| 光谱学与光谱分析 |
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| Application and Prospect of Near Infrared Reflectance Spectroscopy in Forage Analysis |
| REN Xiu-zhen1,3,GUO Hong-ru3,JIA Yu-shan2,GE Gen-tu2,WANG Kun1* |
1. Institute of Grassland Science, China Agricultural University, Beijing 100094, China
2. College of Ecology and Environment, Inner Mongolia Agricultural University, Huhhot 010019,China
3. Inner Mongolia University for the Nationalities, Tongliao 028042, China |
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Abstract Forage was the material basis of animal husbandry production, and its quality is directly related to the quality of animal products. It was very important ot control the forage quality and detect the composition of forage raw materials in forage production. Predication of forage quality was often completed by the traditional and classical methods in the past, which were complex, time consuming and expensive, and could not acquire the nutritional value of forage timely. Near infrared reflectance spectroscopy was a highly efficient and rapid modern analysis technique developed in 1970’s. It comprehensively applied the latest research results of computer technique, spectroscopy and chemometrics, and has been widely used in various fields owing to its unique advantages such as being timely, less expensive, non-destructive, and so on. Near infrared reflectance spectroscopy has gained more and more importance though its application to forage analysis was very late. Presently, not only conventional composition (such as moisture, dry matter, crude protein, crude fiber, crude fat, crude ash neutral detergent fiber, acid detergent fiber, etc.), but also non-conventional composition (including minerals, trace elements, enzyme and anti-nutritional factors etc.) and anti-nutritional factors in forage were determined by means of near infrared reflectance spectroscopy. Testing and analysizing the conventional composition in forage was the traditional applied field of near infrared reflectance spectroscopy, a lot of studies of which were done and it has already been one of the standard methods of testing the conventional composition. Forage bioavaibility was also evaluated by near infrared reflectance spectroscopy, so as to assess the utilization rate and nutritional value of forage. Moreover, near infrared spectroscopy could be used successfully to predict the botanical composition in grassland and leaf/stem ratios. Near infrared spectroscopy technique and its application and prospect in forage analysis were reviewed in the present paper.
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Received: 2007-10-16
Accepted: 2008-01-18
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Corresponding Authors:
WANG Kun
E-mail: wangkun6060@sina.com
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[1] Norris K H. Journal of Animal Science, 1976, 43: 4.
[2] Alexandrov A N, Atanassova S L, Peltekova V D, et al. Proceedings 7th International Symposium, Vale de Santarem, Portugal. EAAP Publication, 1995, (81): 133.
[3] Berardo N. Grass and Forge Science, 1997, 52(1): 27.
[4] Boever J L De, Cottyn B G, Brabander D L De, et al. Animal Feed Science and Technology, 1997, 66(1~4): 211.
[5] Villamarin B, Fernandez E, Mendez J. Journal of AOAC International, 2002, 85(3): 541.
[6] Garcia-Criado B, Garcia-Ciudad A. Journal of the Science of Food Agriculture, 1990, 50: 479.
[7] Gislum R, Micklander E, Nielsen J P. Field Crops Research, 2004, 88: 269.
[8] Hansen J L, Viands D R, Steffens J C, et al. Crop Science, 1992, 32(4): 879.
[9] Thiex Ni, Erem T van, Van Eren T. Journal of AOAC International, 1999, 82(4): 799.
[10] Vazquez de Aldana B R, Garcia-Criado B, Garcia- Ciudad A, et al. Commun. Soil Science Plant Analysis, 1996, 27: 795.
[11] Waes C, Carlier L, Kirilov A, et al. Rastenievdni Nauki, 1998, 35(9): 708.
[12] WU Jin-guang(吴瑾光主编). Moden Fourier Transform Infrared Spectroscopy Technology and Application(近代傅里叶变换红外光谱技术及应用). Beijing: Literature Press of Science and Technology Press(北京: 科学技术文献出版社), 1994.
[13] LIU Xian, HAN Lu-jia(刘 贤, 韩鲁佳). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2006, 26(11): 2016.
[14] BAI Qi-lin, CHEN Shao-jiang, DONG Xiao-ling, et al(白淇林, 陈绍江, 董晓玲, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2004, 24(11): 1345.
[15] ZHAO Huan-huan, HU Yue-gao, ZHAO Qi-bo(赵环环, 胡跃高, 赵其波). Acta Zoonutrimenta Sinica(动物营养学报), 2001, 13(4): 40.
[16] Reeves J B, Blosser T H. J. Dairy Science, 1989, 72: 79.
[17] Park R S, Agnew R E, Gordon F J, et al. Animal Feed Science and Technology, 1998, 72: 155.
[18] Cozzolino D, Labandera M. Journal of the Science of Food and Agriculture, 2002, 82: 380.
[19] Waters C J, Givens D I. Animal Feed Science and Technology, 1992, 38(4): 335.
[20] CHEN Peng-fei, RONG Yu-ping, HAN Jian-guo, et al(陈鹏飞, 戎郁萍, 韩建国, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2007, 27(7): 1304.
[21] Park R S, Agnew R E, Kilpatrick D J, et al. Animal Feed Science and Technology, 2002, 109(1~2): 151.
[22] Clark D H, Cary E E, Mayland H F. Agronomy Journal, 1989, 81(1): 91.
[23] Shenk J S, Westerhaus M O, Hoover M R. J. Dairy Science, 1979, 62: 807.
[24] Valdes E V, Young L G, Leeson S, et al. Poultry Science, 1985, 65(3): 753.
[25] Cozzolino D, Moron A. Animal Feed Science and Technology,2004, 111: 161.
[26] Norris K H, Barnes R F, Moore J E, et al . Journal of Animal Science, 1976, 43: 889.
[27] Marten G C, Brink D R, Halgerson J L, et al. Crop Science, 1984, 24: 1179.
[28] Abrams S M, Shenk J S, Westerhaus M O, et al. Journal of Dairy Science, 1987, 70: 806.
[29] Givens D I, De Boever J L, Deaville E R. Nutrition Research Review, 1997, 10: 83.
[30] Mcelrog A R, Hope H J, Vera D M. Forage Notes, 1991, 35: 31.
[31] Ferri D, Convertini G, et al. Annali Dell′I Stituto Sperimentale Agronomico, 1991, 22: 67.
[32] Terramoccia S, Casoli C. Use of Marginal Land of Wild Ungulate Production. Bologna, Italy, Proceedings of the 10th National Congress. Scientific Association of Animal Production, 1993. 31.
[33] Dorgeloh W G. African Journal of Ecology, 1999, 37(2): 168.
[34] Gordon F J, Coopre K M, Park R S, et al. Animal Feed Science Technology. 1998, 70: 339.
[35] Coleman S W, Murray I. Animal Feed Science and Technology, 1993, 44(3~4): 237.
[36] Windham W R, Barton F E. Association of Official Analytical Chemists, 1991, 74(2): 324.
[37] Broderick G A, Fahey G C Jr. Forage Quality, Evaluation and Utilization , 1994, 200.
[38] Btrardo N, Settineri D, Bergoglio G, et al. NIRS Prediction of Ruminal Degradability of the NDF and ADF of a Wide Range of Raw Materials in Cattle and Buffalo: First Results. Bologna, Italy, Proceedings of the 10th National Congress. Scientific Association of Animal Production, 1993. 55.
[39] Guzman J L, Garrido A, et al. Animal Feed Science and Technology, 1996, 57(1~2): 149.
[40] Lindgren E. Swedish Journal of Agricultural Research(Sweden), 1988, 18( 1): 21.
[41] Wilman D, Field M. Animal Feed Science and Technology, 2000, 88: 139.
[42] Volkers K C, Wachendorf M. Animal Feed Science and Technology, 2003, 109: 183.
[43] BAI Qi-lin, CHEN Shao-jiang, YAN Yan-lu, et al(白淇林, 陈绍江, 严衍禄, 等). Scientia Agricultura Sinica(中国农业科学), 2006, 39(7): 1346.
[44] NIE Zhi-dong, HAN Jian-guo, YU Zhu, et al(聂志东, 韩建国, 玉 柱, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2007, 27(7): 1308.
[45] Clark D H, Ralphs M H, Lamb R C. Agron. J., 1987, 79(3): 481.
[46] Andrés S, Calleja A, López S, et al. Animal Feed Science and Technology, 2005, 123: 487.
[47] Goodchild A V, Haramein F J, Moneim A, et al. Infrared Spectroscopy, 1998, (6): 175.
[48] Landau S, Dvash L, Decandia M, et al. Journal of Agricultural and Food Chemistry, 2004, 52(4): 638.
[49] Windham W R, Fales S L, Hoveland C S. Crop Sci., 1988, 28: 705.
[50] Roberts C A, Beuselinck P R, Ellersieck M R, et al. Crop Sci., 1993, 33 : 675.
[51] Roberts C A, Marek S M, Lei W, et al. Crop Science, 1994, 34(4): 1070.
[52] Fairbrother T E, Brink G E. Animal Feed Science and Technology, 1990, 28: 293.
[53] SHEN Heng-sheng, CHEN Jun-chen, ZHONG Zang-wen, et al(沈恒胜, 陈君琛, 种藏文, 等). Scientia Agricultura Sinica(中国农业科学), 2003, 36(9): 1086.
[54] Shaffer J A. Agronomy Journal, 1990, 82(4): 669.
[55] Coleman S W, Christiansen S, Shenk J S. Crop Sci., 1990, 30: 202.
[56] Wachendorf M, Ingwersen B, Taube F. Grass and Forage Science, 1999, 54: 87.
[57] Petersen J C, Barton F E. Crop Science, 1987, 27: 1077.
[58] Alexander J. American Society of Agronomy, 2004, 94: 316.
[59] Smart A J, Schacht W H, Moser L E, et al. Agronomy J., 2004, 96: 316. |
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