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Oxime

An oxime is a class of compounds belonging to the imines, characterized by the C=NOH and the general formula RR′C=NOH, where R and R′ are side chains, atoms, or other substituents, with oximes derived from aldehydes termed aldoximes and those from ketones termed ketoximes. Oximes are typically synthesized through the of aldehydes or ketones with (NH₂OH) under mildly acidic or basic conditions, a process that involves to the followed by . This reaction is reversible and widely employed in laboratories for the identification and characterization of carbonyl compounds due to the distinct physical properties of oximes, such as their and melting points. Structurally, oximes exhibit E/Z geometric isomerism around the C=N bond, and they can tautomerize to forms under certain conditions, contributing to their reactivity. In , oximes play a crucial role as versatile intermediates and protecting groups for carbonyl functionalities, enabling selective transformations. Notable reactions include the , where oximes are converted to amides using acid catalysts or metal complexes, a process essential for producing ε-caprolactam, the monomer for nylon-6. They also undergo dehydration to nitriles and reduction to hydroxylamines, facilitating the construction of nitrogen-containing heterocycles and other complex molecules. Beyond synthesis, oximes find applications in ; for instance, compounds like act as antidotes for poisoning by reactivating inhibited through nucleophilic attack on the . Additionally, some oximes serve as inhibitors or in the formulation of artificial sweeteners.

Structure and Properties

Molecular Structure and Nomenclature

Oximes are compounds with the general molecular RR'C=NOH, where R and R' represent atoms or substituents. When R' is , the compounds are classified as aldoximes, typically derived from aldehydes, while cases where both R and R' are groups are known as ketoximes, derived from ketones. The defining of oximes is the C=N-OH unit, which constitutes an derivative in which the atom bears a hydroxyl substituent, resulting from the addition of to a carbonyl compound. In IUPAC , oximes are named by appending the term "oxime" to the name of the parent or , such as ethanal oxime for CH_3CH=NOH. This approach reflects their origin as derivatives of carbonyl compounds, with stereochemical descriptors like (E) or (Z) incorporated when specifying geometric isomers. The term "oxime" was coined in the 19th century as a portmanteau of "oxygen" and "imine," highlighting the compound's incorporation of an oxygen-containing imine-like structure.

Stereoisomerism

Oximes exhibit geometric isomerism arising from the restricted rotation around the C=N double bond, similar to that in alkenes, due to the sp² hybridization of both the carbon and nitrogen atoms. This leads to E and Z isomers, where the configuration is determined by the Cahn-Ingold-Prelog priority rules: the E isomer (often termed anti) has the higher-priority substituents on opposite sides of the double bond, while the Z isomer (often termed syn) has them on the same side. For aldoximes specifically (R-CH=NOH), the traditional syn/anti nomenclature is commonly used, with the syn isomer defined as the one where the hydroxyl (OH) group and the aldehydic hydrogen (H) are on the same side of the C=N bond, corresponding to the E configuration, and the anti isomer having them on opposite sides, corresponding to the Z configuration. The Z isomers of oximes are generally less stable than the E isomers owing to steric hindrance between the OH group and the R substituent on the carbon atom. This destabilization arises from the closer proximity of these bulky groups in the Z configuration, leading to higher energy conformations, as confirmed by thermodynamic calculations showing the E isomers as the global minima for various oxime structures. Thermal interconversion between E and Z isomers is rare under ambient conditions due to the high energy barrier of the C=N rotation. Instead, isomerization typically requires , such as acid-promoted mechanisms in aqueous media involving of the oxime to form an iminoxy cation that facilitates , or photochemical conditions using visible .

Physical and Spectroscopic Properties

Oximes are typically colorless crystalline solids or viscous liquids at , depending on the specific and substituents. For example, acetone oxime is a white crystalline solid ( 60–63 °C) with a of 134.8 °C, significantly higher than that of acetone (56 °C), owing to intermolecular hydrogen bonding facilitated by the hydroxyl group. Similarly, cyclohexanone oxime is a white crystalline solid with a of 88–91 °C and a of 204–206 °C, compared to cyclohexanone's of 155 °C, again attributable to enhanced hydrogen bonding interactions. Solubility profiles of oximes vary: solubility in water depends on the substituents, with simple oximes often soluble while those with larger hydrophobic groups exhibit lower solubility, but they generally dissolve more readily in polar organic solvents such as and . Solubility in water tends to decrease with increasing aliphatic length, as longer hydrophobic tails reduce overall , while solubility in non-polar organic solvents may increase accordingly. In () , oximes display characteristic absorption bands that aid in their identification. The O-H stretching vibration appears as a broad band between 3115 and 3600 cm⁻¹, reflecting hydrogen bonding. The C=N stretch is observed around 1640–1665 cm⁻¹, while the N-O stretch occurs in the 900–1000 cm⁻¹ region, typically at 930–990 cm⁻¹ for simple oximes. Nuclear magnetic resonance (NMR) provides further diagnostic features. In ¹H NMR, the hydroxyl proton of oximes resonates as a broad , often in the downfield region of 11–13 , due to its acidic character and hydrogen bonding; this signal can shift or broaden further with or concentration changes. In ¹³C NMR, the carbon of the C=N group typically appears at 150–160 , deshielded by the adjacent and oxygen atoms. Aliphatic oximes demonstrate notable hydrolytic stability under acidic conditions, with rate constants for approximately 10³ times lower than those for analogous hydrazones, making them more resistant to reversion to the parent carbonyl compounds. This enhanced stability arises from the structural reinforcement provided by the N-O bond, which slows the acid-catalyzed cleavage mechanism.

Preparation

Condensation with Hydroxylamine

The condensation of carbonyl compounds with represents the primary method for synthesizing oximes in both laboratory and industrial settings. This reaction involves the of hydroxylamine (NH₂OH) to the of an or , yielding the corresponding oxime after . The general equation for the process is: \mathrm{R_2C=O + NH_2OH \rightarrow R_2C=NOH + H_2O} where R can be hydrogen, alkyl, or aryl groups. This method was first reported in 1882 by German chemist Victor Meyer and his student Alois Janny, who synthesized the first oximes, including acetone oxime and methylglyoxime, by treating carbonyl derivatives with . Their work established the foundational approach for oxime preparation and highlighted the utility of as a reagent. The proceeds via a nucleophilic addition-elimination . acts as a , with its attacking the electrophilic carbonyl carbon to form a tetrahedral . This undergoes proton transfers, followed by to generate the C=N characteristic of the oxime. The process is reversible under certain conditions, but can be driven toward product formation by removing or using excess . Acid or base facilitates the steps, with the often requiring mild acidification to protonate the hydroxyl group for elimination. Typical reaction conditions involve neutral or mildly basic pH to deprotonate and enhance its nucleophilicity, often achieved using buffers such as . is commonly generated from its hydrochloride salt (NH₂OH·) by addition of a base like or , in solvents such as , , or . Reactions are generally carried out at to , with yields exceeding 80% for most substrates under optimized conditions. For example, aromatic aldehydes react efficiently in ethanolic at 60–80°C. Aldehydes exhibit higher reactivity than ketones due to reduced steric hindrance and greater electrophilicity at the carbonyl carbon, with rate differences up to 44-fold (e.g., versus 2-butanone). This selectivity allows sequential oximation in molecules containing both functional groups. Dialdehydes, such as or , can form bis-oximes under stoichiometric conditions, provided the geometry permits double addition without steric interference.

Alternative Synthetic Routes

Oximes can be synthesized through the partial , particularly primary alkanes, which are converted to the corresponding aldoximes using metal salts such as stannous chloride (SnCl₂) or chromous chloride (CrCl₂) in aqueous media. This method selectively stops at the oxime stage for aliphatic nitro compounds bearing an α-, avoiding over- to amines; for example, 1-nitropropane yields propionaldoxime in moderate yields under these conditions. Catalytic represents another reduction pathway, where compounds are treated with gas and a homogeneous catalyst like chlorotris()rhodium(I) to produce oximes directly, as demonstrated in early studies on both aromatic and aliphatic substrates. An alternative route involves the rearrangement of s with active methylene compounds, which generates oximes via nitroso tautomerism and subsequent . In this process, the acts as a nitrosating agent; for instance, the reaction of (CH₃CH₂ONO) with acetone (CH₃COCH₃) proceeds through rearrangement to yield acetone oxime ((CH₃)₂C=NOH) alongside other byproducts. This method is particularly useful for preparing ketoximes from simple ketones and is metal-free, though it requires careful control to minimize side reactions like O-alkylation. Recent advancements in the have introduced sustainable electrosynthetic routes, exemplified by anode-cathode cascade of hydroxyl compounds and ions. In one such approach, and are co-upgraded in a flow electrolyzer using a CoOOH/Ni foam and Cu-substituted Fe₃C , producing pyruvatoxime at a rate of 2.61 mmol cm⁻² h⁻¹ with 87 mM outlet concentration under ambient conditions (2.8 V cell voltage). This paired avoids hazardous intermediates like , leverages abundant feedstocks from , and demonstrates versatility for other oximes such as acetone oxime. A related method employs a Zn-Cu catalyst for reduction coupled with to form cyclohexanone oxime in a one-pot process under mild aqueous conditions. While these routes provide valuable alternatives to the conventional condensation of carbonyls with hydroxylamine, they are less frequently used owing to challenges in achieving high yields and regioselectivity, particularly for complex substrates.

Reactions

Hydrolysis and Reduction

Oximes undergo acid-catalyzed hydrolysis to regenerate the parent carbonyl compound and hydroxylamine, reversing the condensation reaction used in their preparation. This transformation typically employs dilute hydrochloric acid under heating conditions, with the reaction proceeding via protonation of the oxime oxygen, followed by nucleophilic attack of water on the resulting iminium-like intermediate. The general equation for this process is: \mathrm{R_2C=NOH + H_2O + H^+ \rightarrow R_2C=O + NH_2OH} Such hydrolytic cleavage is valuable for deprotecting carbonyl groups in synthetic sequences where oximes serve as temporary protecting groups. Reduction of oximes provides a direct route to primary amines by cleaving the N–O bond and hydrogenating the C=N double bond, yielding compounds of the form R₂CH–NH₂. Traditional methods include treatment with lithium aluminum hydride (LiAlH₄) in ether solvents at reflux, which delivers hydride to both the nitrogen-oxygen linkage and the carbon-nitrogen π-bond. Catalytic hydrogenation using palladium on carbon (Pd/C) under atmospheric or elevated hydrogen pressure, often in protic solvents like methanol or ethanol, achieves similar results with high efficiency and milder conditions. Another classical approach employs sodium amalgam (Na/Hg) in aqueous alcoholic media, facilitating electron transfer and protonation steps to form the amine product. These reductions are broadly applicable to both aldoximes and ketoximes, though yields may vary with steric hindrance around the C=N unit. The of oxime reductions is significantly influenced by the E/Z of the oxime, which can lead to diastereoselective or enantioselective formation of stereoisomers, particularly in catalytic hydrogenations using chiral catalysts. For example, E- and Z-oximes often produce opposite stereoisomers due to differences in substrate-catalyst interactions and the rigid of the oxime influencing the facial bias in or delivery. This selectivity enables access to enantioenriched amines when chiral catalysts are employed. In , oxime reduction serves as a key strategy for converting ketones or aldehydes to primary amines, bypassing limitations of direct such as instability or over-alkylation. For instance, this sequence has been utilized in the preparation of bioactive amines and derivatives, offering high and compatibility with sensitive functional groups.

Rearrangement Reactions

Oximes undergo several important rearrangement reactions, with the Beckmann and Neber rearrangements being the most prominent examples involving carbon-nitrogen bond migrations. These transformations highlight the versatility of oximes as synthetic intermediates in organic chemistry. The Beckmann rearrangement is an acid-catalyzed conversion of oximes to amides, where the group anti to the hydroxyl functionality on the oxime migrates to the nitrogen atom. This reaction typically employs strong acids such as sulfuric acid or phosphorus pentachloride as catalysts, proceeding through an O-protonated or O-acylated intermediate that facilitates the stereospecific migration. The stereospecificity ensures that the anti substituent becomes the N-acyl group in the resulting amide, as illustrated by the general transformation: \ce{R-(C=NOH)-R' ->[H2SO4 or PCl5] R-C(=O)-NH-R'} where R migrates if it is anti to the OH group. This rearrangement is widely utilized due to its efficiency in synthesizing amides from ketones via oxime precursors. In contrast, the Neber rearrangement involves base-catalyzed conversion of ketoximes to α-aminoketones, typically through activation of the oxime hydroxyl with tosyl chloride followed by treatment with or another base. The mechanism proceeds via formation of an O-tosylated oxime intermediate, which undergoes intramolecular cyclization to a 2H-azirine, followed by ring-opening to yield the α-aminoketone product. This stereospecific process is valuable for introducing amino functionality adjacent to carbonyl groups in complex molecules. Industrially, the holds significant importance, particularly in the production of ε-caprolactam from oxime, which serves as the precursor to nylon-6. This process involves treating the oxime with or fuming at elevated temperatures to achieve high yields of caprolactam on a large scale. Recent developments in the have focused on milder conditions for the Beckmann rearrangement by activating the oxime hydroxyl group with non-harsh catalysts, such as iron-based systems under mechanochemical conditions, enabling efficient transformations without strong acids. These advancements improve and applicability to sensitive substrates.

Other Transformations

Oximes undergo oxidation in the Ponzio reaction, where aldoximes are converted to compounds using oxidizing agents such as or . This transformation involves initial formation of a intermediate followed by tautomerization and oxidation, providing a direct route to primary compounds or gem-dinitroalkanes from aldehydes via their oxime derivatives; for example, acetaldoxime can yield using peroxytrifluoroacetic acid in moderate yields under controlled conditions. The reaction is particularly useful for preparing aliphatic and aromatic compounds, though it may require careful control to avoid over-oxidation. Recent advances in N-O of oximes have focused on and photocatalytic methods to generate iminyl radicals, enabling selective C-C formation. These approaches typically involve visible-light or single-electron transfer processes, where oximes are activated to cleave the N-O , producing amidyl or iminyl radicals that add to alkenes or participate in cyclizations. For instance, in 2021, a copper-catalyzed relay mechanism using oxime esters allowed iminyl generation and subsequent C-C coupling with boronic acids, achieving high in the of diverse amines. Similarly, photocatalytic systems employing or organic dyes have enabled remote C-C functionalization via 1,5-hydrogen atom transfer from iminyl radicals, as demonstrated in protocols for constructing quaternary carbons from cyclic oximes. These methods, developed between 2020 and 2025, highlight the versatility of oxime-derived radicals in avoiding traditional multi-step sequences for C-C assembly. Oximes serve as precursors to nitrile oxides, which act as 1,3-dipoles in reactions with to form . The nitrile oxide is generated by of the oxime using reagents like or , followed by [3+2] dipolar addition that proceeds with high , typically favoring the 5-substituted isomer. This transformation, rooted in Huisgen's foundational work on 1,3-dipolar , is widely employed for synthesizing bioactive heterocycles; for example, the reaction of benzaldoxime-derived benzonitrile oxide with styrene yields 3,5-diphenyl in excellent yield under mild conditions. The process benefits from the dipole's concerted mechanism, minimizing side reactions and enabling stereocontrol in chiral substrates. O-Alkylation of oximes produces oxime ethers, typically achieved by treating the oxime with alkyl halides or tosylates in the presence of a base like or , favoring O-selectivity due to the nucleophilic oxygen. This ether formation is a key step in synthesizing compounds for agricultural applications, where oxime ethers function as pesticides or intermediates in ; notable examples include alkyloxyimino derivatives used in fungicides exhibiting broad-spectrum activity against crop pathogens. Additionally, certain oxime ethers serve as stabilizers in formulations, preventing oxidative degradation by scavenging free radicals, as seen in their incorporation into rubber compounds to enhance thermal stability. These derivatives maintain the oxime's reactivity for further transformations while imparting beneficial for biological applications.

Applications

Industrial Applications

One of the primary industrial applications of oximes is in the production of ε-caprolactam, a key for nylon-6 . oxime undergoes the , typically catalyzed by strong acids such as fuming , to yield ε-caprolactam on a massive scale. This process is central to the global polyamide industry, with worldwide ε-caprolactam production exceeding 6.8 million metric tons annually as of 2023, driven largely by demand for textiles, engineering plastics, and films. The rearrangement involves migration of the anti-alkyl group to the nitrogen atom, forming the lactam ring essential for into nylon-6. Methyl ethyl ketoxime () finds widespread use as an anti-skinning additive in alkyd-based s and coatings. In these formulations, MEKO complexes with metal driers like or salts, inhibiting oxidative drying on the paint surface while allowing normal curing upon application. This prevents the formation of a surface during storage, extending for air-drying systems used in architectural and industrial coatings. MEKO's volatility ensures it evaporates during film formation, avoiding interference with the final paint properties. Perillartine, the oxime derivative of perillaldehyde, serves as a high-intensity artificial in and products. Synthesized via of perillaldehyde with , perillartine exhibits sweetness approximately 2,000 times that of , activating sweet taste receptors in a species-dependent manner. It is particularly employed in to enhance flavors in low-calorie beverages and to reduce irritation in smoke, providing a minty aftertaste without significant caloric contribution. Oximes also act as versatile intermediates in the of fragrance compounds for perfumes. For instance, certain oximes, such as 2-methyl-3-hexanone oxime, are transformed into carbamoyloxime derivatives or other odorants through reactions like oximation and reduction, contributing to woody, floral, or musky notes in commercial scents. These transformations leverage the oxime's nitrogen-oxygen functionality for selective functionalization, enabling the creation of stable, long-lasting aroma chemicals used in fine fragrances and .

Analytical and Extractive Uses

Oximes play a significant role in analytical chemistry, particularly in gravimetric methods for metal ion detection and quantification. Dimethylglyoxime (DMG), a common oxime derivative, is widely used to detect and determine nickel(II) ions by forming a bright red, insoluble chelate complex, nickel dimethylglyoximate (Ni(DMG)2), which precipitates quantitatively from ammoniacal solutions. This reaction allows for precise gravimetric analysis, where the precipitate is filtered, dried, and weighed to calculate nickel content with high accuracy, often achieving results within 0.1% error in standard laboratory conditions. In extractive applications, oximes facilitate the selective recovery of metals from aqueous solutions through solvent processes in . Commercial oxime-based reagents, such as the LIX series (e.g., LIX 84 and LIX 984), are employed to extract (II) ions from acidic leach solutions by forming stable, lipophilic complexes that partition into an , typically or similar diluents. These reagents enable high selectivity over iron and other impurities, with extraction efficiencies exceeding 95% in multi-stage counter-current operations, supporting large-scale purification in operations. Amidoximes, a subclass of oximes, have been immobilized on polymeric supports for the adsorption and extraction of as from , addressing the low concentration (approximately 3.3 ppb) challenge through via the amidoxime functional group. These adsorbents bind selectively amid competing ions like and calcium, with capacities reaching up to 1.5 g U/kg adsorbent after prolonged exposure. A 2017 advancement introduced amidoxime-functionalized carbon hybrid fibers integrated with half-wave rectified , achieving extraction nine times more efficiently than passive adsorption methods by enhancing and release, reducing processing time from weeks to hours. Recent developments in the have focused on bifunctional oxime reagents that incorporate additional coordinating groups to improve selectivity in metal recovery from complex matrices. For instance, novel oxime derivatives paired with β-diketones or isoxazolones enable synergistic solvent extraction of rare earth elements (e.g., ) with distribution coefficients over 103 under optimized pH conditions, facilitating sustainable recovery from leachates while minimizing co-extraction of base metals. These bifunctional systems enhance kinetic rates and stripping efficiencies, promoting greener hydrometallurgical processes.

Pharmaceutical and Biological Applications

Oximes play a critical role in , particularly as antidotes for (OP) poisoning. , also known as 2-PAM, is a prototypical oxime that reactivates (AChE) inhibited by OP compounds, such as nerve agents like or pesticides. By binding to the anionic site of the phosphorylated AChE, pralidoxime displaces the OP moiety, forming a hydrolyzable complex that restores the enzyme's and alleviates symptoms. This mechanism is most effective when administered early, ideally within 48 hours, before irreversible "aging" of the enzyme occurs. Developed in the 1950s through rational design to counter agents, was among the first oximes approved by the FDA for treating OP toxicity, often in combination with atropine. In plant biology, oximes serve as versatile signaling molecules derived from via enzymes, influencing growth regulation, pathogen defense, and ecological interactions. For instance, indole-3-acetaldoxime (IAOx) acts as a precursor in biosynthesis, modulating root and development, while phenylacetaldoxime contributes to defense pathways against herbivores and microbes by integrating with signaling. Oximes also facilitate attraction through volatile emissions, such as in floral scents where they enhance benzoxazinoid-derived compounds that deter antagonists while luring beneficial . The E-isomers of these oximes often exhibit higher bioactivity, owing to their stability and preferential recognition by enzymatic systems in stress responses.30384-2.pdf) Beyond and , oxime derivatives demonstrate diverse therapeutic potential, including anticancer, , and antiviral effects. In , compounds like indirubin-3'-oxime induce in cancer cells by inhibiting kinases such as CDK2 and GSK-3β, leading to arrest and caspase-3 activation, as observed in pancreatic and models with IC50 values in the low micromolar range. properties arise from suppression of and JNK pathways, reducing production (e.g., TNF-α, IL-6) in LPS-stimulated models, exemplified by 6-bromoindirubin-3'-oxime in fibroblasts. Antiviral activity is evident in derivatives like penta-1,4-diene-3-one oxime ethers, which inhibit replication, and indirubin oximes that delay A (H5N1) propagation by modulating proinflammatory responses. , an oxime ether antidepressant, inspires derivatives with enhanced and potential antiviral profiles through agonism. Efficacy of oximes in OP poisoning treatment varies significantly across species, complicating . For example, reactivates AChE more effectively in s and rabbits than in rats or mice, where rapid enzyme aging and differing limit reactivation rates. In dogs, obidoxime shows promise but induces hepatic toxicity absent in , attributed to variations in paraoxonase levels and AChE . These differences underscore the need for species-specific dosing and highlight challenges in extrapolating animal data to therapy.

History and Developments

Discovery and Early History

The discovery of oximes is attributed to , who in 1882 synthesized the first examples by reacting with aldehydes and ketones, such as the preparation of acetone oxime from acetone and hydrochloride. This reaction demonstrated the general formation of the >C=NOH , establishing oximes as a new class of organic nitrogen compounds and laying the groundwork for their structural elucidation. In the early , oximes gained recognition in for their utility in protecting carbonyl groups and as intermediates in structural determinations, while Meyer's earlier work also introduced a diagnostic test for primary nitroalkanes involving to form α-nitro oximes (nitrolic acids), which produce a characteristic red color upon treatment with . This test, developed in , highlighted oximes' role in for distinguishing nitro group types and contributed to broader applications in synthetic methodologies during the period. Following , the development of (OP) pesticides and nerve agents spurred research into oximes as therapeutic antidotes, with a significant medicinal push in the 1950s. (2-PAM), synthesized as an reactivator, was introduced in 1958 through studies demonstrating its efficacy in reversing OP-induced enzyme inhibition in human subjects. By the 1960s, five key oximes—, obidoxime, HI-6, TMB-4 (trimedoxime), and MMB-4 (methoxime)—had been synthesized and entered clinical and military use for treating OP poisoning, marking a pivotal milestone in their therapeutic application.

Recent Advances

In recent years, innovations in oxime have emphasized through electrochemical methods. A notable 2025 advancement involves an -cathode cascade electrolyzer that co-upgrades biomass-derived hydroxyl compounds, such as , with ions to produce oximes like pyruvatoxime. This process operates at 2.8 V with a of 0.5 mL cm⁻² min⁻¹, using a CoOOH/ foam and Cu substrate/Fe₃C , achieving a production rate of 2.61 mmol cm⁻² h⁻¹ and an outlet concentration of 87 mM, while maintaining stability over 72 hours. Unlike traditional routes that rely on explosive or unstable carbonyl intermediates, this method integrates oxidation and reduction in a single step, minimizing , hazardous byproducts, and , thereby enhancing for applications. Progress in asymmetric synthesis has enabled efficient production of chiral amines from oximes. A 2024 review highlights recent developments in catalytic of oximes and oxime ethers to chiral hydroxylamines, employing catalysts such as , , and under mild conditions, achieving up to 99% enantiomeric excess for various aryl and alkyl substrates. These approaches address the challenges of the labile N-O bond and inert C=N bond, providing hydroxylamines as versatile precursors for chiral amines used in pharmaceuticals like sabcomeline. The review also covers expansions to oxime ethers using and complexes, streamlining access to enantiopure building blocks. Radical chemistry leveraging oxime derivatives has emerged as a powerful for carbon-carbon bond formation in the . Oxime esters serve as bifunctional reagents in the radical difunctionalization of alkynes, where visible-light triggers C-centered addition followed by N-centered migration via N-O bond cleavage, enabling alkylamination with yields up to 85% for diverse terminal alkynes. This strategy facilitates the synthesis of functionalized enamines useful in . Complementing this, N-O bond cleavage of oximes generates iminyl radicals that participate in C-C couplings, such as the coupling of oxime ethers with boronic acids under copper , producing ketones with moderate to high efficiency (50-90% yields) while avoiding harsh oxidants. These methods underscore the versatility of oxime-derived radicals in constructing complex scaffolds. In therapeutic applications, oxime-based compounds have advanced nerve agent detoxification. A 2025 library of 100 click-chemistry-derived oximes identified potent reactivators for (BChE) inhibited by s like , , , and tabun. Notably, mono-pyridinium oxime 5B achieved a reactivation rate of 34,120 M⁻¹ min⁻¹ for cyclosarin-inhibited BChE, surpassing standards like 2-PAM (525-fold) and HI-6 (44-fold), with reactivation exceeding 90% in within 6 minutes. These oximes enhance binding affinity and maximal reactivation rates, enabling pseudo-catalytic bioscavenging for improved antidotal efficacy. Efforts toward environmental include greener variants of oxime transformations and less toxic derivatives. A 2025 catalytic using a Hg(II)-perimidine-2-thione complex promotes ketoxime conversion to amides and lactams under mild conditions (80°C in ), accommodating aryl, alkyl, and cyclic substrates with yields of 71-99%, such as 95% for oxime and 92% for oxime, while improving and reducing formation compared to conventional acid-mediated processes. Additionally, oxime ethers have been explored as biodegradable alternatives to parent aldehydes and ketones in fragrances, exhibiting reduced toxicity—for instance, oxime O-ethyl ether shows EC₅₀ values up to 154 mg/L in versus higher sensitivity for carbonyls—offering greater chemical stability and lower environmental persistence.

References

  1. [1]
    IUPAC - oximes (O04372)
    ### Extracted IUPAC Definition of Oximes
  2. [2]
    Metal-Involving Synthesis and Reactions of Oximes - ACS Publications
    In metal-free organic chemistry, the main types of high-yield reactions leading to oximes include the condensation of RR′C═O (R′ = alkyl, aryl, or H) with ...
  3. [3]
    Oxime: Definition, Structure, Formation, and Compounds
    Sep 8, 2025 · An oxime is a class of organic compounds characterized by the presence of the C=NOH functional group. The general formula is RR′C=NOH, where R ...
  4. [4]
    Oxime - an overview | ScienceDirect Topics
    1 Introduction. An oxime is a chemical compound belonging to the imines, with the general formula R1R2C double bond NOH where R1 is an organic side-chain ...
  5. [5]
    FDA-Approved Oximes and Their Significance in Medicinal Chemistry
    Oximes have gained wide popularity due to their potency to act as antidotes against nerve agents. This is achieved by their ability to reactivate the enzyme— ...Missing: definition | Show results with:definition
  6. [6]
    Oximes - BYJU'S
    Oximes are the chemical compounds that belong to the class of imines, having the general formula of R1R2C=N O H. ... Where R1 is the organic side-chain whereas R2 ...
  7. [7]
    oxime (CHEBI:25750) - EMBL-EBI
    Compounds of structure R 2 C=NOH derived from condensation of aldehydes or ketones with hydroxylamine. Oximes from aldehydes may be called aldoximes; ...
  8. [8]
    Illustrated Glossary of Organic Chemistry - Oxime; aldoxime; ketoxime
    Oxime: A functional group consisting of a hydroxyl group bonded to the nitrogen atom of an imine, or a molecule containing this functional group.
  9. [9]
    Rule C-842 Oximes and Their Derivatives - ACD/Labs
    Compounds RHC=N-OH or , termed generic ally "oximes", are named (a) by placing the word "oxime" after the name of the aldehyde RCHO or the ketone , ...Missing: definition | Show results with:definition
  10. [10]
    OXIME definition in American English - Collins Dictionary
    Definition of 'oxime'. COBUILD frequency band. oxime in American English ... Word origin. C19: from ox(ygen) + im(id)e. Quick word challenge. Quiz Review.
  11. [11]
    [PDF] Geometrical Isomerism in Alkenes and Oximes | Dalal Institute
    If they are on the same side, the system is 'Z'; and if they are on the opposite side, the compound should be labeled as 'E' isomer. Buy the complete book ...
  12. [12]
    The role of water on the acid-promoted E/Z isomerization of oximes ...
    May 30, 2006 · Our calculations suggest that E/Z isomerization in water occurs through the formation of a protonated oxime–water adduct that involves the creation of a C( ...
  13. [13]
    Acetone, oxime | C3H7NO | CID 67180 - PubChem
    Acetone, oxime | C3H7NO | CID 67180 - structure, chemical names, physical and chemical properties, classification, patents, literature, ...
  14. [14]
    Oximes: Structure, Formula, Preparation & Uses in Chemistry
    Rating 4.2 (373,000) An oxime refers to an organic compound formed by the reaction of an aldehyde or a ketone with hydroxylamine, featuring the functional group C=N–OH.
  15. [15]
    II. THE INFRARED SPECTRA OF SOME COMPLEX OXIMES
    Simple oxinle spectra exhibit an OH band at 3115-3300 cn-I, a C=N band at about. 1640 cm-', and an N-0 band at 930-990 cm-l (2-4). Similarly, various ...
  16. [16]
    Arylamines (Anilines), Azines, and Oximes - ScienceDirect
    In the vapor phase vN–O for both aliphatic and aromatic oximes are reported to occur in the range 910–980 cm-1, and in the liquid or solid phase for a larger ...
  17. [17]
    A simple and straightforward method for determination of oxime ...
    Additionally, the 1H NMR spectrum revealed a signal at δ 11.15–11.20 ppm and another signal at δ 11.45–11.59 ppm that confirmed the presence of the hydroxyl ...
  18. [18]
    13C chemical shifts - Steffen's Chemistry Pages
    C chemical shifts ; >C=NOH (oximes), 155 to 165 ; -C(=O)OR (esters), 155 to 175 ; -CO-NHR (amides), 160 to 170 ; -COOH (carbon acid), 160.
  19. [19]
    Hydrolytic Stability of Hydrazones and Oximes - PMC - NIH
    Rate constants for oxime hydrolysis were nearly 103-fold lower than those for simple hydrazones; a trialkylhydrazonium ion (formed after condensation) was even ...
  20. [20]
    Oximes and Hydrazones in Bioconjugation: Mechanism and Catalysis
    As expected, the hydrolysis and transimination of hydrazones and oximes are significantly faster under acidic conditions and at elevated temperature.
  21. [21]
    Ueber stickstoffhaltige Acetonderivate - Meyer - 1882
    Berichte der deutschen chemischen Gesellschaft. Mittheilungen. Ueber ... Kukushkin, Metal-Involving Synthesis and Reactions of Oximes, Chemical Reviews, 10.1021/ ...
  22. [22]
    https://doi.org/10.1021/ja01544a017
  23. [23]
    A rapid, convenient, solventless green approach for the synthesis of ...
    Classically, oximes are prepared [2] by refluxing an alcoholic solution of a carbonyl compound with hydroxylamine hydrochloride and pyridine. The method has ...
  24. [24]
    https://doi.org/10.1002/anie.200602877
  25. [25]
    [PDF] Notes on Preparation and important reactions of nitro compounds ...
    (1) Partial reduction of dinitro compound is accomplished by catalytic hydrogenation using Pd on carbon and cyclohexene or triethylammonium formate. Other ...
  26. [26]
    Oxime and oximate metal complexes: unconventional synthesis and ...
    2.1.​​ The reduction of an aliphatic nitro compound containing an α-hydrogen, RR′CHNO2, may be stopped at the oxime, RR′CNOH, stage. Numerous methods for this ...
  27. [27]
    Homogeneous catalyzed reduction of nitro compounds. I. Synthesis ...
    Homogeneous catalyzed reduction of nitro compounds. I. Synthesis of oximes | The Journal of Organic Chemistry.
  28. [28]
    [PDF] Oximes - Thieme Connect
    Electrophilic Nitrosation of Active Methylene Compounds ... The rearrangement of alkyl nitrites is an alternative method for the preparation of oxime.
  29. [29]
    Hydroxyl and nitrate co-upgrading to oxime via anode-cathode ...
    Jul 3, 2025 · We report an economical and sustainable electrosynthesis route to oximes using hydroxyl compounds and nitrate in an anode-cathode cascade electrolyzer.
  30. [30]
    Sustainable Electrosynthesis of Cyclohexanone Oxime through ...
    Feb 15, 2024 · We report an electrochemical method for the one-pot synthesis of cyclohexanone oxime under ambient conditions with aqueous nitrate as the nitrogen source.
  31. [31]
    The mechanism of the formation and hydrolysis of cyclohexanone ...
    Buffer catalysis was observed at pH 4 and pH 6 on the hydrolysis of 13, which would be expected for a rate-limiting attack of water on the oxyiminium (II) (see ...
  32. [32]
    Reduction of oximes, oxime ethers, and oxime esters with diborane ...
    Reactivity of oximes for diverse methodologies and synthetic applications. ... The efficient solvent-free reduction of oximes to amines with NaBH3CN catalyzed by ...
  33. [33]
    Amine synthesis by oxime reduction - Organic Chemistry Portal
    Reduction of oximes and oxime ethers​​ The combination of lipase/palladium catalysis reduces prochiral ketoximes to optically active acetylated amines in the ...
  34. [34]
    Catalytic Reduction of Oximes to Hydroxylamines - NIH
    Dec 22, 2021 · Conventional oxime (ether) syntheses involve ketone condensation with hydroxylamine (or an O‐substituted analogue) (5→7), or the tautomerization ...
  35. [35]
    [PDF] Reactivity of oximes for diverse methodologies and synthetic ...
    Their reactivity towards photocatalysis and transition metals makes them ideal starting materials for N-containing heterocycles, amino alcohols, and amines.
  36. [36]
    Beckmann Rearrangement - Chemistry Steps
    The Beckmann rearrangement is a reaction in which a ketone is first converted to an oxime which, under acidic or Lewis acidic conditions, rearranges into an
  37. [37]
    Beckmann Reaction - an overview | ScienceDirect Topics
    The Beckmann reaction is defined as a chemical rearrangement that converts an oxime into a lactam, typically exhibiting regiospecificity and configurational ...<|separator|>
  38. [38]
    Beckmann Rearrangement - Master Organic Chemistry
    The Beckmann rearrangement is a reaction of oximes that can result in either amides or nitriles, depending on the starting material.
  39. [39]
    Neber Rearrangement - an overview | ScienceDirect Topics
    The Neber reaction probably occurs either through an internal concerted nucleophilic displacement at nitrogen and the leaving of a sulfonate moiety.
  40. [40]
    Beckmann Rearrangement with Improved Atom Economy ...
    Oct 5, 2022 · The industrial synthesis of caprolactam involves acid-catalyzed rearrangement of cyclohexanone oxime to caprolactamium hydrogen sulfate ...
  41. [41]
    On the Mechanism of the Beckmann Rearrangement, A Molecular ...
    The Beckmann rearrangement is one of the most important industrial reactions for ε-caprolactam production. A theoretical study focusing on the mechanism of ...
  42. [42]
    The Mechanochemical Beckmann Rearrangement: An Eco-efficient ...
    Jan 27, 2021 · A simple, iron-based catalytic system allows for facile Beckmann rearrangement of various oximes. The mild conditions avoid the use of harsh or ...Introduction · Results and Discussion · Conclusion · References
  43. [43]
    Beckmann rearrangement of ketoximes for accessing amides and ...
    Jul 11, 2025 · ... Beckmann rearrangement. Different types of substrates were successfully converted into corresponding amides under mild reaction conditions.
  44. [44]
    Improved Preparation of 3‐Oximinooxetane – An Important ...
    Jan 27, 2022 · Direct oxidation of oximes with peroxy acids such as peroxytrifluoroacetic acid allows conversion into the corresponding mononitro compounds 2.
  45. [45]
    Recent Advances in N-O Bond Cleavage of Oximes and ... - MDPI
    In this paper, the recent advances in the NO bond cleavage of oximes and hydroxylamines are reviewed. We hope that this review provides a new perspective on ...
  46. [46]
    Recent Advances in Molecule Synthesis Involving C-C Bond ... - NIH
    Mar 15, 2023 · Herein, we summarized the radical reactions involving oxime N–O bond and C–C bond cleavage through this special reaction form, including those ...
  47. [47]
    1,3-Dipolar cycloaddition reactions of carbohydrate derived nitrones ...
    Oct 17, 2002 · This review aims to summarise key features of the synthesis and 1,3-dipolar cycloaddition reactions of carbohydrate derived nitrones and oximes ...
  48. [48]
    Electrochemical Synthesis of Isoxazoles and Isoxazolines via ...
    Oct 31, 2023 · Conversion to the desired isoxazol(in)es requires initial oxidation to their respective nitrile oxides and subsequent 1,3-dipolar cycloaddition ...
  49. [49]
    Oxime ethers as versatile precursors in organic synthesis: a review
    This review is a survey of the literature describing synthetic applications of oxime ethers. The cyclization and metal-catalyzed cross-coupling reactions of ...
  50. [50]
    Highly efficient catalytic production of oximes from ketones using in ...
    May 5, 2022 · Cyclohexanone oxime is a key precursor in the production of caprolactam, a commodity chemical used in the synthesis of the polyamide nylon-6.
  51. [51]
    Caprolactam Market Size, Share Analysis and Industry Forecast
    May 7, 2025 · The caprolactam market was over 6800 thousand tons in 2023 and is estimated to grow at a CAGR of 4.8% from 2024 to 2034.
  52. [52]
    [PDF] The Beckmann rearrangement of cyclohexanone oxime to (epsilon)
    Jan 1, 2011 · In industry the Beckmann rearrangement reaction is applied by the conversion of molten cyclohexanone oxime into ε-caprolactam. A commonly used ...
  53. [53]
    New insights on the anti-skinning effect of methyl ethyl ketoxime in ...
    New insights on the anti-skinning effect of methyl ethyl ketoxime in alkyd paints. S. Tanase, J. Hierso, E. Bouwman, J. Reedijk, J. ter Borg, J. H. Bieleman and ...
  54. [54]
    MEKO-Free Anti-Skinning Agents | Borchers: A Milliken Brand
    Methyl Ethyl ketoxime (MEKO) anti-skinning agents are commonly used to prevent alkyd coating surfaces from forming a film called skin, particularly when ...
  55. [55]
    Perillartine (CAS 30950-27-7) - Foreverest Resources Ltd
    Perillartine is the oxime of perillaldehyde, extracted from Perilla plants, and a semisynthetic sweetener, about 2000 times sweeter than sucrose.
  56. [56]
    Perillartine - PMC - NIH
    To this solution was added perillaldehyde (4.50 g, 0.03 mol). The mixture was kept at 318 K for 2 h. The solution was cooled and the solid that formed was ...Missing: synthesis | Show results with:synthesis
  57. [57]
    US20030069167A1 - Oxime as perfuming ingredient - Google Patents
    The present invention relates to the use as a perfuming ingredient of 2-methyl-3-hexanone-oxime of formula in which the wavy line represents a bond having a ...
  58. [58]
    An oxime as perfuming ingredient - EP 1291409 B1
    Jan 3, 2007 · In said document, EP 79537, the oxime of the invention is mentioned as a chemical intermediate in the synthesis of some derivatives of the ...
  59. [59]
    [PDF] The Gravimetric Determination of Nickel | Truman ChemLab
    Jun 2, 2014 · Nickel(II) forms a precipitate with the organic compound dimethylglyoxime, C4H6(NOH)2. The formation of the red chelate occurs quantitatively in ...
  60. [60]
    Gravimetric Estimation of Nickel (Theory) - Amrita Virtual Lab
    The Gravimetric Estimation of Nickel:​​ The nickel is precipitated as nickel dimethyl glyoxime by adding alcoholic solution of dimethyl glyoxime C4H6(NOH)2 and ...
  61. [61]
    Commercial chelating solvent extraction reagents. III. Oximes
    Structures of the proprietary aliphatic and aromatic oxime extractants, marketed by General Mills, Inc., under the name LIX reagents, have been investigated ...
  62. [62]
    Hydrometallurgy - BASF
    At the core of BASF's hydrometallurgical offer is an extensive range of LIX® oxime extractants that are widely used in the purification of copper and nickel ...
  63. [63]
    New Sustainable Solvent Extraction Pathways for Rare Earth Metals ...
    This research investigation presents the synthesis and complexation ability of two oxime molecules used as synergistic agents during liquid–liquid extraction of ...
  64. [64]
    Pralidoxime - StatPearls - NCBI Bookshelf - NIH
    These drugs were collectively developed in the 1950s with a vision to develop an antidote that could reverse the inhibition of acetylcholinesterase enzyme ...
  65. [65]
    Pralidoxime Is No Longer Fit for Purpose as an Antidote to ...
    Feb 22, 2024 · Pralidoxime is the only oxime antidote to organophosphate poisoning stocked in the United Kingdom, produced by rational drug design in the 1950s.
  66. [66]
    Oximes: Unrecognized Chameleons in General and Specialized ...
    Jan 8, 2018 · The German chemist Victor Meyer who, together with Alois Janny, reported the first chemically synthesized oxime. Unfortunately no picture of ...Missing: Viktor | Show results with:Viktor
  67. [67]
    Oximes: Novel Therapeutics with Anticancer and Anti-Inflammatory ...
    A large number of oximes have been reported with useful pharmaceutical properties, including compounds with antibacterial, anticancer, anti-arthritis, and anti ...
  68. [68]
    Synthesis and bioactivity evaluation of penta-1,4-diene-3-one oxime ...
    Bioactivity evaluations showed that most target compounds had significant antiviral effects against tobacco mosaic virus (TMV).
  69. [69]
    The Role of Oximes in the Management of Organophosphorus ...
    Aug 23, 2012 · Oximes being considered particularly effective in nerve agent poisoning. Moreover, remarkable species differences in the susceptibility to oximes were revealed.
  70. [70]
    Reactivation kinetics of acetylcholinesterase from different species ...
    In the past decades numerous oximes were prepared and tested for their efficacy in OP poisoning, mostly in animal experiments. However, data indicate that the ...
  71. [71]
    [PDF] Victor Meyer (1848-1897) Chemist - FUPRESS
    Sep 15, 2025 · An important oxime synthe- sized by Meyer and Janny in 1882 was dimethylglyoxi- me, introduced into Analytical Chemistry (nickel detec- tion) ...Missing: Gesellschaft | Show results with:Gesellschaft
  72. [72]
    Nitronic - an overview | ScienceDirect Topics
    4.3 Nitrosation of nitroalkanes. Victor Meyer in 1873 showed that primary nitroalkanes undergo ready nitrosation to give α-nitro oximes (nitrolic acids), Eq.
  73. [73]
    Organophosphorus compounds and oximes: a critical review - PMC
    Jun 6, 2020 · Treatment of OP poisoning with atropine and an oxime is the general procedure since the implementation of 2-PAM in the 1950s and obidoxime in ...
  74. [74]
    Rhodium‐Catalyzed Asymmetric Hydrogenation and Transfer ...
    Feb 17, 2024 · Existing reports for the synthesis of hydroxylamines predominantly center on the catalytic asymmetric hydrogenation of oximes, the oxidative ...
  75. [75]
    Recent advances on catalytic asymmetric hydrogenation of oximes ...
    Feb 17, 2024 · This review describes the recent progress in the development of catalytic asymmetric hydrogenation of oximes and oxime ethers.
  76. [76]
    Oxime ester as bifunctional reagent for the alkylamination of alkynes ...
    Aug 26, 2025 · Herein, we report an unprecedented radical difunctionalization of alkynes employing oxime esters as bifunctional reagents through a novel C- ...Missing: 2020s | Show results with:2020s
  77. [77]
    Recent Advances in N-O Bond Cleavage of Oximes and ... - NIH
    Feb 13, 2023 · In this paper, the recent advances in the NO bond cleavage of oximes and hydroxylamines are reviewed. We hope that this review provides a new perspective on ...Missing: 2020s | Show results with:2020s
  78. [78]
    Recent Advances in Molecule Synthesis Involving C-C Bond ... - MDPI
    Mar 15, 2023 · Herein, we summarized the radical reactions involving oxime N–O bond and C–C bond cleavage through this special reaction form, including those ...Missing: 2020s | Show results with:2020s
  79. [79]
    Click-chemistry-derived oxime library reveals efficient reactivators of ...
    A library of 100 click-chemistry-derived oximes was evaluated as reactivators of butyrylcholinesterase (BChE) inhibited by the nerve agents (NAs) sarin, ...
  80. [80]
    Beckmann rearrangement of ketoximes for accessing amides ... - NIH
    Jul 11, 2025 · A newly synthesized Hg(ii)–perimidine-2-thione complex catalyzes the Beckmann rearrangement across a broad range of oximes, enabling high-yield access to ...Missing: 2020s | Show results with:2020s
  81. [81]
    Aquatic toxicity comparison between selected flavour and fragrance ...
    Apr 22, 2025 · This study provides the first systematic ecotoxicological evaluation of oxime ethers, a class of compounds with potential applications as safer fragrance ...