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全株玉米青贮饲料饲料是适宜收获期将整株玉米粉碎发酵制成的优质饲料,具有营养丰富、产量高、能量密度大等特点。随着“粮改饲”政策推进,其种植面积不断扩大,已成为降低养殖成本的重要饲料来源。本文总结了优质全株玉米青贮饲料饲料具有的特性、达到优质全株玉米青贮饲料饲料发酵标准的原料品质及其加工方式要求等,为提高优质全株玉米青贮饲料饲料提供参考及育种改良技术提供创新性研究方向。
Abstract:Whole plant corn silage is a high-quality feed made by crushing and fermenting the whole plant corn during the suitable harvest period. It has the characteristics of rich nutrition, high yield and high energy density. With the promotion of the " grain to feed " policy, its planting area has been expanding and has become an important source of feed to reduce the cost of breeding. This paper summarizes the characteristics of high-quality whole-plant corn silage, the quality of raw materials that meet the fermentation standards of high-quality whole-plant corn silage and the requirements of its processing methods, so as to provide reference for improving high-quality whole-plant corn silage and provide innovative research directions for breeding improvement technology.
[1]Yang Q, Wang L, Wang P, et al. Effect of the diet level of whole-plant corn silage on the colonic microflora of hezuo pigs[J]. PeerJ, 2024, 12: e18630.
[2]Ta?k?n S Z, Duman A, Bilgili U. Accelerating silage maize breeding: forage yield and nutritive quality of doubled haploid-derived hybrids[J]. PeerJ, 2025, 13: e20197.
[3]王斐, 王克雄, 关耀兵, 等. 宁夏南部山区不同生态类型条件下青贮玉米产量和品质的差异研究[J]. 饲料研究, 2022, 45(20): 79-82.
[4]Lajús C R, Sebben C, Pasqualotto D L, et al. Production and nutritive value of silage corn in different reproductive stages[J]. International Journal of Advanced Engineering Research and Science, 2020, 7(2): 130-136.
[5]Serva L. A comparative evaluation of maize silage quality under diverse pre-ensiling strategies[J]. PLOS ONE, 2024, 19(9): e0308627.
[6]Jiang J, Yin D, Sun Z, et al. Global trend of methane abatement inventions and widening mismatch with methane emissions[J]. Nature Climate Change, 2024, 14(4): 393-401.
[7]Eslamizad M, Schmicke M, Sauerwein H, et al. Partial replacement of high-fibre forages with corn silage across the lactation cycle: effects on methane emission, rumen fermentation and efficiency in dairy cows[J]. Animal, 2025, 19(5): 101494.
[8]De Boever J L, Goossens K, Peiren N, et al. The effect of maize silage type on the performances and methane emission of dairy cattle[J]. Journal of Animal Physiology and Animal Nutrition, 2017, 101(5): 0-11.
[9]Miku?a R, Pszczola M, Rzewuska K, et al. The Effect of Rumination Time on Milk Performance and Methane Emission of Dairy Cows Fed Partial Mixed Ration Based on Maize Silage[J]. Animals, 2021, 12(1).
[10]Cueva S F, Stefenoni H, Melgar A, et al. Lactational performance, rumen fermentation, and enteric methane emission of dairy cows fed an amylase-enabled corn silage[J]. Journal of Dairy Science, 2021, 104(9): 9827-9841.
[11]Wang C, Han H, Sun L, et al. Bacterial succession pattern during the fermentation process in whole-plant corn silage processed in different geographical areas of northern China[J]. Processes, 2021, 9(5): 900.
[12]凯, 孔凡林, 季少雄, 等. 不同留茬高度对全株玉米青贮营养成分、发酵品质、瘤胃降解率和奶牛生产性能的影响[J]. 动物营养学报, 2024, 36(9): 5722-5735.
[13]Tabacco E, Ferrero F, Borreani G. Feasibility of utilizing biodegradable plastic film to cover corn silage under farm conditions[J]. Applied Sciences, 2020, 10(8): 2803.
[14]Ferraretto L F, Shaver R D, Luck B D. Silage review: recent advances and future technologies for whole-plant and fractionated corn silage harvesting[J]. Journal of Dairy Science, 2018, 101(5): 3937-3951.
[15]Rocha E M C, Drewry J L, Willett R M, et al. Assessing kernel processing score of harvested corn silage in real-time using image analysis and machine learning[J]. Computers and Electronics in Agriculture, 2022, 203: 107415.
[16]Ferraretto L F, Saylor B A, Goeser J P, et al. Case study: effect of type of processor on corn silage processing score in samples of whole-plant corn silage[J]. Professional Animal Scientist, 2018, 34(3): 293-298.
[17]Ignjatovi?-Mici? D, Van?etovi? J, Markovi? K, et al. Advantages of quality protein maize use in broiler diets[J]. Scientia Agricola, 2025, 82: e20240028.
[18]王旭哲, 张凡凡, 唐开婷, 等. 密度对玉米青贮发酵品质、微生物和有氧稳定性的影响[J]. 中国草地学报, 2018, 40(1): 80-86.
[19]Greveniotis V, Bouloumpasi E, Zotis S, et al. Estimations on trait stability of maize genotypes[J]. Agriculture, 2021, 11(10): 952.
[20]温振民, 张永科. 用高稳系数法估算玉米杂交种高产稳产性的探讨[J]. 作物学报, 1994(4): 508-512.
[21]He L, Wang C, Xing Y, et al. Ensiling characteristics, proteolysis and bacterial community of high-moisture corn stalk and stylo silage prepared with bauhinia variegate flower[J]. Bioresource Technology, 2020, 296: 122336.
[22]Wang M, Franco M, Cai Y, et al. Dynamics of fermentation profile and bacterial community of silage prepared with alfalfa, whole-plant corn and their mixture[J]. Animal Feed Science and Technology, 2020, 270: 114702.
[23]Pang H, Zhou P, Yue Z, et al. Fermentation characteristics, chemical composition, and aerobic stability in whole crop corn silage treated with lactic acid bacteria or artemisia argyi[J]. Agriculture, 2024, 14(7): 1015.
[24]Jiao T, Lei Z, Wu J, et al. Effect of additives and filling methods on whole plant corn silage quality, fermentation characteristics and in situ digestibility[J]. Animal Bioscience, 2021, 34(11): 1776-1783.
[25]Wang Y, Ying G, Zhang Z, et al. Bacillus velezensis promotes the proliferation of lactic acid bacteria and influences the fermentation quality of whole-plant corn silage[J]. Frontiers in Plant Science, 2024, 15: 1285582.
[26]Jiang F gui, Cheng H jian, Liu D, et al. Treatment of whole-plant corn silage with lactic acid bacteria and organic acid enhances quality by elevating acid content, reducing pH, and inhibiting undesirable microorganisms[J]. Frontiers in Microbiology, 2020, 11: 593088.
[27]Kung L, Robinson J R, Ranjit N K, et al. Microbial populations, fermentation end-products, and aerobic stability of corn silage treated with ammonia or a propionic acid-based preservative[J]. Journal of Dairy Science, 2000, 83(7): 1479-1486.
[28]Xia G hao, Huang Y, Wu C rong, et al. Characterization of mycotoxins and microbial community in whole-plant corn ensiled in different silo types during aerobic exposure[J]. Frontiers in Microbiology, 2023, 14.
[29]Guo Q, Hao X, Li Y, et al. Microbial communities and metabolites of whole crop corn silage inoculated with lentilactobacillus plantarum and lentilactobacillus buchneri[J]. Processes, 2022, 10(11): 2369.
[30]Wang Y L, Wang W K, Wu Q C, et al. The effect of different lactic acid bacteria inoculants on silage quality, phenolic acid profiles, bacterial community and In vitro rumen fermentation characteristic of whole corn silage[J]. Fermentation, 2022, 8(6): 285-305.
[31]Li X, Cheng Y, Yang F, et al. Improving total mixed ration silage: effects of lactic acid bacteria inoculants and antimicrobial additives on fermentation quality and aerobic stability[J]. Agronomy, 2024, 14(8): 1602.
[32]Cheas S, Suntara C, Cherdthong A. Bioactive roles of lactic acid bacteria in enhancing corn silage quality and ruminant dietary fiber utilization: a comprehensive review[J]. Bioactive Carbohydrates and Dietary Fibre, 2025, 34: 100512.
[33]Jatkauskas J, Amaral R C D, Witt K L, et al. Early fermentation dynamics and aerobic stability of maize silage improved by dual-strain lactic acid bacteria inoculation[J]. Fermentation, 2025, 11(5): 293-311.
[34]Diepersloot E C, Pupo M R, Shaver R D, et al. Effect of cutting height on the nutritive value, dry matter yield, and fermentation profile of whole-plant corn forage and silage through a meta-analysis[J]. Journal of Dairy Science, 2025: S0022030225009440.
[35]Yu M, Wang P, Li F, et al. Fermentation quality and In vitro digestibility of sweet corn processing byproducts silage mixed with millet hull or wheat bran and inoculated with a lactic acid bacteria[J]. Fermentation, 2024, 10(5): 254-268.
[36]Sousa D O, Hansen H H, Nussio L G, et al. Effects of wilting and ensiling with or without additive on protein quality and fermentation of a lucerne-white clover mixture[J]. Animal Feed Science and Technology, 2019, 258: 114301.
[37]Lv R, Horiguchi K I, Tagawa S I, et al. Degradability of dry matter and crude protein and rumen fermentation characteristics of jatropha curcas kernel meal with different detoxification treatments[J]. Indian Journal of Animal Sciences, 2022, 92(3): 353-358.
[38]Radchicov V, Tzai V, Kot A, et al. Rumen cannulation of young cattle depending on protein diet[J]. Tehnologìa virobnictva ì pererobki produktìv tvarinnictva, 2019(2(150)): 93-104.
[39]Totakul P, Matra M, Sommai S, et al. Cnidoscolus aconitifolius leaf pellet can manipulate rumen fermentation characteristics and nutrient degradability[J]. 2021: 0-9.
[40]Gallo A, Ghilardelli F, Atzori A S, et al. Co-occurrence of regulated and emerging mycotoxins in corn silage: relationships with fermentation quality and bacterial communities[J]. Toxins, 2021, 13(3): 232-257.
[41]Wang M, Xu S, Wang T, et al. Effect of inoculants and storage temperature on the microbial, chemical and mycotoxin composition of corn silage[J]. Asian-Australasian Journal of Animal Sciences, 2018, 31(12): 1903-1912.
[42]Boudra H, Morgavi D P. Reduction in fusarium toxin levels in corn silage with low dry matter and storage time[J]. Journal of Agricultural and Food Chemistry, 2008, 56(12): 4523-4528.
[43]Zhang X M, Chen W X, Yan Q X, et al. Low-protein diet promotes nitrogen retention efficiency via enhanced renal urea reabsorption and microbial hydrogen incorporation in the rumen of goats[J]. Animal Feed Science and Technology, 2023, 305: 115762.
[44]Ren H, Liu M, Zhang J, et al. Effects of agronomic traits and climatic factors on yield and yield stability of summer maize (Zea mays L) in the Huang-Huai-Hai Plain in China[J]. Frontiers in Plant Science, 2022, 13: 1050064.
[45]Weaver A C, Weaver D M, Adams N, et al. Co-occurrence of 35 mycotoxins: a seven-year survey of corn grain and corn silage in the United States[J]. Toxins, 2021, 13(8): 516-539.
[46]Zhao J, Li X, Liu H, et al. Ensilage using leuconostoc lactis and weissella confusa reduces microbial risk and enhances hygienic quality of whole-crop corn[J]. Chemical and Biological Technologies in Agriculture, 2024, 11(1): 44.
[47]Guo X, Xu D, Li F, et al. Current approaches on the roles of lactic acid bacteria in crop silage[J]. Microbial Biotechnology, 2023, 16(1): 67-87.
[48]Liu X, Wang A, Zhu L, et al. Effect of additive cellulase on fermentation quality of whole-plant corn silage ensiling by a bacillus inoculant and dynamic microbial community analysis[J]. Frontiers in Microbiology, 2024, 14.
[49]Bachmann M, Kuhnitzsch C, Okon P, et al. Ruminal In Vitro Protein Degradation and Apparent Digestibility of Energy and Nutrients in Sheep Fed Native or Ensiled + Toasted Pea (Pisum sativum) Grains[J]. Animals, 2019, 9(7).
[50]Chang M. Supplementation with galacto-oligosaccharides in early life persistently facilitates the microbial colonization of the rumen and promotes growth of preweaning holstein dairy calves[J]. 2022: 0-11.
[51]De Lucena K H D O S, Mazza P H S, Oliveira R L, et al. Slow-releasing urea coated with low-trans vegetable lipids: effects on lamb performance, nutrient digestibility, nitrogen balance, and blood parameters[J]. Animal Feed Science and Technology, 2024, 310: 115925.
[52]Nascimento K B, Zavala Ramírez D A, Meneses J A M, et al. Nutritional, ruminal, and metabolic parameters of beef bulls fed high-energy diets as a function of dietary addition of a magnesium oxide blend associated or not with monensin[J]. Animal Feed Science and Technology, 2024, 312: 115976.
[53]Simmons C R, Lafitte H R, Reimann K S, et al. Successes and insights of an industry biotech program to enhance maize agronomic traits[J]. Plant Science, 2021, 307: 110899.
[54]Amler R. Optimal Maize Ripeness by Application of Dynamic Ripening and Analysis (DRA) System: System Biological Expression for Exactly Planning the Processes and Carrying out the Harvest, Location Suitability, Ripeness-Specific, Highly Efficient Type and Choice of Variety by Means of Silage Maize Ripeness Index (SRI) in Maize Cultivation[J]. Gesunde Pflanzen, 2021, 73(1): 5-11.
[55]Eberhart S A, Russell W A, Penny L H. Double Cross Hybrid Prediction in Maize When Epistasis is Present~(1)[J]. Crop Science, 1964, 4(4): 363-366.
[56]Hülse J, Neumann M, Le?o G F M, et al. Effect of raising the cutting height in corn on performance and carcass traits of lambs[J]. Ciência Animal Brasileira, 2020, 21: e-52862.
[57]Dias Junior G S, Ferraretto L F, Salvati G G S, et al. Relationship between processing score and kernel-fraction particle size in whole-plant corn silage[J]. Journal of Dairy Science, 2016, 99(4): 2719-2729.
[58]Salvati G G de S, Santos W P dos, Carvalho-Estrada P de A, et al. Strategies to maximize kernel processing in a brazilian vitreous endosperm hybrid[J]. Agronomy, 2023, 13(3): 616.
[59]Zhang L, Liu S, Wang X, et al. Effect of Harvesting Time on Starch Degradation in Rumen of Whole-Plant Corn and Its Silage[J]. Fermentation, 2025, 11(9): 522-537.
[60]Tuovinen O H, Niemel? S I, Rajala-Schultz P J. The role of microbes in ensiling[J]. Microorganisms, 2025, 13(10): 2237.
[61]Jatkauskas J, Vrotniakiene V, Amaral R C D, et al. Influence of ensiling timing and inoculation on whole plant maize silage fermentation and aerobic stability (preliminary research)[J]. Plants, 2024, 13(20): 2894.
[62]Muck R E, Nadeau E M G, McAllister T A, et al. Silage review: recent advances and future uses of silage additives[J]. Journal of Dairy Science, 2018, 101(5): 3980-4000.
[63]Weiss K, Kroschewski B, Auerbach H. Effects of air exposure, temperature and additives on fermentation characteristics, yeast count, aerobic stability and volatile organic compounds in corn silage[J]. Journal of Dairy Science, 2016, 99(10): 8053-8069.
[64]Nikolaevich K N. Problem of aerobic stability in the harvesting and use of corn silos[J]. Adaptive Fodder Production, 2023, 2023(3): 69-87.
[65]Liu H, Li X, Hu J, et al. Fermentation quality and aerobic stability evaluation of rice straw silage with different ensiling densities[J]. Fermentation, 2023, 10(1): 20-32.
[66]Zhang X, Meng Y, Xu L. Lactic acid bacteria additives effectively regulate nitrogen compounds and related bacterial communities in silage infected with leaf spot disease[J]. Frontiers in Animal Science, 2025, 6: 1577383.
[67]Bai R, Li H, Chen S, et al. Microbiome and response surface methodology analyses reveal acetobacter pasteurianus as the core bacteria responsible for aerobic spoilage of corn silage (zea mays) in hot and humid areas[J]. Frontiers in Microbiology, 2024, 15: 1473238.
[68]Shen J, Luo X, Zhou M, et al. Effect of different opening times on methanogenic potential of different fermentation types of silage during feed-out stage[J]. Renewable Energy, 2024, 230: 120883.
[69]Faé G S, Kemanian A R, Roth G W, et al. Soybean yield in relation to environmental and soil properties[J]. European Journal of Agronomy, 2020, 118: 126070.
基本信息:
中图分类号:S816.53
引用信息:
[1]徐慧敏,张学峰,甄玉国.优质全株玉米青贮饲料特性及其对原料品质和加工方式的要求[J].经济动物学报().
基金信息:
国家重点研发计划项目(2023YFD1300905)
2026-03-30
2026-03-30
2026-03-30