactivity compared to the parent . Esters of cinnamic acid, including , ethyl cinnamate, and benzyl cinnamate, are prominent examples valued for their aromatic profiles. exhibits a fruity, balsamic reminiscent of strawberries and serves as a key fragrance ingredient in perfumes and essential oils. Ethyl cinnamate possesses a sweet, balsamic aroma with fruity and honey-like notes, contributing to flavor formulations that evoke cinnamon and berry profiles. Benzyl cinnamate imparts a sweet, balsamic scent with floral undertones, commonly incorporated into fragrance compositions for its fixative qualities. Hydroxylated derivatives of cinnamic acid demonstrate pronounced capabilities, often surpassing the parent molecule in scavenging free radicals. , or 4-hydroxycinnamic acid, acts as an effective by protecting against oxidative damage in biological tissues. , known chemically as 3-methoxy-4-hydroxycinnamic acid and abundant in rice bran, provides enhanced UV protection through its ability to absorb radiation and neutralize . Other notable derivatives include cinnamoyl chloride and α-cyano-4-hydroxycinnamic acid, each tailored for specialized chemical applications. Cinnamoyl chloride functions as a versatile acylating agent in , facilitating the introduction of the cinnamoyl group into various molecules via reactions. α-Cyano-4-hydroxycinnamic acid serves as a matrix in (MALDI) , enabling sensitive detection of peptides and biomolecules by promoting efficient ionization. These derivatives are typically synthesized through esterification of cinnamic acid with alcohols under acidic conditions or via for introducing functional groups like hydroxyl or cyano moieties. For instance, ester derivatives such as methyl and ethyl cinnamates are prepared by esterification, yielding compounds with improved lipophilicity and over the free acid. Substituted variants like often involve selective methoxylation and hydroxylation steps on the aromatic ring, enhancing their bioactivity for targeted uses.

Safety and toxicology

Cinnamic acid is classified under the Globally Harmonized System (GHS) as causing serious eye irritation (Category 2A) and being harmful to aquatic life (Category 3).

Acute toxicity

Cinnamic acid exhibits low . The oral (LD50) is 2,500 mg/kg body weight in rats, greater than 5,000 mg/kg in mice and guinea pigs, and the dermal LD50 exceeds 5,000 mg/kg in rabbits. No specific inhalation LC50 data are available, but it is not expected to pose significant respiratory risks under normal handling.

Irritation and sensitization

It acts as a mild skin irritant at concentrations above 10%, but shows no in short-term tests. Cinnamic acid causes serious eye . Regarding , it is not considered a concern at typical use levels in fragrances and (up to 0.043%), though weak potential was observed at 15% in guinea pigs, which is reversible. It is not phototoxic or photoallergenic.

Chronic toxicity and genotoxicity

In repeated-dose studies, the (NOAEL) is 7.5 mg/kg/day. For developmental toxicity, the NOAEL is 50 mg/kg/day. Cinnamic acid is rapidly absorbed, metabolized (primarily to ), and excreted, with 82% eliminated in urine within 24 hours in rats. results are mixed: negative in bacterial assays but positive in some in vitro mammalian cell tests (e.g., CHO cells at 10–33.3 μM); no in vivo data confirm genotoxicity.

Carcinogenicity and reproductive toxicity

There is no evidence of carcinogenicity; it is not listed by IARC, NTP, or OSHA as a carcinogen. Reproductive and developmental toxicity data indicate low concern, with margins of exposure exceeding 100 at typical exposure levels.

Regulatory status

Cinnamic acid is generally recognized as safe (GRAS) by the U.S. Food and Drug Administration (FDA) for use as a flavoring agent in food at low levels. The Joint FAO/WHO Expert Committee on Food Additives (JECFA) also deems it safe for food use. In fragrances, systemic exposure is estimated at 0.00097 mg/kg/day, with no safety concerns identified. It is listed on the Toxic Substances Control Act (TSCA) inventory. Occupational exposure limits are not established, but handling requires eye protection, gloves, and avoidance of environmental release. As of 2023, the European Chemicals Agency (ECHA) classifies it similarly for eye irritation.