In-Situ Screening of Soybean Quality with a Novel Handheld Near-Infrared Sensor

This study evaluates a novel handheld sensor technology coupled with pattern recognition to provide real-time screening of several soybean traits for breeders and farmers, namely protein and fat quality. We developed predictive regression models that can quantify soybean quality traits based on near...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2020-11, Vol.20 (21), p.6283
Main Authors: Aykas, Didem Peren, Ball, Christopher, Sia, Amanda, Zhu, Kuanrong, Shotts, Mei-Ling, Schmenk, Anna, Rodriguez-Saona, Luis
Format: Article
Language:English
Subjects:
Amino acids
Amino Acids - analysis
Chromatography
Composition
essential amino acids
Esterification
fat content
Fats - analysis
Fatty acids
Fatty Acids - analysis
Feeds
Food Analysis - instrumentation
Food Quality
Gas chromatography
Glycine max - chemistry
Infrared spectra
Laboratories
Least-Squares Analysis
Livestock
Lysine
major fatty acids
Methionine
Moisture content
Near infrared radiation
near-infrared spectroscopy
Nitrogen
Oils & fats
Pattern recognition
Plant Proteins - analysis
Prediction models
protein content
Proteins
Real time
Soy products
soybean
Soybeans
Spectroscopy, Near-Infrared
Spectrum analysis
Tryptophan
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Summary:This study evaluates a novel handheld sensor technology coupled with pattern recognition to provide real-time screening of several soybean traits for breeders and farmers, namely protein and fat quality. We developed predictive regression models that can quantify soybean quality traits based on near-infrared (NIR) spectra acquired by a handheld instrument. This system has been utilized to measure crude protein, essential amino acids (lysine, threonine, methionine, tryptophan, and cysteine) composition, total fat, the profile of major fatty acids, and moisture content in soybeans ( = 107), and soy products including soy isolates, soy concentrates, and soy supplement drink powders ( = 15). Reference quantification of crude protein content used the Dumas combustion method (AOAC 992.23), and individual amino acids were determined using traditional protein hydrolysis (AOAC 982.30). Fat and moisture content were determined by Soxhlet (AOAC 945.16) and Karl Fischer methods, respectively, and fatty acid composition via gas chromatography-fatty acid methyl esterification. Predictive models were built and validated using ground soybean and soy products. Robust partial least square regression (PLSR) models predicted all measured quality parameters with high integrity of fit (R ≥ 0.92), low root mean square error of prediction (0.02-3.07%), and high predictive performance (RPD range 2.4-8.8, RER range 7.5-29.2). Our study demonstrated that a handheld NIR sensor can supplant expensive laboratory testing that can take weeks to produce results and provide soybean breeders and growers with a rapid, accurate, and non-destructive tool that can be used in the field for real-time analysis of soybeans to facilitate faster decision-making.
ISSN:1424-8220
1424-8220
DOI:10.3390/s20216283