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Determination of metmyoglobin in cooked tan mutton using Vis/NIR hyperspectral imaging system.
J Food Sci. 2020 May; 85(5):1403-1410.JF

Abstract

In this study, the ENVI 4.6 software was used to obtain the spectral reflection value of samples. The outlier samples were eliminated by the Monte Carlo method, and then SPXY (sample set partitioning based on be x-y distances) was used to divide the calibration set and prediction set. The spectral images were pretreated and characteristic wavelengths were extracted. The spectral models of full and pretreated spectra and characteristic bands were established by partial least squares regression (PLSR) and principle component regression (PCR), and the optimal modeling combination was selected. The results showed that the modeling effect of the original spectrum was the best. In full-PLSR model, the determination coefficient of the calibration set (Rc2), the determination coefficient of prediction set (Rp2), and the determination coefficient of interactive verification set (Rcv2) were 0.8804, 0.7375, and 0.7422, and root-mean-square error of calibration set (RMSEC), root-mean-square error of prediction (RMSEP), and root mean square error of interactive validation set (RMSECV) were 2.3630, 2.9607, and 3.4209, respectively. PLSR and PCR models were established to obtain the optimal models of CARS-PLSR and PCR-PLSR. In the CARS-PLSR model, the Rc2 , Rp2 , and Rcv2 were 0.9135, 0.7654, and 0.8171, respectively, while RMSEC, RMSEP, and RMSECV were 2.0275, 2.9306, and 2.9262, respectively. In the iRF-PCR model, Rc2 , Rp2 , and Rcv2 were 0.7952, 0.7372, and 0.7280, respectively, while RMSEC, RMSEP, and RMSECV were 3.0207, 2.8278, and 3.4288, respectively. This study has demonstrated that visible and near-infrared hyperspectral imaging system can rapidly predict the content of metmyoglobin in cooked tan mutton. PRACTICAL APPLICATION: This study has demonstrated that visible and near-infrared (Vis/NIR) hyperspectral imaging system can rapidly predict the content of MetMb in cooked tan mutton. With the advantages of nondestructive, rapid, real-time, Vis/NIR, hyperspectral imaging system can be widely expanded and applied to the detection of myoglobin in meat to evaluate the color of meat.

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Publisher Full Text (DOI)

Authors+Show Affiliations

Yuan R
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Liu G
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
He J
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Ma C
School of Physics and Electrical and Electronic Engineering, Ningxia University, Yinchuan, 750021, China.
Cheng L
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Fan N
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Ban J
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Li Y
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.
Sun Y
Non-Destructive Detection Laboratory of Agricultural Products, School of Agriculture, Ningxia University, Yinchuan, 750021, China.

MeSH

AnimalsCattleCookingHot TemperatureLeast-Squares AnalysisMeatMetmyoglobinSpectroscopy, Near-Infrared

Pub Type(s)

Evaluation Study
Journal Article

Language

eng

PubMed ID

32304238

Citation

Yuan, Ruirui, et al. "Determination of Metmyoglobin in Cooked Tan Mutton Using Vis/NIR Hyperspectral Imaging System." Journal of Food Science, vol. 85, no. 5, 2020, pp. 1403-1410.
Yuan R, Liu G, He J, et al. Determination of metmyoglobin in cooked tan mutton using Vis/NIR hyperspectral imaging system. J Food Sci. 2020;85(5):1403-1410.
Yuan, R., Liu, G., He, J., Ma, C., Cheng, L., Fan, N., Ban, J., Li, Y., & Sun, Y. (2020). Determination of metmyoglobin in cooked tan mutton using Vis/NIR hyperspectral imaging system. Journal of Food Science, 85(5), 1403-1410. https://doi.org/10.1111/1750-3841.15137
Yuan R, et al. Determination of Metmyoglobin in Cooked Tan Mutton Using Vis/NIR Hyperspectral Imaging System. J Food Sci. 2020;85(5):1403-1410. PubMed PMID: 32304238.
* Article titles in AMA citation format should be in sentence-case
TY - JOUR T1 - Determination of metmyoglobin in cooked tan mutton using Vis/NIR hyperspectral imaging system. AU - Yuan,Ruirui, AU - Liu,Guishan, AU - He,Jianguo, AU - Ma,Chao, AU - Cheng,Lijuan, AU - Fan,Naiyun, AU - Ban,Jingjing, AU - Li,Yue, AU - Sun,Yourui, Y1 - 2020/04/18/ PY - 2019/12/22/received PY - 2020/03/14/revised PY - 2020/03/30/accepted PY - 2020/4/19/pubmed PY - 2020/9/8/medline PY - 2020/4/19/entrez KW - competitive adaptive reweighted sampling KW - hyperspectral imaging KW - metmyoglobin KW - partial least squares regression KW - tan mutton SP - 1403 EP - 1410 JF - Journal of food science JO - J Food Sci VL - 85 IS - 5 N2 - In this study, the ENVI 4.6 software was used to obtain the spectral reflection value of samples. The outlier samples were eliminated by the Monte Carlo method, and then SPXY (sample set partitioning based on be x-y distances) was used to divide the calibration set and prediction set. The spectral images were pretreated and characteristic wavelengths were extracted. The spectral models of full and pretreated spectra and characteristic bands were established by partial least squares regression (PLSR) and principle component regression (PCR), and the optimal modeling combination was selected. The results showed that the modeling effect of the original spectrum was the best. In full-PLSR model, the determination coefficient of the calibration set (Rc2), the determination coefficient of prediction set (Rp2), and the determination coefficient of interactive verification set (Rcv2) were 0.8804, 0.7375, and 0.7422, and root-mean-square error of calibration set (RMSEC), root-mean-square error of prediction (RMSEP), and root mean square error of interactive validation set (RMSECV) were 2.3630, 2.9607, and 3.4209, respectively. PLSR and PCR models were established to obtain the optimal models of CARS-PLSR and PCR-PLSR. In the CARS-PLSR model, the Rc2 , Rp2 , and Rcv2 were 0.9135, 0.7654, and 0.8171, respectively, while RMSEC, RMSEP, and RMSECV were 2.0275, 2.9306, and 2.9262, respectively. In the iRF-PCR model, Rc2 , Rp2 , and Rcv2 were 0.7952, 0.7372, and 0.7280, respectively, while RMSEC, RMSEP, and RMSECV were 3.0207, 2.8278, and 3.4288, respectively. This study has demonstrated that visible and near-infrared hyperspectral imaging system can rapidly predict the content of metmyoglobin in cooked tan mutton. PRACTICAL APPLICATION: This study has demonstrated that visible and near-infrared (Vis/NIR) hyperspectral imaging system can rapidly predict the content of MetMb in cooked tan mutton. With the advantages of nondestructive, rapid, real-time, Vis/NIR, hyperspectral imaging system can be widely expanded and applied to the detection of myoglobin in meat to evaluate the color of meat. SN - 1750-3841 UR - https://www.unboundmedicine.com/medline/citation/32304238/Determination_of_metmyoglobin_in_cooked_tan_mutton_using_Vis/NIR_hyperspectral_imaging_system_ DB - PRIME DP - Unbound Medicine ER -