Back Article

Simmer RA, Jansen EJ, Patterson KJ, Schnoor JL. 2023. Climate change and the sea: a major disruption in steady state and the master variables. ACS Environmental Au 4(3):195−208

Manzoor S, Fayaz U, Dar AH, Dash KK, Shams R, et al. 2024. Sustainable development goals through reducing food loss and food waste: a comprehensive review. Future Foods 9:100362

Borsetta G, Zovi A, Vittori S. 2025. Long-term frameworks for food security and sustainability through climate-smart interconnected agrifood systems. Sci 7(1):15

Food and Agriculture Organization of the United Nations (FAO), International Fund for Agricultural Development (IFAD), United Nations Children’s Fund (UNICEF), World Food Programme (WFP), World Health Organization (WHO). 2025. The state of food security and nutrition in the world 2025. Rome, Italy: FAO, IFAD, UNICEF, WFP, WHO. doi: 10.4060/cd6008en

United Nations Environment Programme (UNEP). 2024. Think eat save tracking progress to halve global food waste. https://www.unep.org/resources/publication/food-waste-index-report-2024

World Bank. 2020. Addressing food loss and waste: A global problem with local solutions. https://openknowledge.worldbank.org/server/api/core/bitstreams/674c11d6-79eb-5905-8822-fcd9663eabb4/content

Goraya RK, Singla M, Kaura R, Singh CB, Singh A. 2025. Exploring the impact of high pressure processing on the characteristics of processed fruit and vegetable products: a comprehensive review. 2025. Critical Reviews in Food Science and Nutrition 65(20):3856−3879

Aganovic K, Hertel C, Vogel RF, Johne R, Schlüter O, et al. 2021. Aspects of high hydrostatic pressure food processing: perspectives on technology and food safety. Comprehensive Reviews in Food Science and Food Safety 20(4):3225−3266

Raak N, Symmank C, Zahn S, Aschemann-Witzel J, Rohm H. 2017. Processing- and product-related causes for food waste and implications for the food supply chain. Waste Management 61:461−472

Xue L, Liu G. 2019. Introduction to global food losses and food waste. In Saving Food, ed. Galanakis CM. USA: Academic Press. pp. 1−31 doi: 10.1016/B978-0-12-815357-4.00001-8

Nema PK, Sehrawat R, Ravichandran C, Kaur BP, Kumar A, et al. 2022. Inactivating food microbes by high-pressure processing and combined nonthermal and thermal treatment: a review. Journal of Food Quality 2022:5797843

Sampedro F, McAloon A, Yee W, Fan X, Geveke DJ. 2014. Cost analysis and environmental impact of pulsed electric fields and high pressure processing in comparison with thermal pasteurization. Food and Bioprocess Technology 7(7):1928−1937

Anandharamakrishnan C, Sinija VR, Mahendran R (Eds. ) 2024. Non-thermal technologies for the food industry: Advances and regulations. CRC Press. 392 doi: 10.1201/9781003359302

Kateh SA, Purnomo EH, Hasanah U. 2024. Meta-analysis: Microbial inactivation in milk using high-pressure processing (HPP). International Journal of Food Science and Technology 59(6):4185−4193

Serment-Moreno V, Barbosa-Cánovas G, Torres JA, Welti-Chanes J. 2014. High-pressure processing: kinetic models for microbial and enzyme inactivation. Food Engineering Reviews 6(3):56−88

Szczepańska J, Barba FJ, Skąpska S, Marszałek K. 2020. High pressure processing of carrot juice: effect of static and multi-pulsed pressure on the polyphenolic profile, oxidoreductases activity and colour. Food Chemistry 307:125549

Balasubramaniam VM. 2021. Process development of high pressure-based technologies for food: research advances and future perspectives. Current Opinion in Food Science 42:270−277

Knoerzer K, Sevenich R. 2025. From concept to commercialization: unlocking the potential of high-pressure thermal processing. Food Engineering Reviews 17:627−644

Song Q, Li R, Song X, Clausen MP, Orlien V, et al. 2022. The effect of high-pressure processing on sensory quality and consumer acceptability of fruit juices and smoothies: a review. Food Research International 157:111250

Fernández-Sestelo A, de Saá RS, Pérez-Lamela C, Torrado-Agrasar A, Rúa ML, et al. 2013. Overall quality properties in pressurized kiwi purée: Microbial, physicochemical, nutritive and sensory tests during refrigerated storage. Innovative Food Science & Emerging Technologies 20:64−72

Hiperbaric. 2021. Hiperbaric HPP in-bulk: an award-winning solution for large productions of beverages. www.hiperbaric.com/en/hiperbaric-hpp-in-bulk-an-award-winning-solution-for-large-productions-of-beverages/

Nabi BG, Mukhtar K, Arshad RN, Radicetti E, Tedeschi P, et al. 2021. High-pressure processing for sustainable food supply. Sustainability 13(24):13908

Reesman C, Sullivan G, Danao MG, Pfeiffer M, More S, et al. 2023. Use of high-pressure processing to improve the redness of dark-cutting beef. Meat and Muscle Biology 7(1):15716

Barbosa-Cánovas GV, Juliano P. 2008. Food sterilization by combining high pressure and thermal energy. In Food Engineering: Integrated Approaches, eds. Gutiérrez-López GF, Barbosa-Cánovas GV, Welti-Chanes J, Parada-Arias E. New York, NY: Springer. pp. 9–46 doi: https://doi.org/10.1007/978-0-387-75430-7_2

Paini A, Stefanini R, Vignali G. 2022. Environmental impact analysis of HPP and PCT decontamination technologies: an LCA comparison. Proceedings of the 8^th International Food Operations and Processing Simulation Workshop, 19−21 2022, Rome, Italy. Italy: Caltek. doi: 10.46354/i3m.2022.foodops.006

Pardo G, Zufía J. 2012. Life cycle assessment of food-preservation technologies. Journal of Cleaner Production 28(7):198−207

Muñoz I, de Sousa DAB, Guardia MD, Rodriguez CJ, Nunes ML, et al. 2022. Comparison of different technologies (conventional thermal processing, radiofrequency heating and high-pressure processing) in combination with thermal solar energy for high quality and sustainable fish soup pasteurization. Food Bioprocessing and Technology 15(4):795−805

Koutchma T. 2014. Adapting High Hydrostatic Pressure (HPP) for Food Processing Operations. USA: Academic Press. pp. 1−67 doi: 10.1016/C2013-0-12997-2

Pauziah M, Hamilah H, Tarmizi S, Masdek N. 1992. Quality evaluation of hand-harvested fruit of durian clone D24. Proceedings of the National IRPA Intensification of research in Priority Areas Seminar Agricultural Sector. Serdang, Malaysia: Universiti Pertanian Malaysia: pp. 634−635

Araújo RG, Rodriguez-Jasso RM, Ruiz HA, Govea-Salas M, Pintado ME, et al. 2020. Process optimization of microwave-assisted extraction of bioactive molecules from avocado seeds. Industrial Crops and Products 154:112623

Espinosa-García FJ, García-Rodríguez YM, Bravo-Monzón AE, Vega-Peña EV, Delgado-Lamas G. 2021. Implications of the foliar phytochemical diversity of the avocado crop Persea americana cv. Hass in its susceptibility to pests and pathogens. PeerJ 9:e11796

Hiperbaric. 2013. Guacamole and avocado products. www.hiperbaric.com/en/hpp-technology/hpp-applications/guacamole-and-avocado-products/

Ketsa S, Daengkanit T. 1998. Changes in softening enzymes of durian fruit ripening. International Postharvest Science Conference Postharvest. Acta Horticulturae. pp. 451−454 doi: 10.17660/actahortic.1998.464.70

Tan PF, Ng SK, Tan TB, Chong GH, Tan CP. 2018. Shelf life determination of durian (Durio zibethinus) paste and pulp upon high pressure processing. Food Research 3(3):221−230

Nitta N. 2022. How high-pressure processing is helping remote farmers bring fresher foods to market: a cold preservation method is pumping more value into crops by capturing ripeness and extending shelf life. https://modernfarmer.com/2022/05/high-pressure-processing-food-security/

Bu Z, Luo W, Wei J, Peng J, Wu J, et al. 2022. Impacts of thermal processing, high pressure, and CO₂-assisted high pressure on quality characteristics and shelf life of durian fruit puree. Foods 11(17):2717

Woolf AB, Wibisono R, Farr J, Hallett I, Richter L, et al. 2013. Effect of high pressure processing on avocado slices. Innovative Food Science & Emerging Technologies 18:65−73

Chin ST, Hamid Nazimah SA, Quek SY, Bin Che Man Y, et al. 2010. Effect of thermal processing and storage condition on the flavour stability of spray-dried durian powder. LWT − Food Science and Technology 43(6):856−861

Suzihaque MUH, Jamil NAM, Sahabuzan SNZ, Alwi H, Abd Karim SF. 2025. Effects of high-pressure process (HPP) treatment of tempoyak on microbial growth. Archives of Metallurgy and Materials 70(2):843−850

Leong SY, Duque SMM, Conde LA, Khrisanapant P, Oey I. 2024. Addressing the opportunities of non-thermal food processing technologies in the ASEAN region context. International Journal of Food Science and Technology 59(10):7739−7753

Sundram P. 2023. Food security in ASEAN: progress, challenges and future. Frontier Sustainable Food System 7:1260619

Rajashri K, Rastogi NK, Negi PS. 2022. Non- thermal processing of tender coconut water − a review. Food Reviews International 38:34−55

Rethinam P, Krishnakumar V. 2022. Global scenario of coconut and coconut water. In Coconut Water, eds. Rethinam P, Krishnakumar V. Cham: Springer International Publishing. pp. 17–35 doi: 10.1007/978-3-031-10713-9_2

Ma Y, Xu L, Wang S, Xu Z, Liao X, et al. 2019. Comparison of the quality attributes of coconut waters by high-pressure processing and high-temperature short time during the refrigerated storage. Food Science & Nutrition 7(4):1512−1519

Raghubeer EV, Phan BN, Onuoha E, Diggins S, Aguilar V, et al. 2020. The use of high-pressure processing (HPP) to improve the safety and quality of raw coconut (Cocos nucifera L) water. International Journal of Food Microbiology 331:108697

Khaizura MARN, Pratama AB, Chorng PK, Mohamad A, Azman EM, et al. 2025. Chilli paste processing using high-pressure and conventional approaches. Canrea Journal: Food Technology, Nutritions, and Culinary Journal 8(1):184−200

Hiperbaric. 2023. Regulatory Compliance in Asia and Oceania for HPP Products. www.hiperbaric.com/en/regulatory-compliance-in-asia-and-oceania-for-hpp-products/

Xu Z. 2025. How to transfer innovative ideas into market success: The story of HPP products in China. IFT-NPD/EFFoST Nonthermal Processing Workshop, 2025. www.2025nonthermal.com/