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Nyhan L, Sahin AW, Schmitz HH, Siegel JB, Arendt EK. 2023. Brewers' spent grain: an unprecedented opportunity to develop sustainable plant-based nutrition ingredients addressing global malnutrition challenges. Journal of Agricultural and Food Chemistry 71:10543−10564

de Paula M, Latorres JM, Martins VG. 2023. Potential valorization opportunities for Brewer's spent grain. European Food Research and Technology 249:2471−2483

Allegretti C, Bellinetto E, D'Arrigo P, Griffini G, Marzorati S, et al. 2022. Towards a complete exploitation of brewers' spent grain from a circular economy perspective. Fermentation 8:151

Bachmann SAL, Calvete T, Féris LA. 2022. Potential applications of brewery spent grain: critical an overview. Journal of Environmental Chemical Engineering 10:106951

Zheng Y, Wang Z, Huang Y, Wang H, Xiao Q, et al. 2024. Extraction and preparation of cellulose nanocrystal from Brewer's spent grain and application in Pickering emulsions. Bioactive Carbohydrates and Dietary Fibre 31:100418

Kaur N, Pandey S, Bhushan K. 2025. Recent developments in extraction, molecular characterization, bioactivity, and application of brewers spent grain arabinoxylans. Journal of Food Science 90:e70239

Liu L, Chen M, Coldea TE, Yang H, Zhao H. 2023. Emulsifying properties of arabinoxylans derived from brewers' spent grain by ultrasound-assisted extraction: structural and functional properties correlation. Cellulose 30:359−372

Bazsefidpar N, Ahmadi Gavlighi H, Ghandehari Yazdi AP, Jafari SM. 2024. Optimization of protein extraction from brewer's spent grain and production of bioactive peptides. Biomass Conversion and Biorefinery 14:17455−17465

Mikkelsen RK, Queiroz LS, Gregersen Echers S, Hobley TJ, Overgaard MT, et al. 2025. Extracting proteins from brewers' spent grain using emerging technologies: evaluating efficiency and use as emulsifier. Sustainable Food Proteins 3:e70016

Santos LG, de Paula M, Gomes BM, Latorres JM, Martins VG. 2025. High-power ultrasound as a trigger for extraction of proteins from brewery waste: optimization and techno-functional properties. Biomass Conversion and Biorefinery 15:14113−14122

Loushigam G, Shanmugam A. 2023. Modifications to functional and biological properties of proteins of cowpea pulse crop by ultrasound-assisted extraction. Ultrasonics Sonochemistry 97:106448

Czubaszek A, Wojciechowicz-Budzisz A, Spychaj R, Kawa-Rygielska J. 2022. Effect of added brewer's spent grain on the baking value of flour and the quality of wheat bread. Molecules 27:1624

Nicolai M, Palma ML, Reis R, Amaro R, Fernandes J, et al. 2025. Assessing the potential of brewer's spent grain to enhance cookie physicochemical and nutritional profiles. Foods 14:95

Cuomo F, Trivisonno MC, Iacovino S, Messia MC, Marconi E. 2022. Sustainable re-use of brewer's spent grain for the production of high protein and fibre pasta. Foods 11:642

Mastanjević K, Perković I, Škrivanko M, Kovačević D, Biondić H, et al. 2023. Effect of the addition of brewers' spent grain (BSG) on the physicochemical and consumer liking attributes of Croatian indigenous cooked sausage "bijela krvavica. Applied Sciences 13:13049

Błaszak B, Demir İE, Długosz A, Kołaczyk P, Bąk M, et al. 2025. Sustainable processing of brewers’ spent grain for plant-based yogurt alternatives. Sustainability 17:4087

Wang Y, Ai C, Wang H, Chen C, Teng H, et al. 2023. Emulsion and its application in the food field: an update review. eFood 4:e102

Ragonese VE, Moscoso Ospina YA, Cabezas DM, Kakisu EJ. 2024. Effect of ultrasound treatment on the composition and emulsifying properties of quinoa okara. International Journal of Food Science and Technology 59:1481−1489

Montellano Duran N, Spelzini D, Wayllace N, Boeris V, Barroso da Silva FL. 2018. A combined experimental and molecular simulation study of factors influencing interaction of quinoa proteins–carrageenan. International Journal of Biological Macromolecules 107:949−956

Lingiardi N, Galante M, Spelzini D. 2024. Development of bioactive quinoa protein hydrolysate-based emulsion gels: evaluation of their antioxidant and rheological properties. Food Biophysics 20:3

Rosti ME, Takagi S. 2021. Shear-thinning and shear-thickening emulsions in shear flows. Physics of Fluids 33:083319

Red de Seguridad Alimentaria (RSA). 2021. Informe final: recomendaciones para la inclusión del bagazo seco en el código alimentario argentino (CAA). CONICET, Argentina. pp. 1−9 https://alimentosargentinos.magyp.gob.ar/HomeAlimentos/marco-normativo/documentos/Monitor_Bagazo.pdf

Kumari B, Tiwari BK, Walsh D, Griffin TP, Islam N, et al. 2019. Impact of pulsed electric field pre-treatment on nutritional and polyphenolic contents and bioactivities of light and dark brewer's spent grains. Innovative Food Science & Emerging Technologies 54:200−210

da Rosa Almeida A, Geraldo MRF, Ribeiro LF, Silva MV, De Oliveira Brisola Maciel MV, et al. 2017. Bioactive compounds from brewer's spent grain: phenolic compounds, fatty acids and in vitro antioxidant capacity. Acta Scientiarum Technology 39:269−277

Bonifácio-Lopes T, Vilas Boas AA, Coscueta ER, Costa EM, Silva S, et al. 2020. Bioactive extracts from brewer's spent grain. Food & Function 11:8963−8977

Chin YL, Dinani ST, Chen WN, Boom R. 2024. The emulsifying performance of brewers' spent grains treated by colloid milling. Innovative Food Science & Emerging Technologies 91:103541

Olivares-Galván S, Marina ML, García MC. 2022. Extraction of valuable compounds from brewing residues: malt rootlets. spent hops, and spent yeast. Trends in Food Science & Technology 127:181−197

Niemi P, Tamminen T, Smeds A, Viljanen K, Ohra-aho T, et al. 2012. Characterization of lipids and lignans in brewer's spent grain and its enzymatically extracted fraction. Journal of Agricultural and Food Chemistry 60:9910−9917

Li H, Zhang X, Zhao C, Zhang H, Chi Y, et al. 2022. Entrapment of curcumin in soy protein isolate using the pH-driven method: nanoencapsulation and formation mechanism. LWT 153:112480

Li Q, Li W, Li L, Zong X, Coldea TE, et al. 2023. Enhancing the foaming properties of brewer's spent grain protein by ultrasound treatment and glycation reaction. Food & Function 14:2781−2792

Shokri S, Javanmardi F, Mohammadi M, Mousavi Khaneghah A. 2022. Effects of ultrasound on the techno-functional properties of milk proteins: a systematic review. Ultrasonics Sonochemistry 83:105938

Li W, Jiao B, Li S, Faisal S, Shi A, et al. 2022. Recent advances on Pickering emulsions stabilized by diverse edible particles: stability mechanism and applications. Frontiers in Nutrition 9:864943

Wang W, Wang R, Yao J, Luo S, Wang X, et al. 2022. Effect of ultrasonic power on the emulsion stability of rice bran protein-chlorogenic acid emulsion. Ultrasonics Sonochemistry 84:105959

Li N, Zhang X, Zhu J, Li Y, Liu R, et al. 2024. Optimization and preparation of ultrasound-treated whey protein isolate Pickering emulsions. Foods 13:3252

Cheng T, Zhang G, Sun F, Guo Y, Ramakrishna R, et al. 2024. Study on stabilized mechanism of high internal phase Pickering emulsions based on commercial yeast proteins: modulating the characteristics of Pickering particle via sonication. Ultrasonics Sonochemistry 104:106843

Muiz A, Klojdová I, Stathopoulos C. 2023. Utilization of by-products for preparation of Pickering particles. European Food Research and Technology 249:3069−3083

Klosowski AB, Riccio BVF, de Castro Pereira K, Balado MGP, Lopes AC, et al. 2025. Starch nanoparticles with brewers' spent grain extract as stabilizers for Pickering emulsions: a biodegradable and sustainable alternative for natural cosmetics. Observatório de la Economía Latinoamericana 23:e9711

Tian Y, Sun F, Wang Z, Yuan C, Wang Z, et al. 2024. Food Chemistry : X Research progress on plant-based protein Pickering particles : stabilization mechanisms. preparation methods , and application prospects in the food industry. Food Chemistry: X 21:101066

Chong WT, Siow LF, Chan ES, Tey BT, Lee YY. 2025. Palm-based nanocrystal cellulose-stabilized Pickering emulsions: investigating characteristics. stability and in vitro digestion for potential application as substitution of coconut milk. Journal of the Science of Food and Agriculture 105:4609−4620

Hu H, Shen X, Zou Y, Dong H, Dai Y, et al. 2025. Carboxylated cellulose nanofibrils from sugarcane bagasse as stabilizers for Pickering emulsions. LWT 215:117225

Deng W, Zhang Y, Hu L, Azeez NP, Xu C, et al. 2025. Lignocellulosic nanofibrils isolate via laccase/TEMPO-mediated oxidation for stabilizing Pickering emulsions. Cellulose 32:5407−5424

Teo SH, Ching YC, Fahmi MZ, Lee HV. 2023. Surface functionalization of sugarcane-bagasse-derived cellulose nanocrystal for Pickering emulsion gel: microstructural properties and stability efficiency. Gels 9:734

Jantason N, Suphantharika M, Wipatanawin A, Chansong S, Payongsri P. 2024. Valorization of spent grains from beer production through β-glucan extraction. Foods 13:440

Pal R. 2024. Non-Newtonian behaviour of suspensions and emulsions: review of different mechanisms. Advances in Colloid and Interface Science 333:103299

Kong Y, Chen J, Hong Z, Guo R, Huang Q. 2025. Insights into the Pickering emulsions stabilized by yeast dietary fiber: interfacial adsorption kinetics, rheological characteristics, and stabilization mechanisms. Food Chemistry 464:141924

Lin J, Tang ZS, Brennan CS, Chandrapala J, Gao W, et al. 2023. Thermomechanically micronized sugar beet pulp: emulsification performance and the contribution of soluble elements and insoluble fibrous particles. Food Research International 165:112467

Wu J, Gao Y, Shen H, Yan S, Zhao R, et al. 2024. Application potential of wheat bran cellulose nanofibers as Pickering emulsion stabilizers and stabilization mechanisms. Food Chemistry: X 24:101922

Mello NA, Rousseau D. 2025. Stability and rheology of water-in-oil high internal phase emulsions containing continuous phase solid fat. Journal of the American Oil Chemists’ Society 102:1131−1138

Huang H, Jia C, Chen X, Zhang L, Jiang Y, et al. 2024. Progress in research on the effects of quinoa (Chenopodium quinoa) bioactive compounds and products on intestinal flora. Frontiers in Nutrition 11:1308384