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Bioengineered Volume 12, 2021 - Issue 1
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Review

Apple orchard waste recycling and valorization of valuable product-A review

Yumin Duana College of Natural Resources and Environment, Northwest A&F University, Yangling, Shaanxi ProvinceChinaView further author information
,
Sanjeet Mehariyab Department of Engineering, University of Campania “Luigi Vanvitelli”, Aversa (CE), ItalyView further author information
,
Aman Kumarc CSIR-National Environmental Engineering Research Institute, NagpurMaharashtra, IndiaView further author information
,
Ekta Singhc CSIR-National Environmental Engineering Research Institute, NagpurMaharashtra, IndiaView further author information
,
Jianfeng Yanga College of Natural Resources and Environment, Northwest A&F University, Yangling, Shaanxi ProvinceChinaORCID Iconhttps://orcid.org/0000-0003-0497-7751View further author information
ORCID Icon,
Sunil Kumarc CSIR-National Environmental Engineering Research Institute, NagpurMaharashtra, IndiaView further author information
,
Huike Lia College of Natural Resources and Environment, Northwest A&F University, Yangling, Shaanxi ProvinceChinaCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0002-9753-2788View further author information
ORCID Icon &
Mukesh Kumar Awasthia College of Natural Resources and Environment, Northwest A&F University, Yangling, Shaanxi ProvinceChina;d Swedish Centre for Resource Recovery, University of Borås, Borås, SwedenCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0003-0879-184XView further author information
ORCID Icon show all
Pages 476-495 | Received 08 Oct 2020, Accepted 05 Jan 2021, Published online: 20 Jan 2021

References

  • Cruz MG, Bastos R, Pinto M, et al.. Waste mitigation: from an effluent of apple juice concentrate industry to a valuable ingredient for food and feed applications. J Clean Prod. 2018;193:652–660.
  • Barnwal BK, Sharma MP. Prospects of biodiesel production from vegetable oils in India. Renew. Sustain. Energy. Rev. 2005;9(4):363–378.
  • Nati C, Boschiero M, Picchi G, et al.. Energy performance of a new biomass harvester for recovery of orchard wood wastes as alternative to mulching. Renew. Energ. 2017;124:121–128.
  • Wang X, Kristo E, Lapointe G. The effect of apple pomace on the texture, rheology and microstructure of set type yogurt. Food. Hydrocolloid. 2019;91:83–91.
  • Al-Hamamre Z, Saidan M, Hararah M, et al.. Wastes and biomass materials as sustainable-renewable energy resources for Jordan. Renew. Sustain. Energy. Rev. 2017;67:295–314.
  • Avcioglu AO, Dayioglu MA, Turker U. Assessment of the energy potential of agricultural biomass residues in turkey. Renew. Energ. 2019;138:610–619.
  • Alavijeh MK, Yaghmaei S. Biochemical production of bioenergy from agricultural crops and residue in iran. Waste. Manage. 2016;52:375–394.
  • Conti J, Holtberg P,Diefenderfer J, et al. International energy outlook 2016, in: with Projections to 2040, U.S. Energy Information Administration Office of Energy Analysis U.S, Department of Energy, Washington DC. 2016;290:20585.
  • Kumar A, Kumar K, Kaushik N, et al.. Renewable energy in India: current status and future potentials. Renew. Sustain. Energy. Rev. 2010;14(8):2434–2442.
  • Brand M, Jacinto R. Apple pruning residues: potential for burning in boiler systems and pellet production. Renew. Energ. 2020;152:458–466.
  • Zlatanovic S, Ostoji S, Mici DM, et al.. Thermal behaviour and degradation kinetics of apple pomace flours. Thermochimica. Acta. 2019;673:17–25.
  • Rupasinghe HPV, Kean C, Nichols D, et al.. Orchard waste as a valuable bio-resource: a chemical composition analysis. Acta Horticult. 2007;737(737):17–23.
  • Awasthi MK, Sarsaiya S, Wainaina S, et al.. A critical review of organic manure bio-refinery models toward sustainable circular bio-economy: technological challenges, advancements, innovations, and future perspectives. Renew. Sustain. Energy. Rev. 2019;111:115–131.
  • Taherzadeh MJ. Bioengineering to tackle environmental challenges, climate changes and resource recovery. Bioengineered. 2019;10(1):698–699.
  • García R, Pizarro C, Lavín AG, et al.. Spanish biofuels heating value estimation. Part II: proximate analysis data. Fuel. 2014;117:1139–1147.
  • EUROSTAT Sustainable Development in the European Union :Monitoring Report of the EU Sustainable Development Strategy;Publications Office of the European Union:Luxembourg;2011.
  • García-Galindo D, Cay Villa-Ceballos F, Vila-Villarroel L, et al. Seeking for ratios and correlations from field data for improving biomass assessments for agricultural pruning in Europe. Method and Results. In Proceedings of the 24th European Biomass Conference and Exhibition, Amsterdam, The Netherlands. 2016; 6–9.
  • Uzodinma EO, Ofoefule AU, Enwere NJ. Optimization of biogas fuel production from maize (Zea mays) bract waste: comparative study of biogas production from blending maize bract with biogenic wastes. Am. J. Food. Nutr. 2011;1(1):1–6.
  • Bouallagui H, Touhami Y, Cheikh RB, et al.. Bioreactor performance in anaerobic digestion of fruit and vegetable wastes. Process. Biochem. 2005;40(3–4):989–995.
  • Guo S, Lu C, Wang K, et al.. Enhancement of pH values stability and photofermentation bio-hydrogen production by phosphate buffer. Bioengineered. 2020;11(1):291–300.
  • Wainaina S, Lukitawesa AMK, Taherzadeh MJ. Bioengineering of anaerobic digestion for volatile fatty acids, hydrogen or methane production: A critical review. Bioengineered. 2019;10(1):437–458.
  • Li K, Liu R, Cui S, et al.. Anaerobic co-digestion of animal manures with corn stover or apple pulp for enhanced biogas production. Renew. Energ. 2018;118:335–342.
  • Jansson AT, Patinvoh RJ, Taherzadeh MJ, et al.. Effect of organic compounds on dry anaerobic digestion of food and paper industry wastes. Bioengineered. 2019;11(1):502–509.
  • Kafle G, Kim S. Anaerobic treatment of apple waste with swine manure for biogas production: batch and continuous operation. Appl Energy. 2013;103:61–72.
  • Xiao W, Li H, Xia W, et al.. Co-expression of cellulase and xylanase genes in Sacchromyces cerevisiae toward enhanced bioethanol production from corn stover. Bioengineered. 2019;10(1):513–521.
  • Karmakar A, Karmakar S, Mukherjee S. Properties of various plants and animals’ feed-stocks for biodiesel production. Bioresource. Technol. 2010;101(19):7201–7210.
  • Diyauddeen BH, Aziz AA, Daud W. Chakrabarti M. Performance evaluation of biodiesel from used domestic waste oils: a review. Process. Saf. Environ. 2012;90(3):164–179.
  • Atadashi IM, Aroua MK, Aziz AA, et al.. Production of biodiesel using high free fatty acid feedstocks. Renew. Sustain. Energy. Rev. 2012;16(5):3275–3285.
  • Li S, Wang Y, Dong S, et al.. Biodiesel production from Eruca Sativa Gars vegetable oil and motor, emissions properties. Renew. Energ. 2009;34(7):1871–1876.
  • Su W, Ma H, Gao M, et al. Research on biodiesel and ethanol production from food waste. In 2010 4th International Conference on Bioinformatics and Biomedical Engineering. china. 2010.
  • Pizarro AVL, Park EY. Lipase-catalyzed production of biodiesel fuel from vegetable oils contained in waste activated bleaching earth. Process. Biochem. 2003;38(7):1077–1082.
  • Keera ST, El Sabagh SM, Taman AR. Transesterification of vegetable oil to biodiesel fuel using alkaline catalyst. Fuel. 2011;90(1):42–47.
  • Shu Q, Gao J, Nawaz Z, et al.. Synthesis of biodiesel from waste vegetable oil with large amounts of free fatty acids using a carbon-based solid acid catalyst. Appl Energy. 2010;87(8):2589–2596.
  • Aguilar C, Ruiz H, Rios A, et al.. Emerging strategies for the development of food industries. Bioengineered. 2019;10(1):522–537.
  • Li P, He C, Li G, et al.. Biological pretreatment of corn straw for enhancing degradation efficiency and biogas production. Bioengineered. 2020;11(1):251–260.
  • Lee S, Posarac D, Ellis N. An experimental investigation of biodiesel synthesis from waste canola oil using supercritical methanol. Fuel. 2012;91(1):229–237.
  • Sandhu DK, Joshi VK. Solid state fermentation of apple pomace for con- comitant production of ethanol and animal feed. J. Sci. Ind. Res. 1997;56:86–90.
  • Ngadi MO, Correia LR. Solid state ethanol fermentation of apple pomace as affected by moisture and bioreactor mixing speed. J. Food. Sci. 1992;57(3):667–670.
  • Dhillon GS, Kaur S, Brar SK. Perspective of apple processing wastes as low-cost substrates for bioproduction of high value products: A review. Renew. Sustain. Energy. Rev. 2013;27:789–805.
  • Zhang S, Wang Y, Liu S. Process optimization for the anaerobic digestion of poplar (Populus L.) leaves. Leaves. Bioengineered. 2020;11(1):439–448.
  • Lütke-Eversloh T, Bahl H. Metabolic engineering of Clostridium acetobutylicum: recent advances to improve butanol production. Curr Opin Biotech. 2011;22(5):634–647.
  • Voget CE, Mignone CF, Ertola RJ. Butanol production from apple pomace. Biotechnol Lett. 1985;7(1):43–46.
  • Patakova P, Lipovský J, Cížková H, et al.. Exploitation of food feedstock and waste for production of biobutanol. Czech. J. Food. Sci. 2009;27(No. 4):276–283.
  • Gomes RJ, Borges M, Rosa M, et al.. Acetic acid bacteria in the food industry: systematics, characteristics and applications. Food. Technol. Biotech. 2018;56(2):139–151.
  • Shi T, Peng H, Zeng S, et al.. Microbial production of plant hormones: opportunities and challenges. Bioengineered. 2017;8(2):124–128.
  • Show KY, Lee DJ, Chang JS. Bioreactor and process design for bio-hydrogen production. Bioresource. Technol. 2011;102(18):8524–8533.
  • Kharkwal G. Qualitative analysis of tree species in evergreen forests of Kumaun Himalaya, Uttarakhand, India. African. J. Plant. Sci. 2009;3:049–052.
  • Mohanakrishna G, Goud RK, Mohan SV, et al.. Enhancing biohydrogen production through sewage supplementation of composite vegetable-based market waste. Int J Hydrogen Energy. 2010;35(2):533–541.
  • Yao B, Xiao T, Jie X, et al.. H2–rich gas production from leaves. Catal Today. 2018;317:43–49.
  • Tenca A, Schievano A, Perazzolo F, et al.. Biohydrogen from thermophilic co-fermentation of swine manure with fruit and vegetable waste: maximizing stable production without pH control. Bioresource. Technol. 2011;102(18):8582–8588.
  • Lukitawesa PR, Millati R, Horváth S, et al.. Factors influencing volatile fatty acids production from food wastes via anaerobic digestion. Bioengineered. 2019;11(1):39–52.
  • Lu C, Zhang Z, Ge X, et al.. Bio-hydrogen production from apple waste by photosynthetic bacteria HAU-M1. Int. J. Hydrogen. Energ. 2016;41(31):13399–13407.
  • Tagliavini M, Tonon G, Scandellari F, et al.. Nutrient recycling during the decomposition of apple leaves (Malus domestica) and mowed grasses in an orchard. Agr. Ecosyst. Environ. 2007;118(1–4):191–200.
  • Tartachnyk II, Blanke MM. Effect of delayed fruit harvest on photosynthesis, transpiration and nutrient remobilization of apple leaves. New. Phytol. 2004;164(3):441–450.
  • Kopcic N, Domanovac MV, Kucic D, et al.. Evaluation of laboratory-scale in-vessel co-composting of tobacco and apple waste. Waste Manage. 2014;34(2):323–328.
  • Mia S, Uddin ME, Kader MA, et al.. Pyrolysis and co-composting of municipal organic waste in Bangladesh: A quantitative estimate of recyclable nutrients, greenhouse gas emissions, and economic benefits. Waste. Manage. 2018;75:503–513.
  • Venkatesh RM, Eevera T. Mass reduction and recovery of nutrients through vermicomposting of fly ash. Appl. Ecol. Env. Res. 2008;6(1):77–84.
  • Sinha RK, Agarwal S, Chauhan K, et al.. The wonders of earthworms & its vermicompost in farm production: charles Darwin’s ‘friends of farmers’, with potential to replace destructive chemical fertilizers. Agr. Sci. 2010;1:76.
  • Hanc A, Chadimova Z. Nutrient recovery from apple pomace waste by vermicomposting technology. Bioresource. Technol. 2014;168:240–244.
  • García-Sánchez M, Tausnerova H, Hanc A, et al.. Stabilization of different starting materials through vermicomposting in a continuous-feeding system: changes in chemical and biological parameters. Waste. Manage. 2017;62:33–42.
  • Singh RP, Embrandiri A, Ibrahim MH, et al.. Management of biomass residues generated from palm oil mill: vermicomposting a sustainable option. Resour. Conserv. Recy. 2011;55(4):423–434.
  • Bhat SA, Singh S, Singh J, et al.. Bioremediation and detoxification of industrial wastes by earthworms: vermicompost as powerful crop nutrient in sustainable agriculture. Bioresource. Technol. 2018;252:172–179.
  • Macdonald C, Singh B. Harnessing plant-microbe interactions for enhancing farm productivity. Bioengineered. 2014;5(1):5–9.
  • Manyuchi MM, Phiri A. Vermicomposting in solid waste management: a review. Int. J. Sci. Engineer. Technol. 2013;2:1234–1242.
  • Ahad S, Mir M, Ashraf S, et al.. Nutrient Management in High Density Apple Orchards–A Review. Curr. J. Appl. Sci. Technol. 2018;29(1):1–16.
  • Kumar A, Singh E, Khapre A, et al.. Sorption of volatile organic compounds on non-activated biochar. Bioresource. Technol. 2020;297:122469.
  • DeLuca TH, Gundale MJ, MacKenzie MD, et al.. Biochar effects on soil nutrient transformations. Biochar for Environmental Management: Science, Technology and Implementation. 2015;2:421–454.
  • Li S, Liang C, Shangguan Z. Effects of apple branch biochar on soil C mineralization and nutrient cycling under two levels of N. Sci Total Environ. 2017;607-608:109.
  • Navia R, Crowley DE. Closing the loop on organic waste management: biochar for agricultural land application and climate change mitigation. Waste Management & Research the Journal of the International Solid Wastes & Public Cleansing Association ISWA. 2010;28(6):479–480.
  • Atkinson CJ, Fitzgerald JD. Hipps NA. Potential mechanisms for achieving agricultural benefits from biochar application to temperate soils: a review. Plant Soil. 2010;337(1–2):1–18.
  • Lehmann J, Gaunt J, Rondon M. Bio-char sequestration in terrestrial ecosystems–a review. Mitig. Adapt. Strat. Gl. 2006;11(2):403–427.
  • Dhillon GS, Brar SK, Kaur S, et al.. Screening of agro-industrial wastes for citric acid bioproduction by Aspergillus niger NRRL 2001 through solid state fermentation. J. Sci. Food. Agric. 2013;93(7):1560–1567.
  • Chang Y, Lai JY, Lee DJ. Thermodynamic parameters for adsorption equilibrium of heavy metals and dyes from wastewaters: research updated. Bioresour Technol. 2016;222:513–516.
  • Lu J, Lv Y, Qian X. et al.. Current advances in organic acid production from organic wastes by using microbial co-cultivation systems. Biofuel. Bioprod. Bio. 2020;14(2):481–492. DOI:10.1002/bbb.2075.
  • Kim HM, Park JH, Choi IS, et al. Effective approach to organic acid production from agricultural kimchi cabbage waste and its potential application. PLoS One. 2018;13:1–14.
  • Becker J, Lange A, Fabarius J, et al.. Top value platform chemicals: bio-based production of organic acids. Curr Opin Biotech. 2015;36:168–175.
  • Vashisht A, Thakur K, Kauldhar BS, et al.. Waste valorization: identification of an ethanol tolerant bacterium Acetobacter pasteurianus SKYAA25 for acetic acid production from apple pomace. Sci Total Environ. 2019;690:956–964.
  • Pal P, Nayak J. Acetic acid production and purification: critical review towards process intensification. Sep. Purif. Rev. 2017;46(1):44–61.
  • De Roos J, De Vuyst L. Acetic acid bacteria in fermented foods and beverages. Curr Opin Biotech. 2018;49:115–119.
  • Evcan E, Tari C. Production of bioethanol from apple pomace by using co-cultures: conversion of agro-industrial waste to value added product. Energy. 2015;88:775–782.
  • Jin Q, Qureshi N, Wang H, et al.. Acetone-butanol-ethanol (ABE) fermentation of soluble and hydrolyzed sugars in apple pomace by Clostridium beijerinckii P260. Fuel. 2019;244:536–544.
  • Dhillon GS, Brar SK, Verma M, et al.. Enhanced solid-state citric acid bio-production using apple pomace waste through surface response methodology. J Appl Microbiol. 2011;110(4):1045–1055.
  • Sun X, Lu H, Wang J. Recovery of citric acid from fermented liquid by bipolar membrane electrodialysis. J Clean Prod. 2017;143:250–256.
  • Guo F, Wu M, Dai Z, et al. Current advances on biological production of fumaric acid. Biochem Eng J. 2020;153:107397.
  • Papadaki A, Androutsopoulos N, Patsalou M, et al. Biotechnological Production of Fumaric Acid: the Effect of Morphology of Rhizopus arrhizus NRRL 2582. Fermentation. 2017;3(3):33.
  • Martin-Dominguez V, Estevez J, Ojembarrena F, et al.. Fumaric Acid Production: A Biorefinery Perspective. Fermentation. 2018;4(2):33.
  • Das RK, Brar SK, Verma M. A fermentative approach towards optimizing directed biosynthesis of fumaric acid by Rhizopus oryzae 1526 utilizing apple industry waste biomass. Fungal Biol. 2015;119(12):1279–1290.
  • Gullón B, Yáñez R, Alonso JL, et al.. L-Lactic acid production from apple pomace by sequential hydrolysis and fermentation. Bioresour Technol. 2008;99(2):308–319.
  • Piwowarek K, Lipinska E, Hac-Szymanczuk E, et al.. Optimization of propionic acid production in apple pomace extract with Propionibacterium freudenreichii. Prep Biochem Biotechnol. 2019;49(10):974–986.
  • Zang L, Wu B, Lin Y, et al.. Research progress of ursolic acid’s anti-tumor actions. Chin J Integr Med. 2014;20(1):72–79.
  • Cargnin ST, Gnoatto SB. Ursolic acid from apple pomace and traditional plants: A valuable triterpenoid with functional properties. Food Chemistry. 2017;220:477–489.
  • Ravindran R, Hassan SS, Williams GA, et al.. Review on Bioconversion of Agro-Industrial Wastes to Industrially Important Enzymes. Bioengineering. 2018;5:93.
  • Salim AA, Grbavcic S, Šekuljica N, et al.. Production of enzymes by a newly isolated Bacillus sp. TMF-1 in solid state fermentation on agricultural by-products: the evaluation of substrate pretreatment methods. Bioresour. Technol. 2017;228:193–200.
  • Kaur S, Dhillon GS, Brar SK, et al.. Carbohydrate degrading enzyme production by plant pathogenic mycelia and microsclerotia isolates of Macrophomina phaseolina through koji fermentation. Ind Crops Prod. 2012;36(1):140–148.
  • Kuvvet C, Uzuner S, Cekmecelioglu D. Improvement of Pectinase Production by Co-culture of Bacillus spp. Using Apple Pomace as a Carbon Source. Waste. Biomass. Valori. 2019;10(5):1241–1249.
  • Sharma R, Oberoi HS, Dhillon GS. Chapter 2 - Fruit and Vegetable Processing Waste: renewable Feed Stocks for Enzyme Production,” in Agro-Industrial Wastes as Feedstock for Enzyme Production. Dhillon GS, Kaur S, eds. (San Diego: Academic Press); 2016. p. 23–59.
  • Favela-Torres E, Volke-Sepúlveda T, Viniegra-González G. Production of Hydrolytic Depolymerising Pectinases. Food. Technol. Biotech. 2006;44(2):221–227.
  • Huang S, Huang D, Wu Q, et al.. Effect of environmental C/N ratio on activities of lignin-degrading enzymes produced by Phanerochaete chrysosporium. Pedosphere. 2020;30:285–292.
  • Asgher M, Wahab A, Bilal M, et al.. Lignocellulose degradation and production of lignin modifying enzymes by Schizophyllum commune IBL-06 in solid-state fermentation. Biocatal. Agric. Biotechnol. 2016;6:195–201.
  • Zhang S, Xiao J, Wang G, et al.. Enzymatic hydrolysis of lignin by ligninolytic enzymes and analysis of the hydrolyzed lignin products. Bioresour Technol. 2020;304:122975.
  • Wang J, Cui Z, Li Y, et al.. Techno-economic analysis and environmental impact assessment of citric acid production through different recovery methods. J Clean Prod. 2020;249:119315.
  • Bilal M, Iqbal H, Hu H, et al.. Metabolic engineering and enzyme-mediated processing: A biotechnological venture towards biofuel production – A review. Renew. Sustain. Energy. Rev. 2018;82:436–447.
  • Gassara F, Brar SK, Tyagi RD, et al.. Screening of agro-industrial wastes to produce ligninolytic enzymes by Phanerochaete chrysosporium. Biochem Eng J. 2010;49(3):388–394.
  • Gassara F, Brar SK, Tyagi RD, et al.. Parameter optimization for production of ligninolytic enzymes using agro-industrial wastes by response surface method. Biotechnol. Bioproc. E. 2011;16(2):343–351.
  • Vodnar DC, Calinoiu LF, Dulf FV, et al.. Identification of the bioactive compounds and antioxidant, antimutagenic and antimicrobial activities of thermally processed agro-industrial waste. Food Chem. 2017;231:131–140.
  • Guardia L, Suárez L, Querejeta N, et al.. Apple Waste: A sustainable source of carbon materials and valuable compounds. ACS. Sustain. Chem. Eng. 2019;7(20):17335–17343.
  • Perussello CA, Zhang Z, Marzocchella A, et al.. Valorization of apple pomace by extraction of valuable compounds. Compr. Rev. Food. Sci. Food. Saf. 2017;16(5):776–796.
  • Waldbauer K, McKinnon R, Kopp B. Apple pomace as potential source of natural active compounds. Planta Medica. 2017;83(12/13):994–1010.
  • Rodríguez Madrera R, Pando Bedriñana R, Suárez Valles B. Production and characterization of aroma compounds from apple pomace by solid-state fermentation with selected yeasts. LWT – Food. Sci. Technol. 2015;64(2):1342–1353.
  • Ricci A, Cirlini M, Guido A, et al.. From By-product to resource: fermented apple pomace as beer flavoring. Foods. 2019,8(8):8. DOI:10.3390/foods8080309.
  • Rebocho AT, Pereira JR, Neves LA, et al. Preparation and characterization of films based on a natural P(3HB)/mcl-PHA blend obtained through the co-culture of Cupriavidus Necator and Pseudomonas Citronellolis in Apple Pulp Waste. Bioengineering. 2020;7(2):32.
  • Bakshi PS, Selvakumar D, Kadirvelu K, et al.. Chitosan as an environment friendly biomaterial – a review on recent modifications and applications. Int J Biol Macromol. 2020;150:1072–1083.
  • Riaz A, Lagnika C, Abdin M, et al.. Preparation and characterization of Chitosan/Gelatin-Based Active Food Packaging Films Containing Apple Peel Nanoparticles. J Polym Environ. 2020;28(2):411–420.
  • Vendruscolo F, Ninow JL. Apple pomace as a substrate for fungal chitosan production in an airlift bioreactor. Biocatal. Agric. Biotechnol. 2014;3(4):338–342.
  • Torquati B, Marino D, Venanzi S, et al.. Using tree crop pruning residues for energy purposes: A spatial analysis and an evaluation of the economic and environmental sustainability. Biomass. Bioenerg. 2016;95:124–131.
  • Frackowiak P, Adamczyk F, Wachalski G, et al.. A prototype machine for harvesting and baling of pruning residues in orchards: first test on apple orchard (MALUS MILL.) in Poland. J. Res. Appl. Agr. Engineering. 2016:61(3).
  • Molinuevo-Salces B, González-Fernández C, Gómez X, et al.. Vegetable processing wastes addition to improve swine manure anaerobic digestion: evaluation in terms of methane yield and SEM characterization. Appl Energy. 2012;91(1):36–42.
  • John J, Kaimal K, Smith ML, et al.. Advances in upstream and downstream strategies of pectinase bioprocessing: A review. Int J Biol Macromol. 2020;162:1086–1099.
  • Lyu F, Luiz SF, Azeredo D, et al.. Apple Pomace as a Functional and Healthy Ingredient in Food Products: A Review. Processes. 2020;8(3):319.

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