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Ammonium thioglycolate

Ammonium thioglycolate, also known as perm salt, is the ammonium salt of with the HSCH₂CO₂NH₄ or C₂H₇NO₂S, and a molecular weight of 109.15 g/mol. It appears as a clear, colorless to faint pink liquid, typically supplied as a 60-70% , with a of approximately 1.2 g/cm³, a around 115°C, and a around -15°C. This compound serves primarily as a in , where it breaks disulfide bonds in hair to enable reshaping for permanent waves, straightening, or curling treatments, and is also used in depilatory creams to dissolve hair proteins. In applications, ammonium thioglycolate functions by reducing the cysteine residues in hair's structural proteins, allowing the hair to be reformed into new shapes when set with a neutralizer; formulations are typically adjusted to 9.0-9.8 for effective action, making it a key ingredient in professional perming and products. Beyond , it has limited industrial uses, such as in wool shrink-proofing treatments due to its protein-altering properties. Safety concerns with ammonium thioglycolate are significant, as it is classified as toxic if swallowed, harmful in contact, and a strong that can cause , , burns, or allergic reactions, particularly on sensitive scalps. It is corrosive to metals and emits highly toxic fumes when heated above 120°C or exposed to acids, necessitating careful handling under fume hoods with protective equipment. Regulatory bodies recommend patch testing and professional application to minimize risks like hair breakage or chemical burns.

Chemical Identity

Formula and Structure

Ammonium thioglycolate is with the \ce{HSCH2CO2NH4} or equivalently \ce{C2H7NO2S}. This exists as an ionic salt, consisting of the thioglycolate anion (\ce{HSCH2COO-}) and the ammonium cation (\ce{NH4+}). The thioglycolate anion features a two-carbon chain derived from , where a group (-\ce{SH}) is attached to the alpha carbon adjacent to the group, conferring specific reactivity due to the nucleophilic atom. The of ammonium thioglycolate is 109.15 g/mol. It is derived from the parent compound (\ce{HSCH2COOH}) through of the group followed by salt formation with . This structural relationship highlights its classification as the ammonium salt of a weak and weak .

Nomenclature and Identifiers

Ammonium thioglycolate is systematically named ammonium 2-sulfanylacetate according to IUPAC nomenclature. Common synonyms for the compound include ammonium mercaptoacetate and perm salt. The (CAS) Registry Number assigned to ammonium thioglycolate is 5421-46-5. Additional unique identifiers encompass the Compound ID (CID) 21534, the European Community () number 226-540-9, and the Simplified Molecular Input Line Entry System (SMILES) notation [NH4+].[O-]C(=O)CS. Ammonium thioglycolate serves as the ammonium salt of , the parent compound bearing the systematic name 2-sulfanylacetic .

Physical and Chemical Properties

Appearance and Solubility

Ammonium thioglycolate is most commonly utilized in the form of an aqueous solution at concentrations of 60-80%, presenting as a colorless to pale yellow liquid. In its pure state, the compound manifests as a white crystalline solid. The material emits a strong, unpleasant sulfurous odor attributable to its functional group. The profile of ammonium thioglycolate is dominated by its high affinity for polar solvents; it is miscible with in all proportions, facilitating its widespread use in aqueous formulations. It exhibits slight in alcohols, while remaining insoluble in non-polar solvents such as hydrocarbons. Commercial solutions of ammonium thioglycolate decompose prior to boiling and lack a distinct , remaining at ambient temperatures. The of a typical 60% measures approximately 1.2 g/cm³ at 20°C.

Reactivity and Stability

Ammonium thioglycolate functions as a primarily through its group, which facilitates the cleavage of bonds in proteins such as . The mechanism involves a nucleophilic attack by the deprotonated thiolate ion (RS⁻) on the bond (R'-S-S-R'), leading to the formation of a mixed intermediate and subsequent release of a (R'-SH), ultimately converting the original to two groups (2 R'-SH). This - exchange reaction is central to its role in altering protein structures. In aqueous solutions, ammonium thioglycolate exists in with and , as represented by the reaction: \text{HSCH}_2\text{COOH} + \text{NH}_3 \rightleftharpoons \text{HSCH}_2\text{COO}^- + \text{NH}_4^+ This allows for the presence of free , which contributes to its reducing activity, while the component helps maintain an alkaline . The compound exhibits good stability under neutral to alkaline conditions but is sensitive to acidic environments, where it decomposes to release (H₂S), a toxic gas. It is also prone to gradual oxidation by atmospheric oxygen over time, forming species and diminishing its reducing potency. To mitigate oxidation, formulations often include stabilizers. Its reactivity is highly pH-dependent, with optimal performance in the range of 9-10, where the group is predominantly deprotonated to the more nucleophilic thiolate form (RS⁻), enhancing the rate of bond cleavage. At lower values, reduces the concentration of the active species, slowing the reaction significantly.

Synthesis and Production

Laboratory Preparation

Ammonium thioglycolate is prepared in laboratory settings through the neutralization of with , a straightforward acid-base that forms the corresponding . This method is widely used for small-scale in research environments due to its simplicity and the availability of starting materials. The proceeds as follows: \ce{HSCH2CO2H + NH3 -> HSCH2CO2NH4} , typically supplied as an 80% , is combined with 30% to achieve the desired product concentration. In a representative for preparing a % ammonium thioglycolate , 63.29 ml of 80% is mixed with 31.20 ml of 30% aqueous , followed by dilution to 100 ml with . The molar ratio of to is maintained near 1:1, often slightly in excess of (1:1.01 to 1:1.2) to ensure complete neutralization. The reaction is exothermic and is conducted at temperatures ranging from 25°C to 100°C, with often sufficient for lab-scale reactions; higher temperatures (–80°C) may be used for faster completion, but excess heat should be avoided to prevent of the product. The is monitored and adjusted to 6.5–9.0, ideally 7.5–8.5, during the process. To minimize oxidation of the sensitive group, the reaction is preferably carried out under an inert atmosphere, such as . Reaction times are typically 0.5–3 hours. For purification, especially when starting from contaminated with impurities like isopropyl thioglycolate esters, the mixture can undergo stripping at 10–50 mmHg and 25–40°C to remove volatile byproducts such as , followed by if necessary. The final product is a clear with high purity, suitable for applications.

Industrial Methods

Ammonium thioglycolate is produced commercially through the neutralization of with in large-scale reactors. , the key precursor, is synthesized by reacting with in an aqueous medium, followed by acidification to yield the acid form. This step is typically conducted under controlled conditions to minimize byproducts like , often through precise management during the reaction. The neutralization process involves adding anhydrous or to in continuous or batch reactors, forming a 60-80% of ammonium thioglycolate. Reactions occur at temperatures between 25°C and 100°C, with optimal ranges of 60-80°C to ensure complete conversion while controlling volatility and odor. Pressure may be applied in closed systems to handle the and maintain solution integrity, particularly in continuous flow setups that enhance efficiency for high-volume output. Purification follows to achieve cosmetic-grade standards, often exceeding 99% purity. is pretreated via or organic extraction to remove impurities such as isopropyl esters, which contribute to ; the subsequent solution may undergo or additional if needed for low- variants. Major producers include Bruno Bock and Evans Chemetics, which supply high-purity aqueous solutions tailored for cosmetic applications.

Applications

In Hair Care Products

Ammonium thioglycolate serves as a primary in products designed for permanent waving, commonly known as , and chemical straighteners or relaxers. In perm formulations, it is present in lotions at concentrations up to 18%, enabling the reshaping of structure. In hair relaxers, concentrations up to 18% are employed to achieve straightening effects on curly or wavy . In the perming process, ammonium thioglycolate is applied to that has been wrapped around rods or curlers, where it functions by cleaving bonds in the hair's proteins, converting cystine residues to two units and allowing the hair to take on a new curled configuration. This reduction step is followed by rinsing to remove excess agent, after which a neutralizing solution of (H₂O₂) is applied to reoxidize the sulfhydryl groups, reforming the bonds in the desired curled shape for a lasting effect. For hair relaxers, ammonium thioglycolate alters the permanent bonds in curly to produce a straightened . In formulations, it is often combined with to adjust the pH to an alkaline range of 9.0-9.6, which enhances penetration into the shaft and facilitates the process. However, repeated applications can progressively weaken the 's structural integrity by causing cumulative protein loss. Ammonium thioglycolate is effective across various types, including straight, wavy, and curly, as it targets the universal linkages in . Nonetheless, its efficacy diminishes on damaged or previously chemically treated , where existing bond disruptions reduce the agent's ability to achieve uniform reshaping.

Other Industrial Uses

Ammonium thioglycolate serves as a chemical intermediate in the of various derivatives and , leveraging its functionality to facilitate reactions such as thiol-ene additions and bond cleavage for surface modifications. For instance, it is employed in the preparation of amphiphilic hyperbranched by reducing bonds on protein surfaces to enable conjugation with polymer chains. Additionally, it contributes to the of -functionalized materials, including cellulose-rhodamine B methacrylamide derivatives for advanced applications. In , ammonium thioglycolate is utilized to functionalize materials for chelating , exploiting the affinity of its group for ions such as mercury, lead, and . A notable application involves treating eggshell membranes with ammonium thioglycolate to introduce groups, enhancing capacities—for example, increasing adsorption of Pb(II) by 12.4-fold and Cd(II) by 12.7-fold compared to untreated membranes—making it suitable for purification column packing. It also forms the basis for task-specific ionic liquids that extract (II) and (II) from aqueous solutions with high distribution ratios, up to 950 and 1200 respectively, while allowing recycling over multiple cycles. As a , ammonium thioglycolate acts as a in and biochemistry, particularly for cleaving bonds in proteins to enable modifications or denaturation studies. This property is applied in protocols, where it catalyzes thiol-click reactions on biological surfaces without damaging protein integrity when used appropriately. Ammonium thioglycolate is incorporated into depilatory products for industrial and veterinary applications, where it dissolves structures at concentrations up to 5% to facilitate processes. In niche areas, it functions as an additive in rubber formulations for dip molding, serving as a mercaptocarboxylic acid salt to stabilize compositions. Furthermore, it is used as a stabilizer in solutions for color materials, often in combination with chelating agents to enhance performance. It is also applied in wool shrink-proofing treatments due to its ability to alter protein structures.

Health, Safety, and Regulations

Toxicity and Hazards

Ammonium thioglycolate exhibits slight acute oral toxicity, with an LD50 greater than 1 g/kg body weight in rats when tested as a 17.5% solution. It is practically nontoxic via acute dermal exposure, with an LD50 of 7.9 mL/kg in rabbits for a 10.98% solution. The compound acts as a moderate irritant, producing primary irritation indices of 2.30 to 2.45 in rabbits at 17.5% concentration under occlusive or semi-occlusive conditions, and can cause in sensitized individuals, particularly hairdressers exposed occupationally. It is also a moderate ocular irritant at concentrations of 17.5%, causing transient conjunctival redness. Exposure via skin or inhalation poses additional risks, as the compound decomposes to release toxic (H₂S) fumes when heated or acidified, resulting in symptoms such as , , burning sensations, and papular rashes. Inhalation of vapors may cause irritation, while direct contact leads to burning and potential blistering. Chronic exposure may sensitize individuals, acting as a mild sensitizer in guinea pig models at 5% to 30% concentrations, though human repeated insult patch tests at 1.25% showed no . Studies indicate it is not mutagenic in the across multiple typhimurium strains and lacks carcinogenic potential based on available animal data. Safe handling requires use in well-ventilated areas or fume hoods to minimize vapor exposure; includes gloves (minimum 0.11 mm thickness), safety goggles, and protective clothing, with respiratory protection (type ABEK filter) if aerosols form. For , flush skin or eyes with water for at least 15 minutes and remove contaminated clothing; in case of , move to ; for , rinse mouth with water, do not induce , and seek immediate medical attention. In cosmetics, the Cosmetic Ingredient Review (CIR) Expert Panel has deemed ammonium thioglycolate safe for use in hair care products at concentrations up to 15.2% (expressed as thioglycolic acid), provided products are formulated to be non-irritating and non-sensitizing.

Environmental and Regulatory Considerations

Ammonium thioglycolate is readily biodegradable under aerobic conditions, with thioglycolic acid (its parent compound) achieving 86-87% degradation in the OECD 301F manometric respirometry test and 38-50% in the OECD 301D closed bottle test, indicating rapid breakdown by microorganisms in oxygenated environments. However, its degradation can release sulfide ions, which may contribute to oxygen depletion in aquatic systems by promoting anaerobic conditions and potentially forming hydrogen sulfide under low-oxygen scenarios. Due to its high water solubility and ionic nature, ammonium thioglycolate exhibits low bioaccumulation potential, with negligible uptake in organisms as evidenced by its negative log Kow value (-2.85, estimated) and lack of reported bioconcentration factors exceeding regulatory thresholds. Under the EU Cosmetics Regulation (EC) No 1223/2009, ammonium thioglycolate, as a of , is restricted to a maximum concentration of 11% (calculated as thioglycolic acid) in professional-use hair waving or straightening products at 7-9.5, with 8% for general-use hair products and 5% for depilatories at 7-12.7; products must include warnings such as "Avoid contact with eyes" and be labeled for professional use only. As of 2025, these limits remain unchanged. In the United States, the FDA considers ammonium thioglycolate safe for use in , including hair straighteners and , when formulated to be non-irritating, with mandatory ingredient labeling under 21 CFR 701.3 to ensure consumer awareness of potential hazards. Globally, it is classified as hazardous under the Globally Harmonized System (GHS), specifically as a irritant (Category 2) due to its potential to cause reversible damage, alongside warnings for and allergic reactions. Waste management practices for ammonium thioglycolate emphasize neutralization of effluents prior to disposal to mitigate risks from (H₂S) release, typically achieved by treatment with oxidants such as to convert thiols to less reactive disulfides. In hair salons, where wastewater containing ammonium thioglycolate contributes to elevated organic loads and potential , effluents are monitored for physicochemical parameters like , , and to assess environmental discharge impacts, with pretreatment such as or chemical oxidation recommended before release into municipal systems.

History and Cultural Impact

Development and Commercialization

Ammonium thioglycolate was first described in 1915. Its base compound, (also known as mercaptoacetic acid), emerged from studies on thiol-containing carboxylic acids dating back to the late , with initial syntheses reported as early as 1862 through reactions involving derivatives. Early research in the early focused on its reducing properties, laying the groundwork for applications in chemical processing, though commercial interest in developed later. A key milestone occurred in the late 1930s with the invention of the perm, pioneered by F. Willatt in 1938, who utilized ammonium thioglycolate solutions to achieve curls without heat or machinery. This innovation advanced earlier heatless methods, such as the 1931 bisulfite-based system by Ralph L. Evans and Everett G. McDonough, revolutionizing permanent waving by breaking disulfide bonds in more gently than prior heat-based methods. By the , ammonium thioglycolate had become the preferred in perms, supplanting harsher solutions from the 1930s that required high heat and often caused scalp irritation; this shift enabled safer, more precise salon-based cold perms operable at with a pH of 8-9.5. Commercialization accelerated post-World War II amid surging demand for home and professional styling, as perms gained popularity in the and for their convenience and versatility in achieving defined curls on various types. Production scaled up in the through major chemical firms such as Evans Chemetics and Bruno Bock, which specialized in high-purity solutions for cosmetic use, supporting the ingredient's integration into widespread waving lotions containing 5-10% ammonium thioglycolate. In the late , concerns over allergies led to developments in alternative reducing agents, reducing reliance on ammonium thioglycolate in some formulations. Further advancements in purity came in the 1990s with patented methods for removing impurities like isopropyl thioglycolate esters from precursors, enhancing safety and efficacy in formulations (US Patent 5,319,136). This evolution marked a transition to more controlled, user-friendly products, solidifying ammonium thioglycolate's role in the cosmetics industry.

References in Popular Culture

Ammonium thioglycolate gained notable visibility in through its mention in the 2001 film , directed by . In a pivotal scene, protagonist , played by , demonstrates her expertise in cosmetic science by cross-examining witness Chutney Windham on the rules of maintenance. Elle states, "Isn't the first cardinal rule of maintenance that you're forbidden to wet your hair for at least 24 hours after getting a at the risk of deactivating the ammonium thioglycolate?" This line underscores the chemical's role in hair ing and highlights Elle's intelligence, turning a seemingly trivial fact into a key that exposes inconsistencies in Chutney's testimony. The compound has come to symbolize the bold hair trends of the and in retrospectives, where perms featuring ammonium thioglycolate were iconic for creating voluminous, curly styles popularized by celebrities and everyday . outlets have referenced these trends in discussions of revivals, noting how the chemical's use in "" processes contributed to the era's distinctive looks, often evoking or cautionary tales of over-styling. In educational contexts within , ammonium thioglycolate appears in accessible chemistry explanations linking laboratory concepts to consumer products, particularly how it breaks bonds in to enable reshaping. Chemistry-focused blogs use it as an example to illustrate reactions in everyday applications, making complex relatable for non-experts.