Prediction and visualization map for physicochemical indices of kiwifruits by hyperspectral imaging

Qinglong Meng; Tao Tan; Shunan Feng; Qingchun Wen; Jing Shang

doi:10.3389/fnut.2024.1364274

Prediction and visualization map for physicochemical indices of kiwifruits by hyperspectral imaging

Front Nutr. 2024 Mar 14:11:1364274. doi: 10.3389/fnut.2024.1364274. eCollection 2024.

Authors

Qinglong Meng^{1

2}, Tao Tan¹, Shunan Feng¹, Qingchun Wen¹, Jing Shang^{1

2}

Affiliations

¹ School of Food Science and Engineering, Guiyang University, Guiyang, China.
² Research Center of Nondestructive Testing for Agricultural Products of Guizhou Province, Guiyang, China.

Abstract

Soluble solid content (SSC), firmness, and color (L^*, a^*, and b^*) are important physicochemical indices for assessing the quality and maturity of kiwifruits. Therefore, this research aimed to realize the nondestructive detection and visualization map for the physicochemical indices of kiwifruits at different maturity stages by hyperspectral imaging coupled with the chemometrics. To further improve the detection accuracy and working efficiency of the models, competitive adaptive reweighted sampling (CARS) and successive projection algorithm were employed to choose feature wavelengths for predicting the physicochemical indices of kiwifruits. Multiple linear regression (MLR) was designed to develop simplified detection models based on feature wavelengths for determining the physicochemical indices of kiwifruits. The results showed that 32, 18, 26, 29, and 32 feature wavelengths were extracted from 256 full wavelengths to predict the SSC, firmness, L^*, a^*, and b^*, respectively, with the CARS algorithm. Not only was the working efficiency of the CARS-MLR model improved, but the prediction accuracy of the CARS-MLR model for determining the physicochemical indices was also at its relative best. The residual predictive deviations of the CARS-MLR model for determining the SSC, firmness, L^*, a^*, and b^* were 3.09, 2.90, 2.32, 2.74, and 2.91, respectively, which were all above 2.3. Compared with the model based on the full spectra, the CARS-MLR model could be used to predict the physicochemical indices of kiwifruits. Finally, the visualization map for the physicochemical indices of kiwifruits at different maturity stages was generated by calculating the spectral response of each pixel on the kiwifruit samples with the CARS-MLR model. This made the detection for the physicochemical indices of kiwifruits more intuitive. This study demonstrates that hyperspectral imaging coupled with the chemometrics is promising for the nondestructive detection and visualization map for the physicochemical indices of kiwifruits, and also provides a novel theoretical basis for the nondestructive detection of kiwifruit quality.

Keywords: chemometrics; hyperspectral imaging; kiwifruits; nondestructive detection; physicochemical index; visualization.

Grants and funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This work was supported by the Fund Project of the Central Government Guide Local Science and Technology Department (grant numbers QKZYD[2022]4050), the Fund Project of Guiyang Science and Technology Bureau (grant numbers ZKHT[2021]43-15; ZKHT-GCC[2023]022), the Special Project of Academic New Seedling Cultivation and Free Exploration and Innovation of Guizhou Provincial Science and Technology Department (grant numbers 2023), and the Project of Undergraduate Innovation and Entrepreneurship Training (202310976026).