Rice Bean-adzuki Bean Multitrait Near Infrared Reflectance Spectroscopy Prediction Model: a Rapid Mining Tool for Trait-specific Germplasm

Overview

Journal Front Nutr

Specialty Nutritional Sciences

Date 2024 Jan 1

PMID 38162522

Authors

Racheal John

Arti Bartwal

Christine Jeyaseelan

Paras Sharma

R Ananthan

Amit Kumar Singh

Mohar Singh

Gayacharan

Jai Chand Rana

Rakesh Bhardwaj

Affiliations

Soon will be listed here.

Abstract

In the present era of climate change, underutilized crops such as rice beans and adzuki beans are gaining prominence to ensure food security due to their inherent potential to withstand extreme conditions and high nutritional value. These legumes are bestowed with higher nutritional attributes such as protein, fiber, vitamins, and minerals than other major legumes of the family. With the typical nutrient evaluation methods being expensive and time-consuming, non-invasive techniques such as near infrared reflectance spectroscopy (NIRS) combined with chemometrics have emerged as a better alternative. The present study aims to develop a combined NIRS prediction model for rice bean and adzuki bean flour samples to estimate total starch, protein, fat, sugars, phytate, dietary fiber, anthocyanin, minerals, and RGB value. We chose 20 morphometrically diverse accessions in each crop, of which fifteen were selected as the training set and five for validation of the NIRS prediction model. Each trait required a unique combination of derivatives, gaps, smoothening, and scatter correction techniques. The best-fit models were selected based on high RSQ and RPD values. High RSQ values of >0.9 were achieved for most of the studied parameters, indicating high-accuracy models except for minerals, fat, and phenol, which obtained RSQ <0.6 for the validation set. The generated models would facilitate the rapid nutritional exploitation of underutilized pulses such as adzuki and rice beans, showcasing their considerable potential to be functional foods for health promotion.

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