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Metanil Yellow

Metanil Yellow, chemically sodium 3-[(4-anilinophenyl)diazenyl]benzenesulfonate (C18H14N3NaO3S), is a synthetic primarily employed as an acid-base indicator in , transitioning from red to yellow over a range of 1.2 to 2.3. It also functions as a in histological techniques, such as periodic acid-Schiff , to enhance in tissue sections. With number 587-98-4, the compound appears as a brownish-yellow soluble in , reflecting its group that imparts anionic properties suitable for dyeing and indication purposes. Despite these legitimate applications, Metanil Yellow is widely recognized for its illicit use as a non-permitted food colorant, particularly in adulterating spices like , pulses, and sweets in regions such as , where it mimics natural yellow hues but induces toxicity. Empirical studies demonstrate its genotoxic effects, including DNA damage and chromosomal aberrations, alongside promotion of , , and in neural tissues upon chronic exposure. Such health risks, potentially encompassing carcinogenicity and , underscore regulatory prohibitions on its food application, though enforcement challenges persist due to economic incentives for adulteration.

History and Discovery

Early Synthesis and Development

Metanil Yellow, a synthetic monoazo classified as Acid Yellow 36 (CAS 587-98-4), was first synthesized in 1879 by C. Rumpff via diazotization of metanilic acid (3-aminobenzenesulfonic acid) and subsequent coupling with , yielding the structure sodium 3-[(4-anilinophenyl)diazenyl]benzenesulfonate. This process exploited the emerging reaction, pioneered earlier in the 1860s, to produce vibrant colored compounds from aromatic amines. An independent synthesis was reported by Hepp in 1882, confirming the dye's reproducible preparation through the same diazotization-coupling route, which introduced the azo (-N=N-) linkage responsible for its chromophoric properties. The molecule's sulfonic acid group imparted water solubility, distinguishing it from less polar contemporaries and facilitating early aqueous applications. Initial evaluations highlighted its intense yellow hue in neutral to alkaline media, shifting to reddish tones in strong acid, which spurred laboratory testing as an acid-base indicator with a transition range around pH 1.2 to 2.3. This solubility and color stability in solution positioned it among the first azo dyes explored for analytical purposes beyond textile coloration.

Commercial Adoption

Metanil Yellow, synthesized in , experienced rapid commercial uptake in the late 19th and early 20th centuries as an affordable valued for its vibrant yellow hue and stability in various media. European dye manufacturers integrated it into textile production, where it colored and fabrics, as evidenced by its detection in historical garments from and Persian artifacts dated to this era. Its synthesis from coal-tar derivatives aligned with the broader industrial expansion of synthetic colorants following the aniline dye revolution, enabling cost-effective alternatives to natural pigments. By the 1880s and 1890s, the dye's application extended to inks and paper, supporting the growing demand for colored printing materials in , including broadside prints by artists like . The absence of toxicity regulations at the time permitted unrestricted , with production scaling in chemical plants focused on coal-tar intermediates like . This era's lax oversight contrasted with later scrutiny, allowing Metanil Yellow to become a staple in industrial dyeing processes before analytical standardization efforts emerged. In , Metanil Yellow gained traction as a by the early 1900s, with its red-to-yellow transition exploited in titrations and staining protocols, such as variants of Masson's trichrome for histological differentiation. Purity specifications for reagent-grade material, akin to those later formalized in pharmacopoeias, supported its reliability in laboratory settings across . Commercial variants proliferated without stringent controls, facilitating export to Asian markets by the early , where it supplemented local traditions in textiles.

Chemical Properties

Molecular Structure and Synthesis

Metanil Yellow is the sodium salt of 3-[(4-anilinophenyl)diazenyl]benzenesulfonate, characterized by an azo (-N=N-) linkage between a moiety ( at the position relative to the azo group) and a 4-(phenylamino). This configuration, typical of monoazo dyes, enables its yellow chromophoric properties through extended conjugation involving the azo bridge and aromatic rings. The molecular formula is C₁₈H₁₄N₃NaO₃S, with a molecular weight of 375.38 g/mol. The compound is synthesized industrially by diazotizing metanilic acid (3-aminobenzenesulfonic acid) with in acidic conditions, followed by coupling the resulting diazonium salt with (N-phenylaniline) in an alkaline medium to form the azo bond at the para position. Commercial products often contain about 70% pure , with the remainder consisting of inorganic salts and auxiliaries from the synthesis process. It exhibits in (approximately 25 g/L at 20°C) but is insoluble in most organic solvents, reflecting its ionic sulfonate group. Spectroscopically, it shows UV-Vis absorption maxima at 414-419 nm, with a specific (E 1%/1 cm) of at least 18,500, aiding in its identification and quantification.

Physical and Spectroscopic Characteristics


Metanil yellow appears as a yellow-orange to brownish-yellow powder, odorless and soluble in water at approximately 25 g/L. Its molecular weight is 375.38 g/mol, corresponding to the formula C₁₈H₁₄N₃NaO₃S, with a melting point exceeding 250 °C. As a pH indicator, it exhibits a color transition from red in acidic conditions (pH ≈1.2) to yellow in slightly less acidic to neutral media (pH ≈2.3), enabling its use in visual pH assessments. The compound demonstrates high stability to heat and light, characteristic of azo dyes, with only slow under prolonged UV or visible . This thermal and photostability supports its persistence in analytical and industrial contexts, though it undergoes azo bond reduction under specific reductive conditions. Spectroscopically, metanil yellow shows strong UV-Vis absorption maxima at 414–419 nm, with molar absorptivity ≥18,500 L·mol⁻¹·cm⁻¹, facilitating quantitative detection via at trace levels. Infrared spectroscopy reveals characteristic peaks for the azo (-N=N-) group around 1400–1500 cm⁻¹ and (-SO₃⁻) stretches near 1200–1300 cm⁻¹, aiding structural confirmation and in chemical protocols.

Legitimate Applications

Analytical Chemistry Uses

Metanil yellow functions as an acid-base indicator in analytical titrations, displaying a reversible color change from red in acidic conditions to yellow in slightly less acidic media over the pH range of 1.2 to 2.4. This property makes it suitable for detecting endpoints in titrations of strong acids against weak bases or in scenarios where the equivalence point falls within low pH values, such as the determination of acidity in certain inorganic or organic analyses. Indicator solutions are typically prepared as 0.1% w/v metanil yellow in methanol to ensure sensitivity and stability during use. In microscopic , metanil yellow is applied as a following periodic acid-Schiff () and iron-hematoxylin staining to augment contrast in tissue sections. The dilute aqueous solution of the dye selectively enhances the visibility of PAS-positive structures, such as or mucopolysaccharides, by providing yellow counterstaining against the purple nuclei and PAS regions, thereby improving overall detail resolution without interfering with primary stains. This technique has been documented in protocols for examining carbohydrate-rich tissues, where the counterstain's affinity for non-PAS elements aids in differentiating cellular components.

Industrial Dyeing and Staining

Metanil Yellow, also designated as Acid Yellow 36 (CI 13065), functions as an anionic with a strong affinity for protein fibers such as and , enabling effective dyeing under acidic conditions that promote bonding with amino groups in these materials. It similarly dyes polyamide fibers like , as well as , where it imparts a bright coloration with reasonable wash fastness suitable for industrial and processing. The dye's solubility in water facilitates uniform application on these substrates, though its performance is optimized for proteinaceous rather than cellulosic fibers, limiting broader versatility in natural plant-based . In paper production, Metanil Yellow is applied to color and finished sheets, providing a stable tint used in and specialty s, with its ease of contributing to efficient large-scale processes. Beyond fibers and paper, the serves as a in wash-fast inks for and marking applications, where its vibrant hue maintains integrity under mechanical stress. It is also incorporated into paints for surface coatings and select for pigmentation, leveraging its in non-aqueous formulations, though usage levels are constrained by limits in solvents. The adoption of Metanil Yellow in these industrial contexts stems from its cost-effectiveness relative to higher-purity alternatives, offering vivid yellow pigmentation at lower production expenses, which is particularly advantageous in developing markets prioritizing over premium fastness properties. This economic edge arises from straightforward and high , though it necessitates careful to mitigate potential in end-use products due to moderate light fastness ratings in prolonged exposure scenarios.

Toxicity and Biological Effects

Mechanisms of Toxicity

Metanil yellow exerts toxicity primarily through reductive metabolism in the gastrointestinal tract, where anaerobic gut bacteria employ azoreductase enzymes to cleave the azo (-N=N-) bond, yielding aromatic amine metabolites such as sulfanilic acid derivatives and aniline-like compounds. These amines are electrophilic and capable of forming covalent adducts with DNA nucleobases, particularly guanine, thereby inducing mutations, chromosomal aberrations, and genotoxic damage via interference with DNA replication and repair processes. Exposure further triggers by catalyzing the production of (ROS), including superoxide anions and hydroxyl radicals, which deplete endogenous antioxidants like and while promoting and protein carbonylation. This imbalance disrupts cellular redox signaling and mitochondrial integrity, amplifying ROS propagation and compromising energy metabolism across affected tissues. Neurotoxic pathways involve direct inhibition of (AChE), reducing hydrolysis and causing cholinergic overload, alongside mitochondrial-mediated triggered by ROS-induced release and activation, which culminate in independent of genotoxic routes.

from Studies

Studies in rats administered metanil yellow orally at doses of 50 to 200 mg/kg body weight demonstrated dose-dependent , characterized by reduced activity in liver homogenates and histopathological degenerative changes in hepatic tissue. Similar effects were observed at higher doses up to 430 mg/kg, with activation of detoxification enzymes alongside severe liver degeneration, indicating consistent reproducibility across experiments from the late onward. Body weight reductions were noted in conjunction with these hepatic impacts in chronic exposure models, though specific dose-response curves varied by duration. Genotoxicity assessments in assays revealed chromosomal aberrations and sister chromatid exchanges in following prolonged oral treatment with metanil yellow, often in combination with , at doses promoting clastogenic effects reproducible in models. These findings from studies align with later validations showing dose-related increases in micronuclei and aberrations, underscoring metanil yellow's potential to induce heritable genetic damage in hematopoietic tissues. More recent investigations from the and reported oxidative damage in and gut tissues of rats exposed to metanil yellow, with elevated markers in cerebellar and duodenal correlating to doses around 100 mg/kg over subchronic periods. in the cerebellar was evident alongside in Purkinje and granular layers, with effects intensifying over 30-day exposures. Gastrointestinal was slowed in a dose-dependent manner, reducing percent transit in exposed rats compared to controls, as measured by charcoal meal assays. In vitro and plant-based models, such as cepa root meristems, showed metanil yellow inducing chromosomal abnormalities and reduced , with effects escalating from 24-hour to 48-hour exposures at concentrations of 0.25 to 1.0% solutions, demonstrating time-dependent . Blends of metanil yellow with sunset yellow and (1:1:1 ratio) amplified serological alterations in rats, including elevated liver enzymes such as SGPT and at combined doses equivalent to individual colorant levels of approximately 50 mg/kg, exceeding effects of single dyes and indicating synergistic dose-response potentiation. These changes, including increased total , were reproducible across replicates and persisted post-exposure.

Regulatory Framework

Bans and Legal Status

Metanil Yellow is prohibited as a food colorant in the under regulations governing unauthorized additives, with the identifying it among illegal dyes due to potential health risks including carcinogenicity. It is similarly banned for food use in the United States, as it does not appear on the FDA's list of certified or exempt color additives for foods, drugs, or cosmetics, rendering uncertified synthetic dyes impermissible. In , the dye has been banned for food applications since the Prevention of Adulteration of 1954, enforced by the and Standards Authority, owing to its toxicity profile. Indonesia's of Drug and Control (BPOM) also prohibits its use in foodstuffs, classifying it as a hazardous textile dye unsuitable for consumption. Under the standards administered by the FAO and WHO, Metanil Yellow is treated as a non-permitted , absent from the General Standard for Food Additives with no established , reflecting consensus on its unsuitability for ingestion. Bans extend to in jurisdictions like , where it is explicitly disallowed in drugs and alongside . Permitted applications are confined to non-consumable industrial and analytical contexts, such as indication in laboratories, dyeing of textiles, , , and inks, where high-purity grades are required to minimize impurities. In textiles, while generally allowable for adult apparel, restrictions apply under frameworks like the EU's REACH Regulation Annex XVII, limiting azo dyes—including those like Metanil Yellow that may cleave to restricted aromatic amines such as above 30 —in products for infants and young children to prevent dermal exposure risks. These regulatory variances underscore enforcement challenges, with stricter prohibitions in developed economies contrasting persistent illicit deployment in unregulated markets despite global toxicity data.

Detection and Enforcement Challenges

Laboratory detection of metanil yellow residues in adulterated spices, such as , commonly employs (HPLC) coupled with UV-Vis detection, enabling quantification at parts-per-million () levels, including linearity from 5 to 10 . serves as a complementary preliminary screening method, identifying the dye's characteristic absorbance peaks in extracted samples from powder. For field applications, spot tests provide rapid qualitative assessment; for instance, mixing samples with (HCl) produces a distinct color change indicative of metanil yellow presence, facilitating on-site checks without sophisticated equipment. Enforcement faces significant obstacles due to metanil yellow's low production cost—often approximately half that of permitted food dyes—which drives its appeal for black-market adulteration in cost-sensitive supply chains. In regions like , where the dye remains prevalent despite regulatory prohibitions, informal markets and fragmented supply networks complicate comprehensive monitoring, as small-scale vendors evade routine inspections. Understaffed agencies exacerbate these issues, limiting the scale of surveillance and leading to persistent violations even in urban areas. Across , economic incentives prioritizing affordability over perpetuate adulteration, with metanil yellow detected in spices exported from ban-enforcing countries, underscoring gaps in cross-border and harmonized testing protocols. While advanced methods like HPLC offer high sensitivity, their reliance on centralized labs delays response times, allowing contaminated products to reach consumers before interventions. These challenges highlight the need for scalable, portable detection tools to bridge enforcement disparities in resource-constrained settings.

Misuse and Controversies

Adulteration in Food and Spices

Metanil yellow serves as an illegal in various and spice products across and parts of , primarily to artificially enhance yellow coloration in low-grade powder, sweets, and pigeon peas for deceptive visual appeal and . This non-permitted is blended into to mimic the natural hue of , enabling vendors to sell inferior or diluted products at higher prices. Empirical detection studies in markets have confirmed metanil yellow contamination in sourced from retailers, with concentrations up to 30% w/w identified via and . In sweets such as laddus and jalebis, systematic extraction procedures coupled with chemical assays reveal the dye's presence, often in street-vended . Similarly, quantifies metanil yellow adulteration in pigeon peas (toor ), where it imparts an unnatural vibrancy to substandard grains. Adulteration persists despite regulatory interventions by India's Food Safety and Standards Authority (FSSAI), which conducts raids on markets and vendors; one analysis reported metanil yellow in 16.4% of sampled spices and foods. Vendors evade detection by mixing it with permitted colors or using it in informal supply chains, particularly for street foods and unregulated sweets. Such practices remain rare in markets owing to rigorous controls and requirements that minimize opportunities for synthetic dye infiltration.

Public Health Impacts and Case Studies

Metanil yellow exposure through adulterated food products has been linked to neurotoxic effects, including alterations in neurotransmitter levels such as and serotonin in animal models, with chronic consumption in developing rats leading to irreversible changes in the , , and stem. In rats, serological analyses following blended dye exposure, including metanil yellow, revealed decreased total protein and levels alongside elevated alkaline phosphatase, SGPT, and total , indicative of hepatic stress and potential liver damage. studies in plant and animal cells demonstrate that metanil yellow reduces and induces chromosomal aberrations, raising concerns for mutagenic risks in humans via dietary intake. Public health risks are amplified in regions with prevalent food adulteration, such as , where metanil yellow is commonly added to , spices, and sweets to enhance yellow coloration despite its non-permitted status. A 2013 all-India survey of sweets and savories found adulteration with non-permitted colors, including metanil yellow, in up to 80.3% of samples from the East zone, correlating with widespread low-level chronic exposure among consumers, particularly children and low-income populations reliant on affordable street foods. Long-term ingestion is associated with gastric irritation, intestinal epithelial damage, and hyperactivity-like symptoms, though human epidemiological data remain limited to extrapolations from toxicological profiles rather than large-scale cohort studies. Notable cases include detections in turmeric samples across , where metanil yellow adulteration alongside other dyes like lead chromate has prompted health alerts for carcinogenic potential, with animal data supporting DNA damage and tumor promotion risks at dietary doses. In , , routine monitoring from 2017 onward identified metanil yellow in local sweets and spices, leading to regulatory seizures but no documented acute poisoning outbreaks; instead, impacts manifest as cumulative effects like potential neurobehavioral deficits in exposed populations. Enforcement challenges exacerbate these issues, as undetected residues contribute to ongoing burdens without isolated incident reports, underscoring the need for vigilant over acute event tracking.