不同比例棉秆和甜菜渣混合发酵产物的体外产气特性及发酵参数的研究

doi:10.11686/cyxb2019357

草业学报 ›› 2020, Vol. 29 ›› Issue (5): 58-66.DOI: 10.11686/cyxb2019357

不同比例棉秆和甜菜渣混合发酵产物的体外产气特性及发酵参数的研究

芦岩¹, 张伶俐^2,*, 罗远琴¹, 魏利¹, 薛雪¹, 孙新文¹, 向春和¹, 毛胜勇³, 王新峰^1,*, 张文举^1,*

1.石河子大学动物科技学院, 新疆石河子 832003;
2.汕头大学医学院, 广东汕头 515041;
3.南京农业大学动物科技学院, 江苏南京 210095

收稿日期:2019-08-14 出版日期:2020-05-20 发布日期:2020-05-20
通讯作者: * E-mail: wxf-4@163.com, zhangll_007@163.com, zhangwj1022@sina.com
作者简介:芦岩(1994-),男,河南三门峡人,在读硕士。E-mail: 392589637@qq.com
基金资助:
国家自然科学基金(31360558),广东省创新强校工程项目青年创新人才项目(2018KQNCX083),动物消化道营养国际联合研究中心开放课题和国家重点研发计划子课题(2018YFD0502101)资助

In vitro gas production characteristics and fermentation parameters of feedstuffs with varying proportions of cotton stalks and beet pulp

LU Yan¹, ZHANG Ling-li^2,*, LUO Yuan-qin¹, WEI Li¹, XUE Xue¹, SUN Xin-wen¹, XIANG Chun-he¹, MAO Sheng-yong³, WANG Xin-feng^1,*, ZHANG Wen-ju^1,*

1.College of Animal Science & Technology, Shihezi University, Shihezi 832003, China;
2.Medical College, Shantou University, Shantou 515041, China;
3.College of Animal Science & Technology, Nanjing Agricultural University, Nanjing 210095, China

Received:2019-08-14 Online:2020-05-20 Published:2020-05-20
Contact: * E-mail: wxf-4@163.com, zhangll_007@163.com, zhangwj1022@sina.com

摘要/Abstract

摘要： 本试验旨在利用体外发酵法评价棉秆与甜菜渣混合发酵产物的产气特性和营养品质并筛选出最佳发酵组合。甜菜渣的添加比例分别为10%、30%和50%,尿素添加比例分别为0.1%、0.2%和0.3%,菌液添加比例分别为0.05%、0.1%和0.2%,食盐添加量为0.2%的三因素三水平的正交试验设计,研究各组发酵产物的营养品质,筛选出最佳的发酵条件。结果表明,48 h累积产气量I组与K组差异极显著(P<0.01),与A、D、F组差异显著(P<0.05);G组显著高于K组56.03%(P<0.05);其他组间差异不显著(P>0.05);I组可消化有机物(DOM)和代谢能(ME)最高,分别为722.40 g·kg^-1和9.75 MJ·kg^-1;各组慢速降解参数(b),I组与K组差异极显著(P<0.01),与A、D、F组差异显著(P<0.05);G、H组与K组差异显著(P<0.05);各组快速降解参数(a)、产气速率(c)差异不显著;H组氨态氮浓度与其他各组差异显著(P<0.05),K组与D和F组差异不显著(P>0.05);H、I组可溶性糖与其他各组差异显著(P<0.05),H组显著高于B组44.06%、K组31.23%,K组与其他各组差异显著;pH值、乳酸和微生物蛋白则均无显著性差异(P>0.05);H组的总挥发性脂肪酸(VFA)浓度最高,为100.31 mmol·L^-1,显著高于除G组外的其他各组(P<0.05);乙酸和丁酸浓度也最高,显著高于除G和I组外的其他各组(P<0.05);丙酸浓度则为G组最高,显著高于除H组外的其他各组(P<0.05);同时,其乙酸/丙酸(A/P)最低,显著低于A、B、C和K组(P<0.05)。通过对棉秆与甜菜渣混合发酵产物隶属函数分析及综合价值排序得出各组隶属函数平均值分别为I组(0.719)>H组(0.692)>F组(0.595)>G组(0.591)>C组(0.407)>E组(0.400)>B组(0.395)>K组(0.374)>D组(0.307)>A组(0.243)。综上,以干物质基础棉秆与甜菜渣比例50∶50,添加尿素0.1%,复合菌液0.2%,食盐0.2%的I组,其混合发酵产物的体外产气量最高,可消化有机物和代谢能最大,乙酸和丁酸浓度较高,发酵组合综合价值排序最高,为最佳发酵组合,可作为饲喂反刍动物的粗饲料。

关键词: 棉秆, 甜菜渣, 产气特性, 发酵参数

Abstract: This experiment evaluated the nutritional quality, gas production characteristics and the fermentation products of mixed feedstuffs comprising cotton stalk and beet pulp. A three-factor, three-level orthogonal treatment combination and an in vitro fermentation method were used, in order to identify the optimal fermentation conditions. Beet pulp was added to cotton stalk in proportions of 10%, 30% or 50%, with 0.1%, 0.2% or 0.3% added urea, and 0.05%, 0.1% or 0.2% added bacterial liquid (lactic acid bacteria and yeast are the main components), with salt added 0.2% in all cases. From the 27 available combinations, 9 were chosen for inclusion in the experiment, designated A-I, and a control, K, as follows: A) 10% beet pulp, 90% cotton stalk, 0.1% urea, 0.05% bacterial liquid, 0.2% salt; B) 10% beet pulp, 90% cotton stalk, 0.2% urea, 0.1% bacterial liquid, 0.2% salt; C) 10% beet pulp, 90% cotton stalk, 0.3% urea, 0.2% bacterial liquid, 0.2% salt; D) 30% beet pulp, 70% cotton stalk, 0.3% urea, 0.05% bacterial liquid, 0.2% salt; E) 30% beet pulp, 70% cotton stalk, 0.1% urea, 0.1% bacterial liquid, 0.2% salt; F) 30% beet pulp, 70% cotton stalk, 0.2% urea, 0.2% bacterial liquid, 0.2% salt; G) 50% beet pulp, 50% cotton stalk, 0.2% urea, 0.05% bacterial liquid, 0.2% salt; H) 50% beet pulp, 50% cotton stalk, 0.3% urea, 0.1% bacterial liquid, 0.2% salt; I) 50% beet pulp, 50% cotton stalk, 0.1% urea, 0.2% bacterial liquid, 0.2% salt and control group K (100% cotton stalk, 0 urea, 0 bacterial liquid, 0.2% salt). It was found that for gas production at 48 hours, Group I was significantly higher than groups A, D, F (P<0.05), and group K (P<0.01), while, there were no significant difference between the other groups (P>0.05). Group I had the highest organic matter digestibility and metabolizable energy: 722.40 g·kg^-1 and 9.75 MJ·kg^-1, respectively. The slow degradation parameter, b, was significantly higher in group I than in groups A, D, F (P<0.05), and group K (P<0.01). Groups G and H, were also significantly higher than group K (P<0.05), while there were no significant differences between the other groups (P>0.05). The rapid degradation parameter (a), and the gas production rate (c), did not differ significantly between any of the groups. The concentration of ammonia nitrogen in group H was significantly lower (P<0.05) than in other groups, and group K was significantly lower than groups A, B, C and E. Soluble sugar was significantly higher (P<0.05) in groups H and I than other groups, and in group H was 44.06% and 31.23% higher than the lowest groups, B and K, respectively. No significant differences between groups for pH, lactic acid and microbial protein were detected (P>0.05). The highest total volatile fatty acid (VFA) concentrations occurred in groups was group H and G (100.31 and 99.73 mmol·L^-1, respectively), and these values were which was significantly (P<0.05) higher than those of other groups. For the volatile fatty acids, acetate and butyrate were highest in Groups G, H, and I and propionate was highest in Groups G and H, while acetate:propionate ratio was lowest in groups G, H, and I. Using a membership function analysis for multivariate ranking of the mixed fermentation products of cotton stalk and beet pulp, the average membership function values of each group were I (0.719)>H (0.692)>F (0.595)>G (0.591)>C (0.407)>E (0.400)>B (0.395)>K (0.374)>D (0.307)>A (0.243). In conclusion, a dry matter-based ratio of cotton stalk to beet pulp of 50∶50, with 0.1% urea, 0.2% bacterial liquid, and 0.2% salt (group I) is recommended based on this research. The mixed fermentation product of this mixture has the highest in vitro gas production, the highest digestible organic matter and metabolic energy content, the higher concentration of acetic acid and butyric acid, and the highest multivariate score of the fermentation products. It is the best among the fermentation combinations tested and is suitable as a roughage for ruminants.

Key words: cotton straw, beet pulp, gas production characteristics, fermentation parameters

芦岩, 张伶俐, 罗远琴, 魏利, 薛雪, 孙新文, 向春和, 毛胜勇, 王新峰, 张文举. 不同比例棉秆和甜菜渣混合发酵产物的体外产气特性及发酵参数的研究[J]. 草业学报, 2020, 29(5): 58-66.

LU Yan, ZHANG Ling-li, LUO Yuan-qin, WEI Li, XUE Xue, SUN Xin-wen, XIANG Chun-he, MAO Sheng-yong, WANG Xin-feng, ZHANG Wen-ju. In vitro gas production characteristics and fermentation parameters of feedstuffs with varying proportions of cotton stalks and beet pulp[J]. Acta Prataculturae Sinica, 2020, 29(5): 58-66.

参考文献

[1] National Bureau of Statistics. China statistical yearbook. China statistical yearbook. Beijing: China Statistics Bureau Press, 2018.
中华人民共和国国家统计局. 中国统计年鉴. 北京: 中国统计出版社, 2018.
[2] Wei M, Luo Q J, Pan R, et al. Initial evaluation on nutritional value of cotton stalk. Journal of Xinjiang Agricultural University, 2003, 26(1): 1-4.
魏敏, 雒秋江, 潘榕, 等. 对棉花秸秆饲用价值的基本评价. 新疆农业大学学报, 2003, 26(1): 1-4.
[3] Lu L L, Gao L, Wang J, et al. Effects of different mixture proportion of cotton straw and beet residue on silage fermentation quality. Grass-Feeding Livestock, 2017, 4: 28-32.
路立里, 高丽, 王晶, 等. 棉花秸秆和甜菜渣不同比例混贮对发酵品质的影响. 草食家畜, 2017, 4: 28-32.
[4] Menke K H, Steingass H. Estimation of the energetic feed value obtained from chemical analysis and in vitro gas production using rumen fluid. Animal Research and Development, 1988, 28: 7-55.
[5] Ørskov E R, McDonald I. The estimation of protein degradation in the rumen from incubation measurements weighted according to the rate of passage. Journal of Agricultural Science, 1979, 92(2): 499-503.
[6] Menke K H, Raab L, Salewski A, et al. The estimation of the digestibility and metabolizable energy content of ruminant feeding stuffs from the gas production when they are incubated with rumen liquor in vitro. The Journal of Agricultural Science, 1979, 93(1): 217-222.
[7] Broderick G A, Kang J H. Automated simultaneous determination of ammonia and total amino acids in ruminal fluid and in vitro media. Journal of Dairy Science, 1980, 63(1): 64-75.
[8] Gao J F. Plant physiology experiment guide. Beijing: Higher Education Press, 2006.
高俊风. 植物生理学实验指导. 北京: 高等教育出版社, 2006.
[9] Makkar H P S, Shavma O P, Dawra R K, et al. Simple determination of microbial protein in rumen liquid. Journal of Dairy Science, 1982, 65(11): 2170-2173.
[10] Qin W L. Determination of rumen volatile fatty acids by means of gas chromatography. Journal of Nanjing Agricultural College, 1982, 4: 110-116.
秦为琳. 应用气相色谱测定瘤胃挥发性脂肪酸方法的研究改进. 南京农学院学报, 1982, 4: 110-116.
[11] Zhang F F, Yu L, Zhang Q B, et al. Comprehensive assessment of the main legume forages’ nutritional value of natural mowing steppe in Shaertao Mountain, Zhaosu, Xinjiang. Xinjiang Agricultural Science, 2014, 51(10): 1907-1915.
张凡凡, 于磊, 张前兵, 等. 沙尔套山天然割草场主要豆科牧草营养价值综合评价研究. 新疆农业科学, 2014, 51(10): 1907-1915.
[12] Wang L F. The effect of dietary addition of different methane inhibitors on sheep rumen methane production. Hohhot: Inner Mongolia Agricultural University, 2004.
王丽凤. 日粮中添加甲烷抑制剂对绵羊瘤胃中甲烷产量影响的研究. 呼和浩特: 内蒙古农业大学, 2004.
[13] Huang Y L, Zou C X, Wei S J, et al. Effects of cysteamine on ruminal fermentation parameters and methane production of water buffalo by in vitro gas production method. Chinese Journal of Animal Nutrition, 2014, 26(1): 125-133.
黄雅莉, 邹彩霞, 韦升菊, 等. 体外产气法研究半胱胺对水牛瘤胃发酵参数和甲烷产量的影响. 动物营养学报, 2014, 26(1): 125-133.
[14] Cheng P H, Liao X D, Wu Y B, et al. Studies on evaluation of fiber quality of fodder grass. Acta Prataculturae Sinica, 2007, 16(5): 61-69.
程鹏辉, 廖新俤, 吴银宝. 利用猪粪液为菌源体外发酵产气法评价牧草纤维品质. 草业学报, 2007, 16(5): 61-69.
[15] He T Y. Studies on the degradation rule of different roughage in rumen and in vitro of the sheep and established the mathmatical predictor model of ME. Hohhot: Inner Mongolia Agricultural University, 2013.
何亭漪. 不同粗饲料在绵羊瘤胃和体外降解规律的研究及代谢能数学预测模型的建立. 呼和浩特: 内蒙古农业大学, 2013.
[16] Yang T, Liu X, Tian K X. Application of beet residue in ruminal production. Guangdong Feed, 2017, 26(5): 40-42.
杨泰, 柳序, 田科雄. 甜菜渣在反刍动物生产中的应用. 广东饲料, 2017, 26(5): 40-42.
[17] Zhang D F, Yang H J. In vitro ruminal methanogenesis of a hay-rich substrate in response to different combination supplements of nitrocompounds; Pyromellitic diimide and 2-bromoethanesulphonate. Animal Feed Science and Technology, 2011, 163: 20-32.
[18] Cone J W, Gelder A H. Influence of protein fermentation on gas production profiles. Animal Feed Science and Technology, 1999, 76(3/4): 251-264.
[19] Shen M Y. The effect of different forage quality on rumen fermentation and microflora of sheep. Hohhot: Inner Mongolia Agricultural University, 2006.
沈美英. 日粮内不同粗饲料品质对绵羊瘤胃发酵功能和微生物区系的影响. 呼和浩特: 内蒙古农业大学, 2006.
[20] Wang J Q. Ruminant nutrition research methods. Beijing: Modern Education Press, 2011.
王加启. 反刍动物营养学研究方法. 北京: 现代教育出版社, 2011.
[21] Murphy J J, Kennelly J J. Effect of protein concentration and protein source on the degradability of dry matter and protein in situ. Journal of Dairy Science, 1987, 70(9): 1841-1849.
[22] Li Y F, Hao J X, Cheng Y F, et al. Nutritive value evaluation of different types of feeds by in vitro ruminal fermentation method. Chinese Journal of Animal Nutrition, 2013, 25(10): 2403-2413.
李袁飞, 郝建祥, 成艳芬, 等. 体外瘤胃发酵法评定不同类型饲料的营养价值. 动物营养学报, 2013, 25(10): 2403-2413.
[23] Feng Y L, Li S L. Proposals for dairy amino acid nutrition system. Dairy Science and Technology, 2004, (4): 166-173.
冯仰廉, 李胜利. 奶牛氨基酸营养体系的建议. 乳业科学与技术, 2004, (4): 166-173.

不同比例棉秆和甜菜渣混合发酵产物的体外产气特性及发酵参数的研究

In vitro gas production characteristics and fermentation parameters of feedstuffs with varying proportions of cotton stalks and beet pulp

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