REFERENCES

1. Guo, X.; Broeze, J.; Groot, J. J.; Axmann, H.; Vollebregt, M. A worldwide hotspot analysis on food loss and waste, associated greenhouse gas emissions, and protein losses. Sustainability 2020, 12, 7488.

2. FAO. Hunger numbers stubbornly high for three consecutive years as global crises deepen: UN report. 2023. https://www.fao.org/newsroom/detail/hunger-numbers-stubbornly-high-for-three-consecutive-years-as-global-crises-deepen--un-report/en (accessed 2026-01-16).

3. Campbell, B. M.; Beare, D. J.; Bennett, E. M.; et al. Agriculture production as a major driver of the Earth system exceeding planetary boundaries. Ecology. Soc. 2017, 22.

4. Rodrigues, M.; Miguéis, V. A literature review on the quantitative approaches to food waste: descriptive, predictive, and prescriptive analyses. Environ. Sci. Pollut. Res. Int. 2025, 32, 21301-37.

5. Negi, S.; Fan, L.; Kim, H.; Hidaka, T.; Rani, A.; Pan, S. Unlocking the potential of global greenhouse gas mitigation by reducing food loss and waste. J. Agric. Food. Res. 2025, 21, 101925.

6. Yılmaz, S.; Günal, A. M.; Köse, G.; Baş, M. The environmental and economic dynamics of food waste and greenhouse gas emissions: a causal time series analysis from 2000 to 2022. Sustainability 2025, 17, 775.

7. Al Sholi, H. Y.; Wakjira, T.; Kutty, A. A.; et al. How circular economy can reduce scope 3 carbon footprints: lessons learned from FIFA world cup Qatar 2022. Circular. Economy. 2023, 2, 100026.

8. Gazal, A. A.; Bonnet, S.; Silalertruksa, T.; Gheewala, S. H. Circular economy strategies for agri-food production - a review. Circ. Econ. Sust. 2025, 5, 2467-93.

9. Thi, N. B.; Kumar, G.; Lin, C. Y. An overview of food waste management in developing countries: current status and future perspective. J. Environ. Manage. 2015, 157, 220-9.

10. Hanson, C.; Lipinski, B.; Robertson, K.; et al. Food loss and waste accounting and reporting standard. 2016. https://flwprotocol.org/wp-content/uploads/2017/05/FLW_Standard_final_2016.pdf (accessed 2026-01-16).

11. Gustavsson, J.; Cederberg, C.; Sonesson, U. Global food losses and food waste. Swedish Institute for Food and Biotechnology (SIK), Gothenburg; Robert van Otterdijk Alexandre Meybeck FAO Rome, Italy. 2011. https://openknowledge.fao.org/server/api/core/bitstreams/10388b16-5f1a-45d0-b690-e89bb78d33bb/content (accessed 2026-01-16).

12. Aragie, E.; Balié, J.; MoralesOpazo, C. Does reducing food losses and wastes in sub-Saharan Africa make economic sense? Waste. Manag. Res. 2018, 36, 483-94.

13. Tostivint, C.; de Veron, S.; Jan, O.; Lanctuit, H.; Hutton, Z. V.; Loubière, M. Measuring food waste in a dairy supply chain in Pakistan. J. Clean. Prod. 2017, 145, 221-31.

14. EMBRAPA. The 2023 Dairy Yearbook. Embrapa Dairy Cattle. 2023. https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1154264/anuario-leite-2023-leite-baixo-carbono (accessed 2026-01-16).

15. FAO. World food and agriculture - statistical yearbook 2021. https://openknowledge.fao.org/items/3bd1ea1c-6865-4e1a-b1a1-dd4ce7266a7c (accessed 2026-01-16).

16. Silva, D. V. D.; Pavan, A. L. R.; Faria, L. C. D.; Piekarski, C. M.; Saavedra, Y. M. B.; Lopes Silva, D. A. Opportunities to integrate ecosystem services into life cycle assessment (LCA): a case study of milk production in Brazil. Ecosyst. Serv. 2024, 69, 101646.

17. EMBRAPA. The consumer market for milk and dairy products. Juiz de Fora: Embrapa Dairy Cattle. 2019. http://www.infoteca.cnptia.embrapa.br/infoteca/handle/doc/1110792 (accessed 2026-01-16).

18. Karkou, E.; Teo, C. J.; Savvakis, N.; Poinapen, J.; Arampatzis, G. Industrial circular water use practices through the application of a conceptual water efficiency framework in the process industry. J. Environ. Manage. 2024, 370, 122596.

19. Damian, C. S.; Devarajan, Y.; Jayabal, R. A comprehensive review of the resource efficiency and sustainability in biofuel production from industrial and agricultural waste. J. Mater. Cycles. Waste. Manag. 2024, 26, 1264-76.

20. Al‐hammadi, M.; Güngörmüşler, M. From refuse to resource: exploring technological and economic dimensions of waste‐to‐energy. Biofuels. Bioprod. Bioref. 2025, 19, 570-92.

21. Scherhaufer, S.; Moates, G.; Hartikainen, H.; Waldron, K.; Obersteiner, G. Environmental impacts of food waste in Europe. Waste. Manag. 2018, 77, 98-113.

22. Salihoglu, G.; Salihoglu, N. K.; Ucaroglu, S. Banar M. Food loss and waste management in Turkey. Bioresour. Technol. 2017, 248(PA), 88-99.

23. Veteikytė, A.; Šiekštelė, R.; Tvaska, B.; Matijošytė, I. Sequential application of waste whey as a medium component for Kluyveromyces lactis cultivation and a co-feeder for lipase immobilization by CLEA method. Appl. Microbiol. Biotechnol. 2017, 101, 3617-26.

24. Brändström, J.; Saidani, M. Comparison between circularity metrics and LCA: a case study on circular economy strategies. J. Clean. Prod. 2022, 371, 133537.

25. European Commission. European Green Deal COM 640. Brussels. 2019. https://eur-lex.europa.eu/legal-content/PT/TXT/?uri=COM%3A2019%3A640%3AFIN (accessed 2026-01-16).

26. Bleischwitz, R.; Yang, M.; Huang, B.; et al. The circular economy in China: Achievements, challenges and potential implications for decarbonisation. Resour. Conserv. Recycl. 2022, 183, 106350.

27. Rood, T.; Muilwijk, H.; Westhoek, H. Food for the Circular Economy. PBL Netherlands Environmental Assessment Agency. Haia. 2017. https://www.pbl.nl/uploads/default/downloads/PBL-2017-Food-for-the-circular-economy-2878.pdf (accessed 2026-01-16).

28. Ahmad, T.; Aadil, R. M.; Ahmed, H.; et al. Treatment and utilization of dairy industrial waste: a review. Trends. Food. Sci. Technol. 2019, 88, 361-72.

29. Principato, L.; Ruini, L.; Guidi, M.; Secondi, L. Adopting the circular economy approach on food loss and waste: the case of Italian pasta production. Resour. Conserv. Recycl. 2019, 144, 82-9.

30. Oliveira, M. M. D.; Lago, A.; Dal’Magro, G. P. Food loss and waste in the context of the circular economy: a systematic review. J. Clean. Prod. 2021, 294, 126284.

31. WRAP. Household food & drink waste: a product focus. 2014. https://www.wrap.ngo/resources/report/household-food-drink-waste-product-focus (accessed 2026-01-16).

32. Lipinski, B. FLW quantification method ranking tool. WRI. 2016. https://flwprotocol.org/flw-standard/ (accessed 2026-01-16).

33. Östergren, K.; Gustavsson, J.; Bos-Brouwers, H.; et al. FUSIONS definitional framework for food waste - full report. Project report FUSIONS. 2014. https://hal.inrae.fr/hal-02800861/file/2014_Barbara%20redlingshofer_FUSIONS%20Definitional%20framework%2003072014_1.pdf (accessed 2026-01-16).

34. Campbell, C. G.; Feldpausch, G. L. Invited review: the consumer and dairy food waste: an individual plus policy, systems, and environmental perspective. J. Dairy. Sci. 2022, 105, 3736-45.

35. ADPF. Managing climate and environment. Dairy sector food waste action plan. Stop Food Waste Australia. 2023. https://endfoodwaste.com.au/wp-content/uploads/2023/11/Dairy-Food-Waste-Action-Plan-Report.pdf (accessed 2026-01-16).

36. Abiq - Brazilian Association of Cheese Industries. News, 2019. https://abiq.com.br/ (accessed 2026-01-16).

37. Buzby, J. C.; Farah-Wells, H.; Hyman, J. The estimated amount, value, and calories of postharvest food losses at the retail and consumer levels in the United States. USDA-ERS Economic Information Bulletin Number 121. https://papers.ssrn.com/sol3/papers.cfm?abstract_id=2501659 (accessed 2026-01-16).

38. Al-Obadi, M. Dairy wastage footprint analysis: a farm-to-fork life cycle approach across dairy supply chain. In Proceedings of the First Central American and Caribbean International Conference on Industrial Engineering and Operations Management, Port-au-Prince, Haiti, June 15-16, 2021. https://ieomsociety.org/proceedings/2021haiti/245.pdf (accessed 2026-01-16).

39. Kechagias, E. P.; Gayialis, S. P.; Panayiotou, N.; Papadopoulos, G. A. A holistic framework for evaluating food loss and waste due to marketing standards across the entire food supply Chain. Foods 2024, 13, 3273.

40. Glanz, R. Causes of food waste generation in households - an empirical analysis. Department of Water, Atmosphere and Environment and School of Applied Sciences, University of Natural Resources and Applied Life Sciences, Vienna and Cranfield University. 2008. https://www.readkong.com/page/university-of-natural-resources-and-applied-life-sciences-1185871 (accessed 2026-01-16).

41. Parfitt, J.; Barthel, M.; Macnaughton, S. Food waste within food supply chains: quantification and potential for change to 2050. Philos. Trans. R. Soc. Lond. B. Biol. Sci. 2010, 365, 3065-81.

42. Mehner, E.; Fantin, V.; Pizzichini, D.; Vaccari, M. Decentralised by-product valorisation in the dairy value chain: an opportunity for sustainable intensification. J. Clean. Prod. 2024, 478, 143958.

43. Nicolás, P.; Ferreira, M. L.; Lassalle, V. A review of magnetic separation of whey proteins and potential application to whey proteins recovery, isolation and utilization. J. Food. Eng. 2019, 246, 7-15.

44. Mirzakulova, A.; Sarsembaeva, T.; Suleimenova, Z.; et al. Whey: composition, processing, application, and prospects in functional and nutritional beverages-a review. Foods 2025, 14, 3245.

45. Martínez-Ruano, J. A.; Restrepo-serna, D. L.; Carmona-garcia, E.; Giraldo, J. A. P.; Aroca, G.; Cardona, C. A. Effect of co-digestion of milk-whey and potato stem on heat and power generation using biogas as an energy vector: techno-economic assessment. Appl. Energy. 2019, 241, 504-18.

46. Prazeres, A. R.; Carvalho, F.; Rivas, J. Cheese whey management: a review. J. Environ. Manage. 2012, 110, 48-68.

47. Giulianetti de Almeida, M. P.; Mockaitis, G.; Weissbrodt, D. G. Got Whey? Sustainability endpoints for the dairy industry through resource biorecovery. Fermentation 2023, 9, 897.

48. Ribera-pi, J.; Badia-fabregat, M.; Calderer, M.; et al. Anaerobic membrane bioreactor (AnMBR) for the treatment of cheese whey for the potential recovery of water and energy. Waste. Biomass. Valor. 2020, 11, 1821-35.

49. Quaiser, J.; Gilbert, E. M. Wastewater treatment in the dairy processing industry - recovering energy using anaerobic technology. 2016. https://www.researchgate.net/publication/297685564_Wastewater_treatment_in_the_dairy_processing_industry_-_recovering_energy_using_anaerobic_technology (accessed 2026-01-16).

50. Meneses, Y. E.; Flores, R. A. Feasibility, safety, and economic implications of whey-recovered water in cleaning-in-place systems: a case study on water conservation for the dairy industry. J. Dairy. Sci. 2016, 99, 3396-407.

51. Gil, F.; Taf, R.; Mikula, K.; et al. Advancing sustainable agriculture: converting dairy wastes into amino acid fertilizers. Sustain. Chem. Pharm. 2024, 42, 101782.

52. Mozejko-Ciesielska, J.; Moraczewski, K.; Czaplicki, S.; Singh, V. Production and characterization of polyhydroxyalkanoates by Halomonas alkaliantarctica utilizing dairy waste as feedstock. Sci. Rep. 2023, 13, 22289.

53. Jansen, M. Duckweed: a key component for recycling dairy processing wastewater. 2018. https://www.ucc.ie/en/newtrients/blog/duckweed-a-key-component-for-recycling-dairy-processing-wastewater.html (accessed 2026-01-16).

54. O’Mahoney, R.; Coughlan, N. E.; Walsh, É.; Jansen, M. A. K. Cultivation of lemna minor on industry-derived, anaerobically digested, dairy processing wastewater. Plants 2022, 11, 3027.

55. Galanakis, C. M. Food waste recovery: processing technologies and industrial techniques. 2015 Elsevier. https://shop.elsevier.com/books/food-waste-recovery/galanakis/978-0-12-800351-0 (accessed 2026-01-21).

56. Chandrasekaran, M. Valorization of food processing by-products, 1th ed.; Taylor & Francis Group, Florida, 2013, pp739-56. https://www.routledge.com/link/link/p/book/9781138199422 (accessed 2026-01-21).

57. Luo, N.; Olsen, T.; Liu, Y.; Zhang, A. Reducing food loss and waste in supply chain operations. Transp. Res. Part. E. Logist. Transp. Rev. 2022, 162, 102730.

58. Romadlon, F.; Wan Ahmad, W. N. K.; Shamsuddin, A.; et al. Systematic review on mitigation of food loss and waste in the milk supply chain. E3S. Web. Conf. 2025, 603, 04006.

59. Sar, T.; Harirchi, S.; Ramezani, M.; et al. Potential utilization of dairy industries by-products and wastes through microbial processes: a critical review. Sci. Total. Environ. 2022, 810, 152253.