Rice straw is a major kind of biomass that can be utilized as lignocellulosic materials and renewable energy. Rapid prediction of the lignocellulose (cellulose, hemicellulose, and lignin) and organic elements (carbon, hydrogen, nitrogen, and sulfur) of rice straw would help to decipher its growth mechanisms and thereby improve its sustainable usages. In this study, 364 rice straw samples featuring different rice subspecies (japonica and indica), growing seasons (early-, middle-, and late-season), and growing environments (irrigated and rainfed) were collected, the differences among which were examined by multivariate analysis of variance. Statistic results showed that the cellulose content exhibited significant differences among different growing seasons at a significant level (p < 0.01), and the contents of cellulose and nitrogen had significant differences between different growing environments (p < 0.01). Near infrared reflectance spectroscopy (NIRS) models for predicting the lignocellulosic and organic elements were developed based on two algorithms including partial least squares (PLS) and competitive adaptive reweighted sampling-partial least squares (CARS-PLS). Modeling results showed that most CARS-PLS models are of higher accuracy than the PLS models, possibly because the CARS-PLS models selected optimal combinations of wavenumbers, which might have enhanced the signal of chemical bonds and thereby improved the predictive efficiency. As a major contributor to the applications of rice straw, the nitrogen content was predicted precisely by the CARS-PLS model. Generally, the CARS-PLS models efficiently quantified the lignocellulose and organic elements of a wide variety of rice straw. The acceptable accuracy of the models allowed their practical applications.
Keywords: rice straw, near infrared reflectance spectroscopy models, rapid prediction, competitive adaptive reweighted sampling, partial least-squares, lignocellulose
DOI: 10.25165/j.ijabe.20191202.4374

Citation: Diallo A A, Yang Z L, Shen G H, Ge J Y, Li Z C, Han L J. Comparison and rapid prediction of lignocellulose and organic elements of a wide variety of rice straw based on near infrared spectroscopy. Int J Agric & Biol Eng, 2019; 12(2): 166–172.

rice straw, near infrared reflectance spectroscopy models, rapid prediction, competitive adaptive reweighted sampling, partial least-squares, lignocellulose

Abraham A, Mathew A K, Sindhu R, Pandey A, Binod P. Potential of rice straw for bio-refining: An overview. Bioresour Technol., 2016; 215: 29–36. doi: org/10.1016/j.biortech.2016.04.011

Jin S Y, Chen H Z. Near-infrared analysis of the chemical composition of rice straw. Ind Crop Prod., 2007; 26(2): 207–211. doi: 10.1016/ j.indcrop.2007.03.004

Huang C, Han L, Yang Z, Liu X. Ultimate analysis and heating value prediction of straw by near infrared spectroscopy. Waste Manage., 2009; 29(6): 1793–1797. doi: 10.1016/j.wasman.2008.11.027

Huang C, Han L J, Liu X, Ma L. The rapid estimation of cellulose, hemicellulose, and lignin contents in rice straw by near infrared spectroscopy. Energ Source Part A., 2010; 33(2): 114–120. doi: org /10.1080/15567030902937127

Hattori T, Murakami S, Mukai M, Yamada T, Hirochika H, Ike M, et al. Rapid analysis of transgenic rice straw using near-infrared spectroscopy. Plant Biotechnol-Nar., 2012; 29: 359–366. doi: org/10.5511/plantbiotech- nology.12.0501a

Sluiter J B, Ruiz R O, Scarlata C J, Sluiter A D, Templeton D W. Compositional analysis of lignocellulosic feedstocks. 1. Review and Description of Methods. J Agric Food Chem., 2010; 58: 9043–9053. doi: 10.1021/jf1008023

Roggo Y, Chalus P, Maurer L, Lema-Martinez C, Edmond A, Jent N. A review of near infrared spectroscopy and chemometrics in pharmaceutical technologies. J Pharmaceut Biomed., 2007; 44: 683–700. doi: org/10. 1016/j.jpba.2007.03.023

Huang C J, Han L J, Yang Z L, Liu X. Prediction of heating value of straw by proximate data, and near infrared spectroscopy. Energ Convers Manage., 2008; 49(12): 3433–3438. doi: 10.1016/j.enconman.2008. 08.020

Belal E B. Bioethanol production from rice straw residues. Braz J Microbiol., 2013; 44: 225–234. doi: 10.1590/S1517-83822013000100033

Liao C P, Wu C Z, Yany Y J, Huang H T. Chemical elemental characteristics of biomass fuels in China. Biomass Bioenerg., 2004; 27(2): 119–130. doi: 10.1016/j.biombioe.2004.01.002

Banta S, Mendoza C. Organic Matter and Rice. Manila, Philippines: International Rice Research Institute, 1984.

Garivait S, Chaiyo U, Patumsawad S, Deakhuntod J. Physical and chemical properties of thai biomass fuels from agricultural residues. The 2nd Joint International Conference on Sustainable Energy and Environment. 2006; 1–23.

Stahl R, Ramadan A B. Fuels and chemicals from rice straw in Egypt. Forschungszentrum Karlsruhe, FZKA-7361, 2007. doi: 10.5445/IR/2700 69896

Niu W J, Huang G Q, Liu X, Chen L J, Han L J. Chemical composition and calorific value prediction of wheat straw at different maturity stages using near-infrared reflectance spectroscopy. Energ Fuel., 2014; 28(12): 7474–7482. doi: 10.1021/ef501446r

Lande S, Riel S V, Høibø O A, Schneider M H. Development of chemometric models based on near infrared spectroscopy and thermogravimetric analysis for predicting the treatment level of furfurylated Scots pine. Wood Sci Technol., 2010; 44(2): 189–203. doi: org/10.1007/s00226-009-0278-x

Sun B L, Liu J L, Liu S J, Yang Q. Application of FT-NIR-DR and FT-IR-ATR spectroscopy to estimate the chemical composition of bamboo (Neosinocalamus affinis Keng). Holzforschung, 2011; 65(5): 689–696. doi: org/10.1515/hf.2011.075

He W M, Hu H R. Prediction of hot-water-soluble extractive, pentosan and cellulose content of various wood species using FT-NIR spectroscopy. Bioresour Technol., 2013; 140: 299–305. doi: org/10.1016 /j.biortech. 2013.04.115

Wójciak A, Kasprzyk H, Sikorska E, Krawczyk A, Sikorski M, Wesełucha-Birczyńska A. FT-Raman, FT-infrared and NIR spectroscopic characterization of oxygen-delignified kraft pulp treated with hydrogen peroxide under acidic and alkaline conditions. Vib Spectrosc., 2014; 71:

–69. doi: org/10.1016/j.vibspec.2014.01.007

Li X L, Sun C J, Zhou B X, He Y. Determination of hemicellulose, cellulose and lignin in moso bamboo by near infrared spectroscopy. Sci Rep., 2015; 5: 17210. doi: org/10.1038/srep17210

Workman J, Weyer L. Practical guide to interpretive near-infrared spectroscopy. Boca Raton, FL, USA: CRC Press, Inc.2007.

Urbano-Cuadrado M, Castro L D, Pérez-Juan P M, García-Olmo J, Gómez-Nieto M A. Near infrared reflectance spectroscopy and multivariate analysis in enology: determination or screening of fifteen parameters in different types of wines. Anal Chim Acta, 2004; 527: 81–88. doi: org/10.1016/j.aca.2004.07.057

Li J, Tian X H, Wang S X, Ba Y L, Li Y B, Zheng X F. Effects of nitrogen fertilizer reduction on crop yields,soil nitrate nitrogen and carbon contents with straw returning. Journal of Northwest A & F University: Natural Science Edition, 2014; 42: 137–143. (in Chinese)

Xia L L, Xia Y Q, Ma S T, Wang J Y, Wang S W, Zhou W, et al. Greenhouse gas emissions and reactive nitrogen releases from rice production with simultaneous incorporation of wheat straw and nitrogen fertilizer. Biogeosciences, 2016; 13(15): 4569–4579. doi: org/10.5194/ bg-13-4569-2016

Valdez-Vazquez I, Torres-Aguirre G J, Molina C, Ruiz-Aguilar G M L. Characterization of a lignocellulolytic consortium and methane production from untreated wheat straw: Dependence on nitrogen and phosphorous content. BioResources, 2016; 11(2): 4237–4251. doi: 10.15376/biores. 11.2.4237-4251