Osmotic pretreatment is commonly used in drying to preserve the quality of dried fruit. Several studies have been conducted to evaluate the impact of osmotic pretreatment on the quality of dried food, but, these evaluations have mainly been qualitative and have relied heavily on the author's. A meta-analysis was performed in this work to investigate the osmotic pretreatment effect on the properties of dried fruit, such as water activity, moisture content, crispness, and hardness. The Scopus database yielded 2832 potential references, of which 13 met the criteria for meta-analysis. Subgroup analysis on the type of fruit, osmotic agent, concentration, drying method, and temperature was performed to ascertain the influence of moderator variables on the evaluated fruit's characteristics. The data collection and statistical analysis were both done with the OpenMEE software. According to the findings, osmotic pretreatment significantly affected the product's water activity, moisture content, and crispness. Still, it had no such impact on the hardness of the product. In the analysis subgroup, all types of fruit, solution concentration, drying method, and temperature increased water activity, decreased water content, and improved crispness. Meanwhile, it was determined that each fruit's hardness varied depending on the type of fruit, solution concentration, drying method, and temperature. Except for xylitol, all osmotic agents increased water activity. Sucrose and stachyose affect moisture content and hardness differently. Sucrose can enhance crispness. Although osmotic pretreatment improved the characteristics of dried fruit (moisture content and crispness), it negatively influenced water activity, as was concluded. The moderator variable influences the characteristics of dried fruit.

Concentration; dried fruit; drying method; osmotic agent

Ahmed, I., I. M. Qazi, and S. Jamal. 2016. Developments in osmotic dehydration technique for the preservation of fruits and vegetables. Innovative Food Science and Emerging Technologies 34:29–43.

An, K., H. Li, D. Zhao, S. Ding, H. Tao, and Z. Wang. 2013. Effect of Osmotic Dehydration with Pulsed Vacuum on Hot-Air Drying Kinetics and Quality Attributes of Cherry Tomatoes. Drying Technology 31(6):698–706.

Andreou, V., I. Thanou, M. Giannoglou, M. C. Giannakourou, and G. Katsaros. 2021. Dried figs quality improvement and process energy savings by combinatory application of osmotic pretreatment and conventional air drying. Foods 10(8).

Bassey, E. J., J. H. Cheng, and D. W. Sun. 2021. Novel nonthermal and thermal pretreatments for enhancing drying performance and improving quality of fruits and vegetables. Trends in Food Science and Technology 112(March):137–148.

Bekele, Y., and H. Ramaswamy. 2010. Going beyond conventional osmotic dehydration for quality advantage and energy savings. Ejast 1(1)(1):1–15.

Brochier, B., L. D. F. Marczak, and C. P. Z. Noreña. 2015. Osmotic Dehydration of Yacon Using Glycerol and Sorbitol as Solutes: Water Effective Diffusivity Evaluation. Food and Bioprocess Technology 8(3):623–636.

Chandra, A., S. Kumar, A. Tarafdar, and P. K. Nema. 2020. Ultrasonic and osmotic pretreatments followed by convective and vacuum drying of papaya slices. Journal of the Science of Food and Agriculture 101(6):2264–2272.

Chandra, S., and D. Kumari. 2015. Recent Development in Osmotic Dehydration of Fruit and Vegetables: A Review. Critical Reviews in Food Science and Nutrition 55(4):552–561.

Chavan, U. D., and R. Amarowicz. 2012. Osmotic Dehydration Process for Preservation of Fruits and Vegetables 1(2):202–209.

Cichowska-Bogusz, J., A. Figiel, A. A. Carbonell-Barrachina, M. Pasławska, and D. Witrowa-Rajchert. 2020. Physicochemical properties of dried apple slices: Impact of osmo-dehydration, sonication, and drying methods. Molecules 25(5).

Ciurzyńska, A., H. Kowalska, K. Czajkowska, and A. Lenart. 2016. Osmotic dehydration in production of sustainable and healthy food. Trends in Food Science and Technology 50:186–192.

Damodaran, S. 2017. Water and Ice Relations in Foods. Pages 19–90 in S. Damodaran and K. L. Parkin, editors. Fennema’s Food Chemistry. Fifth edition. CRC Press, Boca Raton.

Deng, L. Z. 2019. Chemical and physical pretreatments of fruits and vegetables: Effects on drying characteristics and quality attributes–a comprehensive review.

Higgins, J. P. T., and S. G. Thompson. 2002. Quantifying heterogeneity in a meta-analysis. Statistics in Medicine 21(11):1539–1558.

Kayacier, A., and R. K. Singh. 2003. Textural properties of baked tortilla chips. Lwt 36(5):463–466.

Kek, S. P., N. L. Chin, and Y. A. Yusof. 2013. Direct and indirect power ultrasound assisted pre-osmotic treatments in convective drying of guava slices. Food and Bioproducts Processing 91(4):495–506.

Kowalska, H., A. Marzec, E. Domian, E. Masiarz, A. Ciurzyńska, S. Galus, A. Małkiewicz, A. Lenart, and J. Kowalska. 2020. Physical and sensory properties of japanese quince chips obtained by osmotic dehydration in fruit juice concentrates and hybrid drying. Molecules 25(23):1–20.

Kurniasari, H., W. David, L. Cempaka, and Ardiansyah. 2022. Effects of drying techniques on bioactivity of ginger (Zingiber officinale): A meta-analysis investigation. AIMS Agriculture and Food 7(2):197–211.

Landim, A. P. M., M. I. M. J. Barbosa, and J. L. Barbosa. 2016. Influence of osmotic dehydration on bioactive compounds, antioxidant capacity, color and texture of fruits and vegetables: a review. Ciencia Rural 46(10):1714–1722.

Li, X., J. Bi, Q. Chen, X. Jin, X. Wu, and M. Zhou. 2019. Texture improvement and deformation inhibition of hot air-dried apple cubes via osmotic pretreatment coupled with instant control pressure drop (DIC). Lwt 101(August 2018):351–359.

Liberati, A., D. G. Altman, J. Tetzlaff, C. Mulrow, P. C. Gøtzsche, J. P. A. Ioannidis, M. Clarke, P. J. Devereaux, J. Kleijnen, and D. Moher. 2009. The PRISMA statement for reporting systematic reviews and meta-analyses of studies that evaluate health care interventions: explanation and elaboration. Journal of clinical epidemiology 62(10):e1–e34.

Lyu, J., J. Yi, J. Bi, Q. Chen, L. Zhou, and X. Liu. 2017. Effect of sucrose concentration of osmotic dehydration pretreatment on drying characteristics and texture of peach chips dried by infrared drying coupled with explosion puffing drying. Drying Technology 35(15):1887–1896.

Macedo, L. L., J. L. G. Corrêa, C. da Silva Araújo, W. C. Vimercati, and I. P. Júnior. 2021. Convective Drying with Ethanol Pre-treatment of Strawberry Enriched with Isomaltulose. Food and Bioprocess Technology 14(11):2046–2061.

Matuska, M., A. Lenart, and H. N. Lazarides. 2006. On the use of edible coatings to monitor osmotic dehydration kinetics for minimal solids uptake. Journal of Food Engineering 72(1):85–91.

Mercali, G. D., L. D. Ferreira Marczak, I. C. Tessaro, and C. P. Zapata Noreña. 2011. Evaluation of water, sucrose and NaCl effective diffusivities during osmotic dehydration of banana (Musa sapientum, shum.). Lwt 44(1):82–91.

Ogbuewu, I. P., and C. A. Mbajiorgu. 2023. Meta-analysis of the influence of dietary cassava on productive indices and egg quality of laying hens. Heliyon 9(3):e13998.

de Oliveira, L. F., J. L. G. Corrêa, M. C. de Angelis Pereira, A. de Lemos Souza Ramos, and M. B. Vilela. 2016. Osmotic dehydration of yacon (Smallanthus sonchifolius): Optimization for fructan retention. Lwt 71:77–87.

Onwude, D. I., N. Hashim, R. Janius, K. Abdan, G. Chen, and A. O. Oladejo. 2017. Non-thermal hybrid drying of fruits and vegetables: A review of current technologies. Innovative Food Science and Emerging Technologies 43:223–238.

Osae, R., G. Essilfie, R. N. Alolga, S. Akaba, X. Song, P. Owusu-Ansah, and C. Zhou. 2020. Application of non-thermal pretreatment techniques on agricultural products prior to drying: a review. Journal of the Science of Food and Agriculture 100(6):2585–2599.

Pandiselvam, R., Y. Tak, E. Olum, O. J. Sujayasree, Y. Tekgül, G. Çalışkan Koç, M. Kaur, P. Nayi, A. Kothakota, and M. Kumar. 2022. Advanced osmotic dehydration techniques combined with emerging drying methods for sustainable food production: Impact on bioactive components, texture, color, and sensory properties of food. Journal of Texture Studies 53(6):737–762.

Paraskevopoulou, E., V. Andreou, E. K. Dermesonlouoglou, and P. S. Taoukis. 2022. Combined effect of pulsed electric field and osmotic dehydration pretreatments on mass transfer and quality of air-dried pumpkin. Journal of Food Science 87(11):4839–4853.

Phisut, N. 2012. Factors affecting mass transfer during osmotic dehydration of fruits.

Pravitha, M., M. R. Manikantan, V. Ajesh Kumar, S. Beegum, and R. Pandiselvam. 2021. Optimization of process parameters for the production of jaggery infused osmo-dehydrated coconut chips. Lwt 146(March).

Pu, Y. Y., and D. W. Sun. 2017. Combined hot-air and microwave-vacuum drying for improving drying uniformity of mango slices based on hyperspectral imaging visualisation of moisture content distribution. Biosystems Engineering 156:108–119.

Ramya, V., and N. K. Jain. 2017. A Review on Osmotic Dehydration of Fruits and Vegetables: An Integrated Approach. Journal of Food Process Engineering 40(3):1–22.

Rastogi, N. K., and K. S. M. S. Raghavarao. 1997. Water and solute diffusion coefficients of carrot as a function of temperature and concentration during osmotic dehydration. Journal of Food Engineering 34(4):429–440.

Sanchez-Meca, J., and F. Marin-Martinez. 2010. Meta Analysis. Page International Encyclopedia of Education. 3rd edition. Elsevier, Amsterdam.

Sereno, A. M., R. Moreira, and E. Martinez. 2001. Mass transfer coefficients during osmotic dehydration of apple in single and combined aqueous solutions of sugar and salt. Journal of Food Engineering 47(1):43–49.

Shete, Y., S. Chavan, P. Champawat, and S. Jain. 2018. Reviews on osmotic dehydration of fruits and vegetables. Journal of Pharmacognosy and Phytochemistry 7(2):1964–1969.

Torreggiani, D., and G. Bertolo. 2001. Osmotic pre-treatments in fruit processing: Chemical, physical and structural effects. Journal of Food Engineering 49(2–3):247–253.

Tortoe, C. 2010. A review of osmodehydration for food industry. African Journal of Food Science 4(6):303–324.

Wallace, B. C., M. J. Lajeunesse, G. Dietz, I. J. Dahabreh, T. A. Trikalinos, C. H. Schmid, and J. Gurevitch. 2017. OpenMEE: Intuitive, open-source software for meta-analysis in ecology and evolutionary biology. Methods in Ecology and Evolution 8(8):941–947.

Wang, Y., H. Zhao, H. Deng, X. Song, W. Zhang, S. Wu, and J. Wang. 2019. Influence of pretreatments on microwave vacuum drying kinetics, physicochemical properties and sensory quality of apple slices. Polish Journal of Food and Nutrition Sciences 69(3):297–306.

Xiao, M., J. Bi, J. Yi, Y. Zhao, J. Peng, L. Zhou, and Q. Chen. 2018. Osmotic pretreatment for instant controlled pressure drop dried apple chips: Impact of the type of saccharides and treatment conditions. Drying Technology 37(7):896–905.

Yadav, A. K., and S. V. Singh. 2014. Osmotic dehydration of fruits and vegetables: a review. Journal of Food Science and Technology 51(9):1654–1673.

Zou, K., J. Teng, L. Huang, X. Dai, and B. Wei. 2013. Effect of osmotic pretreatment on quality of mango chips by explosion puffing drying. Lwt 51(1):253–259.