The traditional technology for internal quality detection of citrus fruit is believed to be destructive, inefficient, and error-prone. To address these issues, a novel method has been developed to evaluate nondestructively the sugar-acid ratio (SAR) of soluble solids by using the oil glands density (OGD). In this study, a total of 584 samples with different widths were collected. The sample data were correlated that the SAR and OGD decreased with time during storage. The relevance with time was significant between SAR and OGD of citrus positively correlated in the calibration group (R2=0.82), which indicated that OGD could be used to predict the internal quality of citrus. It indicated that a new generation of digital microscopy could provide an alternative to predict nondestructively the internal quality of citrus fruit, as well as some theoretical insight for further studies of online quality detection in the future.
Keywords: citrus, nondestructive, oil glands, internal quality, storage, microscopy
DOI: 10.25165/j.ijabe.20211406.5996

Citation: Gao S M, Cao C, Hu D Y, Xu R W, Cheng Y J, Chen H, et al. Prediction of Newhall navel orange internal quality based on digital microscopy. Int J Agric & Biol Eng, 2021; 14(6): 222–227.

citrus, nondestructive, oil glands, internal quality, storage, microscopy

Lembe S M, Umezuruike, L O, Paul C, Sandra L, Hélène H N, Abdul M, et al. Assessment of rind quality of 'Nules Clementine' mandarin fruit during postharvest storage: 2. Robust Vis/NIRS PLS models for prediction of physico-chemical attributes. Scientia Horticulturae, 2014; 165: 421–432.

Tian X, Li J B, Yi S L, Jin G Q, Qiu X Y, Li Y J. Nondestructive determining the soluble solids content of citrus using near infrared transmittance technology combined with the variable selection algorithm. Artificial Intelligence in Agriculture, 2020; 4: 48–57.

Baldwin E A, Bai J, Plotto A, Ritenour M A. Citrus fruit quality assessment; producer and consumer perspectives. Stewart Postharvest Review, 2014; 10(2): 1–7.

Dan C, Şerban C, Sestras A F, Militaru M, Morariu P, Sestras R E. Consumer perception concerning apple fruit quality, depending on cultivars and hedonic scale of evaluation - a case study. Notulae Scientia Biologicae, 2015; 7(1): 140–149.

Ghanem N, Mihoubi D, Kechaou N, Mihoubi N B. Microwave dehydration of three citrus peel cultivars: Effect on water and oil retention capacities, color, shrinkage and total phenols content. Ind Crops Prod, 2012; 40(1): 167–177.

Mahato N, Sharma K, Sinha M, Cho M H. Citrus waste derived nutra-/pharmaceuticals for health benefits: Current trends and future perspectives. J. Funct. Foods, 2017; 40: 307–316.

Nekvapil F, Brezestean I, Barchewitz D, Glamuzina B, Chiş V, Pinzaru S C. Citrus fruits freshness assessment using Raman spectroscopy. Food Chem, 2018; 242: 560–567.

Singh E, Kumari J, Jain P, Sharma S. Nutritional evaluation of dried peel of citrous species and its application in cake development. J Nutr Ecol & Food Res, 2014; 2(1): 10–14.

Porat R, Deterre S, Giampaoli P, Plotto A. The flavor of citrus fruit. Wiley Online Library, 2016; 31p.

Zhao S, Zhang B B, Li J H. On China's policy and countermeasures of quality and safety of farm products and foodstuffs. Food Sci, 2006; 10: 630–635.

Schimmenti E, Borsellino V, Galati A. Growth of citrus production among the Euro-Mediterranean countries: Political implications and empirical findings. Span J Agric Res, 2013; 11(3): 561–577.

Jia W S, Liang G, Tian H, Sun J, Wan C H. Electronic nose-based technique for rapid detection and recognition of moldy apples. Food Chem, 2019; 19(7): 1526. doi: 10.20944/preprints201903.0008.v1.

Li C, Heinemann P, Sherry R. Neural network and Bayesian network fusion models to fuse electronic nose and surface acoustic wave sensor data for apple defect detection. Sens. Actuators B Chem, 2007; 125(1): 301–310.

Ren Y, Ramaswamy H S, Li Y, Yuan C, Reny X. Classification of impact injury of apples using electronic nose coupled with multivariate statistical analyses. J Food Process Eng, 2017; 41(5): e12698. doi: 10.1111/jfpe.12698.

Choi J H, Chen P A, Lee B H, Yim S H, Kim M S, Bae Y S, et al. Portable, non-destructive tester integrating VIS/NIR reflectance spectroscopy for the detection of sugar content in Asian pears. Sci Hortic, 2017; 220: 147–153.

Oliveira-Folador G, Bicudo M, Andrade E D, Renard M, Bureau S, Castilhos F D. Quality traits prediction of the passion fruit pulp using NIR and MIR spectroscopy. LWT, 2018; 95: 172–178.

Pérez-Marín D, Torres I, Entrenas J A, Vega M, Sánchez M. Pre-harvest screening on-vine of spinach quality and safety using NIRS technology. Spectrochim Acta A, 2018; 207: 242–250.

Aboudaoud I, Faiz B, Aassif E, Moudden A, Izbaim D, Abassi D, et al. The maturity characterization of orange fruit by using high frequency ultrasonic echo pulse method. IOP Conference Series: Materials Science and Engineering, UCIP 2012, Madrid, Spain, 2012; 42: 2038–2042.

Haydar V S, Mohammad G P, Davood M, Ahmad S. Ultrasonic based determination of apple quality as a nondestructive technology. Sensing & Bio Sensing Research, 2018; 21:22–26.

Guzmán E, Baeten V, Pierna J, García-Mesa J. Determination of the olive maturity index of intact fruits using image analysis. J. Food Sci, 2015; 52(3): 1462–1470.

Kondo N, Ahmad U, Monta M, Murase H. Machine vision based quality evaluation of Iyokan orange fruit using neural networks. Comput Electron Agric, 2000; 29(1-2): 135–147.

Lyu Q, Liao Q, Liu Y, Lan Y. Feasibility of SSC prediction for navel orange based on origin recognition using NIR spectroscopy. IASC, 2015; 21(3): 305–317.

Ilia K, Victor S, Igor K, Ilona K, Ruslan A, Jamila S, et al. On the temporal stability of analyte recognition with an e-nose based on a metal oxide sensor array in practical applications. Sensors, 2018; 18(2): 550. doi: 10.3390/s18020550.

Cortés V, Blasco J, Aleixos N, Cubero S, Talens P. Monitoring strategies for quality control of agricultural products using visible and near-infrared spectroscopy: A review. Trends Food Sci Technol, 2019; 85: 138–148.

Wang A, Hu D, Xie L. Comparison of detection modes in terms of the necessity of visible region (VIS) and influence of the peel on soluble solids content (SSC) determination of navel orange using VIS-SWNIR spectroscopy. J Food Eng, 2014; 126: 126–132.

Mizrach A. Determination of avocado and mango fruit properties by ultrasonic technique. Ultrasonics, 2000; 38(1-8): 717–722.

Firouz M S, Farahmandi A, Hosseinpour S. Recent advances in ultrasound application as a novel technique in analysis, processing and quality control of fruits, juices and dairy products industries: A review. Ultrason Sonochem, 2019; 57: 73–88.

Tripathi M K, Maktedar D D. A role of computer vision in fruits and vegetables among various horticulture products of agriculture fields: A survey. IPA, 2020; 7(2): 183–203.

Fahn A. Secretory tissues in plants: Secretory tissues in plants. Berlin: Springer-Verlag, 1979; 468p.

Bain J M. Morphological, anatomical, and physiological changes in the developing fruit of the Valencia orange, Citrus sinensis (L) Osbeck. Austrilian Journal of Botany, 1958; 6(1): 1–23.

Banafsheh N, Homa R. Structural & phytochemical indentification on developing processes of oil gland in fruit of bakrai (Citrus reticulata´citrus limetta). Iran: Bakrai mandarin x limetta hybrid, 2009; 365p.

Holtzhausen L C. Observations on the developing fruit of Citrus sinensis cultivar Washington Naval from anthesis to ripeness. Repub S Afr Dep Agr Tech Serv Tech Commun, South Africa: Pretoria: Govt. Printer, 1969; 15p.

Knight T G, Klieber A, Sedgley M. The relationship between oil gland and fruit development in Washington Navel Orange (Citrus sinensis L. Osbeck). Annals of Botany, 2001; 88(6): 1039–1047.

Zhou X, Yue J, Yang H, Zhu C, Cheng Y. Integration of metabolome, histochemistry and transcriptome analysis provides insights into lignin accumulation in oleocellosis-damaged flavedo of citrus fruit. Postharvest Biol Tec, 2021; 172: 111362. doi: 10.1016/j.postharvbio.2020.111362.

Guo R X, Zhang Y, Tan X H, Wang F, Cai W, Hu X A. Changes of essential oil content in citrus peel during storage at different storage conditions. Food && Machinery, 2012; 28(2): 190–192, 195. (in Chinese)

Obenland D, Collin S, Mackey B, Sievert J, Arpaia M L. Storage temperature and time influences sensory quality of mandarins by altering soluble solids, acidity and aroma volatile composition. Postharvest Biol Tec, 2011; 59(2): 187–193.

Sheng L, Shen D D, Yang W, Zhang M F, Zeng Y L, Xu J, et al. GABA pathway rate-limit citrate degradation in postharvest citrus fruit evidences from HB Pumelo (Citrus grandis) × Fairchild (Citrus reticulata) hybrid population. J Agric Food Chem, 2017; 65(8): 1669–1676.