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Anthrone

Anthrone is a aromatic , systematically named 9(10H)-anthracenone, with the molecular formula C₁₄H₁₀O and a molecular weight of 194.23. It appears as an off-white to yellow powder or crystals, insoluble in water, with a of 154–157 °C and a estimated at 721 °C. As a derivative of , anthrone features a central six-membered ring with a group at the 9-position and a , making it a key intermediate in . It is commonly synthesized by the reduction of using reagents such as tin and . In natural sources, anthrone derivatives occur in plants like species, where they contribute to compounds such as and are biosynthesized via the pathway. Anthrone's most notable application is as a reagent in colorimetric assays for detecting and quantifying carbohydrates, including reducing and non-reducing sugars like and , as well as in biological fluids and materials. The anthrone test produces a color in the presence of sugars under acidic conditions, enabling sensitive at wavelengths around 620 nm. Additionally, it is used for the quantitative determination of antibiotics like and in the analysis of carbohydrate-containing . Beyond , anthrone serves as a building block for dyes, pigments, and fluorescent whitening agents, and it participates in reactions such as Brønsted base-catalyzed Diels–Alder cycloadditions. Historically, some anthrone derivatives have been explored for properties.

Structure and properties

Molecular structure

Anthrone has the molecular formula C_{14}H_{10}O and a of 194.233 g·mol^{-1}. It is systematically named 9(10H)-anthracenone and consists of a scaffold with two outer rings fused to a central six-membered ring bearing a functionality at the 9-position and a methylene (CH_2) group at the 10-position. This arrangement renders the central ring non-aromatic, distinguishing anthrone from the fully conjugated anthracene parent hydrocarbon. The canonical SMILES notation for anthrone is c1ccc2c(c1)Cc3ccccc3C2=O. Anthrone relates to anthracene (C_{14}H_{10}) as a keto derivative wherein the central ring is partially saturated and an oxygen atom effectively replaces a CH_2 unit to form the 9-carbonyl.

Physical properties

Anthrone appears as a white to light yellow crystalline solid or powder. It has a of 155–158 °C. The is reported as approximately 721 °C at standard pressure, though the compound may decompose before reaching this temperature. Anthrone is insoluble in (solubility approximately 4.6 mg/L) but soluble in solvents such as , acetone, , , , and . The density is estimated at 1.06 g/cm³. Its value, indicating , is 2.82 (computed).

Tautomerism

Anthrone primarily exists in its keto form, known as 9(10H)-anthracenone, which is significantly more stable than the enol tautomer, 9-anthrol. The keto-enol tautomerism is represented by the equilibrium: \ce{(keto) Anthrone ⇌ (enol) Anthrol} where the keto structure features a at position 9 and a methylene at position 10, while the enol has a hydroxyl at position 9 and a between carbons 9 and 10. In , the equilibrium strongly favors the keto form, with the enolization constant K_E = [\text{anthrol}]/[\text{anthrone}] \approx 0.0068 (pK_E = 2.17 at 25°C and 0.1 M), corresponding to a keto:enol ratio of approximately 150:1. X-ray crystallographic analysis confirms that anthrone adopts the structure in the solid state, crystallizing in the monoclinic P2_1/a with parameters a = 15.80 , b = 3.998 , c = 7.860 , and \beta = 101.67^\circ at 20°C, exhibiting long-range disorder due to statistical molecular orientations. The tautomer, 9-anthrol, functions as a compound with a pK_a of approximately 7.84 for its hydroxyl group. Other anthrol isomers, such as 1-anthrol and 2-anthrol, are also but arise from direct of rather than tautomerism of anthrone. This tautomerism impacts anthrone's reactivity, particularly in electrophilic aromatic substitutions like , where the minor population directs preferential attack to positions activated by the hydroxyl, such as the 2-position to it in the form.

Synthesis

Reduction methods

The primary method for synthesizing involves the partial of , a readily available oxidized precursor derived from . This approach selectively reduces the two carbonyl groups of anthraquinone to a methylene group, yielding anthrone as the key product. The most established industrial and laboratory procedure utilizes tin metal (Sn) in glacial acetic acid with concentrated hydrochloric acid (HCl) as the reducing agent, a method that achieves crude yields of about 82% and 62% after recrystallization. The reaction proceeds under heating, typically refluxing the mixture for several hours, followed by isolation via filtration and purification. Alternative reducing agents include tin(II) chloride (SnCl₂) or sodium hydrogen sulfite (NaHSO₃), which also enable selective reduction under acidic or aqueous conditions, though tin/HCl remains the benchmark for its simplicity and efficiency. The general reaction equation is: \text{Anthraquinone} + \text{Sn}/\text{HCl} \rightarrow \text{Anthrone} + \text{byproducts} This reduction technique was first reported by R. Meyer in 1911 to support the burgeoning synthetic dye industry where anthrone served as an intermediate for vat dyes and related compounds. The method's advantages lie in the abundance and low cost of anthraquinone, coupled with straightforward scalability, making it suitable for large-scale production. However, it generates significant metal-containing waste, such as tin salts, posing environmental challenges that have prompted exploration of greener alternatives in modern contexts.

Cyclization methods

Anthrone can be synthesized through the intramolecular cyclization of o-benzylbenzoic acid, providing an alternative route complementary to reductions of anthraquinone. A key method employs liquid hydrogen fluoride (HF) as both dehydrating agent and catalyst. In this procedure, o-benzylbenzoic acid is dissolved in excess HF (typically 7–30 equivalents) and stirred at room temperature for several hours, followed by quenching with water or ice, extraction, and purification to afford anthrone in yields of 82%. The reaction proceeds via an acid-catalyzed mechanism, wherein HF protonates the , facilitating to form an acylium ion intermediate; this then attacks the position of the benzyl aromatic ring in a Friedel–Crafts-type , closing the central six-membered ring. This approach is particularly advantageous on a scale, yielding cleaner products with fewer side reactions—such as avoiding polyalkylation or ketonic condensations—compared to metal-based reductions, and it is widely employed in research settings for preparing anthrone and its derivatives. The overall transformation is depicted as: \ce{C6H5-CH2-C6H4-COOH ->[HF][rt] C14H10O + H2O} Variations utilize other Brønsted or Lewis acids for the cyclization, including polyphosphoric acid, which promotes similar dehydrative ring closures in the synthesis of anthrone analogs from arylalkyl carboxylic acids.

Reactions and applications

Condensation reactions

Anthrone, acting as a with an active , participates in condensation reactions typical of carbonyl compounds. One prominent example is its reaction with , which proceeds via in a substantially water-miscible organic solvent to form the diol intermediate 1,2-bis(10-hydroxy-9-anthryl)ethane, followed by acid-catalyzed to 1,2-bis(9-oxoanthracen-10(9H)-ylidene)ethane. This bis-ylidene compound then undergoes cyclization and dehydrogenation upon heating with aluminum chloride and , yielding acedianthrone, a symmetric octacyclic derivative valued as a in the dye industry. This process highlights anthrone's utility in building complex fused ring structures, with the dehydrogenation step crucial for and color development. Due to its keto-enol tautomerism, anthrone exhibits reactivity influenced by the form. However, standard nitration with in acetic acid yields 10-nitroanthrone, where the nitro group is introduced at the 10-position. As a methylenic , anthrone demonstrates potential for aldol-type condensations in basic media, where at the 10-position generates an that can add to aldehydes or ketones, followed by to form α,β-unsaturated derivatives. For instance, treatment with aromatic aldehydes under alkaline conditions leads to stilbene-like anthrone analogs, though such reactions are less commonly exploited compared to its pigment-forming condensations. The following equation summarizes the glyoxal condensation: \text{Anthrone} + \ce{(CHO)2} \xrightarrow{\text{neutral solvent}} \ce{(10-anthryl-OH)2CH-CH2} \xrightarrow{\text{acid}} \ce{(anthron-10-ylidene)2CH-CH2} \xrightarrow{\ce{AlCl3/NaCl, \Delta}} \text{Acedianthrone} This pathway exemplifies anthrone's role in dye chemistry, contributing to the development of stable, high-chroma pigments for textiles.

Analytical applications

Anthrone serves as a key reagent in colorimetric assays for the quantitative determination of carbohydrates, particularly through the formation of green-colored complexes when sugars react with anthrone in concentrated sulfuric acid, which are measurable by spectrophotometry at approximately 620 nm. This method enables the detection of total carbohydrate content by dehydrating saccharides to furfural derivatives that condense with anthrone, producing a stable chromophore suitable for analysis. The standard anthrone test procedure involves dissolving the sample in concentrated H₂SO₄ containing anthrone (typically 0.2% w/v), heating the mixture at 100°C for 10 minutes to develop the color, cooling it to , and measuring at 620 nm against a glucose standard curve. This approach, adapted for total quantification, was notably developed by et al. in 1952 for analyzing , building on earlier work for and providing a sensitive for hexoses and pentoses with detection limits around 10-50 μg. Applications of the anthrone assay extend to the determination of , , and pentoses in various matrices, including biological fluids such as and plant extracts, where it quantifies both reducing and non-reducing sugars with comparable sensitivity due to the method's reliance on rather than . For instance, it has been employed to measure in cereals and soluble carbohydrates in microbial cultures, offering a rapid alternative to hydrolytic methods. However, limitations include from other reducing agents like or , which can alter color development, and reduced sensitivity for uronic acids or pentoses compared to hexoses.

Synthetic and biological uses

Anthrone serves as a versatile intermediate in , particularly for the production of anthraquinone-based dyes and pigments valued for their vibrant colors and stability in textiles and coatings. It is also employed in the manufacture of fluorescent whitening agents, which enhance the brightness of fabrics, papers, and plastics by absorbing light and emitting . These applications leverage anthrone's ability to undergo oxidation to derivatives, enabling the creation of compounds with desirable photophysical properties. Recent advances include its use in lipase-catalyzed multicomponent reactions for synthesizing anthrone-functionalized benzylic esters and in developing fluorescent α-aminophosphonates. In pharmaceuticals, derivatives of anthrone, such as anthrone glycosides and dianthrones, function as laxatives by promoting intestinal and through of the colonic mucosa. These compounds are found in plants like Rhamnus frangula (frangula bark), (Cape aloe), and (), where they occur as glycosides that are metabolized in the gut to active anthrone forms. Notable examples include sennosides from senna and , which are dianthrone glycosides that exert a effect 6-12 hours after , with anthrone glycosides showing more potent activity than their counterparts. Biologically, anthrone appears as an intermediate in the pathway of in , particularly within families such as , Aloeaceae, and , where it contributes to the formation of anthranoid metabolites like anthrone. In (), glycosides in the leaves synergize with high levels to enhance toxicity, leading to symptoms such as , , and potential kidney damage upon ingestion. This combination underscores anthrone derivatives' role in mechanisms while posing risks in herbal preparations if leaves are consumed. Anthrone-based colorimetric assays have been utilized for the quantitative determination of levels in pharmaceutical and biological samples, exploiting the antibiotic's carbohydrate components like streptose and , which react with anthrone in to produce a measurable color. This method, developed in the mid-20th century, provides a sensitive alternative to microbiological assays for monitoring concentrations. Industrial synthesis of anthrone and its derivatives can lead to environmental release through from dye and . Anthrone is inherently biodegradable and expected to be a major fate process in , though data on persistence remain limited; controlled disposal is recommended to minimize potential risks.