Acid value
The acid value (AV), also known as acid number, is a measure of the free fatty acid content in substances such as fats, oils, waxes, and resins, defined as the milligrams of potassium hydroxide (KOH) required to neutralize the free fatty acids present in one gram of the sample.[1][2] It quantifies the acidity arising from hydrolysis of triglycerides into free fatty acids, which occurs due to enzymatic activity, improper storage, or processing conditions like high temperature and humidity.[2] The acid value is determined through titration, typically by dissolving the sample in a solvent like ethanol and titrating with a standardized KOH solution using an indicator such as phenolphthalein.[2] The calculation follows the formula AV = [(S - B) × N × 56.1] / W, where S is the volume of KOH used for the sample (mL), B is the blank volume (mL), N is the normality of the KOH solution, and W is the sample weight in grams (56.1 represents the molecular weight of KOH).[1] This method aligns with standardized procedures from organizations like the American Oil Chemists' Society (AOCS Cd 3a-63) and ASTM International (D664 or D974).[1] In practical applications, the acid value serves as a critical quality indicator for edible oils and fats, where low values (e.g., 0.07 for canola oil or 0.60 for soybean oil) signify freshness and good refining, while higher values (e.g., 6.6 for virgin olive oil or up to 31 for used frying oil) suggest degradation or rancidity.[2] It is also essential in biodiesel production, with standards like EN 14104 specifying a maximum AV of 0.5 mg KOH/g to ensure fuel stability and prevent corrosion in engines.[1] Additionally, processing techniques such as roasting can lower the acid value by inactivating lipases, as seen in reductions from 2.04 to 1.59 mg KOH/g at 140°C.[1]Definition and Background
Definition
The acid value (AV), also known as acid number, is defined as the mass in milligrams of potassium hydroxide (KOH) required to neutralize the free fatty acids present in 1 gram of a sample, typically consisting of fats, oils, waxes, or resins.[3] This metric quantifies the amount of free acidic components, primarily free fatty acids, in these substances.[4] AV is especially relevant for water-insoluble materials like fats and oils, which cannot be assessed using pH due to their lack of aqueous solubility.[5] Free fatty acids, such as oleic acid or palmitic acid, arise primarily from the hydrolysis of triglycerides during processes like storage, processing, or enzymatic degradation, rather than oxidative rancidity.[6] The standard unit of measurement is milligrams of KOH per gram (mg KOH/g).[3] This value can be converted to the percentage of free fatty acids (% FFA) based on the molecular weight of the predominant fatty acid; for example, in the case of oleic acid (molecular weight 282), % FFA = AV × (282 / 561) ≈ AV × 0.502, or equivalently AV ≈ % FFA × 1.99.[7] Unlike the saponification value, which measures the total fatty acid content (both free and esterified) by quantifying the alkali needed to saponify all esters in the sample, AV specifically targets only the free acids. In contrast, the peroxide value assesses the extent of primary oxidation by measuring peroxides formed during lipid peroxidation, providing insight into rancidity progression rather than acidity.[8]Historical Development
The origins of the acid value as an analytical parameter in fat chemistry can be traced to the early 19th century, when French chemist Michel Eugène Chevreul initiated systematic studies on the composition of soaps and animal fats in 1811. Assigned by Louis Vauquelin to analyze a soap sample, Chevreul employed hydrochloric acid to liberate insoluble organic acids from the saponified material, forming a distinct layer of fatty acids, and later demonstrated in 1823 that fats undergo hydrolysis into glycerol and fatty acids during saponification.[9] This work, foundational to understanding rancidity through the accumulation of free fatty acids from triglyceride breakdown, directly informed early efforts to quantify acidity in fats for soap-making and quality assessment.[10] By the late 19th century, as organic chemistry advanced and industrial processing of fats expanded, titration-based methods emerged to measure free fatty acids more precisely, reflecting the need for standardized quality controls in pharmacopeias and trade. These analytical approaches were formalized in early 20th-century compendia, such as the British Pharmacopoeia of 1914, which incorporated acid value alongside saponification and iodine values to characterize fats and oils for medicinal and commercial use.[11] Concurrently, the American Oil Chemists' Society (AOCS), founded in 1909, began developing official methods like Cd 3d-63 for acid value determination, establishing titration protocols that became benchmarks for the burgeoning edible oil industry.[12] Key milestones in the 20th century included widespread adoption of acid value in post-1900 edible oil standards amid fats' industrialization for food and manufacturing, with organizations like the International Union of Pure and Applied Chemistry (IUPAC) publishing detailed methods in their 1966 Standard Methods for the Analysis of Oils, Fats and Derivatives.[13] The Association of Official Analytical Chemists (AOAC) further influenced its definition through validated procedures in Official Methods of Analysis, emphasizing reproducibility for quality control.[14] In recent decades, updates reflect evolving applications, such as the 2001 adoption of ASTM D6751 for biodiesel, which set initial acid number limits at 0.80 mg KOH/g and tightened them to 0.50 mg KOH/g in 2006 to ensure fuel stability.[15] These global standards from IUPAC and AOAC continue to shape acid value protocols, harmonizing assessments across industries.[16]Measurement Methods
Principle of Determination
The acid value is determined by titrating the free carboxylic acid groups present in fatty acids or other acidic components of a sample with a standardized solution of potassium hydroxide (KOH) in a non-aqueous solvent, such as neutralized ethanol or isopropanol, leading to the formation of water-soluble soap salts.[4] This neutralization reaction exploits the acidic nature of the carboxyl groups (-COOH) in free fatty acids, which react stoichiometrically with the hydroxide ions from KOH to produce carboxylate salts (-COO⁻ K⁺) and water. The endpoint of the titration is detected using an indicator like phenolphthalein, which changes color from colorless to pink in the pH range of 8.2 to 10.0, appropriately matching the equivalence point for the weak acids involved, as fatty acids have pKa values typically around 4.5 to 5.0.[17][18] This pH range ensures accurate detection despite the weak acidity, as the titration curve for weak acids with strong bases rises sharply near pH 9.[19] The stoichiometry of the reaction is 1:1, where one mole of KOH neutralizes one mole of free fatty acid, providing a direct measure of the acid content.[20] KOH is preferred over sodium hydroxide (NaOH) because the resulting potassium soaps exhibit greater solubility in the alcoholic solvents used, preventing precipitation that could obscure the endpoint or incomplete reaction.[21] A key limitation arises from potential interference by other acidic species, such as phospholipids, which can contribute to the titration volume and overestimate the free fatty acid content; this is typically mitigated through prior sample preparation steps like extraction or degumming to isolate the target acids.[22][23]Laboratory Procedure
The laboratory procedure for determining the acid value of fats and oils follows standardized protocols such as AOCS Official Method Cd 3d-63 and ISO 660:2020, which outline titrimetric methods using potassium hydroxide (KOH) to neutralize free fatty acids.[3][24] These methods ensure reproducibility and precision, with repeatability typically within ±0.02 mg KOH/g for single determinations under controlled conditions.[25]Reagents and Apparatus
Key reagents include a neutralized solvent mixture, typically 50–100 mL of a 1:1 blend of ethanol (96% v/v) or isopropanol (99% v/v) with diethyl ether (peroxide-free) or alternatives like tert-butyl methyl ether and toluene; 0.1 mol/L KOH or NaOH solution in ethanol or methanol; and an indicator such as phenolphthalein (1 g/100 mL in ethanol) or thymolphthalein (0.2 g/100 mL in ethanol).[24][26] Essential apparatus comprises an analytical balance accurate to 0.001 g, 250 mL Erlenmeyer or conical flasks, and burettes (10 mL with 0.02 mL graduations or 25 mL with 0.05 mL graduations, ISO 385 Class A).[24][27]Sample Preparation
Prepare the test sample according to ISO 661 if necessary, avoiding excessive heating or filtration that could volatilize short-chain fatty acids. Weigh a test portion of 0.2–20 g of the homogenized fat or oil sample into a 250 mL flask or beaker, using the analytical balance for accuracy and selecting exact mass per expected acid value as per ISO 660:2020 Table 1 (e.g., 20 g for <1 mg KOH/g, 0.5 g for 15–75 mg KOH/g). Add 50–100 mL of the neutralized solvent mixture and gently heat to 50–60°C while swirling to achieve complete dissolution and homogeneity; allow to cool if warming was applied.[24][27]Titration Procedure
Add 1–2 drops (approximately 0.1 mL) of the indicator solution to the dissolved sample. Titrate with the 0.1 mol/L KOH solution from the burette, swirling continuously, until the endpoint is reached—a persistent pink color (for phenolphthalein) or blue (for thymolphthalein or Alkali Blue 6B) that lasts at least 15 seconds after adding a single drop. Record the volume of KOH consumed. Perform a blank titration on the same volume of neutralized solvent mixture under identical conditions to account for any residual acidity.[24][26]Safety and Precision Considerations
Conduct the procedure in a well-ventilated area, wearing appropriate protective equipment, as solvents like diethyl ether and ethanol are highly flammable and may form peroxides; store ether in airtight containers away from light and heat. Ensure precise weighing and volume measurements to meet method precision, where single determinations in the same laboratory exhibit repeatability of no more than 0.07 mg KOH/g for values below 4 mg KOH/g or 1.8% relative for higher values, and inter-laboratory reproducibility limits differences to 0.22 mg KOH/g or 5.5% relative.[24][25]Calculations and Formulas
The acid value (AV) is calculated from the titration data using the formula AV = \frac{(V - V_b) \times N \times 56.1}{W} where V is the volume of potassium hydroxide (KOH) solution used for the sample titration in milliliters, V_b is the volume of KOH used for the blank titration in milliliters, N is the normality of the KOH solution in moles per liter, 56.1 is the molecular weight of KOH in grams per mole, and W is the weight of the sample in grams.[4][28] This expression derives from the definition of acid value as the milligrams of KOH required to neutralize the free fatty acids in one gram of sample, equivalent to the milliequivalents of acid present; the net volume of titrant (V - V_b) accounts for any reagent or solvent background acidity, and multiplication by N \times 56.1 converts to milligrams of KOH, normalized by sample mass W.[29] To convert the acid value to percentage of free fatty acids (% FFA), typically expressed as oleic acid (molecular weight 282 g/mol), the formula is \% \text{ FFA} = \frac{AV \times MW}{561} where MW is the molecular weight of the reference fatty acid (e.g., 282 for oleic acid) and 561 is $10 \times 56.1.[30] This yields approximately % FFA = AV / 1.99 for oleic acid, reflecting the mass of free fatty acid per 100 grams of sample based on the equivalent weight relationship between KOH and the fatty acid. Potential sources of error in these calculations include indicator fade, such as with phenolphthalein where the color change may not persist due to residual acidity or CO₂ absorption, leading to over- or underestimation of the endpoint volume, and solvent evaporation during sample dissolution or titration, which concentrates the analyte and inflates the apparent acid content.[31] To mitigate, titrations are performed under controlled conditions, and results are reported to two decimal places for precision, aligning with standard reporting practices for values up to 1 mg KOH/g.[24]Applications
In Food and Edible Oils
The acid value serves as a critical indicator of hydrolysis and rancidity in edible fats and oils, reflecting the extent of free fatty acid (FFA) formation from the breakdown of triglycerides due to enzymatic, microbial, or hydrolytic processes. In virgin oils, such as extra virgin olive oil, an acid value exceeding approximately 1.6 mg KOH/g often signals the onset of degradation, which can compromise flavor by introducing bitter, soapy off-notes and reduce nutritional quality through the loss of intact glycerides essential for lipid-soluble vitamin absorption and energy provision.[32][33] Regulatory standards enforce strict acid value limits to ensure food safety and quality in edible oils. The European Union stipulates that extra virgin olive oil must have a free acidity of no more than 0.8% (equivalent to an acid value of approximately 1.6 mg KOH/g), while refined olive oils are limited to 0.3% free acidity (about 0.6 mg KOH/g).[34] Internationally, the Codex Alimentarius sets a maximum acid value of 0.6 mg KOH/g for refined vegetable oils, with higher allowances up to 4.0 mg KOH/g for virgin oils, though values approaching these upper limits indicate suboptimal quality.[35] In the United States, while the FDA does not specify exact acid value thresholds, compliance with Codex standards is commonly referenced for refined edible oils, typically maintaining levels below 0.3 mg KOH/g to meet good manufacturing practices.[35][32] During processing, storage, and use, acid value monitoring is essential for maintaining edible oil integrity. In refining, elevated acid values guide neutralization steps to remove FFAs, preventing carryover into finished products; during storage, rising values due to moisture or temperature fluctuations signal the need for antioxidants or repackaging to extend shelf life.[32] In frying applications, acid values increase with repeated heating, correlating strongly with sensory defects such as off-odors from volatile FFA derivatives, prompting discard when exceeding 2-3 mg KOH/g to avoid quality decline.[36] Elevated free fatty acids in edible oils, as indicated by high acid values, are linked to health concerns primarily through promotion of oxidative stress upon consumption, where FFAs can exacerbate lipid peroxidation in vivo and contribute to hepatic fat accumulation, though they pose no direct toxicity at typical dietary levels.[37] Chronic intake of oils with acid values signaling advanced hydrolysis may thus indirectly heighten risks of oxidative damage, underscoring the importance of low-acid products for nutritional safety.[33]In Industrial and Biodiesel Contexts
In industrial applications, the acid value (AV) serves as a critical indicator of raw material purity for lipid-based excipients in cosmetics and pharmaceuticals, where elevated levels signal hydrolysis or oxidation that could compromise product efficacy and safety. For instance, the European Pharmacopoeia specifies upper limits for AV in lipid excipients ranging from 0.2 to 6 mg KOH/g, depending on the substance, to ensure stability in formulations such as soaps and creams.[38] These limits, typically maintained below 5-10 mg KOH/g in practice, help prevent issues like emulsion breakdown by minimizing free fatty acids that alter pH and interfacial tension.[38] In biodiesel production, AV is a key quality parameter to ensure fuel compatibility with engine systems, as high values correlate with free fatty acid content that promotes corrosion and filter clogging. The European standard EN 14214 mandates a maximum AV of 0.50 mg KOH/g for fatty acid methyl esters, corresponding to approximately 0.25% free fatty acids, to mitigate these risks. In the United States, the ASTM D6751 standard similarly limits AV to 0.50 mg KOH/g.[39][40] For feedstocks with high free fatty acid levels, such as waste oils exceeding 2 mg KOH/g, pretreatment via acid-catalyzed esterification is essential to reduce AV before transesterification, enabling efficient conversion to biodiesel.[41][42] Beyond fuels, AV monitors oxidative degradation in vegetable oil-based industrial lubricants and paints, where rising values indicate breakdown of triglycerides into acidic byproducts that accelerate wear or discoloration. In lubricants, an AV exceeding 3.5-4.0 mg KOH/g often signals the need for additive replenishment or replacement, particularly for bio-based formulations derived from vegetable oils that exhibit higher total acid numbers than mineral oils.[43][44][45] Similarly, in paints and coatings, elevated AV in vegetable oil binders prompts the incorporation of antioxidants to extend shelf life and maintain performance, as free acids contribute to viscosity changes and reduced adhesion.[46][47] The role of AV in these contexts has gained economic significance in the 2020s amid the push for sustainable fuels, where it guides feedstock selection for biodiesel from low-cost, high-acid sources like used cooking oil, which often requires pretreatment but offers cost savings over virgin oils. The global used cooking oil market, valued at $8.00 billion in 2023, is projected to reach $13.99 billion by 2032.[48][49][50] This approach supports broader industry contributions, with biomass-based diesel generating $42.4 billion in U.S. economic activity in 2024 alone.[51]Quality Indicators and Data
Typical Acid Values for Fats and Oils
The acid value serves as a key benchmark for assessing the freshness and quality of fats and oils, with lower values indicating minimal hydrolysis and free fatty acid content in fresh or refined samples, while higher values signal degradation in used or crude forms. Typical ranges vary by source material, processing, and storage conditions, but standards from organizations like the American Oil Chemists' Society (AOCS), Codex Alimentarius, and USDA provide reference values for common substances.[52][53] The following table summarizes representative acid values for selected fats and oils, drawn from Codex standards, USDA regulations, and peer-reviewed analyses. Values are expressed in mg KOH/g and reflect standard testing at approximately 20°C unless otherwise noted; ranges account for fresh versus degraded states where applicable.[52][54][53]| Fat or Oil | Typical Acid Value (mg KOH/g) | Notes |
|---|---|---|
| Fresh coconut oil | 0.1–0.5 | Virgin or refined; higher in crude extracts up to 4.0 maximum per Codex standards.[52][54] |
| Olive oil (extra virgin) | 0.1–0.8 | Fresh; maximum 1.6 for compliance (equivalent to 0.8% oleic acid), with refined forms often below 0.3.[54][55] |
| Crude palm oil | 2–5 | Unrefined; reflects natural hydrolysis during extraction; good quality typically below 3.[54][56] |
| Refined palm oil | <0.1 | Processed to remove free acids; maximum 0.6 per Codex.[52] |
| Lard (fresh) | 0.2–1.0 | Rendered animal fat; maximum 1.0 per USDA standards for quality.[53] |
| Canola oil (refined) | 0.05–0.1 | Fresh refined; low values indicate good quality.[2] |
| Soybean oil (refined) | 0.3–0.6 | Fresh refined; typical for commercial products.[2] |
| Used frying oil | 5–20+ | Degraded from repeated heating; values exceed 2.0 indicate rancidity and unsuitability for reuse.[2] |
| Algal oil | 0.3–0.5 | Emerging source post-2020; low values in refined DHA-rich extracts for food applications (maximum 0.5 as of 2023).[57] |