Plant Soil Environ., 2023, 69(9):409-420 | DOI: 10.17221/101/2023-PSE

Biotransformation of food waste into biofertilisers through composting and anaerobic digestion: a reviewReview

Nurul Solehah Mohd Zaini1, Abedelazeez J.D. Khudair1, Aliah Zannierah Mohsin1, Elicia Jitming Lim2, Wakisaka Minato3, Hamidah Idris4, Jamilah Syafawati Yaacob5, Muhamad Hafiz Abd Rahim1
1 Department of Food Science, Faculty of Food Science and Technology, Universiti Putra Malaysia, Malaysia
2 School of Life and Environmental Sciences, The University of Sydney, Sydney, Australia
3 Department of Biochemical Engineering and Science, Kyushu Institute of Technology, Japan
4 Food Study Center, Fukuoka Women's University, Fukuoka, Japan
5 Institute of Biological Sciences, Faculty of Science, Universiti Malaya, Kuala Lumpur, Malaysia

A growing world population means greater pressure on earth’s resources. Currently, 30% of food is wasted, which poses a significant risk to both humans and the environment. One way to offset the growth in food waste (FW) is through the process of microbial bioconversion, whereby FW is transformed into a range of nutrient-dense biofertilisers. This approach not only promotes a highly desirable circular economy, but it can also reduce the use of inorganic fertilisers, which adversely impact the environment through increased greenhouse gases, changes in soil and water characteristics, and loss of biodiversity. The bioconversion of FW to biofertiliser relies on the processes of aerobic (composting) and anaerobic digestion. Recently, alternative decomposition techniques included growing specific beneficial microbes, such as effective microorganisms, to speed up the breakdown process. Microorganisms can act as biostimulants and biodecomposers, possessing nutrient-fixing abilities and providing protection from biotic and abiotic stresses, thus enhancing plant growth and overall health. The potential uses of FW are complex and diverse, but research is actively done to effectively utilise this resource for biofertiliser applications.

Keywords: climate change; recycling material; soil microbiota; digestate; environmental impact; plant-growth promoting microorganism

Received: March 7, 2023; Revised: August 24, 2023; Accepted: August 28, 2023; Prepublished online: September 25, 2023; Published: September 29, 2023  Show citation

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Zaini NSM, Khudair AJD, Mohsin AZ, Jitming Lim E, Minato W, Idris H, et al.. Biotransformation of food waste into biofertilisers through composting and anaerobic digestion: a review. Plant Soil Environ. 2023;69(9):409-420. doi: 10.17221/101/2023-PSE.
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    References

    1. Abdel-Aziz H.M.M., Soliman M.I., Abo Al-Saoud A.M., El-Sherbeny G.A. (2021): Waste-derived NPK nanofertilizer enhances growth and productivity of Capsicum annuum L. Plants, 10: 1144. Go to original source... Go to PubMed...
    2. Abdullah J., Greetham D., Pensupa N., Tucker G., Du C. (2016): Optimizing cellulase production from municipal solid waste (MSW) using solid state fermentation (SSF). Journal of Fundamentals of Renewable Energy and Applications, 6: 10000206. Go to original source...
    3. Abedelazeez K.J.D., Nurul Solehah M.Z., Jaafar A.H., Meor Hussin A.S., Wan-Mohtar W.A.A.Q.I., Abd Rahim M.H. (2023): Production, organo-leptic, and biological activities of belacan (shrimp paste) and pekasam (fermented freshwater fish), the ethnic food from the Malay Archipelago. Sains Malaysiana, 52: 1217-1230. Go to original source...
    4. Ahemad M., Kibret M. (2014): Mechanisms and applications of plant growth promoting rhizobacteria: current perspective. Journal of King Saud University - Science, 26: 1-20. Go to original source...
    5. Ahuja I., Dauksas E., Remme J.F., Richardsen R., Løes A.-K. (2020): Fish and fish waste-based fertilizers in organic farming - with status in Nor-way: a review. Waste Management, 115: 95-112. Go to original source... Go to PubMed...
    6. Ancuța P., Sonia A. (2020): Oil press-cakes and meals valorization through circular economy approaches: a review. Applied Sciences, 10: 7432. Go to original source...
    7. Areeshi M.Y. (2022): Recent advances on organic biofertilizer production from anaerobic fermentation of food waste: overview. International Journal of Food Microbiology, 374: 109719. Go to original source... Go to PubMed...
    8. Barzee T.J., Edalati A., El-Mashad H., Wang D., Scow K., Zhang R. (2019): Digestate biofertilizers support similar or higher tomato yields and quality than mineral fertilizer in a subsurface drip fertigation system. Frontiers in Sustainable Food Systems, 3: 00058. Go to original source...
    9. Chhandama M.V.L., Chetia A.C., Satyan K.B., Supongsenla A., Ruatpuia J.V.L., Rokhum S.L. (2022): Valorisation of food waste to sustainable energy and other value-added products: a review. Bioresource Technology Reports, 17: 100945. Go to original source...
    10. Dalke R., Demro D., Khalid Y., Wu H., Urgun-Demirtas M. (2021): Current status of anaerobic digestion of food waste in the United States. Renewable and Sustainable Energy Reviews, 151: 111554. Go to original source...
    11. De Sousa M.H., da Silva A.S.F., Correia R.C., Leite N.P., Bueno C.E.G., dos Santos Pinheiro R.L., de Santana J.S., da Silva J.L., Sales A.T., de Souza C.C., da Silva Aquino K.A., de Souza R.B., Pinheiro I.O., Henríquez J.R., Schuler A.R.P., de Sá Barretto Sampaio E.V., Dutra E.D., Menezes R.S.C. (2022): Valorizing municipal organic waste to produce biodiesel, biogas, organic fertilizer, and value-added chemicals: an integrated bio-refinery approach. Biomass Conversion and Biorefinery, 12: 827-841. Go to original source...
    12. Debrah J.K., Vidal D.G., Dinis M.A. (2021): Raising awareness on solid waste management through formal education for sustainability: a develop-ing countries evidence review. Recycling, 6: 6. Go to original source...
    13. Devi V., Sumathy V.J.H. (2017): Production of biofertilizer from fruit waste. European Journal of Pharmaceutical and Medical Research, 4: 436-443.
    14. Epstein E. (1997): The Science of Composting. Florida, CRC Press LLC, 504.
    15. Faizal F.A., Ahmad N.H., Yaacob J.S., Abdul-Halim Lim S., Abd Rahim M.H. (2023): Food processing to reduce anti-nutrients in plant-based food. International Food Research Journal, 30: 25-45. Go to original source...
    16. Fan Y., Van Lee C.T., Leow C.W., Chua L.S., Sarmidi M.R. (2016): Physico-chemical and biological changes during co-composting of model kitchen waste, rice bran and dried leaves with different microbial inoculants. Malaysian Journal of Analytical Sciences, 20: 1447-1457. Go to original source...
    17. Figueiredo G.G.O., Lopes V.R., Romano T., Camara M.C. (2020): Chapter 22 - Clostridium. In: Amaresan N., Senthil Kumar M., Annapurna K., Kumar K., Sankaranarayanan A.-E. (eds.): Beneficial Microbes in Agro-Ecology: Bacteria and Fungi. London, Academic Press, 477-491. ISBN: 9780128234143 Go to original source...
    18. Forbes H., Quested T., O'Connor C. (2021): Food waste index report 2021. Nairobi, United Nations Environment Programme.
    19. Gogoi M., Biswas T., Biswal P., Saha T., Modak A., Gantayet L.M., Nath R., Mukherjee I., Thakur A.R., Sudarshan M., Ray Chaudhuri S. (2021): A novel strategy for microbial conversion of dairy wastewater into biofertilizer. Journal of Cleaner Production, 293: 126051. Go to original source...
    20. Gunes B., Stokes J., Davis P., Connolly C., Lawler J. (2019): Pre-treatments to enhance biogas yield and quality from anaerobic digestion of whiskey distillery and brewery wastes: a review. Renewable and Sustainable Energy Reviews, 113: 109281. Go to original source...
    21. Guo S., Chen L. (2022): Why is China struggling with waste classification? A stakeholder theory perspective. Resources, Conservation and Recy-cling, 183: 106312. Go to original source...
    22. Hadidi M., Bahlaouan B., Antri S. El, Benali M., Boutaleb N. (2022): Biotransformation of food waste to bio-products: biogas and biofertilizer. International Journal of Environmental Studies, 80: 672-686. Go to original source...
    23. Hamawand I. (2015): Anaerobic digestion process and bio-energy in meat industry: a review and a potential. Renewable and Sustainable Energy Reviews, 44: 37-51. Go to original source...
    24. Huang J., Xu C., Ridoutt B.G., Wang X., Ren P. (2017): Nitrogen and phosphorus losses and eutrophication potential associated with fertilizer application to cropland in China. Journal of Cleaner Production, 159: 171-179. Go to original source...
    25. Iocoli G.A., Zabaloy M.C., Pasdevicelli G., Gómez M.A. (2019): Use of biogas digestates obtained by anaerobic digestion and co-digestion as fertilizers: characterization, soil biological activity and growth dynamic of Lactuca sativa L. Science of The Total Environment, 647: 11-19. Go to original source... Go to PubMed...
    26. Iriti M., Scarafoni A., Pierce S., Castorina G., Vitalini S. (2019): Soil application of effective microorganisms (EM) maintains leaf photosynthetic efficiency, increases seed yield and quality traits of bean (Phaseolus vulgaris L.) plants grown on different substrates. International Journal of Molecular Sciences, 20: 2327. Go to original source... Go to PubMed...
    27. Itelima J., Bang W., Sila M., Onyimba I., Egbere O. (2018): A review: biofertilizer - a key player in enhancing soil fertility and crop productivity. Journal of Experimental and Clinical Microbiology, 2: 73-83.
    28. Jeng A., Haraldsen T., Grønlund A., Pedersen P. (2006): Meat and bone meal as nitrogen and phosphorus fertilizer to cereals and rye grass. Nutri-ent Cycling in Agroecosystems, 76: 183-191. Go to original source...
    29. Jiang F., Wang S., Zhang Y., Ma S., Huang Y., Fan H., Li Q., Wang H., Wang A., Liu H., Cheng L., Deng Y., Fan W. (2021): Variation of meta-genome from feedstock to digestate in full-scale biogas plants. Frontiers in Microbiology, 12: 660225. Go to original source... Go to PubMed...
    30. Jung H.Y., Kim J.K. (2020): Complete reutilisation of mixed mackerel and brown seaweed wastewater as a high-quality biofertiliser in open-flow lettuce hydroponics. Journal of Cleaner Production, 247: 119081. Go to original source...
    31. Jurado M., López M.J., Suárez-Estrella F., Vargas-García M.C., López-González J.A., Moreno J. (2014): Exploiting composting biodiversity: study of the persistent and biotechnologically relevant microorganisms from lignocellulose-based composting. Bioresource Technology, 162: 283-293. Go to original source... Go to PubMed...
    32. Kefalew T., Lami M. (2021): Biogas and bio-fertilizer production potential of abattoir waste: implication in sustainable waste management in Shashemene City, Ethiopia. Heliyon, 7: e08293. Go to original source... Go to PubMed...
    33. Lamont J.R., Wilkins O., Bywater-Ekegärd M., Smith D.L. (2017): From yogurt to yield: potential applications of lactic acid bacteria in plant pro-duction. Soil Biology and Biochemistry, 111: 1-9. Go to original source...
    34. Li Y., Park S.Y., Zhu J. (2011): Solid-state anaerobic digestion for methane production from organic waste. Renewable and Sustainable Energy Reviews, 15: 821-826. Go to original source...
    35. Lim J., Yaacob J.S., Rasli S., Eyahmalay J., El Enshasy H., Zakaria M.R.S. (2023): Mitigating the repercussions of climate change on diseases affecting important crop commodities in Southeast Asia, for food security and environmental sustainability - a review. Frontiers in Sustainable Food Sys-tems, 6: 1030540. Go to original source...
    36. Liu X., Lendormi T., Lanoisellé J.L. (2019): Overview of hygienization pretreatment for pasteurization and methane potential enhancement of biowaste: challenges, state of the art and alternative technologies. Journal of Cleaner Production, 236: 117525. Go to original source...
    37. Lim S.-F., Matu S.U. (2015): Utilization of agro-wastes to produce biofertilizer. International Journal of Energy and Environmental Engineering, 6: 31-35. Go to original source...
    38. Ma Y., Yin Y., Liu Y. (2017): New insights into co-digestion of activated sludge and food waste: biogas versus biofertilizer. Bioresource Technology, 241: 448-453. Go to original source... Go to PubMed...
    39. Mahdi S.S., Hassan G.I., Samoon S.A., Rather H.A., Dar S.A., Zehra B. (2010): Bio-fertilizers in organic agriculture. Journal of Phytology, 2: 42-54.
    40. Majee S., Sarkar K.K., Sarkhel R., Halder G., Mandal D.D., Rathinam N.K., Mandal T. (2023): Bio-organic fertilizer production from industrial waste and insightful analysis on release kinetics. Journal of Environmental Management, 325: 116378. Go to original source... Go to PubMed...
    41. Martin-Rios C., Demen-Meier C., Gössling S., Cornuz C. (2018): Food waste management innovations in the foodservice industry. Waste Man-agement, 79: 196-206. Go to original source... Go to PubMed...
    42. Menya E., Alokore Y., Ebangu B. (2013): Biogas as an alternative to fuelwood for a household in Uleppi sub-county in Uganda. Agricultural Engi-neering International: The CIGR e-Journal, 15: 50-58.
    43. Mitter E.K., Tosi M., Obregón D., Dunfield K.E., Germida J.J. (2021): Rethinking crop nutrition in times of modern microbiology: innovative biofertilizer technologies. Frontiers in Sustainable Food Systems, 5: 606815. Go to original source...
    44. Mohd Zaini N.S., Idris H., Yaacob J.S., Wan-Mohtar W.A., Putra Samsudin N.I., Abdul Sukor A.S., Lim E.J., Abd Rahim M.H. (2022): The poten-tial of fermented food from Southeast Asia as biofertiliser. Horticulturae, 8: 102. Go to original source...
    45. Moult J.A., Allan S.R., Hewitt C.N., Berners-Lee M. (2018): Greenhouse gas emissions of food waste disposal options for UK retailers. Food Policy, 77: 50-58. Go to original source...
    46. Naidu Y., Meon S., Siddiqui Y. (2013): Foliar application of microbial-enriched compost tea enhances growth, yield and quality of muskmelon (Cucumis melo L.) cultivated under fertigation system. Scientia Horticulturae, 159: 33-40. Go to original source...
    47. Naik K., Mishra S., Srichandan H., Singh P.K., Sarangi P.K. (2019): Plant growth promoting microbes: potential link to sustainable agriculture and environment. Biocatalysis and Agricultural Biotechnology, 21: 101326. Go to original source...
    48. Náthia-Neves G., Berni M., Dragone G., Mussatto S.I., Forster-Carneiro T. (2018): Anaerobic digestion process: technological aspects and recent developments. International Journal of Environmental Science and Technology, 15: 2033-2046. Go to original source...
    49. Nguyen V.-T., Le T.-H., Bui X.-T., Nguyen T.-N., Vo T.-D.-H., Lin C., Vu T.-M.-H., Nguyen H.-H., Nguyen D.-D., Senoro D.B., Dang B.-T. (2020): Effects of C/N ratios and turning frequencies on the composting process of food waste and dry leaves. Bioresource Technology Reports, 11: 100527. Go to original source...
    50. Nosheen S., Ajmal I., Song Y. (2021): Microbes as biofertilizers, a potential approach for sustainable crop production. Sustainability (Switzerland), 13: 1868. Go to original source...
    51. Olle M., Williams I.H. (2013): Effective microorganisms and their influence on vegetable production - a review. The Journal of Horticultural Science and Biotechnology, 88: 380-386. Go to original source...
    52. Owamah H.I., Dahunsi S.O., Oranusi U.S., Alfa M.I. (2014): Fertilizer and sanitary quality of digestate biofertilizer from the co-digestion of food waste and human excreta. Waste Management, 34: 747-752. Go to original source... Go to PubMed...
    53. Palaniveloo K., Amran M.A., Norhashim N.A., Mohamad-Fauzi N., Fang P.H., Low H.W., Yan K.L., Looi J., Chian-Yee M.G., Lai J.Y., Gunasekaran B., Razak S.A. (2020): Food waste composting and microbial community structure profiling. Processes, 8: 723. Go to original source...
    54. Paul S., Dutta A., Defersha F., Dubey B. (2018): Municipal food waste to biomethane and biofertilizer: a circular economy concept. Waste and Biomass Valorization, 9: 601-611. Go to original source...
    55. Rangga J.U., Ismail S.N.S., Rasdi I., Karuppiah K. (2022): Waste management costs reduction and the recycling profit estimation from the segrega-tion programme in Malaysia. Pertanika Journal of Science and Technology, 30: 1457-1478. Go to original source...
    56. Reis V.M., Teixeira K.R. dos S. (2015): Nitrogen fixing bacteria in the family Acetobacteraceae and their role in agriculture. Journal of Basic Micro-biology, 55: 931-949. Go to original source... Go to PubMed...
    57. Sharma A., Saha T.N., Arora A., Shah R., Nain L. (2017): Efficient microorganism compost benefits plant growth and improves soil health in calendula and marigold. Horticultural Plant Journal, 3: 67-72. Go to original source...
    58. Sharma A., Dogra S., Thakur B., Yadav J., Soni R., Soni S.K. (2023): Separate hydrolysis and fermentation of kitchen waste residues using multi-enzyme preparation from Aspergillus niger P-19 for the production of biofertilizer formulations. Sustainability, 15: 9182. Go to original source...
    59. Silva dos Santos I.F., Braz Vieira N.D., de Nóbrega L.G.B., Barros R.M., Tiago Filho G.L. (2018): Assessment of potential biogas production from multiple organic wastes in Brazil: impact on energy generation, use, and emissions abatement. Resources, Conservation and Recycling, 131: 54-63. Go to original source...
    60. Södergren J., Larsson C.U., Wadsö L., Bergstrand K.-J., Asp H., Hultberg M., Schelin J. (2022): Food waste to new food: risk assessment and mi-crobial community analysis of anaerobic digestate as a nutrient source in hydroponic production of vegetables. Journal of Cleaner Production, 333: 130239. Go to original source...
    61. Somers E., Vanderleyden J., Srinivasan M. (2004): Rhizosphere bacterial signalling: a love parade beneath our feet. Critical Reviews in Microbiolo-gy, 30: 205-240. Go to original source... Go to PubMed...
    62. Souza R. de, Ambrosini A., Passaglia L.M.P. (2015): Plant growth-promoting bacteria as inoculants in agricultural soils. Genetics and Molecular Biology, 38: 401-419. Go to original source... Go to PubMed...
    63. Tampio E., Marttinen S., Rintala J. (2016): Liquid fertilizer products from anaerobic digestion of food waste: mass, nutrient and energy balance of four digestate liquid treatment systems. Journal of Cleaner Production, 125: 22-32. Go to original source...
    64. Tashyrev O.B., Matvieieva N.A., Hovorukha V.M., Tashyreva H.O., Bielikova O.I., Havryliuk O.A., Duplij V.P. (2018): Application of lignocellulo-sic substrate obtained after hydrogen dark fermentation of food waste as biofertilizer. Industrial Biotechnology, 14: 315-322. Go to original source...
    65. Tsai S.H., Liu C.P., Yang S.S. (2007): Microbial conversion of food wastes for biofertilizer production with thermophilic lipolytic microbes. Renew-able Energy, 32: 904-915. Go to original source...
    66. Walker L., Charles W., Cord-Ruwisch R. (2009): Comparison of static, in-vessel composting of MSW with thermophilic anaerobic digestion and combinations of the two processes. Bioresource Technology, 100: 3799-3807. Go to original source... Go to PubMed...
    67. Wang T.T., Wang S.P., Zhong X.Z., Sun Z.Y., Huang Y.L., Tan L., Tang Y.Q., Kida K. (2017): Converting digested residue eluted from dry anaero-bic digestion of distilled grain waste into value-added fertilizer by aerobic composting. Journal of Cleaner Production, 166: 530-536. Go to original source...
    68. Wu L., Wei W., Liu X., Wang D., Ni B.J. (2022): Potentiality of recovering bioresource from food waste through multi-stage co-digestion with enzymatic pretreatment. Journal of Environmental Management, 319: 115777. Go to original source... Go to PubMed...
    69. Xin X., Ma Y., Liu Y. (2018): Electric energy production from food waste: microbial fuel cells versus anaerobic digestion. Bioresource Technology, 255: 281-287. Go to original source... Go to PubMed...
    70. Xu F., Li Y., Ge X., Yang L., Li Y. (2018): Anaerobic digestion of food waste - challenges and opportunities. Bioresource Technology, 247: 1047-1058. Go to original source... Go to PubMed...
    71. Yadav M., Goswami P., Paritosh K., Kumar M., Pareek N., Vivekanand V. (2019): Seafood waste: a source for preparation of commercially em-ployable chitin/chitosan materials. Bioresources and Bioprocessing, 6: 8. Go to original source...
    72. Yu Z., Zhang Y., Zhang X., Wang Y. (2015): Conversion of food waste into biofertilizer for the biocontrol of root knot nematode by Paecilomyces lilacinus. Environmental Technology, 36: 3148-3158. Go to original source... Go to PubMed...
    73. Yusof Z., Ramasamy S., Mahmood N., Yaacob J.S. (2018): Vermicompost supplementation improves the stability of bioactive anthocyanin and phenolic compounds in Clinacanthus nutans Lindau. Molecules, 23: 1345. Go to original source... Go to PubMed...
    74. Zaman A., Yaacob J.S. (2022): Exploring the potential of vermicompost as a sustainable strategy in circular economy: improving plants' bioactive properties and boosting agricultural yield and quality. Environmental Science and Pollution Research, 29: 1-17. Go to original source... Go to PubMed...
    75. Zhang C., Xiao G., Peng L., Su H., Tan T. (2013): The anaerobic co-digestion of food waste and cattle manure. Bioresource Technology, 129: 170-176. Go to original source... Go to PubMed...

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