Determination of aflatoxin B1 level in rice (Oryza sativa L.) through near-infrared spectroscopy and an improved simulated annealing variable selection method
Direct quantification analysis of near-infrared (NIR) spectra is challenging because the number of spectral variables is usually considerably higher than the number of samples. To mitigate the so-called curse of dimensionality, var�iable selection is often performed before multivariate calibration...
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| Main Authors: | , , , , |
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| Format: | Article |
| Language: | English |
| Published: |
Elsevier
2022
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| Subjects: | |
| Online Access: | http://eprints.uthm.edu.my/6904/1/J13942_fe1e071d4a672b5009a921fc69dc0ece.pdf http://eprints.uthm.edu.my/6904/ https://doi.org/10.1016/j.foodcont.2022.108886 |
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| Summary: | Direct quantification analysis of near-infrared (NIR) spectra is challenging because the number of spectral variables
is usually considerably higher than the number of samples. To mitigate the so-called curse of dimensionality, var�iable selection is often performed before multivariate calibration. There has been much work in this regard, where
the developed variable selection method can be categorized as individual variable selection, such as uninformative
variable elimination or variable importance in projection, and continuous interval variable selection method such as
interval partial least squares or moving window partial least squares. In this study, a new individual variable se�lection method, modified simulated annealing (MSA), was proposed and used in conjunction with the partial least
squares regression (PLSR) model. The interpretability of the selected variables in the determination of aflatoxin B1
levels in white rice was assessed. The results revealed that the PLSR model combined with MSA not only yielded
higher accuracy than the full-spectrum PLSR but also successfully shrank the variable space. The developed
simplified PLSR model using MSA produced satisfactory performances, with root mean square error of calibration
(RMSEC) of 0.11 μg/kg and 0.56 μg/kg, and root mean square error of prediction (RMSEP) of 7.16 μg/kg and 14.42
μg/kg, were obtained for the low-aflatoxin B1-level- and high-aflatoxin-B1-level samples, respectively. Specifically,
the MSA-based models yielded improvements of 97.80% (calibration set) and 44.62% (prediction set) as well as
95.85% (calibration set) and 62.57% (prediction set) for both datasets when compared with the full-spectrum PLSR
(low aflatoxin: RMSEC = 5.02 μg/kg, RMSEP = 12.93 μg/kg; high aflatoxin: RMSEC = 13.50 μg/kg, RMSEP = 38.53
μg/kg). Compared with the baseline method of simulated annealing (SA) (low aflatoxin: RMSEC = 0.21 μg/kg,
RMSEP = 9.78 μg/kg; high aflatoxin: RMSEC = 12.27 μg/kg, RMSEP = 38.53 μg/kg), the MSA significantly improved
the predictive performance of the regression models, with the number of selected variables being almost half of that
in the SA. A comparison with other commonly used variable selection methods of selectivity ratio (low aflatoxin:
RMSEC = 6.09 μg/kg, RMSEP = 13.75 μg/kg; high aflatoxin: RMSEC = 13.74 μg/kg, RMSEP = 41.13 μg/kg), unin�formative variable elimination (low aflatoxin: RMSEC = 0.32 μg/kg, RMSEP = 5.11 μg/kg; high aflatoxin: RMSEC =
3.80 μg/kg, RMSEP = 17.76 μg/kg), and variable importance in projection (low aflatoxin: RMSEC = 2.67 μg/kg,
RMSEP = 10.71 μg/kg; high aflatoxin: RMSEC = 13.51 μg/kg, RMSEP = 32.53 μg/kg) also indicated the promising
efficacy of the proposed MSA. |
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