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Propionic acid

Propionic acid, also known as propanoic acid, is a straight-chain saturated with the molecular formula CH₃CH₂COOH and a molecular weight of 74.08 g/mol. It appears as a colorless to pale yellow oily liquid at , characterized by a sharp, pungent odor reminiscent of rancid . As one of the simplest , it plays a key role in and is naturally produced during the of carbohydrates in the gastrointestinal tracts of ruminants and humans. Propionic acid is primarily produced industrially through processes, such as the of (Reppe process) or the oxidation of derived from . Alternatively, it can be synthesized via microbial using like Propionibacterium freudenreichii, which converts or sugars into the acid, offering a sustainable alternative especially from renewable feedstocks like . This biotechnological route has gained interest due to its potential for cost-effective production and reduced environmental impact compared to . In applications, propionic acid serves as a versatile chemical intermediate in the manufacture of esters, salts, and polymers, including cellulose propionate plastics and herbicides like 2,4-dichlorophenoxypropionic acid. It is widely used as a food preservative (E280) to inhibit mold and bacterial growth in baked goods, cheeses, and animal feeds, leveraging its antimicrobial properties at concentrations typically below 0.3%. Medically, its calcium or sodium salts act as antifungal agents in topical treatments and veterinary products. Regarding safety, propionic acid is classified as corrosive to , eyes, and respiratory tissues, with potential to cause severe burns upon direct contact or of vapors. It is flammable, with a of 52°C and explosive limits of 2.9–14.8% in air, necessitating proper and protective equipment in handling. Acute oral toxicity is moderate (LD50 in rats: 2,600 mg/kg), and it is (GRAS) by the FDA for use at approved levels, though excessive may lead to gastrointestinal irritation or metabolic disturbances. No evidence of carcinogenicity has been established.

History

Discovery

Propionic acid was first identified in 1844 by German chemist Johann Gottlieb during his investigations into the degradation products of sugar treated with potassium hydroxide. In 1847, French chemist Jean-Baptiste Dumas demonstrated that all previously reported forms of the compound were identical, establishing its chemical unity. Dumas coined the name "acide propionique" (propionic acid in English), derived from the Greek terms prōtos (first) and pion (fat), highlighting its position as the shortest-chain fatty acid following acetic acid. This naming reflected the emerging systematic understanding of organic acids in early organic chemistry. In 1878, Albert Fitz demonstrated bacterial synthesis of propionic acid, establishing the Fitz equation to describe its production by fermentation.

Commercial Development

Propionic acid transitioned from a laboratory compound, first described in 1844, to commercial production in the early 20th century through chemical synthesis methods, driven by increasing demand for effective preservatives in the food industry. By the 1930s, its antifungal properties were recognized for preventing spoilage in baked goods, leading to initial industrial applications as calcium or sodium propionate salts. This marked the beginning of its role as a commodity chemical, with early production focused on meeting needs for mold inhibition in grains and dairy products. Following , production scaled significantly with advancements in processes, exemplified by 's ethylene-based synthesis. In 1941, chemist Walter Reppe developed a method to produce propionic acid from ethylene and , followed by a in 1951 and commercial launch in 1952 at a capacity of 1,200 tons per year. By 1960, expanded to a large-scale facility in , , reaching 149,000 metric tons annually as of recent years, which facilitated broader industrial adoption in preservatives and intermediates. This post-war expansion aligned with rising availability, propelling propionic acid from niche use to a key bulk chemical. As of , global production is approximately 560,000 metric tons annually, fueled by demand in and manufacturing for applications like herbicides and propionate. The market was valued at approximately $1.11 billion in 2023, projected to grow at a (CAGR) of 3.4% from 2024 through 2030.

Properties

Physical Properties

Propionic acid has the molecular formula C₃H₆O₂ and the CH₃CH₂COOH. Its molecular weight is 74.08 g/mol. At standard conditions, propionic acid appears as a colorless, oily with a pungent and rancid . This characteristic arises from its volatile nature and contributes to its role as a in various applications. The compound has a of -20.7 °C, remaining at typical room temperatures, and a of 141.1 °C at 760 mmHg. Its density is 0.993 g/cm³ at 20 °C, slightly less than that of . Propionic acid exhibits high solubility, being miscible with , , and , which reflects its polar functionality. The vapor pressure is 2.9 mmHg at 20 °C, indicating low to moderate under ambient conditions. Additionally, its refractive index is 1.3869 at 20 °C, a value typical for short-chain s.

Chemical Properties

Propionic acid behaves as a weak in aqueous solutions, partially dissociating to form the propionate ion and hydronium ion. Its is K_a = 1.34 \times 10^{-5} at 25 °C, corresponding to a value of 4.87, which indicates moderate acidity compared to stronger acids but sufficient for applications requiring adjustment. Like other carboxylic acids, propionic acid exhibits characteristic reactivity at the carboxyl group. It neutralizes bases to form water-soluble salts, such as sodium or calcium propionates, through proton transfer. With alcohols under acidic , it undergoes Fischer esterification to produce esters, while reactions with amines yield amides, often requiring activation or heating for efficient conversion. These reactions highlight its versatility in forming derivatives central to . Under high temperatures with (a mixture of and ), propionic acid or its sodium salt undergoes , losing the carboxyl group as to produce . The compound remains stable in air at ambient conditions, showing no significant or . However, its acidity makes it corrosive to many metals, including iron and , where it reacts to generate gas and metal propionates./Carboxylic_Acids/Reactivity_of_Carboxylic_Acids/The_Decarboxylation_of_Carboxylic_Acids_and_Their_Salts)

Production

Chemical Synthesis

The primary industrial chemical synthesis of propionic acid involves the process, a hydrocarboxylation reaction of using catalysts. This method, originally developed by Walter Reppe and colleagues at in the early 1950s, proceeds under high pressure (100–300 bar) and temperature (250–320 °C) with (Ni(CO)4) as the catalyst, often promoted by additives like to enhance selectivity and prevent catalyst precipitation. The key reaction is the of with and : \mathrm{C_2H_4 + CO + H_2O \rightarrow CH_3CH_2COOH} This direct route yields propionic acid in a single step, with the crude product purified by and the catalyst recycled; byproducts such as off-gases are managed through with heat recovery. A variant of the Reppe process emphasizes -based for improved efficiency, making it a dominant route due to its cost-effectiveness from readily available feedstocks like derived from or . Alternative chemical routes include the oxidation of propanal, typically produced via of followed by air oxidation under mild conditions (40–50 °C) with optional manganese salts as catalysts, achieving yields over 90%. Similarly, n-propanol can be oxidized to propionic acid using oxygen or air in the presence of catalysts like or silver, though this is less common industrially due to higher costs. Another pathway is the of ethyl alcohol with , catalyzed by metals such as or , but this method is largely obsolete owing to economic disadvantages compared to ethylene-based processes. These routes collectively enable large-scale from sources, emphasizing efficiency and integration with existing processing infrastructure.

Biotechnological Methods

Biotechnological production of propionic acid primarily relies on anaerobic fermentation processes mediated by bacteria from the genus Propionibacterium, such as P. acidipropionici, which convert various carbon sources into propionate through the Wood-Werkman cycle. In this pathway, lactate serves as a key substrate, undergoing fermentation according to the Fitz equation: three molecules of lactate yield two molecules of propionate, one molecule of acetate, one molecule of CO₂, and energy in the form of ATP. This process is obligately anaerobic and leverages the bacteria's ability to oxidize lactate to support reductive steps, producing propionic acid as the primary end product while generating acetate and CO₂ as byproducts. A range of renewable substrates can be utilized by species to enhance sustainability, including derived from , from , and whey lactose from dairy processing. , in particular, supports high propionate yields due to its compatibility with the bacteria's metabolic pathways, often outperforming traditional sugars in co-fermentation setups. Similarly, whey permeate provides an economical waste-based feedstock, enabling efficient conversion without significant inhibition. conditions are optimized for maximal productivity, typically at a of 6-7 to maintain activity and prevent stress, and temperatures of 30-35°C to balance growth and product formation rates. Under these parameters, yields can reach up to 0.6 g of propionic acid per gram of substrate consumed, demonstrating the process's efficiency with low-cost inputs. Recent advancements as of have focused on integrating these fermentations into bio-refineries that utilize waste streams, such as agroindustrial effluents and food byproducts, to produce propionic acid at scale while minimizing environmental impact. These integrated systems, exemplified by processes from companies like and , incorporate waste-derived feedstocks like and biomass sugars, achieving reductions of 20-30% compared to conventional methods reliant on . Such developments underscore the shift toward models, where propionibacteria fermentation not only valorizes wastes but also aligns with broader goals of renewable chemical production, though chemical synthesis still dominates global production (over 95%). Propionibacteria naturally contribute to processes like Swiss cheese ripening through similar fermentative pathways.

Applications

Industrial Applications

Propionic acid plays a significant role as a chemical in various non-food sectors, comprising approximately 48% of global production as of 2024. It is employed in the synthesis of herbicides, such as the propionic acid derivative , which is used for broadleaf weed control in . Additionally, propionic acid serves as a for producing perfumes and fragrances, contributing to their through esterification processes, and for rubber accelerators and stabilizers that enhance in and manufacturing. In the , propionic acid and its anhydride are key components in the production of propionate, a versatile applied in coatings, printing inks, and specialty films due to its optical clarity and durability. The acid also functions as an in , aiding in the and of resins and emulsions for adhesives and coatings. As of 2025, industry trends emphasize the integration of propionates into sustainable polymers, with growing demand for bio-based derivatives to meet regulations on eco-friendly materials and reduce reliance on petroleum-derived alternatives. Its preservative properties further enable applications in formulations requiring microbial stability.

Food and Feed Applications

Propionic acid is recognized as (GRAS) by the U.S. () for use as a direct , specifically under 21 CFR 184.1081, and is designated as E280 in the . This status enables its application as an that inhibits the growth of molds and certain bacteria, thereby extending shelf life in various edible products. Its effectiveness stems from lowering and disrupting microbial metabolism, making it suitable for incorporation at controlled concentrations. In food applications, propionic acid or its salts, such as calcium propionate, are commonly added to baked goods like and tortillas to prevent contamination, typically at levels of 0.1-0.3% by weight. Similarly, it is used in cheeses to control fungal growth during storage and ripening, maintaining product quality without altering sensory attributes significantly at these dosages. In animal feed preservation, particularly , propionic acid enhances aerobic stability by reducing heating and microbial spoilage when applied at 0.1-0.3%, allowing for better nutrient retention in ensiled forages. A key role in feed applications involves preventing mycotoxin formation by inhibiting toxin-producing fungi such as species, which can contaminate grains and forages during storage. Approximately 40% of global propionic acid production is directed toward and preservation, underscoring its importance in livestock to mitigate risks from s. As of 2025, the market for propionic acid in natural preservative formulations is experiencing growth, driven by consumer preferences for clean-label products and biotechnological production methods that emphasize bio-based sources over synthetic alternatives. This trend supports reduced reliance on purely chemical additives while leveraging propionic acid's naturally occurring origins from microbial .

Biological Role

Human Physiology

Propionic acid is produced in the human colon through the of dietary fibers by , serving as a key short-chain (SCFA). This process involves anaerobic bacteria breaking down indigestible carbohydrates, yielding propionic acid alongside and butyrate. As an SCFA, propionic acid contributes to colonic energy metabolism, where SCFAs collectively provide approximately 10% of the host's daily caloric needs through beta-oxidation in colonocytes, supporting epithelial cell function and barrier integrity. Absorbed propionic acid is transported via the to the liver, where it undergoes to propionyl-CoA, subsequently converted to for entry into the tricarboxylic acid cycle; this pathway enables its utilization in , contributing to glucose . In healthy individuals, this hepatic processing maintains balanced levels, but disruptions occur in , a rare autosomal recessive caused by deficiency in propionyl-CoA carboxylase. Elevated propionic acid accumulation in this condition leads to , , and neurological symptoms, including developmental delays, seizures, and autism-like behavioral traits such as social withdrawal and repetitive actions. Humans typically obtain 100–500 mg of propionic acid daily through dietary sources, including fermented foods and additives like calcium propionate used as preservatives in baked goods. Recent 2025 highlights propionic acid's potential effects on gut , with studies showing that propionate-producing supplementation reduces obesity-related via G-protein coupled receptor 41 signaling, modulating immune responses and improving metabolic outcomes in high-fat models.

Microbiology

Propionibacterium freudenreichii, a Gram-positive, bacterium, plays a central role in the production of propionic acid during the ripening of . Under conditions in the cheese matrix, this bacterium ferments to generate propionic acid as the primary end product, along with acetic acid and , which contributes to the formation of characteristic eyes (holes) in the cheese. The propionic acid imparts a nutty flavor to the cheese through the involvement of propionyl-CoA in metabolic pathways. In rumen fermentation, propionic acid is a key volatile fatty acid produced by ruminal such as elsdenii and species from the breakdown of carbohydrates in feed, serving as an energy source for the host animal and helping to regulate rumen . Propionic acid also functions as a natural preservative in , where it is generated during or applied exogenously to lower and inhibit the growth of pathogens like typhimurium by disrupting their cellular and invasion mechanisms. Ecologically, propionic acid contributes to cycling in microbiomes, where like and species produce it during the of residues, facilitating solubilization and . In systems, propionic acid such as Propionibacterium acidipropionici generate propionic acid as an intermediate in of organic waste, supporting the conversion of complex substrates into precursors and aiding in the overall cycling of .

Derivatives

Salts

Propionate salts are formed through the neutralization reaction of propionic acid with a metal hydroxide or carbonate, as exemplified by the general equation: \mathrm{CH_3CH_2COOH + MOH \rightarrow CH_3CH_2COOM + H_2O} where M represents a metal cation. These salts exhibit high water solubility, with sodium propionate dissolving at approximately 1 g per ml in water, and are generally less volatile than the parent acid due to their ionic nature, which reduces vapor pressure and odor intensity compared to the rancid-smelling propionic acid. Key examples include calcium propionate (E282), widely used as an agent in and other baked goods to inhibit growth and extend . Sodium propionate (E281) serves primarily as a feed additive in animal , acting as an to preserve and prevent spoilage. Zinc propionate is employed in , particularly in foot products, for its properties against molds, fungi, and . In the propionic acid derivatives market, salts such as calcium and accounted for approximately 30% of the in 2023.

Esters

Propionate esters are compounds derived from propionic acid through esterification, a reaction in which propionic acid reacts with an in the presence of an acid catalyst, typically , to form the ester and water. The general reaction is represented as: \mathrm{CH_3CH_2COOH + ROH \xrightarrow{H_2SO_4} CH_3CH_2COOR + H_2O} This Fischer esterification process is widely employed for producing short-chain propionate esters due to its simplicity and efficiency, yielding high-purity products suitable for industrial applications. Among the key propionate esters, (CH₃CH₂COOCH₃) is valued for its sweet, fruity, rum-like odor with apple and notes, making it a common flavoring agent in products such as candies and baked goods. (CH₃CH₂COOCH₂CH₃) exhibits a strong fruity, ethereal aroma reminiscent of apples and pineapples, and it is frequently incorporated into perfumes and fragrances to impart fresh, natural fruit scents. Propyl propionate (CH₃CH₂COOCH₂CH₂CH₃), on the other hand, serves primarily as a in industrial coatings and paints, offering good solvency for resins while providing medium evaporation rates that enhance application properties. These esters are characterized by their volatility, with boiling points typically ranging from 80°C for to 122–124°C for propyl propionate, allowing them to evaporate readily in formulations without leaving residues. They also demonstrate low profiles, with oral LD50 values exceeding 1850 mg/kg body weight and no genotoxic effects observed, enabling safe use in , fragrance, and settings at regulated levels. Biotechnological methods utilizing renewable feedstocks are under development to provide eco-friendly alternatives for propionate esters in the aroma chemicals market, aligning with trends.

Safety and Environmental Impact

Health and Safety

Propionic acid poses moderate upon ingestion, with an oral LD50 value of 2,600 mg/kg in rats, indicating potential harm if swallowed in significant quantities. Direct contact with or eyes can cause , and at higher concentrations, it acts as a corrosive agent, leading to severe burns, redness, and possible permanent damage. Its pungent, rancid , detectable at low levels (threshold around 0.026–0.17 ), serves as a sensory warning for potential exposure hazards. Repeated or prolonged exposure to propionic acid vapors may result in to lungs and mucous membranes. In food preservation contexts, it is affirmed as (GRAS) by the U.S. for direct use as an agent, typically at levels up to 0.3% by weight in products such as baked goods, provided good manufacturing practices are followed. To mitigate occupational risks from , the Institute for Occupational Safety and Health (NIOSH) recommends an exposure limit (REL) of 10 (30 mg/m³) as an 8-hour time-weighted average. Safe handling of propionic acid requires the use of appropriate (PPE), including chemical-resistant gloves, safety goggles, face shields, and respiratory protection in poorly ventilated areas to prevent skin, eye, and inhalation . should occur in cool, well-ventilated facilities, away from heat sources, strong bases, and oxidizing agents, to minimize flammability and reactivity risks; containers must be tightly sealed to avoid vapor release. In case of , immediate flushing with and medical attention are essential, with spill response involving neutralization and proper . In October 2025, the confirmed propionic acid and its salts remain safe for use in terrestrial animal feed under Regulation () 2025/2186.

Environmental Considerations

Propionic acid exhibits high biodegradability in aquatic environments, with studies demonstrating 74% degradation via biological oxygen demand (BOD) relative to (ThOD) over 30 days in aerobic conditions using a Warburg respirometer method. Under anaerobic conditions, complete (100%) can occur within 20 days in cultures. This rapid microbial breakdown, often exceeding 70% within a month, underscores its low persistence in the and supports natural processes by and . The compound shows low potential for due to its hydrophilic nature, with an experimentally determined (log Kow) of 0.33, indicating minimal partitioning into fatty tissues of organisms. In terms of production impacts, conventional of propionic acid from fossil feedstocks generates approximately 4.4 kg CO₂ equivalents per kg of product across the , primarily from energy-intensive processes like oxidation. Biotechnological routes, such as of renewable substrates like or sugars, can reduce by 34% to 60% compared to these chemical methods, offering a more sustainable alternative with lower carbon footprints. Production processes also necessitate to neutralize the acid's low (around 2.5), preventing acidification of effluents discharged into aquatic systems. As of 2025, propionic acid is registered under the EU REACH regulation, which imposes general requirements for emission controls and risk assessments but no substance-specific emission limits; manufacturers must ensure safe handling to minimize releases into the environment. Ecotoxicological data reveal moderate aquatic toxicity, with a 96-hour LC₅₀ of 67.1 mg/L for rainbow trout (Oncorhynchus mykiss) and a 48-hour EC₅₀ of 21.0 mg/L for water fleas (Daphnia magna), classifying it as not highly hazardous but requiring monitoring in sensitive ecosystems. Propionic acid has negligible ozone depletion potential, as it lacks the halogenated structures associated with stratospheric ozone breakdown.

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