The loss-on-drying method has been widely used as a standard approach for measuring the moisture content of high-moisture materials such as solid and semi-solid foods. Loss-on-drying method provides reliable results, whilst usually labor-intensive and time-consuming. This paper presents a novel algorithm for predicting the moisture content of meats based on the loss-on drying method. The proposed approach developed a drying kinetics model of meats based on Fick’s Second Law and designed a prediction algorithm for meat moisture content using the least-squares method. The predicted results were compared with the official method recommended by the Association of Official Analytical Chemists (AOAC). When the moisture content of meat samples (beef and pork) was varied from 69.46% to 74.21%, the relative error of the meat moisture content (MMC) calculated by the proposed algorithm was 0.0017-0.0117, the absolute errors were less than 1%. The testing time was about 40.18%-56.87% less than the standard detection procedure.
Keywords: meat moisture content, loss-on-drying method, Fick’s Second Law, fusion algorithm, measurement, prediction
DOI: 10.25165/j.ijabe.20201304.5729

Citation: Ling J, Xu J, Lin H J, Lin J Y. Prediction and fusion algorithm for meat moisture content measurement based on loss-on-drying method. Int J Agric & Biol Eng, 2020; 13(4): 198–204.

meat moisture content, loss-on-drying method, Fick’s Second Law, fusion algorithm, measurement, prediction

Leng Y, Sun Y H, Wang X D, Hou J M, Bai X, Wang M H. A method to detect water-injected pork based on bioelectrical impedance technique. Journal of Food Measurement and Characterization, 2019; 13(2): 1341–1348.

Yang, Y, Wang Z Y, Ding Q, Huang L, Wang C, Zhu D Z. Moisture content prediction of porcine meat by bioelectrical impedance spectroscopy. Mathematical and Computer Modelling, 2013; 58(3): 819–825.

Damez J L, Clerjon S. Meat quality assessment using biophysical methods related to meat structure. Meat Science, 2008; 80(1): 132–149.

Huff-Lonergan E, Lonergan S M. Mechanisms of water-holding capacity of meat: The role of postmortem biochemical and structural changes. Meat Science, 2005; 71(1): 194–204.

Hao D M, Zhou Y N, Wang Y, Zhang S, Yang Y M, Lin L, et al. Recognition of water-injected meat based on visible/near-infrared spectrum and sparse representation. Spectrosc. Spectral Anal, 2015; 35(1): 93–98.

Li Z G, Ren N, Ma Y H, Li Y Y, Guo W P. Determination of illegal drugs for water-retaining in fresh meat by UPLC-MS/MS. Food Sci, 2018; 39(12): 308–312. (in Chinese)

Liu J X, Cao Y, Wang Q, Pan W J, Ma F, Liu C H, et al. Rapid and non-destructive identification of water-injected beef samples using multispectral imaging analysis. Food Chemistry, 2016; 190: 938–943.

Liu D, Sun D W, Qu J H, Zeng X A, Pu H B, Ma J. Feasibility of using hyperspectral imaging to predict moisture content of porcine meat during salting process. Food Chemistry, 2014; 152(1): 197–204.

Analysis of the Association of Analytical Chemists (AOAC). Official methods of analysis Proximate Analysis and Calculations Moisture (M) Meat - item 108. Association of Analytical Communities, Gaithersburg, MD, 17th edition, 2006. Reference data: Method 950.46 (39.1.02);

International Organization for Standardization (ISO). Meat and Meat Products-Determination of moisture content (Routine reference method). Geneva: International Standard ISO, 1997, ISO 1442:1997.

Obi O F, Ezeoha S L, Egwu C O. Evaluation of air oven moisture content determination procedures for pearl millet (Pennisetum glaucum L.). International Journal of Food Properties, 2016; 19(2): 454–466.

Ling J, Teng Z S, Lin H J. Improved method for prediction of milled rice moisture content based on Weibull distribution. Int J Agric & Biol Eng, 2018; 11(3): 159–165.

Ling J, Teng Z S, Lin H J, Wen H. Infrared drying kinetics and moisture diffusivity modeling of pork. Int J Agric & Biol Eng, 2017; 10(3): 302–311.

Ruangratanakorn J, Downey G, Allen P, Sun D W. A review of near infrared spectroscopy in muscle food analysis: 2005–2010. Journal of Near Infrared Spectroscopy, 2011, 19(2): 61. doi: 10.1255/jnirs.924.

Pu Y Y, Sun D W. 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, 2017; 156: 108–119.

Nair V V, Dhar H, Kumar S, Thalla K A, Mukherjee S, W. C., Wong J. Artificial neural network based modeling to evaluate methane yield from biogas in a laboratory-scale anaerobic bioreactor. Bioresource Technology, 2016; 217: 90–99.

Liu X Q, Chen X G, Wu W F, Peng G L. A neural network for predicting moisture content of grain drying process using genetic algorithm. Food Control, 2007; 18(8): 928–933.

Gosukonda R, Mahapatra A, Ekefre D, Latimore M. Prediction of thermal properties of sweet sorghum Bagasse as a function of moisture content using artificial neural networks and regression models. Acta Technologica Agriculturae, 2017; 20(2): 29–35.

Singh N J, Pandey R K. Neural network approaches for prediction of drying kinetics during drying of sweet potato. Agricultural Engineering International: CIGR Journal, 2011; 13(1): 1734.

Husna M, Purqon A. Prediction of dried durian moisture content using artificial neural networks. Journal of Physics: Conference Series, 2016; 739(1): 012077. doi: 10.1088/1742-6596/739/1/012077.

Poonnoy P, Tansakul A, Chinnan M. Artificial neural network modeling for temperature and moisture content prediction in tomato slices undergoing microwave-vacuum drying. Journal of Food Science, 2007; 72(1): E042–E047. doi: 10.1111/j.1750-3841.2006.00220.x.

Aghbashlo M, Hosseinpour S, Mujumdar A S. Application of artificial neural networks (ANNs) in drying technology: a comprehensive review. Drying Technology, 2015; 33(12): 1397–1462.

Jafari, S. M., Ganje, M., Dehnad, D., & Ghanbari, V. Mathematical, fuzzy logic and artificial neural network modeling techniques to predict drying kinetics of onion. Journal of Food Processing and Preservation, 2016; 40(2): 329–339.

Sharma G P, Verma R C, Pathare P B. Thin-layer infrared radiation drying of onion slices. Journal of Food Engineering, 2005; 67(3): 361–366.

Nowak D, Lewicki P P. Infrared drying of apple slices. Innovative Food Science & Emerging Technologies, 2004; 5(3): 353–360.

Pekke M A, Pan Z L, Atungulu G G, Smith G, Thompson J F. Drying characteristics and quality of bananas under infrared radiation heating. Int J Agric & Biol Eng, 2013; 6(3): 58–70.

Chinese National standards. Meat and meat products: Determination of moisture content. Beijing: Standard Press of China, 2008, GB 9695.15–2008. (in Chinese)

Doymaz İ. Drying behaviour of green beans. Journal of Food Engineering, 2005; 69(2): 161–165.

Akpinar E, Midilli A, Bicer Y. Single layer drying behaviour of potato slices in a convective cyclone dryer and mathematical modeling. Energy Conversion and Management, 2003; 44(10): 1689–1705.

Sharma G P, Verma R, Pathare P B. Thin-layer infrared radiation drying of onion slices. Journal of Food Engineering, 2005; 67(3): 361–366.

Crank J. The Mathematics of Diffusion. Oxford: Oxford University Press, 1979; 424p.