Journal of food science and technology(Iran)

Journal of food science and technology(Iran)

Applications of Novel Frying Technologies in Food Processing: Advantages, Limitations, and Industrial Challenges

Document Type : Analytic Review

Authors
bahareh maroufpour 1
aman mohammad ziaiifar 2
hassan sabbaghi 3
Mohammad Ghorbani 4
Saeed Yalghi 5
1 Gorgan University of Agricultural Sciences and Natural Resources
2 Department of Food Industry Engineering, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran
3 Department of Food Science and Technology, Faculty of Agriculture and Animal Science, University of Torbat-e Jam, Razavi Khorasan Province, Iran
4 Professor, Department of Food Chemistry, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran
5 Assistant Professor of Fisheries Department, Golestan Province Fisheries Research Center, Gorgan, Iran
10.48311/fsct.2026.115543.1000
Abstract
Frying is one of the most widely used food processing methods employed by consumers, restaurants, and the food industry worldwide to produce products with distinctive sensory characteristics. The most common approach is deep frying, which, despite its high popularity, is associated with high oil absorption and the formation of carcinogenic compounds such as acrylamide. Regular consumption of deep-fried foods may increase the risk of cardiovascular diseases, diabetes, hypertension, cancer, and obesity. In recent years, novel processing methods including hot air frying, vacuum frying, microwave frying, and hybrid technologies have been developed. These approaches have been introduced as healthier alternatives to deep frying and are capable of reducing oil uptake while maintaining desirable sensory properties. Moreover, they contribute to improving the nutritional quality and overall health attributes of fried products. Consequently, the production of a new generation of healthier fried foods has become feasible. In this review, the operating mechanisms, advantages, and limitations of these novel frying methods in the food industry are discussed. Finally, a comparative framework based on energy consumption, product quality, consumer acceptance, and industrial scalability is presented to identify existing research gaps and provide new insights into food frying technologies.
Keywords
Keywords: Frying
Novel processing methods
Oil absorption
Nutritional quality
Industrial scalability
Subjects
[1] Krokida, M.K., Oreopoulou, V., and Maroulis, Z.B. (2000b). Water Loss and Oil Uptake as a Function of Frying    Time, Journal of Food Engineering, 44: 39-46.
[2] Frakolaki, G., Kekes, T., Bizymis, A.-P., Giannou, V., & Tzia, C. (2023). Fundamentals of food frying processes. In High-temperature processing of food products (pp. 227–291).
[3] Bouchon, P. (2009). Understanding oil absorption during deep-fat frying. In Advances in Food and Nutrition Research (Vol. 57, pp. 209–234). Academic Press.
[4] Dehghannya, J., & Ngadi, M. (2021). Recent advances in microstructure characterization of fried foods: Different frying techniques and process modeling. Trends in Food Science & Technology, 116, 786–801.
[5] Mesias, M., Delgado-Andrade, C., Holgado, F., González-Mulero, L., & Morales, F. J. (2021). Effect of consumer's decisions on acrylamide exposure during the preparation of French fries. Part 1: Frying conditions. Food and Chemical Toxicology, 147, 111857.
[6] Amany, M. M. B., & Hala, H. A. O. (2016). Effect of a novel technology (air and vacuum frying) on sensory evaluation and acrylamide generation in fried potato chips. Banat's Journal of Biotechnology, 7(14), 101.
[7] Garayo, J., and Moreira, R. (2002). Vacuum frying of potatoes chips. Journal of Food Engineering, 55: 181-191.
[8] Cai, L., Wang, Z., Ji, A., Meyer, J. M., & van der Westhuyzen, D. R. (2012). Scavenger receptor CD36 expression contributes to adipose tissue inflammation and cell death in diet-induced obesity. PloS one, 7(5), e36785.
[9] Cahill, L. E., Pan, A., Chiuve, S. E., Sun, Q., Willett, W. C., Hu, F. B., & Rimm, E. B. (2014). Fried-food consumption and risk of type 2 diabetes and coronary artery disease: a prospective study in 2 cohorts of US women and men. The American journal of clinical nutrition, 100(2), 667-675.
[10] Saguy, I.S., and Dana, D. (2003). Integrated approach to deep fat frying: engineering, nutrition, health and consumer aspects, Journal of Food Engineering, 56: 143-152.
[11] Valle, C., Echeverría, F., Chávez, V., Valenzuela, R., & Bustamante, A. (2024). Deep‐frying impact on food and oil chemical composition: Strategies to reduce oil absorption in the final product. Food Safety and Health2(4), 414-428.
[12] Yu, K., Cho, H., & Hwang, K. (2018). Physicochemical properties and oxidative stability of frying oils during repeated frying of potato chips. Food Science and Biotechnology27(3), 651–659. 
[13] Millin, T. M., Medina-Meza, I. G., Walters, B. C., Huber, K. C., Rasco, B. A., & Ganjyal, G. M. (2016). Frying oil temperature: Impact on physical and structural properties of French fries during the par and finish frying processes. Food and Bioprocess Technology, 9(12), 2080–2091.
[14] Ziaiifar, A. M., Achir, N., Courtois, F., Trezzani, I., & Trystram, G. (2008). Review of mechanisms, conditions, and factors involved in the oil uptake phenomenon during the deep-fat frying process. International Journal of Food Science & Technology, 43(8), 1410–1423.
[15] Alam, T., & Takhar, P. (2016). Microstructural characterization of fried potato disks using X-ray micro computed tomography. Journal of Food Science81(3). 
[16] Devi, S., Zhang, M., Ju, R., & Bhandari, B. (2021). Recent development of innovative methods for efficient frying technology. Critical Reviews in Food Science and Nutrition, 61(22), 1–16.
[17] Sabbaghi, Ziaiifar, Amanmohammad, Sadeghi Mahoonak, Kashaninejad, & Mirzaei. (2015). Evaluation of mathematical models in describing the effect of temperature on oil absorption during the frying process. Iranian Journal of Biosystems Engineering, 46(2), 135–145.
[18] Mahmud, N., Islam, J., Oyom, W., Adrah, K., Adegoke, S., & Tahergorabi, R. (2023). A review of different frying oils and oleogels as alternative frying media for fat-uptake reduction in deep-fat fried foods. Heliyon, 9(11), e21500.
[19] Wiege, B., Fehling, E., Matthäus, B., & Schmidt, M. (2020). Changes in physical and chemical properties of thermally and oxidatively degraded sunflower oil and palm fat. Foods, 9(9), 1273.
[20] Ziaiifar, A. M., Courtois, F., & Trystram, G. (2010). Porosity development and its effect on oil uptake during frying process. Journal of Food Process Engineering, 33(2), 191–212.
[21] Khaliliyan, S., Ziaiifar, A. M., Asghari, A., & Mohebi, M. (2017). Effect of cooking pretreatment on frying process of eggplant and evaluation of kinetic of oil absorption and moisture changes of eggplant during deep fat frying and cooling period. Journal of food science and technology (Iran)14(62), 154-147.
[22] Taghavi, N. , Ziaiifar, A. M. , Mirzaee, H. , Sadeghi Mahoonak, A. , Ghorbani, M. and Sabbaghi, H. (2018). Investigation on effect of coating on the oil uptake during deep fat frying process of traditional sweet Pishmeh. Iranian Food Science and Technology Research Journal, 14(4), 561-571.
[23] Sabbaghi, H. , Ziaiifar, A. M. and Kashaninejad, M. (2017). Analysis of heat and mass transfer during frying process of potato strips. Iranian Food Science and Technology Research Journal, 13(2), 379-392.
[24] Zaghi, A. N., Barbalho, S. M., Guiguer, E. L., & Otoboni, A. M. (2019). Frying Process: From Conventional to Air Frying Technology. Food Reviews International, 35(8), 763-777.
[25] Zhang, Q., Saleh, A. S., & Shen, Q. (2016). Monitoring of changes in composition of soybean oil during deep-fat frying with different food types. Journal of the American Oil Chemists’ Society, 93(1), 69–81.
[26] Yaghmur, A., Aserin, A., Mizrahi, Y., Nerd, A., & Garti, N. (2001). Evaluation of argan oil for deep-fat frying. LWT – Food Science and Technology, 34(3), 124–130.
[27] Dourado, C., Pinto, C. A., Cunha, S. C., Casal, S., & Saraiva, J. A. (2020). A novel strategy of acrylamide mitigation in fried potatoes using asparaginase and high pressure technology. Innovative Food Science & Emerging Technologies, 60, 102310.
[28] Pedreschi, F., Kaack, K., & Granby, K. (2004). Reduction of acrylamide formation in potato slices during frying. LWT – Food Science and Technology, 37(6), 679–685.
[29] Ngobese, N. Z., Workneh, T. S., & Siwela, M. (2017). Effect of low-temperature long-time and high-temperature short-time blanching and frying treatments on the French fry quality of six Irish potato cultivars. Journal of food science and technology, 54(2), 507-517.
[30] Fan, L., Zhang, M., and Mujumdar, A.S. (2005a). Vacuum frying of carrots chips. Drying Technology, 23: 645-656.
[31] Da Silva, P. F., & Moreira, R. G. (2008). Vacuum frying of high-quality fruit and vegetable-based snacks. LWT-Food Science and Technology, 41(10), 1758-1767.
[32] Sabbaghi, H. (2021). Application of hydrocolloid compounds (xanthan and carboxymethylcellulose) in doughnut formulation for reducing oil uptake. Iranian Food Science and Technology Research Journal, 17(5), 919-940.
[33] Hosseini, H., Ghorbani, M., Meshginfar, N., & Mahoonak, A. (2016). A review on frying: Procedure, fat, deterioration progress and health hazards. Journal of the American Oil Chemists’ Society, 93(4), 445–466. 
[34] Teruel, M. D. R., Gordon, M., Linares, M. B., Garrido, M. D., Ahromrit, A., & Niranjan, K. (2015). A comparative study of the characteristics of french fries produced by deep fat frying and air frying. Journal of Food Science, 80(2), E349-E358.
[35] Giovanelli, G., Torri, L., Sinelli, N., & Buratti, S. (2017). Comparative study of physico-chemical and sensory characteristics of French fries prepared from frozen potatoes using different cooking systems. European Food Research and Technology, 243(9), 1619-1631.
[36] Maroufpour, B., Ziaiifar, A. M., Ghorbani, M., Sabbaghi, H., & Yalghi, S. (2025a). Hot Air Frying as a Healthier Alternative to Deep Fat Frying for Shrimp: Comparative Analysis of Physicochemical and Sensory Properties. Applied Food Research, 101425.
[37] Fang, M., Huang, G. J., & Sung, W. C. (2021). Mass transfer and texture characteristics of fish skin during deep-fat frying, electrostatic frying, air frying and vacuum frying. Lwt, 137, 110494.
[38] Patra, A., Prasath, V. A., Sutar, P. P., Pandian, N. K. S., & Pandiselvam, R. (2022). Evaluation of effect of vacuum frying on textural properties of food products. Food Research International, 162, 112074.
[39] Su, Y., Zhang, M., Zhang, W., Adhikari, B., & Yang, Z. (2016). Application of novel microwave-assisted vacuum frying to reduce the oil uptake and improve the quality of potato chips. LWT - Food Science and Technology, 73, 490–497.
[40] Parikh, A., & Takhar, P. S. (2016). Comparison of microwave and conventional frying on quality attributes and fat content of potatoes. Journal of Food Science, 81(10), E2743–E2755.
[41] Nelson, L. V., Keener, K. M., Kaczay, K. R., Banerjee, P., Jensen, J. L., & Liceaga, A. (2013). Comparison of the Fry Less 100 K radiant fryer to oil immersion frying. LWT – Food Science and Technology, 53(1), 473–479.
[42] Sabbaghi, H., & Nguyen, N. P. (2025). Infrared drying in food technology: Principles and practical insights. In Drying technologies in Food. IntechOpen.
[43] Andrés, A., Arguelles, Á., Castelló, M. L., & Heredia, A. (2013). Mass transfer and volume changes in French fries during air frying. Food and Bioprocess Technology, 6(8), 1917-1924.
[44] Grant, W. (2019, November 23). 4 of the best air fryers under $100—Get the best for your money! Afresherhome. Retrieved November 23, 2019, from https://afresherhome.com/best-air-fryers-under-100-affordable/
[45] Santos, C. S., Cunha, S. C., & Casal, S. (2017). Deep or air frying? A comparative study with different vegetable oils. European Journal of Lipid Science and Technology, 119(6), 1600375.
[46] Heredia, A., Castelló, M. L., Argüelles, A., & Andrés, A. (2014). Evolution of mechanical and optical properties of French fries obtained by hot air-frying. LWT-Food Science and Technology, 57(2), 755-760.
[47] Sansano, M., Juan‐Borrás, M., Escriche, I., Andrés, A., & Heredia, A. (2015). Effect of pretreatments and air‐frying, a novel technology, on acrylamide generation in fried potatoes. Journal of food science, 80(5), T1120-T1128.
[48] Farber, J. M. (1991). Microbiological aspects of modified-atmosphere packaging technology—A review. Journal of Food Protection, 54(1), 58–70.
[49] Keramat, J., LeBail, A., Prost, C., & Soltanizadeh, N. (2011). Acrylamide in foods: Chemistry and analysis. A review. Food and Bioprocess Technology, 4(2), 340–363.
[50] Tian, J., Chen, S., Shi, J., Chen, J., Liu, D., Cai, Y., ... & Ye, X. (2017). Microstructure and digestibility of potato strips produced by conventional frying and air-frying: An in vitro study. Food structure, 14, 30-35.
[51] Yu, X., Li, L., Xue, J., Wang, J., Song, G., Zhang, Y., & Shen, Q. (2020). Effect of air-frying conditions on the quality attributes and lipidomic characteristics of surimi during processing. Innovative Food Science & Emerging Technologies, 60, 102305.
[52] Sabbaghi, H., Ziaiifar, A. M., Sadeghi, A. R., Kashaninejad, M., and Mirzaei, H. (2017). Kinetic modeling of color changes in french fries during frying process. Journal of Food Technology and Nutrition, 14(1), 65-76.
[53] Abd Rahman, N. A., Abdul Razak, S. Z., Lokmanalhakim, L. A., Taip, F. S., & Mustapa Kamal, S. M. (2017). Response surface optimization for hot air‐frying technique and its effects on the quality of sweet potato snack. Journal of Food Process Engineering, 40(4), e12507.
[54] Maroufpour, B., Ziaiifar, A. M., Ghorbani, M., Sabbaghi, H., & Yalghi, S. (2025b). Analysis of heat and mass transfer during hot air frying and deep frying of shrimp. Journal of Food Science & Technology (2008-8787)22(161).
[55] Rani, L., Kumar, M., Kaushik, D., Kaur, J., Kumar, A., Oz, F., Proestos, C., & Oz, E. (2023). A review on the frying process: Methods, models and their mechanism and application in the food industry. Food Research International, 172, 113176. 
[56] Azam, S. M. R., Zhang, M., Law, C. L., & Mujumdar, A. S. (2018). Effects of drying methods on quality attributes of peach (Prunus persica) leather. Drying Technology, 37(3), 341–351.
[57] Sun, J., Wang, W., & Yue, Q. (2016). Review on microwave-matter interaction fundamentals and efficient microwave-associated heating strategies. Materials, 9(3), 231.
[58] Al Faruq, A., Zhang, M., & Fan, D. (2018). Modeling the dehydration and analysis of dielectric properties of ultrasound and microwave combined vacuum frying apple slices. Drying Technology, 37(4), 409–423.
[59] Zhang, M., Tang, J., Mujumdar, A., & Wang, S. (2006). Trends in microwave-related drying of fruits and vegetables. Trends in Food Science & Technology, 17(10), 524–534.
[60] Mohebbi, M., & Hasanpour, N. (2014). Evaluation of microwave pretreatment and frying temperature on physicochemical properties of deep fat fried zucchini. Journal of Food Science & Technology (2008-8787)12(47).
[61] Motamedzadegan, A., & Mirarab Razi, S. (2021). The effect of basil gum and crees seed gum coating on oil uptake and qualitative characteristics of fried carrot. Journal of Food Researches, 31(3).
[62] Karazhian, H., & Daliri, N. (2016). Effect of microwave pretreatment on mass transfer kinetics of eggplant (Solanum melongena L.) during deep frying process [In Persian]. Journal of Innovation in Food Science and Technology, 103–111.
[63] Dehghannya, J., Gorbani, R., & Ghanbarzadeh, B. (2015). Shrinkage of Mirabelle plum during hot air drying as influenced by ultrasound-assisted osmotic dehydration. International Journal of Food Properties, 19(5), 1093–1103.
[64] Sansano, M., De los Reyes, R., Andrés, A., & Heredia, A. (2018). Effect of microwave frying on acrylamide generation, mass transfer, color, and texture in french fries. Food and Bioprocess Technology11(10), 1934-1939.
[65] Yang, C. S. (1989). Vacuum frying and oil separating device (U.S. Patent No. 4,873,920). Washington, DC: U.S. Patent and Trademark Office.Chicago.
[66] Pandey, A. K., Ravi, N., & Chauhan, O. P. (2020). Quality attributes of vacuum fried fruits and vegetables: A review. Journal of Food Measurement and Characterization, 14(4), 1543–1556.
[67] Yagua, C. V., & Rosana, G. M. (2011). Physical and thermal properties of potato chips during vacuum frying. Journal of Food Engineering, 104(2), 272–283.
[68] Dueik, V., Robert, P., & Bouchon, P. (2010). Vacuum frying reduces oil uptake and improves the quality parameters of carrot crisps. Food Chemistry, 119(3), 1143–1149.
[69] Belkova, B., Hradecký, J., Hurkova, K., Forstova, V., Vaclavik, L., & Hajslova, J. (2018). Impact of vacuum frying on quality of potato crisps and frying oil. Food Chemistry, 241, 51–59.
[70] Mariotti-Celis, M. S., Cortés, P., Dueik, V., Bouchon, P., & Pedreschi, F. (2017). Application of vacuum frying as a furan and acrylamide mitigation technology in potato chips. Food and Bioprocess Technology, 10(11), 2092–2099.
[71] Ayustaningwarno, F., Fogliano, V., Verkerk, R., & Dekker, M. (2021). Surface color distribution analysis by computer vision compared to sensory testing: Vacuum fried fruits as a case study. Food Research International, 143, 110230.
[72] Mir-Bel, J., Oria, R., Salvador, M. L., & Solano, M. L. S. (2012). Influence of temperature on heat transfer coefficient during moderate vacuum deep-fat frying. Journal of Food Engineering, 113(2), 167–176.
[73] Bedoya, M. G., Rodriguez, M. C., & Cotes Torres, J. M. (2018). Influence of vacuum deep fat frying process on quality of potato variety Primavera snacks: A functional food with antioxidant properties. Contemporary Engineering Sciences, 11(51), 2537–2549.
[74] Yamsaengsung, R., & Rungsee, S. (2003). Vacuum frying of fruits and vegetables. Manuscript e #1-2003. Hat Yai, Songkhla 90112: Department of Chemical Engineering, Prince of Songkla University.
[75] Akinpelu, O. R., Idowu, M. A., Sobukola, O. P., Henshaw, F., Sanni, S. A., Bodunde, G., ... & Munoz, L. (2014). Optimization of processing conditions for vacuum frying of high quality fried plantain chips using response surface methodology (RSM). Food Science and Biotechnology23(4), 1121-1128.
[76] Sumnu, G., & Sahin, S. (2005). Recent developments in microwave heating. Emerging technologies for food processing, 419-444.
[77] Su, Y., Zhang, M., Zhang, W., Liu, C., & Bhandari, B. (2017). Low oil content potato chips produced by infrared vacuum pre-drying and microwave-assisted vacuum frying. Drying Technology, 36(3), 294–306.
[78] Yildiz, A. Y., Echegaray, N., Öztekin, S., & Lorenzo, J. M. (2024). Quality and stability of frying oils and fried foods in ultrasound and microwave–assisted frying processes and hybrid technologies. Comprehensive Reviews in Food Science and Food Safety23(4), e13405.
[79] Su, Y., Zhang, M., & Zhang, W. (2015). Effect of low temperature on the microwave-assisted vacuum frying of potato chips. Drying Technology, 34(2), 227–234.
[80] Quan, X., Zhang, M., Zhang, W., & Adhikari, B. (2014). Effect of microwave-assisted vacuum frying on the quality of potato chips. Drying Technology, 32(16), 1812–1819.
[81] Devi, S., Zhang, M., & Law, C. L. (2018). Effect of ultrasound and microwave assisted vacuum frying on mushroom (Agaricus bisporus) chips quality. Food Bioscience, 25, 111–117. 
[82] Pankaj, S. K., & Keener, K. M. (2017). A review and research trends in alternate frying technologies. Current Opinion in Food Science, 16, 74–79.
[83] Riadh, M. H., Ahmad, S. A., Marhaban, M. H., & Soh, A. C. (2015). Infrared heating in food drying: An overview. Drying Technology, 33(3), 322–335.
[84] Anumudu, C. K., Onyeaka, H., Ekwueme, C. T., Hart, A., Isaac-Bamgboye, F., & Miri, T. (2024). Advances in the application of infrared in food processing for improved food quality and microbial inactivation. Foods, 13(24), 4001.
[85] Radhi, S. S., Al-Khafaji, Z. S., & Falah, M. W. (2022). Sustainable heating system by infrared radiators. Heritage and Sustainable Development, 4(1), 42–52.
[86] Nowacka, M., Matys, A., & Witrowa-Rajchert, D. (2024). Innovative technologies for improving the sustainability of the food drying industry. Current Food Science and Technology Reports, 2(2), 1–9.
[87] Sakare, P., Prasad, N., Thombare, N., Singh, R., & Sharma, S. C. (2020). Infrared drying of food materials: Recent advances. Food Engineering Reviews, 12(3), 381-398.
[88] Da Silva Ferreira, M. V., Ahmed, M. W., Oliveira, M., Sarang, S., Ramsay, S., Liu, X., et al. (2024). AI-enabled optical sensing for smart and precision food drying: Techniques, applications and future directions. Food Engineering Reviews, 1–29.
[89] Wang, Q., Li, S., Han, X., Ni, Y., Zhao, D., & Hao, J. (2019). Quality evaluation and drying kinetics of shiitake mushrooms dried by hot air, infrared and intermittent microwave–assisted drying methods. LWT - Food Science and Technology, 107, 236–242.
[90] Wang, J., & Sheng, K. (2006). Far-infrared and microwave drying of peach. LWT - Food Science and Technology, 39(3), 247–255.
[91] Parikh, D. M. (2015). Vacuum drying: Basics and application. Chemical Engineering, 122(4), 48–54.
[92] Salehi, F., & Kashaninejad, M. (2018). Thin layer drying of tomato slices using a combined infrared-vacuum dryer. Food Science and Technology (Iran)15(82), 119-127.
[93] Tagalpallewar, G., Shrigod, N., & Sardar, N. (2015). Vacuum frying technology-new technique for healthy fried foods. In Abstracts, National Seminar on Indian Dairy Industry-Opportunities and Challenges (pp. 5-6).