134-96-3

Basic information

• Product Name: Syringaldehyde
• Synonyms: 3,5-Dimethoxy-4-hydroxybenzaldehyde 4-Hydroxy-3,5-dimethoxybenzaldehyde Syringic Aldehyde;3,5-DIMETHOXY-4-HYDROXYBENZALDEHYDE FOR;The lilac aldehyde;3,5-DiMethoxy-4-hydroxybenzaldehyde SynonyMs 4-Hydroxy-3,5-diMethoxybenzaldehyde;Syringaldehyde Vetec(TM) reagent grade, 98%;Lilac aldehyde;3,5-Dimethoxy-4-hydroxybenzaldehyde for synthesis;FEMA 4049
• CAS NO: 134-96-3
• Molecular Formula: C₉H₁₀O₄
• Molecular Weight: 182.17
• EINECS: 205-167-5
• Product Categories: Aldehydes;Building Blocks;C9;Carbonyl Compounds;Chemical Synthesis;Organic Building Blocks;Building block;Aromatic Aldehydes & Derivatives (substituted)
• Mol File: 134-96-3.mol
• Article Data: 75

Chemical Properties

• Melting Point: 110-113 °C(lit.)
• Boiling Point: 192-193 °C14 mm Hg(lit.)
• Flash Point: 192-193°C/14mm
• Appearance: Light yellow-green to brown/Crystalline Powder
• Density: 1.013
• Vapor Pressure: 0.000151mmHg at 25°C
• Refractive Index: 1.4500 (estimate)
• Storage Temp.: Store below +30°C.
• Solubility: Chloroform, Methanol (Slightly)
• PKA: 7.80±0.23(Predicted)
• Water Solubility: very sparingly soluble
• Sensitive: Air Sensitive
• Stability: Hygroscopic
• Merck: 14,9015
• BRN: 784514
• CAS DataBase Reference: Syringaldehyde(CAS DataBase Reference)
• NIST Chemistry Reference: Syringaldehyde(134-96-3)
• EPA Substance Registry System: Syringaldehyde(134-96-3)

Safety Data

• Hazard Codes: Xn,Xi
• Statements: 22-36/37/38
• Safety Statements: 26-37/39-36
• WGK Germany: 3
• RTECS: CU5760000
• TSCA: Yes
• Hazardous Substances Data: 134-96-3(Hazardous Substances Data)

Usage

Overview

Syringaldehyde is a promising aromatic aldehyde that no longer deserves to remain in obscurity. It possesses worthy bioactive properties and is, therefore, used in pharmaceuticals, food, cosmetics, textiles, pulp and paper industries, and even in biological control applications. Mostly, the synthetic form of syringaldehyde is being used. The ever-increasing safety concerns over synthetic antioxidants and the harmful side effects of chemo-therapeutic drugs, coupled with their high costs[1], have created a new path for the development of cheaper, sustainable, and most crucially, natural anti-oxidants, drugs, and food additives[2]. Syringaldehyde, a compound found only in a minute quantity in nature, is believed to be a promising source that matches the abovementioned requisites. Syringaldehyde, or 3,5-dimethoxy-4-hydroxybenzaldehyde, is a naturally occurring unique compound with assorted bioactive characteristics that belongs to the phenolic aldehyde family. Syringaldehyde is very similar in structure to its infamous counterpart, vanillin, and it has comparable applications[3]. Though not as well commercialized as vanillin, syringaldehyde chemistry and its manipulation are emerging rather rapidly, especially after the discovery of its role as an essential intermediate of the antibacterial drugs Trimethoprim, Bactrim, and Biseptol[4]. Bactrim or Biseptol are combinations of Trimethoprim with sulfamethoxazole. These drugs are common bactericides. Figure 1 the chemical structure of syringaldehyde

Natural sources

An excellent natural source of syringaldehyde lies within the cell walls of plants. Being the second most copious biopolymer only to cellulose, lignin offers a continuous, renewable, and cheap supply of syringaldehyde. This is promising, since lignin is discarded as waste by the pulping industry and is also a major by-product from the biomass-to-ethanol conversion process[5]. Despite the fact that the fate of lignin ends at a bio-fuel refinery[6], its hidden wealth can be extracted prior to its conversion into biomass feedstock. Although this practice is not common for the recovery of syringaldehyde, it is slowly emerging, since value-added products from wastes offer a promising future. Years of tedious research have led to the current development and understanding of the synthesis of the syringyl unit in plants. Lignin being an amorphous heteropolymer, the elucidation of its biosynthetic pathway is not an easy task. In order to appreciate the complexity and diversity of nature and her unique attributes, it is vital to know how the syringyl unit comes into existence in lignin. Moreover, the bio-origin of this compound has not been adequately reviewed. Protolignin (naturally occurring lignin) varies in molecular make-up from plant to plant and even from cell to cell[7]. Research demonstrated that Arabidopsis mutants were no longer upright since they lacked lignified interfascicular fibers, providing evidence that macro-metabolite lignin is responsible for the structural integrity of plants. Lignin also provides plants with a vascular system for the conveyance of water and solutes[8]. The biosynthetic pathway of protolignin comes primarily from the breakthrough discovery and characterization of the enzymes that lead to monolignols syntheses of pcoumaryl, coniferyl, and sinapyl alcohols, whereby they form the hydroxyphenyl (H), guaiacyl (G), and syringyl (S) units in lignin, respectively. These units vary structurally due to different degrees of methoxy substituents[7]. The xylem vessels in plants are known to provide both mechanical support and water conduction. These vessels are mainly composed of G-lignin and do not contain S-lignin since the enzymatic genes that encode for sinapyl alcohol are lacking in gymnosperms[9]. Because G-lignin is lacking in angiosperms, additional specialized cells referred to as fiber cells provide much needed mechanical support[10]. Fascinatingly, in angiosperms, these fiber cells are mainly composed of S-lignin. The genes involved in S-lignin synthesis developed much later than G-lignin, rendering evidence of evolution from softwood plants (gymnosperms) to hardwood plants (angiosperms)[11]. Additionally, various plants commonly used as wood sources and crops with their lignin content identified. These Slignins are the source from which syringaldehyde can be obtained when lignocellulosic materials undergo certain oxidation reactions.

Extraction and isolations

The available percentage of precursors in the lignin structure strictly determines the formation of phenolic compounds such as vanillin or syringaldehyde. It becomes more useful in producing phenolic aldehydes when the lignin is subjected to fewer transformations or chemical treatments. In a study using lignin oxidation, in which the influence of lignin origin, condition of production, and type of pre-treatment on obtained yields of vanillin and syringaldehyde was inspected. The results indicated a competition between lignin fragments (syringyl fragments and guaiacyl fragments) condensation and lignin oxidation into aldehydes[8]. It has been obtained a maximum yield of 14% for the total phenolic aldehydes (syringaldehyde + vanillin), based on nitrobenzene oxidation using lignin precipitated from kraft black liquor with the addition of a calcium salt dissolved in water soluble alcohol. In another study, a yield of about 50 to 59.7% syringaldehyde and vanillin in equal proportions of the total phenolic aldehydes was obtained via nitrobenzene oxidation from the lignin extracted from rice straw[7]. Syringaldehyde has been reported to be separated and analyzed via a recrystallization process. A old study[12] utilized the recrystallization process on the oxidation products of corn stems on one of the fractions using water and obtained syringaldehyde with a reported melting point of 110 to 112 °C. It was also reported that the oxidation of corn stems produced 3.2% crude yields and 2.6% pure syringaldehyde product. In a study of syringaldehyde composition in angiosperm monocotyledons and dicotyledons[13], the recrystallization process was used in purifying the syringaldehyde sublimate. This study reported a yield of total phenolic aldehydes (vanillin and syringaldehyde) in monocotyledons between 21 to 30%, and dicotyledons between 39 and 48%.

Biological activity and applications

Advancements in analytical instruments coupled with breakthroughs in chemistry and pharmacology have allowed for the identification, quantification, and isolation of phenolic aldehydes for the diverse applications such as antioxidants, antifungal or antimicrobial, and anti-tumorigenesis agents in pharmaceuticals. In the food industry there is also a tendency to utilize naturally occurring flavor compounds that exhibit antioxidant and antimicrobial properties, hence providing a potential source of nonsynthetic preservatives and additives. Only preliminary in vitro tests have been reported in most cases, but a new potential research area and application of syringaldehyde has been identified. Keeping this in mind, some of the reported bioactive properties of syringaldehyde are exemplified here. Antioxidant capacity A study related to the structural motifs of syringaldehyde and other benzaldehydes for their antioxidant capabilities was approached by[14]. In that study the presence of syringaldehyde in low quantities exhibited impressive results in peroxyl scavenging activity, based on the CB assay. Its antioxidant activity was recorded to be six times higher than that of protocatechuic aldehyde. The higher the Trolox equivalent value (TEV), the more antioxidant property a molecule will have. This value decreased in the order from syringaldehyde > protocatechuic aldehyde > vanillin. This method measures the ability of molecules with antioxidant properties to suppress ABTS, which is a blue-green chromophore exhibiting characteristic absorption at 734 nm. The suppression ability of the molecule is compared with that of Trolox, a vitamin-E analog. According to their study, the dimethoxy substitution in syringaldehyde as well as its syringol moiety was acknowledged for exhibiting enhanced antioxidant properties[14]. Antimicrobial/antifungal activity Fillat et al. (2012)[15] studied the effects of non-leachable low molecular weight phenols with lactase on unbleached flax fibers in producing bio-modified pulp and paper. The researchers focus on the antimicrobial effect of syringaldehyde and acetosyringone (a derivative of syringaldehyde) in reducing the population of Staphylococcus aureus (Gram+), Klebsiella pneumonia (Gram-), and Pseudomonas aeruginosa (Gram-), which are known widely to cause diseases in humans. The population of Klebsiella pneumonia was reduced to 61% by syringaldehyde, whereas acetosyringone gave a major reduction up to 99%. In the case of Staphylococcus aureus, its reduction in population by syringaldehyde was 55%, which was 15% higher than acetosyringone. Another bacterium, Pseudomonas aeruginosa, was reduced by 71% using syringaldehyde and to a staggering 97% level by acetosyringone. The role of syringaldehyde as an antifungal agent against the medicinally important yeast Candida guilliermondii seems to be promising. It was reported that syringaldehyde successfully inhibited the C. guilliermondii growth rate and reduced xylitol production effectively. The fungicidal effect is most likely due to the aldehyde moiety. The hydroxyl substituent in syringaldehyde is suspected to play a key role in enhancing this fungicidal effect.[16] Mediator Syringaldehyde was one of the first natural laccase mediators discovered. It has been reported to be used as a mediator in the degradation of indigo carmine by bacterial laccase (benzenediol oxygen oxidoreducase) obtained from the organism γ-Proteobacterium JB[18]. The study ascertained that syringaldehyde was able to increase the degradation of indigo carmine by 57%. The enhanced degradation was made possible by the electron-donating methyl and methoxy substituents. Syringaldehyde is also used as a mediator in laccase-assisted biobleaching processes. In these processes, synthetic mediators such as HBT, violuric acid, and promazine were used. Another research focused on potentially cost-effective ligninderived natural mediators, including syringaldehyde obtained from spent pulping liquors and plant materials used in the paper pulp laccase-mediator delignification process in combination with peroxide bleaching[17]. Organic markers in wood smoke For confirmation of carbon-based fractions in smoke emissions, biomarkers or molecular tracers are employed as indicators to detect the origins from natural products of vegetation and their post-combustion residuals. Phenolic compounds (like syringaldehyde), which are obtained from lignin pyrolysis in vegetation, have been proposed as tracers specific for plant taxonomy. Syringaldehyde is widely used as a molecular marker for biomass smoke from aerosol particulate matter, namely to monitor pollution sources and detect the extent of combustion[19]. Since global climate change is affecting the occurrence of wildfires, a need to quantitatively identify atmospheric particulate matter from smoke appears to be of grave importance[20]. Syringaldehyde seems to play a key role in the detection of hardwood smoke. Biological control activity Syringaldehyde has been reported as an Agrobacterium tumefaciens virulence gene inducer. A study on the insecticidal properties of syringaldehyde was carried out on Acanthoscelides obtectus beetles[21]. Syringaldehyde showed a significant decrease in natural mobility by the 4th day and caused significant mortality on the 8th day. An investigation utilizing spectrophotometric analysis to determine amino acids using syringaldehyde was also reported [22]. A simple and sensitive spectrophotometric method was developed for kinetic determination of amino acids through their condensation with syringaldehyde. This provides an additional option in the analysis of amino acids with advantages of reagent availability, reagent stability, and less time consumption.

References

Vergnenegre, A. (2001). Revue des Maladies Respiratoires 18(5), 507-16. Garrote, G., et al (2004). Trends in Food Science & Technology 15, 191-200. Bortolomeazzi, R., et al (2001) Food Chemistry 100(4), 1481-1489. Rouche, H.-L. (1978). US Patent 4,115,650. Xiang, Q., and Lee, Y. (2001). Applied Biochemistry and Biotechnology 91-93(1), 71-80. Kleinert, M., and Barth, T. (2008). Energy & Fuels 22, 13711379. Christiernin, M., et al (2005). Plant Physiology and Biochemistry 43(8), 777-785. Hacke, U. G., and Sperry, J. S. (2001). Evolution and Systematics 4(2), 97-115. Boerjan, W., et al (2003). Annu Rev Plant Biol 54(1), 519-546. Fergus, B. J., et al (1970). Holzforschung 24(4), 113-117. Li, L., et al (2001) Plant Cell 13(7), 1567-1586. Creighton, R. H. J., et al (1941). JACS 63(1), 312. Creighton, R. H. J., et al (1941). JACS 63(11), 3049-3052. Boundagidou, O. G., et al (2010). Food Research International 43(8), 2014-2019. Fillat, A., et al (2012). Carbohydrate Polymers 87(1), 146-152. Kelly, C., et al (2008). In: Biotechnology for Fuels and Chemicals, Humana Press, 615-626. Camarero, S., et al (2007). Enzyme and Microbial Technology 40(5), 1264-1271. Singh, G., et al (2007). Enzyme and Microbial Technology 41, 794-799. Robinson, A. L., et al (2006). Environmental Science & Technology 40(24), 7811-7819 Simoneit, B. R. T. (2002). Applied Geochemistry 17, 129-162. Regnault-Roger, C., et al (2004). Journal of Stored Products Research 40(4), 395-408. Medien, H. A. A. (1998). " Spectrochimica Acta Part A.: Molecular and Biomolecular Spectroscopy, 54(2), 359-365

Chemical Properties

Different sources of media describe the Chemical Properties of 134-96-3 differently. You can refer to the following data:
1. light yellow-green to brown crystalline powder
2. 4-Hydroxy-3,5-dimethoxybenzaldehyde has an alcoholic odor

Occurrence

Reported found in pineapple, beer, wine, grape brandy, rum, many different whisky products, sherry, roasted barley and hardwood smoke

Uses

Different sources of media describe the Uses of 134-96-3 differently. You can refer to the following data:
1. Syringaldehyde is used in biological studies for the isolation and structural characterization of milled wood lignin, dioxane lignin, and cellulolytic lignin preparation from Brewer''s spent grain.
2. Syringaldehyde may be used as an analytical reference standard for the determination of the analyte in guacoextracts and pharmaceutical preparations,(1) cognacs and wines,(2) plum brandies,(4) and wheat straw(5) by various chromatography techniques.

Preparation

Vanillin is converted to 5-iodovanillin, which is treated with sodium methoxide to form 4-hydroxy-3,5- dimethyxybenzaldehyde.

Definition

ChEBI: A hydroxybenzaldehyde that is 4-hydroxybenzaldehyde substituted by methoxy groups at positions 3 and 5. Isolated from Pisonia aculeata and Panax japonicus var. major, it exhibits hypoglycemic activity.

Aroma threshold values

Aroma characteristics at 1.0%: weak sweet, slightly smoky, cinnamic, vanilla, leather-like with a phenolic medicinal nuance

Synthesis Reference(s)

Canadian Journal of Chemistry, 31, p. 476, 1953 DOI: 10.1139/v53-064Synthetic Communications, 20, p. 2659, 1990 DOI: 10.1080/00397919008051474

General Description

Syringaldehyde is an aromatic phenolic aldehyde and a degradation product of lignin. It exhibits antioxidant activity and is reported to inhibit prostaglandin synthetase enzyme. The synthetic form of syringaldehyde is commercially used in pharmaceuticals, food, cosmetics, textiles, pulp and paper industries.

Biochem/physiol Actions

Odor at 1.0%

Purification Methods

Crystallise syringaldehyde from pet ether. [Beilstein 8 H 391, 8 IV 2718.]

InChI:InChI=1/C9H10O4/c1-12-7-3-6(5-10)4-8(13-2)9(7)11/h3-5,11H,1-2H3

Upstream product

• 39657-47-1 O-acetylsyringic acid chloride 
• 81947-97-9 (4-hydroxy-3,5-dimethoxy-phenyl)-glyoxylic acid 
• 99-97-8 Dimethyl-p-toluidine 
• 7664-93-9 sulfuric acid 
• 86-81-7 3,4,5-trimethoxy-benzaldehyde 
• 6635-22-9 2,6-dimethoxy-4-(prop-1-en-1-yl)-phenol 
• 98-95-3 nitrobenzene 
• 6638-05-7 2,6-dimethoxy-4-methylphenol 
• 7732-18-5 water 
• 67-56-1 methanol 
• 111-27-3 hexan-1-ol 
• 530-56-3 syringic alcohol 
• 3934-87-0 5-hydroxyvanillin 
• 77-78-1 dimethyl sulfate 

Downstream Products

• 530-59-6 sinapinic acid 
• 90985-68-5 3-(4-acetoxy-3,5-dimethoxyphenyl)prop-2-enoic acid 
• 33900-62-8 1-(4-Hydroxy-3,5-dimethoxyphenyl)ethanol 
• 70622-87-6 2.6-Dimethoxy-4-(2t-nitro-vinyl-(1r))-phenol 
• 530-59-6 trans-3,5-dimethoxy-4-hydroxycinnamic acid 
• 41628-47-1 ethyl (2E)-3-[4-hydroxy-3,5-bis(methyloxy)phenyl]-2-propenoate 
• 530-56-3 syringic alcohol 
• 530-57-4 3,5-dimethoxy-4-hydroxybenzoic acid 
• 6638-05-7 2,6-dimethoxy-4-methylphenol 
• 39075-25-7 3,5-Dimethoxy-4-ethoxybenzaldehyde 
• 137214-61-0 2-bromo-4-hydroxy-3,5-dimethoxybenzaldehyde 
• 6024-59-5 2-(4-hydroxy-3,5-dimethoxybenzylidene)hydrazine-1-carboxamide 
• 117685-21-9 3,5-dimethoxy-4-(2',3',4',6'-tetra-O-acetyl-β-D-glucopyranosyloxy)benzaldehyde 
• 127035-72-7 2,6-Dimethoxy-4-((E)-2-thiophen-2-yl-vinyl)-phenol 

Related news

Competitive adsorption of vanillin and Syringaldehyde (cas 134-96-3) on a macro-mesopore polymeric resin: modeling09/30/2019

Vanillin and syringaldehyde are widely used as flavoring and fragrance agents in the food products. The potential of a macro-mesoporous adsorption resin was assessed for separation of these binary mixtures. This work focuses on modeling of the competitive adsorption behaviors and exploration of ...detailed

Successful recovery and concentration of vanillin and Syringaldehyde (cas 134-96-3) onto a polymeric adsorbent with ethanol/water solution09/29/2019

The recovery of purified fractions of vanillin and syringaldehyde (V&S) from an oxidized lignin medium has attracted considerable attention driven by the high added value of these products and the importance of lignin valorization processes in biorefineries. Polymeric resins with high specific a...detailed

Separation of Vanillin and Syringaldehyde (cas 134-96-3) from Oxygen Delignification Spent Liquor by Macroporous Resin Adsorption10/01/2019

This paper reports on an approach for separating vanillin and syringaldehyde (VSA) from oxygen delignification spent liquor using non‐polar macroporous resin. The effects of temperature and pH on the adsorption isotherms were studied. The adsorption capacity and adsorption equilibrium constant ...detailed

Relevant articles and documents

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A convenient synthesis of 3,4-dimethoxy-5-hydroxybenzaldehyde

Synthesis of 3,4-dimethoxy-5-hydroxybenzaldehyde (1) in three steps from vanillin with the key step being a copper catalyzed hydrolysis of 5- bromovanillin to give 4,5-dihydroxy-3-methoxybenzaldehyde.

Catalytic oxidation of para-substituted phenols with nitrogen dioxide and oxygen

A series of para-substituted phenols was oxidized to the corresponding benzoquinones in moderate to high yield with catalytic amounts of NO2 under O2 in MeOH. Little or no oxidation is observed under argon. Substrates of lower reactivity gave quinones when treated with stoichiometric amounts of NO2 in CCl4, but nitration of the aromatic ring became a significant side product.

Steric effects of bulky tethered arylpiperazines on the reactivity of Co-Schiff base oxidation catalysts—a synthetic and computational study

New C2-symmetric and C2-asymmetric Co-Schiff base catalysts tethered to arylpiperazine units were synthesized and used to oxidize phenolic lignin models to para-benzoquinones. Synthetic approaches to these catalysts were optimized to include fewer steps and broaden the types of catalyst structures available. In contrast to conventional Co-Schiff base catalysts, these systems induce phenolic oxidation in the absence of an external axial base, simplifying the process. Asymmetric catalysts bearing a phenylethylene or diphenylmethyl piperazine substituent display the highest catalytic activity observed to date for the conversion of S-models to 2,6-dimethoxybenzoquinone (DMBQ). Computational analysis shows that more reactive catalysts populate conformations that favor oxidation in preference to non-productive decomposition routes. This balance between catalyst reactivity and catalyst deactivation is optimized by inclusion of sufficient steric bulk around the periphery of the Schiff base ligand, reducing catalyst deactivation and allowing oxidations to proceed in the absence of an added axial ligand.

Initial steps of the peroxidase-catalyzed polymerization of coniferyl alcohol and/or sinapyl aldehyde: Capillary zone electrophoresis study of pH effect

Capillary zone electrophoresis has been used to monitor the first steps of the dehydrogenative polymerization of coniferyl alcohol, sinapyl aldehyde, or a mixture of both, catalyzed by the horseradish peroxidase (HRP)-H2O2 system. When coniferyl alcohol was the unique HRP substrate, three major dimers were observed (β-5, β-β, and β-O-4 interunit linkages) and their initial formation velocity as well as their relative abundance varied with pH. The β-O-4 interunit linkage was thus slightly favored at lower pH values. In contrast, sinapyl aldehyde turned out to be a very poor substrate for HRP except in basic conditions (pH 8). The major dimer observed was the β,β′-di-sinapyl aldehyde, a red-brown exhibiting compound which might partly participate in the red coloration usually observed in cinnamyl alcohol dehydrogenase-deficient angiosperms. Finally, when a mixture of coniferyl alcohol and sinapyl aldehyde was used, it looked as if sinapyl aldehyde became a very good substrate for HRP. Indeed, coniferyl alcohol turned out to serve as a redox mediator (i.e. shuttle oxidant ) for the sinapyl aldehyde incorporation in the lignin-like polymer. This means that in particular conditions the specificity of oxidative enzymes might not hinder the incorporation of poor substrates into the growing lignin polymer.

Aerobic oxidation of syringyl alcohol over N-doped carbon nanotubes

Carbon nanotubes (CNTs) doped with nitrogen were prepared using two methodologies, chemical vapor deposition (N-CNTs) and post-modification (N-CNTs-P), and characterized by N2 adsorption, TEM, XPS, Raman spectroscopy, and water capacity measurements. Their catalytic performance was assessed for aerobic oxidation of syringyl alcohol, a model of syringyl unit of lignin. With N-CNTs, the reaction readily proceeds under mild conditions (40–80 °C, 1 atm of air, isopropanol, ethanol, or water as solvents), leading to syringaldehyde with 95–97% yield. A correlation between N content in N-CNTs and oxidation rate has been established. Spectroscopic studies coupled with water capacity measurements implicated that a blend of graphitic and pyridinic nitrogen species is crucial for catalytic activity. The catalysts can be easily recovered, regenerated, and reused without significant loss of the catalytic performance. N-CNTs-P catalysts, which endow high content of quinone-type oxygen groups, provide significantly lower syringaldehyde yield due to fast deactivation.

Mild selective oxidative cleavage of lignin C-C bonds over a copper catalyst in water

The conversion of lignin into aromatics as commodity chemicals and high-quality fuels is a highly desirable goal for biorefineries. However, the presence of robust inter-unit carbon-carbon (C-C) bonds in natural lignin seriously impedes this process. Herein, for the first time, we report the selective cleavage of C-C bonds in β-O-4 and β-1 linkages catalyzed by cheap copper and a base to yield aromatic acids and phenols in excellent yields in water at 30 °C under air without the need for additional complex ligands. Isotope-labeling experiments show that a base-mediated Cβ-H bond cleavage is the rate-determining step for Cα-Cβ bond cleavage. Density functional theory (DFT) calculations suggest that the oxidation of β-O-4 ketone to a key intermediate, i.e., a peroxide, by copper and O2 lowers the Cα-Cβ bond dissociation energy and facilitates its subsequent cleavage. In addition, the catalytic system could be successfully applied to the depolymerization of various authentic lignin feedstocks, affording excellent yields of aromatic compounds and high selectivity of a single monomer. This study offers the potential to economically produce aromatic chemicals from biomass.

Structural features and antioxidant activities of Chinese quince (Chaenomeles sinensis) fruits lignin during auto-catalyzed ethanol organosolv pretreatment

Chinese quince fruits (Chaenomeles sinensis) have an abundance of lignins with antioxidant activities. To facilitate the utilization of Chinese quince fruits, lignin was isolated from it by auto-catalyzed ethanol organosolv pretreatment. The effects of three processing conditions (temperature, time, and ethanol concentration) on yield, structural features and antioxidant activities of the auto-catalyzed ethanol organosolv lignin samples were assessed individually. Results showed the pretreatment temperature was the most significant factor; it affected the molecular weight, S/G ratio, number of β-O-4′ linkages, thermal stability, and antioxidant activities of lignin samples. According to the GPC analyses, the molecular weight of lignin samples had a negative correlation with pretreatment temperature. 2D-HSQC NMR and Py-GC/MS results revealed that the S/G ratios of lignin samples increased with temperature, while total phenolic hydroxyl content of lignin samples decreased. The structural characterization clearly indicated that the various pretreatment conditions affected the structures of organosolv lignin, which further resulted in differences in the antioxidant activities of the lignin samples. These results can be helpful for controlling and optimizing delignification during auto-catalyzed ethanol organosolv pretreatment, and they provide theoretical support for the potential applications of Chinese quince fruits lignin as a natural antioxidant in the food industry.