Technological advancement in lignin recovery and valorization for sustainable and economic biorefinery developments

Prashant Katiyar; Deepshikha Kushwaha; Tirath Raj; Shailendra Kumar Srivastava; Manoj Kumawat; Reeta Rani Singhania

doi:10.1007/s43393-025-00426-4

Systems Microbiology and Biomanufacturing ›› 2026, Vol. 6 ›› Issue (2) :32 DOI: 10.1007/s43393-025-00426-4

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Technological advancement in lignin recovery and valorization for sustainable and economic biorefinery developments

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Abstract

Lignin recovery from lignocellulosic material is a prominent solution to environmental concerns and problems and establishes more sustainable and competitive lignocellulosic biorefineries. Lignin has the potential to produce various commodity chemicals, biofuels, plastics, dyes, adhesives, concrete binders, foaming agents, lubricants, and nanomaterials, and is a commitment step for a safer and sustainable circular bioeconomy development. However, lignin valorization is hindered by a series of factors, i.e., heterogeneous nature, intrinsic recalcitrance, and the presence of strong intermolecular bonding and functionalities. Most of the lignin residue generated during cellulosic or pulp industries is combusted for electricity production in an uneconomic manner. Therefore, we have critically assessed and discussed the main constraints of novel strategies concerning lignin isolation and valorization, which is widely used in the landscape of lignocellulose biomass-based biorefining to reduce the dependency on fossil reserves and indirectly impacts the circular economy and lifestyle of people. Finally, this review highlights the integrated approach linked to enzyme-to-microbe, microbe-to-microbe interactions, or modified lignin fraction via employing metabolic engineering, discusses the commercial aspects of lignin in the market, and describes the future perspectives as well. Additionally, various advanced catalytic approaches under oxidative/reductive environments and hydrodeoxygenation are well explored, illustrating their influence on the selectivity of lignin depolymerization. The article will consolidate existing knowledge but also incorporate some novel perspectives for future advancement concerning lignin valorization in a sustainable way, which is a prerequisite objective for various biorefinery developments.

Keywords

Lignin / Lignocellulose / Circular economy / Valorization / Depolymerization

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Prashant Katiyar, Deepshikha Kushwaha, Tirath Raj, Shailendra Kumar Srivastava, Manoj Kumawat, Reeta Rani Singhania. Technological advancement in lignin recovery and valorization for sustainable and economic biorefinery developments. Systems Microbiology and Biomanufacturing, 2026, 6(2): 32 DOI:10.1007/s43393-025-00426-4

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References

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[1]	Saini R, Kaur A, Saini JK, Patel AK, Varjani S, Chen CW, et al.. Trends in lignin biotransformations for bio-based products and energy applications. Bioenergy Res, 2023, 16: 88-104

[2]	Sharma V, Tsai ML, Nargotra P, Chen CW, Sun PP, Singhania RR, et al.. Journey of lignin from a roadblock to bridge for lignocellulose biorefineries: a comprehensive review. Sci Total Environ, 2023, 861 160560

[3]	Raj T, Chandrasekhar K, Kumar AN, Kim S-H. Recent biotechnological trends in lactic acid bacterial fermentation for food processing industries. Syst Microbiol Biomanuf, 2022, 2: 14-40

[4]	Hemati A, Aliasgharzad N, Khakvar R, Delangiz N, Asgari Lajayer B, van Hullebusch ED. Bioaugmentation of thermophilic lignocellulose degrading bacteria accelerate the composting process of lignocellulosic materials. Biomass Convers Biorefin, 2023, 13: 15887-15901

[5]	Mujtaba M, Fernandes Fraceto L, Fazeli M, Mukherjee S, Savassa SM, Araujo de Medeiros G, et al.. Lignocellulosic biomass from agricultural waste to the circular economy: a review with focus on biofuels, biocomposites and bioplastics. J Clean Prod, 2023, 402: 136815

[6]	Raj T, Singh V. Natural deep eutectic solvents (NADES) assisted deconstruction of oilcane bagasse for high lipid and sugar recovery. Ind Crops Prod, 2024, 210: 118127

[7]	Raj T, Kapoor M, Gaur R, Christopher J, Lamba B, Tuli DK, et al.. Physical and chemical characterization of various Indian agriculture residues for biofuels production. Energy Fuels, 2015, 29: 3111-3118

[8]	Devi A, Singh A, Bajar S, Pant D, Din ZU. Ethanol from lignocellulosic biomass: an in-depth analysis of pre-treatment methods, fermentation approaches and detoxification processes. J Environ Chem Eng, 2021, 9 105798

[9]	Tian Q, Xu P, Huang D, Wang H, Wang Z, Qin H, et al.. The driving force of biomass value-addition: selective catalytic depolymerization of lignin to high-value chemicals. J Environ Chem Eng, 2023, 3 109719

[10]	Ahmad N, Aslam S, Hussain N, Bilal M, Iqbal HMN. Transforming lignin biomass to value: interplay between ligninolytic enzymes and lignocellulose depolymerization. Bioenergy Res, 2023, 16: 1246-1263

[11]	Jacobs B, Yao Y, Van Nieuwenhove I, Sharma D, Graulus GJ, Bernaerts K, et al.. Sustainable lignin modifications and processing methods: green chemistry as the way forward. Green Chem, 2023, 25: 2042-2086

[12]	Wu X, Smet E, Brandi F, Raikwar D, Zhang Z, Maes BUW, et al.. Advancements and perspectives toward lignin valorization via O-demethylation. Angew Chem, 2024, 136 e202317257

[13]	Mankar AR, Pandey A, Modak A, Pant KK. Pretreatment of lignocellulosic biomass: a review on recent advances. Bioresour Technol, 2021, 334 125235

[14]	Korányi TI, Fridrich B, Pineda A, Barta K. Development of ‘lignin-first’ approaches for the valorization of lignocellulosic biomass. Molecules, 2020, 25: 2815

[15]	Zhou M, Tian X. Development of different pretreatments and related technologies for efficient biomass conversion of lignocellulose. Int J Biol Macromol, 2022, 202: 256-268

[16]	Sivagurunathan P, Raj T, Chauhan PS, Kumari P, Satlewal A, Gupta RP, et al.. High-titer lactic acid production from pilot-scale pretreated non-detoxified rice straw hydrolysate at high-solid loading. Biochem Eng J, 2022, 187 108668

[17]	Periyasamy S, Karthik V, Senthil Kumar P, Isabel JB, Temesgen T, Hunegnaw BM, et al.. Chemical, physical and biological methods to convert lignocellulosic waste into value-added products. A review. Environ Chem Lett, 2022, 20: 1129-1152

[18]	Gayap HT, Akhloufi MA. SALM: a unified model for 2D and 3D region of interest segmentation in lung CT scans using vision transformers. Appl Biosci, 2025, 4 11

[19]	Jędrzejczak P, Collins MN, Jesionowski T, Klapiszewski Ł. The role of lignin and lignin-based materials in sustainable construction – a comprehensive review. Int J Biol Macromol, 2021, 187: 624-650

[20]	Mikulski D, Kłosowski G. Hydrotropic pretreatment on distillery stillage for efficient cellulosic ethanol production. Bioresour Technol, 2020, 300 122661

[21]	Prasad BR, Padhi RK, Ghosh G. A review on key pretreatment approaches for lignocellulosic biomass to produce biofuel and value-added products. Int J Environ Sci Technol, 2023, 20: 6929-6944

[22]	Moretti C, Corona B, Hoefnagels R, Vural-Gürsel I, Gosselink R, Junginger M. Review of life cycle assessments of lignin and derived products: lessons learned. Sci Total Environ, 2021, 770 144656

[23]	Peng M, Nakabayashi M, Kim K, Kamiya K, Qian EW. Lignin depolymerization with alkaline ionic liquids and ethylene glycol in a continuous flow reactor. Fuel, 2023, 335 126960

[24]	Sangeetha B, Mohana Priya S, Pravin R, Tamilarasan K, Baskar G. Process optimization and technoeconomic assessment of biodiesel production by one-pot transesterification of Ricinus communis seed oil. Bioresour Technol, 2023, 376 128880

[25]	Gomes ED, Rodrigues AE. Recovery of vanillin from kraft lignin depolymerization with water as desorption eluent. Sep Purif Technol, 2020, 239 116551

[26]	Ullah M, Liu P, Xie S, Sun S. Recent advancements and challenges in lignin valorization: green routes towards sustainable bioproducts. Molecules, 2022, 27: 6055

[27]	He D, Wang Y, Yoo CG, Chen QJ, Yang Q. The fractionation of woody biomass under mild conditions using bifunctional phenol-4-sulfonic acid as a catalyst and lignin solvent. Green Chem, 2020, 22: 5414-5422

[28]	Schieppati D, Patience NA, Galli F, Dal P, Seck I, Patience GS, et al.. Chemical and biological delignification of biomass: a review. Ind Eng Chem Res, 2023, 62: 12757-12794

[29]	Abushammala H, Mao J. A review on the partial and complete dissolution and fractionation of wood and lignocelluloses using imidazolium ionic liquids. Polymers, 2020

[30]	Kim D-W, Park K-A, Kim M-J, Kang D-H, Yang J-G, Park D-W. Synthesis of glycerol carbonate from urea and glycerol using polymer-supported metal-containing ionic liquid catalysts. Appl Catal A Gen, 2014, 473: 31-40

[31]	Dong C, Meng X, Yeung CS, Tse H-Y, Ragauskas AJ, Leu S-Y. Diol pretreatment to fractionate a reactive lignin in lignocellulosic biomass biorefineries. Green Chem, 2019, 21: 2788-2800

[32]	Baruah J, Nath BK, Sharma R, Kumar S, Deka RC, Baruah DC, et al.. Recent trends in the pretreatment of lignocellulosic biomass for value-added products. Front Energy Res, 2018, 6: 141

[33]	Mandlekar N, Cayla A, Rault F, Giraud S, Salaün F, Malucelli G, et al.. An overview on the use of lignin and its derivatives in fire retardant polymer systems. Lignin Trends Appl, 2018, 9: 207-231

[34]	Domínguez-Robles J, Tamminen T, Liitiä T, Peresin MS, Rodríguez A, Jääskeläinen A-S. Aqueous acetone fractionation of kraft, organosolv and soda lignins. Int J Biol Macromol, 2018, 106: 979-987

[35]	Wang Z, Zhu X, Deuss PJ. The effect of ball milling on birch, pine, reed, walnut shell enzymatic hydrolysis recalcitrance and the structure of the isolated residual enzyme lignin. Ind Crops Prod, 2021, 167 113493

[36]	González-Gloria KD, et al.. Scale-up of hydrothermal processing: Liquid hot water and pilot-scale tubular steam explosion batch reactor for bioethanol production using macroalgae Sargassum spp. biomass. Bioresour Technol, 2023, 369: 128448

[37]	Da Silva ASA, Espinheira RP, Teixeira RSS, De Souza MF, Ferreira-Leitão V, Bon EPS. Constraints and advances in high-solids enzymatic hydrolysis of lignocellulosic biomass: a critical review. Biotechnol Biofuels, 2020, 13 58

[38]	Martín C, Dixit P, Momayez F, Jönsson LJ. Hydrothermal pretreatment of lignocellulosic feedstocks to facilitate biochemical conversion. Front Bioeng Biotechnol, 2022, 10 846592

[39]	Ruiz-Aceituno L, Sanz ML, Ramos L. Use of ionic liquids in analytical sample preparation of organic compounds from food and environmental samples. TrAC Trends Anal Chem, 2013, 43: 121-145

[40]	Ruiz HA, Galbe M, Garrote G, Ramirez-Gutierrez DM, Ximenes E, Sun SN, et al.. Severity factor kinetic model as a strategic parameter of hydrothermal processing (steam explosion and liquid hot water) for biomass fractionation under biorefinery concept. Bioresour Technol, 2021, 342: 12596

[41]	Shorey R, Salaghi A, Fatehi P, Mekonnen TH. Valorization of lignin for advanced material applications: a review. RSC Sustain, 2024, 2: 804-831

[42]	Nguyen TT, Bui XT, Ngo HH, Nguyen TTD, Nguyen KQ, Nguyen HH, et al.. Nutrient recovery and microalgae biomass production from urine by membrane photobioreactor at low biomass retention times. Sci Total Environ, 2021

[43]	Talebi Amiri M, Dick GR, Questell-Santiago YM, Luterbacher JS. Fractionation of lignocellulosic biomass to produce uncondensed aldehyde-stabilized lignin. Nat Protoc, 2019, 14: 921-954

[44]	Radhika NL, Sachdeva S, Kumar M. Lignin depolymerization and biotransformation to industrially important chemicals/biofuels. Fuel, 2022, 312 122935

[45]	Huang J, Xia T, Li A, Yu B, Li Q, Tu Y, et al.. A rapid and consistent near infrared spectroscopic assay for biomass enzymatic digestibility upon various physical and chemical pretreatments in Miscanthus. Bioresour Technol, 2012, 121: 274-281

[46]	Khan MU, Ahring BK. Lignin degradation under anaerobic digestion: influence of lignin modifications—a review. Biomass Bioenergy, 2019, 128 105325

[47]	Aguilar-Reynosa A, Romaní A, Ma. Rodríguez-Jasso R, Aguilar CN, Garrote G, Ruiz HA. Microwave heating processing as alternative of pretreatment in second-generation biorefinery: an overview. Energy Convers Manag, 2017, 136: 50-65

[48]	Rana M, Nshizirungu T, Park JH. Effect of simultaneous use of microwave and ultrasound irradiation on the sulfuric acid hydrolysis lignin (SAHL) depolymerization. Sustain Energy Fuels, 2022, 6: 861-878

[49]	Bundhoo ZMA, Mohee R. Ultrasound-assisted biological conversion of biomass and waste materials to biofuels: a review. Ultrason Sonochem, 2018, 40: 298-313

[50]	Oriez V, Peydecastaing J, Pontalier PY. Lignocellulosic biomass fractionation by mineral acids and resulting extract purification processes: conditions, yields, and purities. Molecules, 2019, 24: 4273

[51]	Khalaji M, Hosseini SA, Ghorbani R, Agh N, Rezaei H, Kornaros M, et al.. Treatment of dairy wastewater by microalgae Chlorella vulgaris for biofuels production. Biomass Convers Biorefin, 2023, 13: 3259-3265

[52]	Duque A, Manzanares P, Ballesteros M. Extrusion as a pretreatment for lignocellulosic biomass: fundamentals and applications. Renew Energy, 2017, 114: 1427-1441

[53]	Osorio-González CS, Hegde K, Brar SK, Vezina P, Gilbert D, Avalos-Ramírez A. Pulsed-ozonolysis assisted oxidative treatment of forestry biomass for lignin fractionation. Bioresour Technol, 2020, 313 123638

[54]	Roy R, Rahman MS, Raynie DE. Recent advances of greener pretreatment technologies of lignocellulose. Current Res Green Sustain Chem, 2020, 3 100035

[55]	Han T, Yang W, Jönsson PG. Pyrolysis and subsequent steam gasification of metal dry impregnated lignin for the production of H2-rich syngas and magnetic activated carbon. Chem Eng J, 2020, 394 124902

[56]	Borand MN, Karaosmanoǧlu F. Effects of organosolv pretreatment conditions for lignocellulosic biomass in biorefinery applications: a review. J Renew Sustain Energy, 2018, 10: 033104

[57]	Kumar A, Chandra R. Ligninolytic enzymes and its mechanisms for degradation of lignocellulosic waste in environment. Heliyon, 2020

[58]	Weiss R, Guebitz GM, Pellis A, Nyanhongo GS. Harnessing the power of enzymes for tailoring and valorizing lignin. Trends Biotechnol, 2020, 38: 1215-1231

[59]	Zhang Q. Waste to biohydrogen: progress, challenges, and prospects. Waste Renew Biohydrogen, 2021, 1: 55-70

[60]	Wong SS, Shu R, Zhang J, Liu H, Yan N. Downstream processing of lignin derived feedstock into end products. Chem Soc Rev, 2020, 49: 5510-5560

[61]	Hermosilla E, Rubilar O, Schalchli H, da Silva ASA, Ferreira-Leitao V, Diez MC. Sequential white-rot and brown-rot fungal pretreatment of wheat straw as a promising alternative for complementary mild treatments. Waste Manag, 2018, 79: 240-250

[62]	Giri R, Sharma RK. Fungal pretreatment of lignocellulosic biomass for the production of plant hormone by Pichia fermentans under submerged conditions. Bioresour Bioprocess, 2020, 7: 30

[63]

Srivastava N, Singh R, Srivastava M, Syed A, Bahadur Pal D, Bahkali AH, et al.. Impact of mixed lignocellulosic substrate and fungal consortia to enhance cellulase production and its application in NiFe2O4 nanoparticles mediated enzymatic hydrolysis of wheat straw. Bioresour Technol, 2022, 345 126560

[64]	Nurika I, Shabrina EN, Azizah N, Suhartini S, Bugg TDH, Barker GC. Application of ligninolytic bacteria to the enhancement of lignocellulose breakdown and methane production from oil palm empty fruit bunches (OPEFB). Bioresour Technol Rep, 2022, 17 100951

[65]	Usman Khan M, Kiaer Ahring B. Anaerobic digestion of biorefinery lignin: effect of different wet explosion pretreatment conditions. Bioresour Technol, 2020, 298 122537

[66]	Zhang A, Shen J, Ni Y (2015) Anaerobic digestion for use in the pulp and paper industry and other sectors: an introductory mini-review. Bioresources. 10:. https://doi.org/10.15376/biores.10.4.zhang

[67]	Gievers F, Walz M, Loewe K, Bienert C, Loewen A. Anaerobic co-digestion of paper sludge: feasibility of additional methane generation in mechanical–biological treatment plants. Waste Manag, 2022, 144: 502-512

[68]	Grgas D, Rukavina M, Bešlo D, Štefanac T, Crnek V, Šikić T, et al.. The bacterial degradation of lignin—a review. Water, 2023

[69]	Zhao B, Liu R, Guo Q, Xu G, Zhang L, Sun P, et al.. The use of newly isolated fungal cultures for the selective delignification of bamboo culms. Front Bioeng Biotechnol, 2023, 11: 1265420

[70]	Bugg TDH, Williamson JJ, Alberti F. Microbial hosts for metabolic engineering of lignin bioconversion to renewable chemicals. Renew Sustain Energy Rev, 2021, 152 111674

[71]	Zhao L, Zhang J, Zhao D, Jia L, Qin B, Cao X, et al.. Biological degradation of lignin: a critical review on progress and perspectives. Ind Crops Prod, 2022, 188 115715

[72]	Gu J, Qiu Q, Yu Y, Sun X, Tian K, Chang M, et al.. Bacterial transformation of lignin: key enzymes and high-value products. Biotechnol Biofuels Bioprod, 2024, 17 2

[73]	Mussatto SI. Biomass fractionation technologies for a lignocellulosic feedstock based biorefinery. Biomass Fract Technol Lignocellul Feedstock Based Biorefinery, 2016

[74]	Sahoo D, Ummalyma SB, Okram AK, Pandey A, Sankar M, Sukumaran RK. Effect of dilute acid pretreatment of wild rice grass (Zizania latifolia) from Loktak Lake for enzymatic hydrolysis. Bioresour Technol, 2018, 253: 252-255

[75]	Wong DWS. Structure and action mechanism of ligninolytic enzymes. Appl Biochem Biotechnol, 2009, 157: 174-209

[76]	Sun Z, Fridrich B, De Santi A, Elangovan S, Barta K. Bright side of lignin depolymerization: toward new platform chemicals. Chem Rev, 2018, 118: 614-678

[77]	Liu H, Zhu L, Wallraf AM, Räuber C, Grande PM, Anders N, et al.. Depolymerization of laccase-oxidized lignin in aqueous alkaline solution at 37° C. ACS Sustain Chem Eng, 2019, 7: 11150-11156

[78]	Collins MN, Nechifor M, Tanasă F, Zănoagă M, McLoughlin A, Stróżyk MA, et al.. Valorization of lignin in polymer and composite systems for advanced engineering applications—a review. Int J Biol Macromol, 2019, 131: 828-849

[79]	Rencoret J, Gutiérrez A, Nieto L, Jiménez-Barbero J, Faulds CB, Kim H, et al.. Lignin composition and structure in young versus adult eucalyptus globulus plants. Plant Physiol, 2011, 155: 667-682

[80]	Wei XZ, Liu J, Ma L. Cleavage via selective catalytic oxidation of lignin or lignin model compounds into functional chemicals. ChemEng, 2021, 5: 74

[81]	Yu X, Wei Z, Lu Z, Pei H, Wang H. Activation of lignin by selective oxidation: an emerging strategy for boosting lignin depolymerization to aromatics. Bioresour Technol, 2019, 291 121885

[82]	Kumar A, Arora PK. Biotechnological applications of manganese peroxidases for sustainable management. Front Environ Sci, 2022, 10 875157

[83]	Millati R, Wikandari R, Ariyanto T, Putri RU, Taherzadeh MJ. Pretreatment technologies for anaerobic digestion of lignocelluloses and toxic feedstocks. Bioresour Technol, 2020, 304 122998

[84]	Chaher NEH, Engler N, Nassour A, Nelles M. Effects of co-substrates’ mixing ratios and loading rate variations on food and agricultural wastes’ anaerobic co-digestion performance. Biomass Convers Biorefin, 2023, 13: 7051-7066

[85]	Vidal-Espinosa PS, Alvarez-Vera M, Cárdenas A, Cobos-Torres JC. Beneficial microorganisms in the anaerobic digestion of cattle and swine excreta. Sustainability, 2023, 15 6482

[86]	Li Z, Chen Z, Ye H, Wang Y, Luo W, Chang J-S, et al.. Anaerobic co-digestion of sewage sludge and food waste for hydrogen and VFA production with microbial community analysis. Waste Manag, 2018, 78: 789-799

[87]	Uddin MM, Wright MM. Anaerobic digestion fundamentals, challenges, and technological advances. Phys Sci Rev, 2023, 8: 2819-2837

[88]	Janusz G, Pawlik A, Sulej J, Świderska-Burek U, Jarosz-Wilkolazka A, Paszczyński A. Lignin degradation: microorganisms, enzymes involved, genomes analysis and evolution. FEMS Microbiol Rev, 2017, 41: 941-962

[89]	Usmani Z, Sharma M, Awasthi AK, Lukk T, Tuohy MG, Gong L, et al.. Lignocellulosic biorefineries: the current state of challenges and strategies for efficient commercialization. Renew Sustain Energy Rev, 2021, 148 111258

[90]	Jaiswal DK, Verma JP, Belwal T, Pereira APDA, Ade AB. Editorial: microbial co-cultures: a new era of synthetic biology and metabolic engineering. Front Microbiol, 2023, 14: 1235565

[91]	Wang S, Bai J, Innocent MT, Wang Q, Xiang H, Tang J, et al.. Lignin-based carbon fibers: formation, modification and potential applications. Green Energy Environ, 2022, 7: 578-605

[92]	Liu Y, Tang Y, Gao H, Zhang W, Jiang Y, Xin F, et al.. Challenges and future perspectives of promising biotechnologies for lignocellulosic biorefinery. Molecules, 2021, 26: 5411

[93]	Singh N, Singhania RR, Nigam PS, Dong CD, Patel AK, Puri M. Global status of lignocellulosic biorefinery: challenges and perspectives. Bioresour Technol, 2022, 344 126415

[94]	Lama S, Thapa LP, Upadhayaya SK, Gauchan DP, Singh A. Metabolic engineering in lignocellulose biorefining for high-value chemicals: recent advances, challenges, and outlook for enabling a bioeconomy. Front Ind Microbiol, 2024, 1: 1319774

[95]	Lu H, Yadav V, Zhong M, Bilal M, Taherzadeh MJ, Iqbal HMN. Bioengineered microbial platforms for biomass-derived biofuel production – a review. Chemosphere, 2022, 288 132528

[96]	Ben Tahar I, Fickers P. Metabolic engineering of microorganisms for urban waste valorization. Case Stud Chem Environ Eng, 2021, 4 100148

[97]	Maleki F, Changizian M, Zolfaghari N, Rajaei S, Noghabi KA, Zahiri HS. Consolidated bioprocessing for bioethanol production by metabolically engineered Bacillus subtilis strains. Sci Rep, 2021, 11 13731

[98]	Jiang S, Si T, Dai J. Whole-genome regulation for yeast metabolic engineering. Small Methods, 2020, 4 1900640

[99]	Jiang J, Carrillo-Enríquez NC, Oguzlu H, Han X, Bi R, Saddler JN, et al.. Acidic deep eutectic solvent assisted isolation of lignin containing nanocellulose from thermomechanical pulp. Carbohydr Polym, 2020, 247 116727

[100]

Yang K, Qiao Y, Li F, Xu Y, Yan Y, Madzak C, et al.. Subcellular engineering of lipase dependent pathways directed towards lipid related organelles for highly effectively compartmentalized biosynthesis of triacylglycerol derived products in Yarrowia lipolytica. Metab Eng, 2019, 55: 231-238

[101]

Qiao K, Wasylenko TM, Zhou K, Xu P, Stephanopoulos G. Lipid production in Yarrowia lipolytica is maximized by engineering cytosolic redox metabolism. Nat Biotechnol, 2017, 35: 173-177

[102]

Xue J, Balamurugan S, Li T, Cai JX, Chen TT, Wang X, et al.. Biotechnological approaches to enhance biofuel producing potential of microalgae. Fuel, 2021, 302 121169

[103]

Sarwer A, Hamed SM, Osman AI, Jamil F, Al-Muhtaseb AH, Alhajeri NS, et al.. Algal biomass valorization for biofuel production and carbon sequestration: a review. Environ Chem Lett, 2022, 20: 2797-2851

[104]

Liu ZH, Le RK, Kosa M, Yang B, Yuan J, Ragauskas AJ. Identifying and creating pathways to improve biological lignin valorization. Renew Sustain Energy Rev, 2019, 105: 349-362

[105]

Erickson E, Bleem A, Kuatsjah E, Werner AZ, DuBois JL, McGeehan JE, et al.. Critical enzyme reactions in aromatic catabolism for microbial lignin conversion. Nat Catal, 2022

[106]

Weiland F, Kohlstedt M, Wittmann C. Guiding stars to the field of dreams: metabolically engineered pathways and microbial platforms for a sustainable lignin-based industry. Metab Eng, 2022, 71 6055

[107]

Lee S, Kang M, Bae JH, Sohn JH, Sung BH. Bacterial valorization of lignin: strains, enzymes, conversion pathways, biosensors, and perspectives. Front Bioeng Biotechnol, 2019

[108]

Tsegaye B, Balomajumder C, Roy P. Microbial delignification and hydrolysis of lignocellulosic biomass to enhance biofuel production: an overview and future prospect. Bull Natl Res Cent, 2019

[109]

Numata K, Morisaki K. Screening of marine bacteria to synthesize polyhydroxyalkanoate from lignin: contribution of lignin derivatives to biosynthesis by Oceanimonas doudoroffii. ACS Sustain Chem Eng, 2015, 3: 569-573

[110]

Moraes EC, Alvarez TM, Persinoti GF, Tomazetto G, Brenelli LB, Paixão DAA, et al.. Lignolytic-consortium omics analyses reveal novel genomes and pathways involved in lignin modification and valorization. Biotechnol Biofuels, 2018, 11: 75

[111]

Pepper JM, Baylis PET, Adler E. The isolation and properties of lignins obtained by the acidolysis of spruce and aspen woods in dioxane–water medium. Can J Chem, 1959

[112]

Wang Z, Liu Y, Barta K, Deuss PJ. The effect of acidic ternary deep eutectic solvent treatment on native lignin. ACS Sustain Chem Eng, 2022, 10: 12569-12579

[113]

Pals M, Lauberts M, Zijlstra DS, Ponomarenko J, Arshanitsa A, Deuss PJ. Mild organosolv delignification of residual Aspen bark after extractives isolation as a step in biorefinery processing schemes. Molecules, 2022, 27: 3185

[114]

Zijlstra DS, Lahive CW, Analbers CA, Figueirêdo MB, Wang Z, Lancefield CS, et al.. Mild organosolv lignin extraction with alcohols: the importance of benzylic alkoxylation. ACS Sustain Chem Eng, 2020, 8: 5119-5131

[115]

Luterbacher JS, Azarpira A, Motagamwala AH, Lu F, Ralph J, Dumesic JA. Lignin monomer production integrated into the γ-valerolactone sugar platform. Energy Environ Sci, 2015, 8: 2657-2663

[116]

Timokhin VI, Regner M, Motagamwala AH, Sener C, Karlen SD, Dumesic JA, et al.. Production of p-Coumaric acid from corn GVL-Lignin. ACS Sustain Chem Eng, 2020, 8: 17427-17438

[117]

Li MF, Sun SN, Xu F, Sun RC. Formic acid based organosolv pulping of bamboo (Phyllostachys acuta): comparative characterization of the dissolved lignins with milled wood lignin. Chem Eng J, 2012, 179: 80-89

[118]

Lancefield CS, Panovic I, Deuss PJ, Barta K, Westwood NJ. Pre-treatment of lignocellulosic feedstocks using biorenewable alcohols: towards complete biomass valorisation. Green Chem, 2017, 19: 202-214

[119]

Liu Y, Deak N, Wang Z, Yu H, Hameleers L, Jurak E, et al.. Tunable and functional deep eutectic solvents for lignocellulose valorization. Nat Commun, 2021, 12 5424

[120]

Chen WJ, Zhao BC, Cao XF, Yuan TQ, Shi Q, Wang SF, et al.. Structural features of alkaline dioxane lignin and residual lignin from Eucalyptus grandis × E. urophylla. J Agric Food Chem, 2019, 67: 968-974

[121]

Lin KT, Wang C, Guo MF, Aprà E, Ma R, Ragauskas AJ, et al.. Lignin with controlled structural properties by N-heterocycle-based deep eutectic solvent extraction. Proc Natl Acad Sci U S A, 2023, 120 e2307323120

[122]

Yang J, Zhang W, Tang Y, Li M, Peng F, Bian J. Mild pretreatment with Brønsted acidic deep eutectic solvents for fractionating β–O–4 linkage-rich lignin with high sunscreen performance and evaluation of enzymatic saccharification synergism. Bioresour Technol, 2023

[123]

Katiyar P, Srivastava S, Tyagi V. Measurement of cellulolytic potential of cellulase producing bacteria. Ann Res Rev Biol, 2018

[124]

Nielsen JB, Jensen A, Madsen LR, Larsen FH, Felby C, Jensen AD. Noncatalytic direct liquefaction of biorefinery lignin by ethanol. Energy Fuels, 2017, 31: 7223-7233

[125]

Gao Z, Lang X, Chen S, Zhao C. Mini-review on the synthesis of lignin-based phenolic resin. Energy Fuels, 2021, 35: 18385-18395

[126]

Xu C, Ferdosian F (2017) Conversion of lignin into bio-based chemicals and materials. Green Chemistry and Sustainable Technology. Published: 05 June 2017.

[127]

Lan W, Amiri MT, Hunston CM, Luterbacher JS. Protection group effects during α, γ-diol lignin stabilization promote high-selectivity monomer production. Angew Chem, 2018, 130: 1370-1374

[128]

Koller M, Sandholzer D, Salerno A, Braunegg G, Narodoslawsky M. Biopolymer from industrial residues: life cycle assessment of poly (hydroxyalkanoates) from whey. Resour Conserv Recycl, 2013, 73: 64-71

[129]

Fazeli M, Mukherjee S, Baniasadi H, Abidnejad R, Mujtaba M, Lipponen J, et al.. Lignin beyond the status quo: recent and emerging composite applications. Green Chem, 2024, 26: 593-630

[130]

Sun Z, Cheng J, Wang D, Yuan TQ, Song G, Barta K. Downstream processing strategies for lignin-first biorefinery. Chemsuschem, 2020, 13: 5199-5212

[131]

Wu T, Li X, Ma X, Ye J, Shen L, Tan W. Modification of lignin by hexamethylene diisocyanate to synthesize lignin-based polyurethane as an organic polymer for marine polyurethane anticorrosive coatings. Mater Res Express, 2022, 9 105302

[132]

Qi G, Yang W, Puglia D, Wang H, Xu P, Dong W, et al.. Hydrophobic, UV resistant and dielectric polyurethane-nanolignin composites with good reprocessability. Mater Des, 2020, 196 109150

[133]

Biswas B, Kumar A, Kaur R, Krishna BB, Bhaskar T. Catalytic hydrothermal liquefaction of alkali lignin over activated bio-char supported bimetallic catalyst. Bioresour Technol, 2021, 337 125439

[134]

Kohlstedt M, Starck S, Barton N, Stolzenberger J, Selzer M, Mehlmann K, et al.. From lignin to nylon: cascaded chemical and biochemical conversion using metabolically engineered Pseudomonas putida. Metab Eng, 2018, 47: 279-293

[135]

Wang Z, Li N, Pan X. Transformation of ammonia fiber expansion (AFEX) corn stover lignin into microbial lipids by Rhodococcus opacus. Fuel, 2019, 240: 119-125

[136]

Liu H, Li H, Luo N, Wang F. Visible-light-induced oxidative lignin c-c bond cleavage to aldehydes using vanadium catalysts. ACS Catal, 2020, 10: 632-643

[137]

Shuai L, Sitison J, Sadula S, Ding J, Thies MC, Saha B. Selective C-C bond cleavage of methylene-linked lignin models and Kraft lignin. ACS Catal, 2018, 8: 6507-6512

[138]

Dong L, Lin L, Han X, Si X, Liu X, Guo Y, et al.. Breaking the limit of lignin monomer production via cleavage of interunit carbon–carbon linkages. Chem, 2019, 5: 1521-1536

[139]

Shen X, Meng Q, Mei Q, Liu H, Yan J, Song J, et al.. Selective catalytic transformation of lignin with guaiacol as the only liquid product. Chem Sci, 2020, 11: 1347-1352

[140]

Sun Z, Cheng J, Wang D, Yuan T, Song G, Barta K. Downstream processing strategies for Lignin‐first biorefinery. Chemsuschem, 2020, 13: 5199-5212

[141]

Shen Z, Shi C, Liu F, Wang W, Ai M, Huang Z, et al.. Advances in heterogeneous catalysts for lignin hydrogenolysis. Adv Sci, 2024, 11: 2306693

[142]

Kumar N, Taylor BR, Chourasia V, Rodriguez A, Gladden JM, Simmons BA, et al.. Multi-scale computational screening and mechanistic insights of cyclic amines as solvents for improved lignocellulosic biomass processing. Green Chem, 2025, 27: 5482-5497

[143]

Jha AK, Martinez DV, Salinas JE, Martinez EJ, Davis RD, Rodriguez A, et al.. Deconstruction of carbon-carbon bonded polymers for biological conversion through COOH-functionalization and Fenton chemistry. Polym Degrad Stab, 2025, 231 111081

[144]

Bourbiaux D, Pu J, Rataboul F, Djakovitch L, Geantet C, Laurenti D. Reductive or oxidative catalytic lignin depolymerization: an overview of recent advances. Catal Today, 2021, 373: 24-37

[145]

Kumar A, Biswas B, Kaur R, Krishna BB, Thallada B. Oxidative valorisation of lignin into valuable phenolics: effect of acidic and basic catalysts and reaction parameters. Bioresour Technol, 2021, 338 125513

[146]

Kong L, Liu C, Gao J, Wang Y, Dai L. Efficient and controllable alcoholysis of Kraft lignin catalyzed by porous zeolite-supported nickel-copper catalyst. Bioresour Technol, 2019, 276: 310-317

[147]

Pu J, Laurenti D, Geantet C, Tayakout-Fayolle M, Pitault I. Kinetic modeling of lignin catalytic hydroconversion in a semi-batch reactor. Chem Eng J, 2020, 386 122067

[148]

Schneider I, Kebelmann K, Risse S, Dieguez-Alonso A, Schartel B, Strecker C, et al.. Hydroliquefaction of two Kraft lignins in a semibatch setup under process conditions applicable for large-scale biofuel production. Energy Fuels, 2019, 33: 11057-11066

[149]

Martinez DV, Rodriguez A, Choudhary H, Salinas J, Martinez EJ, Davydovich O, et al.. Deconstructing poplar lignin from ionic liquid pretreatment for biological conversion through sulfonation and Fenton chemistry. RSC Sustain, 2025, 3: 1721-1728

[150]

Zhang X, Zhang Q, Long J, Xu Y, Wang T, Ma L, et al.. Phenolics production through catalytic depolymerization of alkali lignin with metal chlorides. BioResources, 2014, 9: 3347

[151]

Wang R, Zhao S, Wang Z, Koffas MA. Recent advances in modular co-culture engineering for synthesis of natural products. Curr Opin Biotechnol, 2020, 62: 65-71

[152]

Wang X, Rinaldi R. Bifunctional Ni catalysts for the one-pot conversion of Organosolv lignin into cycloalkanes. Catal Today, 2016, 269: 48-55

[153]

Santos MCB, Barouh N, Baréa B, Villeneuve P, Bourlieu-Lacanal C, Ferreira MSL, et al.. Sequential one-pot NaDES assisted extraction and biotransformation of rice bran: a new strategy to boost antioxidant activity of natural extracts. Process Biochem, 2022, 117: 110-116

[154]

Fanali C, Gallo V, Posta SD, Dugo L, Mazzeo L, Cocchi M, et al.. Choline chloride–lactic acid-based NADES as an extraction medium in a response surface methodology-optimized method for the extraction of phenolic compounds from hazelnut skin. Molecules, 2021, 26 2652

[155]

Aggarwal G, Singh PP, Gupta MK, Sharma U. NADES-based essential oil extraction and isolation of new epoxysesquiterpene from Ageratina adenophora flowers. J Mol Struct, 2023, 1292 136077

[156]

Raj T, Singh V. Natural deep eutectic solvents (NADES) assisted deconstruction of oilcane bagasse for high lipid and sugar recovery. Ind Crops Prod, 2024, 210 118127

[157]

Raj T, Singh V. Integrated green biorefinery for the production of anthocyanins, fermentable sugars, and high pure lignin from Miscanthus × giganteus. Adv Energy Sustain Res, 2025

[158]

Raj T, Dien BS, Singh V. Process strategies for recovery of sugars, lipids, and lignin from oilcane bagasse using natural deep eutectic solvents (NADES). Chem Eng J, 2024, 493 152657

[159]

Xiao H, Goundry WRF, Griffiths R, Feng Y, Karlsson S. Recovery and reuse of homogeneous palladium catalysts via organic solvent nanofiltration: application in the synthesis of AZD4625. Green Chem, 2025, 27: 3186-3196

[160]

Singh K, Mehra S, Kumar A. Recent advances in catalytic conversion of lignin to value-added chemicals using ionic liquids and deep eutectic solvents: a critical review. Green Chem, 2023, 26: 1062-1091

[161]

Qiu S, Wu Z, Liu X, Liu P, Jiang Z, Xie M, et al.. Selective catalytic depolymerization of lignin to targeted phenolic monomers using noble metals supported on MgAl2O4without external hydrogen. J Agric Food Chem, 2025, 73: 22540-22553

[162]

Tang C, Cao Y, Gao J, Luo G, Fan J, Clark JH, et al.. Oxidative catalytic depolymerization of lignin into value-added monophenols by carbon nanotube-supported Cu-based catalysts. Molecules, 2024, 29: 4762

[163]

Park JH, Rana HH, Lee JY, Park HS. Renewable flexible supercapacitors based on all-lignin-based hydrogel electrolytes and nanofiber electrodes. J Mater Chem A, 2019, 7: 16962-16968

[164]

Canales RI, Brennecke JF. Comparison of ionic liquids to conventional organic solvents for extraction of aromatics from aliphatics. J Chem Eng Data, 2016, 61: 1685-1699