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Pyrazolone

Pyrazolone refers to a class of five-membered heterocyclic compounds characterized by a ring bearing a at the 5-position, typically existing in tautomeric forms such as 2-pyrazolin-5-one or 3-pyrazolin-5-one, and serving as a key in and . These compounds were first synthesized in 1883 by Ludwig Knorr as antipyrine (), marking the beginning of their recognition for pharmacological potential, particularly as analgesics and antipyretics. Over the decades, pyrazolones have demonstrated a broad spectrum of biological activities, including , , antitumor, , and central nervous system-modulating effects, making them valuable scaffolds for . Notable derivatives include the FDA-approved , used as a free radical scavenger for (ALS) and treatment; aminophenazone (amidopyrine), an early withdrawn by the FDA in the 1970s due to agranulocytosis risks; and (dipyrone), a potent approved in some countries but withdrawn from the US market for similar safety concerns. Beyond pharmaceuticals, pyrazolones find applications as chelating agents in metal extraction, dyes (e.g., azo-pyrazolone pigments like ), and α-glucosidase inhibitors for antidiabetic therapy, with ongoing research exploring their potential in kinase inhibition and agents.

Structure and Properties

Molecular Structure

Pyrazolone refers to a class of heterocyclic compounds characterized by a five-membered containing two adjacent nitrogen atoms at positions 1 and 2, a at position 5, and a between carbons 3 and 4, systematically named as 1H-pyrazol-5(4H)-one. The core structure can be represented as: \begin{array}{c} \chemfig{**5(-NH-N=CH-C(=O)-CH=)} \end{array} This arrangement imparts aromatic-like stability due to the conjugated system involving the nitrogens and the enone moiety. Pyrazolones exist in isomeric forms, notably 3-pyrazolone (1H-pyrazol-3(2H)-one) and 5-pyrazolone (1H-pyrazol-5(4H)-one), which differ in the position of the carbonyl group relative to the nitrogens. The 5-pyrazolone isomer predominates due to greater thermodynamic stability, as evidenced by spectroscopic studies showing preferential adoption of this form in both solid and solution states. Tautomerism in pyrazolones primarily involves lactam-lactim (-) , where the form features the carbonyl at and an NH group at , while the (lactim) form has a hydroxyl at and a shifted to =C2. Additional imine-enamine tautomerism can occur, involving proton shifts between and C4. In non-polar solvents like CDCl₃, the form (e.g., 5PYR1 in 3-methyl-5-pyrazolone) is favored with relative energy of 0.00 kcal/mol, whereas in polar solvents like DMSO, the hydroxy form (5PYR3) predominates due to hydrogen bonding stabilization, with favoring the by up to 75% in protic media. Substituent effects significantly influence stability; N-alkylation or N-arylation at locks the form by preventing NH involvement, thereby stabilizing the . For instance, in 1-phenyl-3-methylpyrazol-5-one, the at enhances the CH-form () stability through electronic delocalization, with UV absorption at 248 nm and 323 nm in non-polar solvents, while the OH-form prevails in at 244 nm. Pyrazolones exhibit photochromism through reversible tautomer interconversion under UV irradiation, resulting in color changes from colorless to . This process involves excited-state proton transfer (ESPT), where UV light (e.g., 365 nm) promotes the enol-to-keto shift via double proton transfer along hydrogen bonds, generating new absorption bands at 370–490 nm; thermal relaxation or visible light reverses the process. In derivatives like 4-acyl pyrazolones, the mechanism proceeds through an intermediate , with pseudo-first-order confirming the ESPT pathway.

Physical Properties

Pyrazolones and their simple derivatives, such as 1-phenyl-3-methyl-5-pyrazolone, are typically white to yellow crystalline solids at . These compounds exhibit that depend on substituents, with 1-phenyl-3-methyl-5-pyrazolone melting at 126–128 °C; increasing molecular weight from bulkier substituents generally elevates the ./110110-SDS-EN.pdf) Boiling points are high due to the polar nature of the ring, as seen with 1-phenyl-3-methyl-5-pyrazolone at approximately 287 °C under reduced . Pyrazolones show poor solubility in water, with values around 3 g/L at 20 °C for 1-phenyl-3-methyl-5-pyrazolone, but they dissolve well in organic solvents like , acetone, and alkaline solutions. Their weak acidity is reflected in values around 7, as in the derivative (3-methyl-1-phenyl-2-pyrazolin-5-one). Infrared spectra of pyrazolones feature a characteristic C=O stretching absorption at approximately 1650–1680 cm⁻¹ due to the conjugated carbonyl. reveals absorption maxima in the 250–300 nm range, arising from π–π* transitions in the heterocyclic ring. Proton NMR spectra display signals for ring-associated protons (including attached aromatics) in the 6–8 region. The density of pyrazolone solids typically ranges from 1.1 to 1.4 g/cm³, exemplified by 1-phenyl-3-methyl-5-pyrazolone at 1.12 g/cm³. Tautomerism between and forms can subtly affect these bulk properties.

Chemical Properties

Pyrazolones display amphoteric character, functioning as both weak acids and weak bases due to the presence of the N-H group and lone pairs in their five-membered ring structure. The form imparts acidity with values around 7-8 (e.g., 7.0), while the N-H proton has ~13-14, comparable to that of itself. The basicity is weaker, characterized by pKb values around 10-12 for the lone pair, corresponding to a of approximately 2-4 for the protonated conjugate acid; occurs preferentially at the N1 or N2 positions depending on substituents. In terms of reactivity, the carbon at position 4 serves as the primary site for owing to its elevated , facilitating reactions such as condensations with aldehydes. The atoms at positions 1 and 2 are nucleophilic centers amenable to , while the carbonyl oxygen at position 5 undergoes , akin to other β-dicarbonyl compounds. Pyrazolones exhibit notable behavior, with the C4-H bond susceptible to oxidation, often forming stable radicals that can dimerize or couple further under oxidative conditions. of the exocyclic to a secondary alcohol is achievable using mild agents like in protic solvents, though the ring nitrogens remain largely inert to . Thermal stability of pyrazolones extends up to about 200°C, allowing in standard laboratory conditions, but they undergo in strong acidic or basic media, cleaving the ring to and β-keto acid derivatives. The keto- tautomerism, favoring the keto form in nonpolar solvents but shifting toward in polar protic environments, modulates this reactivity by altering distribution. In coordination chemistry, pyrazolones function as bidentate ligands, binding metals via the pyrrole-like and the carbonyl oxygen, which enhances their utility in forming chelate complexes with transition metals.

Synthesis

Classical Synthesis

The classical synthesis of pyrazolones is primarily associated with the Knorr pyrazolone synthesis, first reported by Ludwig Knorr in 1883 through the condensation of with to yield 1-phenyl-3-methyl-5-pyrazolone, commonly known as antipyrine. This reaction proceeds via an initial nucleophilic attack by the terminal of on the carbonyl of , forming a intermediate, followed by intramolecular cyclization involving the adjacent attacking the ester carbonyl, and subsequent dehydration to afford the pyrazolone ring. The process typically requires refluxing the reactants in for several hours under anhydrous conditions to minimize hydrolysis of the β-ketoester and achieve yields of 70-90%. In its general form, the Knorr synthesis involves the reaction of a hydrazine derivative (R-NHNH₂) with a β-ketoester (R'-CO-CH₂-COOR'') or β-diketone, leading to the formation of 5-pyrazolones substituted at the 1-position with R and at the 3-position with R'. The equation for the prototypical reaction is: \ce{R-NHNH2 + R'-CO-CH2-COOR'' ->[EtOH, reflux] 1-R-3-R'-5-pyrazolone + R''OH + H2O} This method establishes the foundational route for pyrazolone preparation, with the cyclization step favoring the 5-hydroxy tautomer that predominates in the product. Variations of the Knorr synthesis extend to other β-ketoesters or β-diketones, allowing for 3- or 4-substituted pyrazolones by altering the substituents on the 1,3-dicarbonyl precursor; for instance, using ethyl benzoylacetate instead of yields 1-phenyl-3-phenyl-5-pyrazolone. However, the method has limitations, including the necessity for conditions to prevent side reactions such as , and the potential formation of regioisomeric side products when unsymmetrical 1,3-dicarbonyl compounds are employed, due to competing nucleophilic attacks on the two carbonyl groups.

Alternative Methods

Multicomponent reactions offer efficient one-pot strategies for pyrazolone synthesis, surpassing traditional stepwise approaches. These reactions typically involve hydrazines, β-ketoesters, and , proceeding via initial formation, followed by cyclization and , often under irradiation to enhance reaction rates and yields exceeding 80%. For instance, the solvent-free -assisted of substituted hydrazines, β-ketoesters, and aromatic at 420 W for 10 minutes affords 4-arylmethylidene-substituted pyrazol-5-ones in 51–98% yields, demonstrating broad substrate scope with electron-withdrawing and donating groups on the . Alternative routes from pyrazoles involve oxidation or N-oxidation steps followed by rearrangement to access pyrazolones, providing access to functionalized derivatives not easily obtained via direct cyclization. Treatment of 4,5-dihydro-5-methylene-1H-pyrazoles with m-chloroperbenzoic acid (mCPBA) in at oxidizes the exocyclic , yielding 2-pyrazol-5-ones through formation and subsequent ring opening in 70–85% yields. This method is particularly useful for aroyl-substituted substrates, where the rearrangement proceeds regioselectively to favor the 5-one . Metal-catalyzed methods, particularly palladium- and copper-mediated N-arylation, facilitate the construction of N-aryl pyrazolones under mild conditions, often employing solvents to minimize environmental impact. -catalyzed Buchwald-Hartwig of pyrazolone precursors with aryl bromides or iodides, using ligands like in water or () at 80–100°C, achieves N-arylation in 75–92% yields, with enabling catalyst recycling over multiple runs. Similarly, copper(I)-catalyzed N-arylation with pyrazolyl-nicotinic acid ligands in water tolerates a wide range of heteroaryl halides, delivering N-aryl pyrazolones in 80–98% yields while avoiding toxic organic solvents. Enantioselective synthesis of pyrazolones employs chiral organocatalysts to control at key centers, enabling access to biologically active single enantiomers. Proline-derived squaramide catalysts promote asymmetric additions of pyrazol-5-ones to α,β-unsaturated aldehydes, followed by hemiketalization, furnishing spirocyclic pyrazolone derivatives with up to 99% enantiomeric excess (ee) and 85–95% yields under mild conditions at . These methods highlight the role of bifunctional in activating both nucleophilic and electrophilic partners for high stereocontrol. Post-2000 advances emphasize sustainable protocols, including solvent-free and ultrasonic-assisted condensations that drastically reduce reaction times from hours to minutes while improving . Ultrasound irradiation of derivatives with β-keto esters under solvent-free conditions at 40–60 kHz generates substituted pyrazol-5-ones in 85–98% yields within 10–20 minutes, leveraging effects for enhanced mixing and activation without heat. More recent developments include flow chemistry approaches for continuous , offering and benefits for pyrazolone production.

History

Discovery

The discovery of pyrazolone derivatives occurred in 1883 through the work of German chemist Ludwig Knorr, who was investigating synthetic analogs of for potential pharmaceutical applications. While attempting to condense with —a recently developed by his mentor —Knorr unexpectedly obtained a novel compound that he later named antipyrine (1-phenyl-2,3-dimethyl-5-pyrazolone). This serendipitous reaction marked the first synthesis of a pyrazolone, highlighting the versatility of derivatives in forming heterocyclic rings. Knorr's initial characterization revealed antipyrine as a new five-membered heterocycle exhibiting potent properties, capable of reducing fever in humans more effectively than natural remedies like . He reported these findings in a seminal paper published in Berichte der deutschen chemischen Gesellschaft, where he described the product's isolation, structure, and , establishing pyrazolones as a promising class for . This publication not only documented the compound's but also introduced the foundational now known as the Knorr pyrazole synthesis. The nomenclature "pyrazolone" was coined by Knorr shortly thereafter, deriving from ""—the parent heterocycle he simultaneously named—and the suffix "-one" to denote the functionality at the 5-position. Early studies encountered confusion regarding the tautomeric isomers of pyrazolone (3-pyrazolone versus 5-pyrazolone) and their relation to variants, which was resolved through structural elucidations in the via spectroscopic and derivatization methods. This discovery unfolded amid a surge in -based following Fischer's 1875 synthesis of and Theodor Curtius's 1887 isolation of itself, fueling rapid advancements in exploration.

Key Developments

Following the discovery of pyrazolones in the early 1880s, emerged as the first commercially successful synthetic and , marking a pivotal advancement in pharmaceutical production. Synthesized by Ludwig Knorr in 1883, it was rapidly commercialized in and achieved widespread adoption across by the , where it was prescribed for fever reduction and pain relief, supplanting natural remedies like in many clinical settings. In the 1920s, the development of dipyrone (metamizole) by represented a significant evolution in pyrazolone-based analgesics, introducing a more potent non-opioid option for moderate to severe pain and fever. First synthesized in 1920 and entering mass production in 1922 under the brand name Novalgin, it gained global popularity and reached peak sales in the 1970s, with annual production in the kilotons range, before regulatory restrictions arose due to reports of . During the mid-20th century, pyrazolones saw expanded application in the dye industry, particularly through azo compounds valued for their vibrant colors and stability. Tartrazine, a prominent pyrazolone discovered in 1884 by Johann Heinrich Ziegler, was initially used in textiles and later foods, spurring interest in pyrazolone-based pigments for industrial and consumer products through the . From the 1990s onward, pyrazolone derivatives shifted toward targeted therapeutic applications, exemplified by the approval of in 2001 by Japan's Ministry of Health, Labour and Welfare for treating acute ischemic by mitigating oxidative stress-induced neuronal damage. was subsequently approved for (ALS) in Japan and in 2015, by the U.S. FDA in 2017, and an oral formulation was approved by the FDA in 2022. This was followed by the U.S. FDA's 2008 approval of , a pyrazolone agonist, for immune , enabling platelet count elevation in patients unresponsive to other treatments and highlighting pyrazolones' potential in precision medicine. Amid rising antimicrobial resistance in the 2000s, research into pyrazolone derivatives surged, focusing on novel scaffolds with broad-spectrum activity against drug-resistant bacteria such as MRSA and multidrug-resistant strains, driven by the need for alternatives to failing antibiotics.

Applications

Pharmaceuticals

Pyrazolone derivatives have been utilized in pharmaceuticals primarily as analgesics and antipyretics, with antipyrine (phenazone) representing one of the earliest examples introduced in 1883 for pain and fever relief. Antipyrine exerts its effects mainly in the central nervous system by increasing the pain threshold through inhibition of cyclooxygenase enzymes (COX-1, COX-2, and COX-3), thereby reducing prostaglandin synthesis. Another prominent derivative, dipyrone (metamizole), provides potent analgesia and antipyresis via a multifaceted mechanism involving central inhibition of cyclooxygenase-3 and peripheral activation of the L-arginine/nitric oxide pathway, as well as modulation of the TRPA1 channel to alleviate acute nociception. Dipyrone is employed for moderate to severe pain and fever, particularly in postoperative and colic-related conditions. In , stands out as a pyrazolone-based free radical scavenger that mitigates by neutralizing peroxyl radicals, thereby slowing motor function decline in (ALS) and reducing neurological deficits in acute ischemic . The U.S. approved intravenous in 2017 for ALS treatment in adults, marking the first new therapy for the disease in over two decades; an oral suspension formulation was approved in May 2022. It had been used earlier in since 2001 for . Beyond these, serves as a non-peptide for managing immune (ITP) and by binding to and activating the c-Mpl receptor on megakaryocytes and platelets, thereby stimulating platelet production without cross-reacting with endogenous thrombopoietin. This oral agent has transformed treatment for chronic ITP by increasing platelet counts in patients unresponsive to other therapies. Emerging research highlights pyrazolone derivatives' potential in and applications, with several scaffolds demonstrating activity against resistant pathogens and tumor cells through inhibition. For instance, certain pyrazolone hybrids exhibit antibacterial effects by targeting , disrupting bacterial in Gram-positive and Gram-negative strains. In , pyrazolone-based compounds have shown against various lines, including breast and lung cancers, often via tubulin polymerization interference or induction, positioning them as candidates for novel targeted therapies. Dosage and administration of pyrazolone pharmaceuticals vary by agent and indication, with historical patterns favoring broader use in the early compared to current, more restricted applications due to safety monitoring. For dipyrone, the standard oral regimen for adults is 500–1000 mg every 6–8 hours, not exceeding 4 g daily, typically for short-term of acute or fever; intravenous forms are reserved for severe cases. While dipyrone was widely prescribed globally since its introduction for everyday analgesia, contemporary usage emphasizes judicious application in regions where it remains available, often as a non- alternative amid opioid crisis concerns.

Dyes and Pigments

Pyrazolones serve as important coupling components in the synthesis of azo dyes, particularly for producing yellow to orange hues in commercial colorants. In the diazotization process, pyrazolone derivatives act as nucleophilic partners, undergoing at the position with diazonium salts derived from aromatic amines. For instance, 1-phenyl-3-methyl-5-pyrazolone readily couples with various diazonium compounds to form vibrant azo dyes suitable for and other applications. A prominent example is (FD&C Yellow 5 or C.I. Acid Yellow 23), a monoazo pyrazolone synthesized by coupling diazotized (4-aminobenzenesulfonic acid) with 1-(4-sulfophenyl)-3-carboxy-5-pyrazolone. This is widely employed in food colorings, beverages, and textiles due to its bright lemon-yellow shade and stability. Tartrazine is produced on a multi-ton scale annually, reflecting its commercial significance in the global dye industry. These pyrazolone-based azo dyes exhibit high tinctorial strength, allowing intense coloration at low concentrations, along with good resistance to acids, making them suitable for wool and from acidic baths. Their visible typically occurs in the 420-450 nm range, corresponding to the region of the ; for specifically, the maximum wavelength is approximately 427 nm in . Industrial production of pyrazolone azo dyes occurs on a multi-ton scale, often involving intermediates analogous to J-acid for enhanced and efficiency. Early patents from the 1920s, such as those describing pyrazolone for dyes, laid the foundation for these processes, with companies like contributing to scale-up efforts. Variants include metal-complexed pyrazolone dyes, where the azo chromophore coordinates with transition metals like or , improving and wash resistance for demanding applications. These complexes maintain the characteristic tones while enhancing durability in industrial settings.

Ligands

Pyrazolones act as effective chelating ligands in coordination chemistry, primarily due to their and oxygen donor atoms that facilitate stable binding with transition metals. These ligands typically coordinate in bidentate N,O modes through the pyrazole ring and the exocyclic carbonyl oxygen, though tridentate coordination can occur with appropriate substituents on the pyrazolone ring. Such is particularly common with transition metals including copper(II), zinc(II), and iron(III). The synthesis of pyrazolone metal complexes often involves direct coordination of the neutral to metal salts in solvents like or , or proceeds via derivatives such as 4-acylpyrazolones, which are prepared by of 3-methyl-1-phenylpyrazol-5-one with acyl chlorides under basic conditions followed by acidification. Deprotonated 4-acylpyrazolonate anions then form stable complexes, such as [M(Q)_2(H_2O)_2] where M is a divalent metal and Q is the anion. Representative examples include pyrazolone-Schiff base ligands, formed by condensation of 4-aminoantipyrine with aldehydes, which coordinate to (IV) in bis(β-ketoamino) complexes for olefin polymerization catalysis; these systems, activated by methylaluminoxane, produce linear polyethylenes and ethylene-norbornene copolymers with activities up to several kg·mol^{-1}·h^{-1}. Additionally, complexes of antipyrine (a simple pyrazolone) with silver(I) exhibit enhanced antimicrobial activity against bacteria like and , with minimum inhibitory concentrations as low as 0.02 mg/100 mL for certain derivatives. The stability of these complexes is notable, with log K values for Cu(II) typically ranging from 5 to 10, reflecting strong influenced by the ligand's electronic properties. Spectroscopic characterization confirms coordination, including d-d transitions in the visible region (around 600-700 nm) for Cu(II) complexes, indicative of octahedral or square-planar geometries. In research applications, pyrazolone complexes serve as analytical reagents for metal ion detection, such as fluorescent probes for Al(III) and Fe(III). Since the , they have been incorporated into metal-organic frameworks (MOFs), for instance Zn(II)-pyrazolonate structures with porous channels suitable for gas storage, including selective adsorption of CO_2 and H_2.

Safety and Toxicology

Human Health Effects

Pyrazolones demonstrate moderate acute toxicity in humans, primarily through oral exposure, with reported oral LD50 values for representative compounds such as 3-methyl-1-phenyl-5-pyrazolone ranging from approximately 1.9 g/kg in models, suggesting a similar threshold in humans. Characteristic symptoms of acute intoxication include gastrointestinal distress such as and vomiting, hypotension associated with , and manifesting as impaired consciousness, convulsions, and progression to . In severe cases, and sudden may occur, necessitating immediate supportive care including and monitoring for . Chronic exposure to pyrazolone derivatives, particularly through pharmaceutical use like (dipyrone), poses significant risks including , a potentially fatal reduction in white blood cells. The incidence of metamizole-induced varies across studies but is estimated at 1 in 1,000 to 10,000 treatment courses in some populations, with higher rates observed in certain regions such as . Allergic reactions are also common, ranging from cutaneous rashes to severe , often mediated by immune responses to metabolites. These risks have led to restrictions on metamizole in pharmaceutical applications, highlighting the need for on symptoms like fever, sore throat, or unexplained bruising. Occupational exposure to pyrazolones, especially during dye and pigment production, presents hazards including skin and eye irritation classified under H315 (causes skin irritation) and H318 (causes serious eye damage). Inhalation of dust or vapors can lead to irritation and potential issues such as coughing or , underscoring the importance of in industrial settings. Regulatory measures reflect these health concerns; metamizole was banned in the United States and in the 1970s due to associations with blood dyscrasias like . In September 2024, the (EMA) recommended measures to minimize risks, including avoiding use in patients susceptible to blood disorders and requiring blood monitoring where appropriate. The advice includes monitoring for signs of , particularly in prolonged use, with recommendations to discontinue treatment upon suspicion of blood disorders. Pyrazolone metabolism primarily occurs in the liver via enzymes, such as for key metabolites of , generating reactive intermediates that contribute to toxicity including and . These reactive metabolites, formed through oxidation and demethylation pathways, can bind to proteins and trigger immune-mediated adverse effects.

Environmental Impact

Pyrazolones enter aquatic environments primarily through industrial effluents from and production. In pharmaceutical applications, residues of pyrazolone-based analgesics and drugs, such as antipyrine derivatives, persist after processes and are discharged into surface waters. Similarly, in the dye industry, pyrazolones are key components of synthetic colorants like , a widely used yellow ; degradation or hydrolysis of during production or environmental breakdown yields pyrazolone intermediates, such as 4-amino-3-carboxy-5-hydroxy-1-(4-sulfophenyl), which contribute to . These compounds demonstrate high persistence in systems, resisting natural due to their heterocyclic , and have been detected in plant effluents and surface waters at concentrations in the µg/L (ppb) range. This recalcitrance limits their breakdown in conventional systems, allowing accumulation in receiving waters from both point sources like industrial discharges and diffuse pharmaceutical runoff. Pyrazolones pose moderate ecotoxicity to organisms, with potential adverse effects on and at environmentally relevant concentrations. is limited for common derivatives. Effective removal from wastewater requires advanced strategies beyond biological treatment, as the N-heterocyclic ring hinders by microbial communities. , such as the Fenton reaction involving Fe²⁺ and H₂O₂ to generate hydroxyl radicals, achieve high degradation rates (>90%) of pyrazolone pollutants under optimized conditions (pH 3-4, oxidant ratios 10:1). Adsorption onto is another viable method, leveraging the compounds' moderate hydrophobicity for solid-phase capture, with removal efficiencies up to 95% in batch systems. Under REACH regulations, specific pyrazolones like 3-methyl-1-phenyl-5-pyrazolone are registered for monitoring due to their environmental release potential, requiring manufacturers to report ecotoxicity and persistence data. Globally, pyrazolones have gained attention as emerging contaminants in the , prompting calls for inclusion in frameworks to mitigate ecological risks from ongoing industrial discharges.