It is difficult to control the quality of Korla pear with different degrees of maturity during storage. Here, a method was proposed for predicting the effects of harvest maturity and cold storage time on the quality indices (soluble solid content (SSC) and Vitamin C (Vc) content) of Korla pear. The generalized regression neural network (GRNN) and adaptive neuro-fuzzy inference system (ANFIS) were employed to predict the quality changes of Korla fragrant pear fruit during storage. The results demonstrated that during cold storage the SSC in pears with 10%-70% harvest maturity showed continuous increases in the first 90 d of storage and then a slight decline thereafter, while that in pears with 80% and 90% harvest maturity exhibited slow decreases throughout the storage process. With the extension of storage time, the Vc content of pears with 10%-90% harvest maturity showed continuous decreases. The harvest maturity of Korla pear was extremely positively correlated with SSC and Vc content (p < 0.01) in a given storage period. Storage time showed an extremely significant negative correlation with the Vc content (p < 0.01) at the 40%-90% harvest maturity and an significant negative correlation with the Vc content (p < 0.05) at the 10%-30% harvest maturity. At the 10%-70% harvest maturity, storage time showed a significant positive correlation with the SSC (p < 0.05). The trained model could well predict the variation trend of quality indices of pear fruit during storage. The ANFIS with the input membership function of gbellmf had the best performance in predicting the SSC (RMSE=0.175; R2=0.98), and that with the input membership function of trimf exhibited the best performance in predicting Vc content (RMSE=0.075; R2 =0.99). The research findings can provide reference for predicting the fruit nutritional quality at delivery and decision-making on the storage time of Korla fragrant pear.
Keywords: Korla fragrant pear, harvest maturity, storage time, nutritional quality, prediction method
DOI: 10.25165/j.ijabe.20211403.5990

Citation: Liu Y, Zhang Q, Niu H, Zhang H, Lan H P, Zeng Y, et al. Prediction method for nutritional quality of Korla pear during storage. Int J Agric & Biol Eng, 2021; 14(3): 247–254.

Korla fragrant pear, harvest maturity, storage time, nutritional quality, prediction method

Wu J, Guo K Q. Dynamic viscoelastic behaviour and microstructural changes of Korla pear (Pyrus bretschneideri rehd) under varying turgor levels. Biosyst Eng, 2010; 106(4): 485–492.

Wang B H, Sun X X, Dong F Y, Zhang F, Niu, J X. Cloning and expression analysis of an MYB gene associated with calyx persistence in Korla fragrant pear. Plant Cell Rep, 2014; 33(8): 1333–1341.

Liu J, Zhang X, Li Z, Zhang X S, Jemric T, Wang X. Quality monitoring and analysis of Xinjiang 'Korla' fragrant pear in cold chain logistics and home storage with multi-sensor technology. Appl Sci, 2019; 9(18): 3895.

Yu X J, Lu H D, Wu D. Development of deep learning method for predicting firmness and soluble solid content of postharvest Korla fragrant pear using Vis/NIR hyperspectral reflectance imaging. Postharvest Biol Technol, 2018; 141: 39‒49.

Andrea C G S, Angel G, María I G. Comparative study of six pear cultivars in terms of their phenolic and vitamin C contents and antioxidant capacity. J Sci Food Agric, 2003; 83(10): 995–1003.

Wang Z H, Wang W H, Jiang Y B, Bao A M, Tong W, Wang B X. Effects of different harvesting periods on the storage quality and senescence of apple at room temperature. Transactions of the CSAE, 2020; 36(7): 300–306. (in Chinese )

Rizzolo A, Grassi M, Vanoli M. Influence of storage (time, temperature, atmosphere) on ripening, ethylene production and texture of 1-MCP treated ‘Abbé Fétel’ pears. Postharvest Biol Technol, 2015; 109: 20–29.

Jia X H, Wang W H, Du Y M, Tong W, Wang Z H, Hera G. Optimal storage temperature and 1-MCP treatment combinations for different marketing times of Korla Xiang pears. J Integr Agric, 2018; 17(03): 693–703.

Saquet A A. Storage of pears. Sci Hortic, 2019; 246: 1009–1016.

Boonyakiat D, Chen P M, Spotts R A, Richardson D G. Effect of harvest maturity on decay and post-harvest life of ‘d’ Anjou’ pear. Sci Hortic, 1987; 31: 131–139.

Blanckenberg A, Muller M, Theron K I, Crouch E M, Steyn W J. Harvest maturity and ripeness differentially affects consumer preference of ‘Forelle’, ‘Packham’s Triumph’ and ‘Abate Fetel’ pears (Pyrus communis L.). Sci Hortic, 2016; 207: 131–139.

Dong Y, Zhang S Y, Wang Y. Compositional changes in cell wall polyuronides and enzyme activities associated with melting/mealy textural property during ripening following long-term storage of ‘Comice’ and ‘d’Anjou’ pears. Postharvest Biol Technol, 2018; 135: 131–140.

Nordey T, Davrieux F, Léchaudel M. Predictions of fruit shelf life and quality after ripening: Are quality traits measured at harvest reliable indicators? Postharvest Biol Technol, 2019; 153: 52–60.

Huang Y B, Lan Y B, Thomson S J, Fang A, Hoffmann W C, Lacey R E. Development of soft computing and applications in agricultural and biological engineering. Comput Electron Agr, 2010; 71: 107–127.

Guo W C, Shang L, Zhu X H, Shang L, Nelson S O. Nondestructive detection of soluble solids content of apples from dielectric spectra with ANN and chemometric methods. Food Bioprocess Tech, 2015; 8(5): 1126–1138.

Jiang Z D, Zheng H, Mantri N, Qi Z C, Zhang X D, Hou Z N, et, al. Prediction of relationship between surface area, temperature, storage time and ascorbic acid retention of fresh-cut pineapple using adaptive neuro-fuzzy inference system (ANFIS). Postharvest Biol Technol, 2016; 113: 1–7.

Zheng H, Jiang B, Lu H F. An adaptive neural-fuzzy inference system (ANFIS) for detection of bruises on Chinese bayberry (Myrica rubra) based on fractal dimension and RGB intensity color. J Food Eng, 2011; 104: 663–667.

National Standard of the People’s Republic of China. Korla fragrant pear, 2002; NY/T 585-2002. (in Chinese)

National Standard of the People’s Republic of China. Production technical rules for Korla fragrant pear, 2004; NY/T 881-2004. (in Chinese)

Lan H P, Jia F G, Tang Y R, Zhang Q, Han Y L, Liu Y. Quantity evaluation method of maturity for Korla fragrant pear. Transactions of the CSAE, 2015; 31(5): 325–330. (in Chinese)

Guo W C, Fang L J, Liu D Y, Wang Z W. Determination of soluble solids content and firmness of pears during ripening by using dielectric spectroscopy. Comput Electron Agr, 2015; 117: 226–233.

Nicolaï B M, Verlinden B E, Desmet M, Saevels S, Saeys W, Theron K, et al. Time-resolved and continuous wave NIR reflectance spectroscopy to predict soluble solids content and firmness of pear. Postharvest Biol Technol, 2008; 47(1): 68–74.

Peiris K H S, Dull G G, Leffler R G, Kays S J. Spatial variability of soluble solids or dry-matter content within individual fruits, bulbs, or tubers: implications for the development and use of NIR spectrometric techniques. HortScience, 1999; 34(1): 114–118.

Paz P, Sánchez M T, Pérez-Marín D, Guerrero J E, Garrido-Varo A. Instantaneous quantitative and qualitative assessment of pear quality using near infrared spectroscopy. Comput Electron Agr, 2009; 69(1): 24–32.

Wang Z H, Wang W H, Jiang Y B, Bao A M, Tong W, Wang B X. Effects of different harvesting periods on the storage quality and senescence of apple at room temperature. Transactions of the CSAE, 2020; 36(7): 300–306. (in Chinese )

Tijskens L M M, Konopacki P, Simcic M. Biological variance, burden or benefit? Postharvest Biol Technol, 2003; 27(1): 15–25.

Heddam S. Generalized regression neural network based approach as a new tool for predicting Total Dissolved Gas (TDG) downstream of spillways of dams: a case study of Columbia river basin dams, USA. Environ Process, 2017; 4: 235‒253.

Li H. Statistic learning method (second edition). Beijing: Tsinghua University Press, 2019; 24p. (in Chinese)

Rooki R. Application of general regression neural network (GRNN) for indirect measuring pressure loss of Herschel-Bulkley drilling fluids in oil drilling. Measurement, 2017; 85: 184–191.

Jang J S. ANFIS: Adaptive-network-based fuzzy inference system. IEEE T Syst Man Cy-s, 1993; 23(3): 665−685.

Liu X. Studies on mechanism of fruit growth and development of different ripening-season of pears in China. PhD dissertation. Ya’an: Sichuan Agricultural University, 2008; 6. 48p. (in Chinese)

Shao M C. Studies on technique for ‘Hosui’ pear storage in China. Master dissertation. Nanjing: Nanjing Agricultural University, 2005; 12. 16 p. (in Chinese)

Li G L. Study on the preservation technique of Huanghua pear in China. Master dissertation. Fuzhou: Fujian Agricultural and Forestry University, 2013; 4. 27p. (in Chinese)

Lee S K, Kader A A. Preharvest and postharvest factors influencing Vitamin C content of horticultural crops. Postharvest Biol Technol, 2000; 20(3): 207–220.