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온실가스 저감을 위한 친환경 한우사료 개발에 관한 연구 = A study on development of Hanwoo feed for greenhouse gas reduction

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' 온실가스 저감을 위한 친환경 한우사료 개발에 관한 연구 = A study on development of Hanwoo feed for greenhouse gas reduction' 의 주제별 논문영향력
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' 온실가스 저감을 위한 친환경 한우사료 개발에 관한 연구 = A study on development of Hanwoo feed for greenhouse gas reduction' 의 참고문헌

  • 한우에서 사료의 급여체계가 반추위 발효성상, 메탄 발생량, 미생물 다양성, 영양소 소화율 및 체내 대사체에 미치는 영향
    이축경 박사학위 경상대학교 [2020]
  • 한우 수송아지에 대한 황토, 일라이트, 올리고당, 활성탄 및 크롬 급여가 성장발육 및 면역기능에 미치는 영향
  • 한구석, 이남배, 김동중, 주재섭. 한우 거세우 황토급여가 발육 및 육질에 미치는 영향
    송동영 대산농촌 p.15 [1999]
  • 축산폐수 처리를 위한 UASB 공정에서 C/Nitrate 비에 따른 메탄화 및 탈질화 특성
    임선영 강원대학교 석사학위논문, pp.3-16 [2005]
  • 유기성폐기물 혐기소화 기술동향 및 향후전망
    김성일 김종수 유기성 자원학회 학술발표대회논문집, 217-223 [2002]
  • 온실가스종합정보센터. 국가온실가스통 인벤토리보고서
    환경부 [2018]
  • 온실가스종합정보센터. 국가온실가스인벤토리보고서. 온실가스종합정보센터, 서울
    대한민국 [2014]
  • 사료의 급여체계가 한우의 영양소 소화율, 반추위 발효성상 및 메탄 발생량에 미치는 영향
    이축경 석사학위 경상대학교 [2016]
  • 농촌진흥청. 기후변화대응 농업기술개발
    2단계(2014∼2023) 중장기 계획, 11-1390000-03600-01. p.22∼23 [2014]
  • 곡류원료의 종류가 반추위 발효성상, Gas발생량 및 미생물 군집에 미치는 영향, 석사학위
    한기준 건국대학교 [2013]
  • 곡류 사료원별 육성기 한우 장내발효에 의한 메탄가스 배출량 비교
  • the role of atmospherictrace gases in chemical climate . Pages 241-252 in G. Zepp , ed . Climate biospgere interaction : biogenic emiccions and environmental effects of climate change
  • Wanapat S. Effect of supplementation of garlic powder on rumen ecology and digestibility of nutrients in ruminants
    7 .
  • Volatile fatty acid analyses of blood and rumen fluid by gas chromatography
    44 ( 9 ) :1768-1771 [1961]
  • V. H. 1968 . Fatty acids of certain bovine tissue and their association with growth , carcass and palatability traits
    27 ( 3 ) , 632-635
  • Understanding and preventing subacute ruminal acidosis in dairy herds : A review
    126 ( 3 ) :215-236 . [2006]
  • Transport of coenzyme M ( 2-mercaptoethanesulfonic acid ) in Methanobacterium ruminantium
    137 ( 1 ) : 264-273 . [1979]
  • The role ofthe rumen ciliate protozoa fer methane suppression caused by coconutoil
    29 : 187-192 . [1999]
  • The estimation of the digestibility and metabolizable energy content of ruminant feedingstuffs from the gas production when they are incubated with rumen liquor in vitro
    93 : 217-222 [1979]
  • The estimation of protein degradability in the rumen from incubation measurements weighted according to rate of passage
    92 , 499-503 [1979]
  • The effects of plant extracts on microbial community structure in a rumen-simulating continuous-culture system as revealed by molecular profiling
    [2004]
  • The effects of feeding 3-nitrooxypropanol on methane emissions and productivity of Holstein cows in mid lactation
    97 ( 5 ) , 3110-3119 [2014]
  • The effects of different crude protein levels in the concentrates on carcass and meat quality characteristics of Hanwoo steers
    [2013]
  • The effect of trichloroacetamide , chloroform and linseed oil given into the rumen of sheep on some of the end-products of rumen digestion
    32 ( 1 ) , 155-161 [1974]
  • The effect of pH on ruminal methanogenesis
    20 ( 4 ) , 205-210 [1996]
  • The effect of homo fermentative and hetero fermentative lactic acid bacteria on conservation characteristics of baled triticale-Hungarian vetch silage and lamb performance
    [2011]
  • The effect of fatty acids on pure cultures of rumen bacteria
    81 : 107-112 [1973]
  • The effect of energy and nitrogen supply pattern on rumen bacterial growth in vitro
    53 ( 2 ) , 165-175 [1991]
  • The effect of bovicin HC5 , a bacteriocin from Streptococcus bovis BC5 , on ruminal methane production invitro
    217 , 51-55 [2002]
  • The effect of a condensed tannin-containing forage on methane emission by goats . ?
    83 ( 1 ) , 182-186 . [2005]
  • The complete genome sequence of the rumen methanogen Methanosarcina barkeri CM1
    10 ( 1 ) , 57 . [2015]
  • The Effect of Nisin and Monensin on Ruminal fermentations in vitro
    Vol . 35 : 90-96 . [1997]
  • Technology, 132(3):186-201.
  • Taxon-specific associations between protozoa and methanogen populatuins in the rumen and a model rumen system
    26 : 71-78 [1998]
  • Supplementation of Acacia mearnsii tannins decreases methanogenesis and urinary nitrogen in forage-fed sheep
    56 ( 9 ) , 961-970 . [2005]
  • Special report on emissions scenarios ( SRES ) , a special report of Working Group III of the intergovernmental panel onClimateChange
    [2000]
  • Screening for the effects of natural plant extracts at different pH on in vitro rumen microbial fermentation of a high-concentrate diet for beefCattle
    83 ( 11 ) :2572-2579 [2005]
  • SAS User Guide . Release 6.12 edition
    [1996]
  • Ruminal methanogenesis as influenced by individual fatty acids supplemented toComplete ruminant diets
    32 ( 1 ) , 47-51 [2001]
  • RumenCiliates : their metabolism and relationships with bacteria and their hosts
    30 ( 3-4 ) , 203-266 [1990]
  • Rumen microbial responses in fermentationCharacteristics and production ofCLA and methane to linoleic acid in associated with malate or fumarate .
    155 ( 2-4 ) , 132-139 [2010]
  • Relationship between Japanese beef marbling standard and intramuscular lipid in the M. longissimus thoracis of Japanese Black and American WagyuCattle
    38 ( 2 ) , 361-364 . [1994]
  • Regulation of fat and fatty acidComposition in beefCattle
    22 ( 9 ) , 1225-1233 . [2009]
  • Recent trends in global greenhouse gas emissions : regional trends 1970 ? 2000 and spatial distributionof key sources in 2000
    2 ( 2-3 ) , 81-99 . [2005]
  • R. O. Williams . 2015 . An inhibitor persistently decreased enteric methane emission from dairyCows with
    of the National Academy of Sciences 112
  • R. M. Teather and R. J. Forster . 2001 . Phylogenetic analysis of methanogens from the bovine rumen
  • R. G. 1970 . Fatty acidComposition of bovine skeletal muscle lipids during growth
    30 ( 5 ) , 726-731
  • Quantitative review of in situ starch degradation in the rumen
    106 ( 1 ) :81-93 [2003]
  • Qin, W. Z., Li, C. Y., Kim, J. K., Ju, J. G., & Song, M. K. 2012. Effects of defaunation on fermentation characteristics and methane production by rumen microbes in vitro when incubated with starchy feed sources. Asian-Australasian journal of animal sciences, 25(10), 1381. Qrskov, E. R. 1979. Recent information on processing of grains for ruminants. Livest. Prod. Sci. 6:335.
  • Processing ofCorn and sorghum for feedlotCattle
    23 ( 2 ) :207-221 [2007]
  • Procedure for two-stage in vitro digestion of forage .Nutrition research technique for domestic and wild animals . J. Bri
    [1970]
  • Prediction of Methane Production from Dairy and BeefCattle
    90 : 3456-3467 . [2007]
  • Potential of various fatty feeds to reduce methane release from rumen fermentation in vitro ( Rusitec )
    71 : 117-130 [1998]
  • Phylogenetic analysis of Butyrivibrio strains reveals three distinct groups of species within theClostridium subphylum of the gram-positive bacteria
    46 ( 1 ) , 195-199 . [1996]
  • P. L. 1964Anaerobic waste treatment fundamentals
    95 ( 9 ) , 107-112
  • Official method of analysis ( 16th Ed. )
    [1995]
  • Nutritional management for enteric methane abatement : a review
    48 ( 2 ) , 21-27 . [2008]
  • Nutritional impact of intestinal drug-microbe interactions . pages 189-251 in Hathcock , J. N. and Coon , J . ( eds ) , Nutrition and drug interrelation
    [1978]
  • Nonstructural carbohydrate and protein effects on rumen fermentation , nutrient flow , and performance of dairy cows
    [1993]
  • New inhibitors of methane production by rumen micro-organisms . Experiments with animals and other practical possibilities . ?
    34 ( 3 ) , 447-457 [1975]
  • Natural products as manipulators of rumen fermentation
    15 . 458-1468 [2002]
  • N. B. and Van Vuuren , A. M. 2010 . Strategies for optimizing nitrogen use by ruminants
    4 ( 7 ) :1184-1196 .
  • Multiple range and multiple F test
    11 : 1-6 [1995]
  • Mohammed, N., Lila, Z. A., Ajisaka, N., Hara, K., Mikuni, K., Hara, K., ... & Itabashi, H. 2004. Inhibition of ruminal microbial methane production by β?cyclodextrin iodopropane, malate and their combination in vitro. Journal of Animal Physiology and Animal Nutrition, 88(5?6), 188-195.
  • Mohammed, N., LILA, Z. A., TATSUOKA, N., Hara, K., Mikuni, K., Hara, K., ... & ITABASHI, H. 2004. Effects of cyclodextrin?iodopropane complex on methane production, ruminal fermentation and microbes, digestibility and blood metabolites in steers. Animal Science Journal, 75(2), 131-137.
  • Mode of action of the yeast Sacchararomyces cerevisiae as a feed additive for ruminants
    76 : 246-261 . [1996]
  • Microbial ecology and activities in the rumen : PartⅡ
    9 ( 4 ) : 253-32 [1982]
  • Microbial counts , fermentation products , and aerobic stability of whole crop corn and a total mixed ration ensiled with and without inoculation of Lactobacillus casei or Lactobacillus buchneri
    87 ( 8 ) :2563-2570 [2004]
  • Methanogen genomics ton discover targets for methane mitigation technologies and options for alternative H2 utilization in the rumen
    [2008]
  • Methaneand nitrogen oxide fluxes in tropical agricultural soils : sources , sinks and mechanisms
    Sustain.6 : -49 [2004]
  • Methane suppression by coconut oil and associater effects on nutrient and energy balance in sheep
    79 : 65-72 . [1999]
  • Methane production from in vitro rumen incubations with Lotus pedunculatus and Medicage sativa , and effects of extractable condensed tannin fractions on methanogenesis
    vol , 123-124 , pp . 403-419 . [2005]
  • Methane production by rumint : Its contribution to global warming
    49 : 321-253 . [2000]
  • Methane production by ruminant : Its contribution to global warming
    49 : 321-253 . [2000]
  • Methane formation in faunated and ciliate-free cattle and its relationship with rumen volatile fatty acid proportions .
    [1984]
  • Methane emissions from cattle
    73 : 2483-2492 . [1995]
  • Methane emissions from beef cattle : effects of monensin , sunflower oil , enzymes , yeast , and fumaric acid
    82 ( 11 ) , 3346-3356 . [2004]
  • Methane Production Potential of FeedI ngredients as Measured by invitro Gas Test
    Vol 16 , No . 8 : 1143-1150 . [2003]
  • Metabolic , phylogenetic , and ecological diversity of the methanogenic archaea
    [2008]
  • Medium-chain fatty acids and theirpotentialto reduce methanogenesis in domestic ruminants
    112 : 107 ? 114 [2006]
  • Measurement and prediction of enteric methane emission .
    55 ( 1 ) , 1-16 . [2011]
  • May, M. L., Quinn, M. J., Reinhardt, C. D., Murray, L., Gibson, M. L., Karges, K. K. and Drouillard, J. S. 2009. Effects of dry-rolled or steam-flaked corn finishing diets with or without twenty-five percent dried distillers grains on ruminal fermentation and apparent total tract digestion. Journal of animal science, 87(11):3630-3638.
  • Manriquez, O. M., Montano, M. F., Calderon, J. F., Valdez, J. A., Chirino, J. O., Gonzalez, V. M. and Zinn, R. A. 2016. Influence of Wheat Straw Pelletizing and Inclusion Rate in Dry Rolled or Steam-flaked Corn-based Finishing Diets on Characteristics of Digestion for Feedlot Cattle. Asian-Australasian journal of animal sciences, 29(6):823.
  • Manipulation of rumen fermentation and ecology of swamp buffalo by coconut oil and garlic powder supplementation . Livest Sci. , 135:84 ? 92
    [2011]
  • Lipid-induced depression of methane production and digestibility in the artificial rumen system ( RUSITEC )
    [1997]
  • Lee, J. M., Park, B. Y., Cho, S. H., Kim, J. H., Yoo, Y. M., Chae, H. S., & Choi, Y. I. 2004. Analysis of carcass quality grade components and chemicophysical and sensory traits of M. longissimus dorsi in Hanwoo. Journal of Animal Science and Technology, 46(5), 833-840.
  • Lauric acid와 Acetogen의 사료 내 첨가가 반추위 발효 성상과 메탄 발생량에 미치는 영향. 석사학위
    주영혜 건국대학교 [2013]
  • L. L. 1996. susceptibility of Helicobacter pylori to bactericidal properties of medium-chain monoglycerides and free fatty acids
    40 ( 2 ) : 302-6 .
  • Kinetics of methane fermentation in anaerobic treatment
    [1969]
  • Kinetics of lactate , acetate and propionate in unadapted and lactate-adapted thermophilic , anaerobic sewage sludge : the influence of sludge adaptation for start-up of thermophilic UASB-reactors
    [1991]
  • Kang, S. W., Cho, C. Y., Kim, J. S., Ahn, B. S., Chung, H. Y., & Seo, K. H. 2002. Effect of Hwangto, Illite, Oligosacharides, Charcoal powder and Chromium picolinate on the Growth Performance and Immunity in Eary Weaned Hanwoo Calves. Journal of Animal Science and Technology, 44(5), 531-540.
  • Isolation and characterization of methanogens from animal feces
    8 : 234-238 . [1986]
  • Inhibiton of ruminal methanogenesis by tropical plants containing secondary compounds
    1293 : 156-163 [2006]
  • Inhibition of rumen methanogenesis by methane analogues
    94 ( 1 ) , 171-175 [1967]
  • Influence of widely diverse finishing regimens and breeding on depot fat composition in beef cattle
    35 ( 5 ) , 1069-1075 .
  • Influence of fat and feed leve on fiber digestibility in vitro and in sacco and on volatile fatty acid proportions in the rumen
    86 ( Suppl . ) , 137-139 . [1989]
  • Influence of different concentrations of disodium fumarate on methane production and fermentation of concentrate feeds by rumen micro-organisms in vitro
    90 ( 3 ) , 617-623 [2003]
  • Influence of breed , sex and anatomical location on lipid and fatty acid composition of bovine subcutaneous fat
    105 [1983]
  • Indirect Estimation of CH4 from Livestock Feeds through TOCs Evaluation .
    25 : 496-501 . [2012]
  • In vitro ruminal methane suppression by lauric acid as influenced by dietary calcium
    82 : 233-239 [2002]
  • Improving rumen fermentation and feed digestibility in cattle by mangosteen peel and garlic pellet supplementation .
    148 ( 3 ) , 291-295 . [2012]
  • Impacts of different spices on in vitro rumen dry matter disappearance , fermentation and methane of wheat or ryegrass hay based substrates
    146 , 84-90 [2012]
  • Impact of corn vitreousness and processing on site and extent of digestion by feedlot cattle
    [2006]
  • Illite. Applied Clay Science 85(0):25-30.
    85 ( 0 ) :25-30
  • IPCC Fourth Assessment Report : Climate Change
    [2007]
  • I. Aselmanm and W. Seiler . 1986 . Methane production by domestic animals , wild ruminants , other herbivorous fauna and humans .
  • High-pressure adsorption of methane on montmorillonite , kaolinite and illite
    85 , 25-30 . [2013]
  • Herbs and botanicals as feed additives in minigastric animals
    16 : 282-289 . [2003]
  • Grain processing considerations influencing starch digestion and performance of feedlot cattle
    [2015]
  • Genetic effects on fatty acid composition of carcass fat of Japanese Black Wagyu steers
    80 ( 4 ) , 1005-1011 .
  • Garlic in ruminant feeding
    5 ( 7 ) :328-340 . [2012]
  • G. H. S. 1957 . A simple method for the isolation and purification of total lipids from animal tissues
  • France J. and McBride B. W. 2007 . Long-term effects of feeding monensin on methane production in lactating dairy cows
    90 ( 4 ) :1781-1788
  • Formate as an intermediate in the bovine rumen fermenation
    102 : 389-397 . [1970]
  • Fish oils as potent rumen methane inhibitors and associated effects on rumen fermentation in vitro and in vivo
    104 ( 1-4 ) , 41-58 [2003]
  • Ferret A. and Kamel C. 2004 . Effects of natural plant extracts on ruminal protein degradation and fermentation profiles in continuous culture
    82 ( 11 ) :3230-3236
  • Fatty acid composition of bovine lipids as influenced by diet , sex and anatomical location and relationship to sensory characteristics
    48 ( 6 ) , 1343-1348 [1979]
  • Factors affecting mitigation of methane emission from ruminants I : feeding strategies
    6 ( 9 ) , 888-908 . [2011]
  • Estimate ofme thane production from rumen fermentation
    60 , 89-92 . [2001]
  • Essential oils and opportunities to mitigate enteric methane emissions from ruminants
    [2011]
  • Enteric methane production and greenhouse gases balance of diets differing in concentrate in the fattening phase of a beef production system
    89 : 2518-2528
  • Effects of the absence of protozoa from birth or from weaning on the growth and methane production of lambs
    100 ( 6 ) , 1220-1227 [2008]
  • Effects of tea saponins on rumen microbiota , rumen fermentation , methane production and growth performance ? a review
    44 ( 4 ) , 697-706 [2012]
  • Effects of sustained reduction of enteric methane emissions with dietary supplementation of 3-nitrooxypropanol on growth performance of growing and finishing beef cattle
    94 ( 5 ) , 2024-2034 [2016]
  • Effects of mixtures of lauric acid myristic acid on rumenm ethanogens and methanogenesis in vitro
    37 : 35-39 . [2003]
  • Effects of fractions contacting saponins from Yucca schidigera , Quillaja saponaria and Acacia auriculoformis on rumen fermentation
    46 , 4324-4328 [1998]
  • Effects of feed carbohydrates with contrasting properties on rumenfermentation and methane release in vitro
    84 : 265-276 [2004]
  • Effects of dose and adaptation time of a specific blend of essential oil compounds on rumen fermentation
    [2007]
  • Effects of a specific blend of essential oil compounds on dry matter and crude protein degradability in heifers fed diets with different forage to concentrate ratios
    114 ( 1 ) :91-104 [2004]
  • Effects of a Saccharomyces cerevisiae yeast on ruminal fermentation and fibre degradation of maize silages in cows
    145 ( 1 ) : 27-40 [2008]
  • Effects of Halogenated Compounds on in vitro Fermentation Characteristics in the Rumen and Methane Emissions
  • Effects of Grain Processing with Focus on Grinding and Steam-Flaking on Dairy Cow Performance
    [2017]
  • Effect of the tropical tannin-rich shrub legumes Calliandra calothyrsus and Flemingia macrophylla on methane emission and nitrogen and energy balance in growing lambs .
    2 ( 5 ) , 790-799 . [2008]
  • Effect of the carbohydrate composition of feed concentrateson methane emission from dairy cows and their slurry
    107 : 329-350 [2005]
  • Effect of the addition of fumarate on methane production by ruminal microorganisms in vitro
    82 , 780-787 [1999]
  • Effect of tea saponin on rumen fermentation in vitro
    120 ( 3-4 ) , 333-339 [2005]
  • Effect of tannin levels in sorghum silage and concentrate supplementation on apparent digestibility and methane emission in beef cattle .
    135 ( 3-4 ) , 236-248 . [2007]
  • Effect of refined coconut oil or copra meal on methane output and on intake and performance of beef heifers
    84 ( 1 ) : 162-70 . [2006]
  • Effect of plant oils and malate on rumen fermentation in vitro . Czech Journal of Animal Science-UZPI ( Czech Republic
    [2002]
  • Effect of oral nitroethane and 2-nitropropanol administration on methane-producing activity and volatile fatty acid production in the ovine rumen
    97 ( 18 ) , 2421-2426 . [2006]
  • Effect of nisin on ruminal methane production and nitrate/nitrite reduction in vitro
    56 , 803-810 [2005]
  • Effect of garlic powder on methane production , rumen fermentation and milk production of buffaloes
    [2013]
  • Effect of garlic oil and four of its compounds on rumen microbial fermentation
    [2005]
  • Effect of garlic and juniper berry essential oils on ruminal fermentation and on the site and extent of digestion in lactating cows
    [2007]
  • Effect of garlic and garlic extracts on rumen archaea
    [2007]
  • Effect of fumaric acid on methane production , rumen fermentation and digestibility of cattle fed roughage alone
    72 ( 2 ) , 139-146 . [2001]
  • Effect of cyclodextrin diallyl maleate on methane production , ruminal fermentation and microbes in vitro and in vivo
    75 ( 1 ) , 15-22 . [2004]
  • Effect of complexing sodium bentonite with soybean meal or urea in vitro ruminal ammonia release and nitrogen utilization in ruminants
    46 ( 6 ) , 1738-1747 . [1978]
  • Effect of coconut oil and garlic powder on in vitro fermentation using gas production technique
    127 ( 1 ) , 38-44 . [2010]
  • Effect of adding acetogenic bacteria on methane production by mixed rumen microorganisms
    78 : 1-9 [1999]
  • Effect of Terminalia chebula and Allium sativum on in vivo methane emission by sheep
    95 ( 2 ) , 187-191 [2011]
  • Effect of Illite , Garlic Powder and Lactobacillus mucosae on In Vitro Rumen Fermentation and Methane Mitigation
    [2014]
  • Effect of 2-bromoethanesulfonic acid on in vitro fermentation characteristics and methanogen population
    22 ( 1 ) , 42-48 . [2009]
  • Development of technologies to improve competitiveness of Hanwoo
    pp 85-98 [2003]
  • Defaunation effects of medium-chain fatty acids and their derivatives on goat rumen protozoa
    37 ( 5 ) , 439-445 [1991]
  • D. P. Morgavi and M. Doreau . 2010 . Methane mitigation in ruminants : from microbe to the farm scale
    4 ( 3 ) : 351-365 .
  • D. I. and Graeve , K. D. 1991. differences in stoichiometry between rumen and hindgut fermentation
    22 : 50-61 .
  • Corn grain and liquid feed as nonfiber carbohydrate sources in diets for lactating dairy cows
    94 ( 6 ) :3045-3053 [2011]
  • Comparative effeciency of various fats rich in medium-chain fatty acids to suppress ruminal methanogenesis as measured with RUSITEC
    80 : 473-482 . [2000]
  • Chloroform decreases rumen methanogenesis and methanogen populations without altering rumen function in cattle
    166 , 101-112 [2011]
  • Cellulolytic activity in the rumen of lambs fed a high concentrate diet is not affected by the removal of protozoa
    85 , 251-254 [2009]
  • C. R. , Al-Khodairy , F. , Carr , A.M. , Enoch , T. 1997. rqh1+ , a fission yeast gene related to the Bloom ’ s and Werner ’ s syndrome genes , is required for reversible S phase arrest
    16 , 2682-2693 .
  • C. J. and Demeyer , D. IControl of rumen methanogenesis
    42 : 73-97 . [1996]
  • C. J. and Chamberlain , D. G. 1988 . Lipids as rumen-defaunation agents
    47 : 154A .
  • Biswas, A. A., Lee, S. S., Mamuad, L. L., Kim, S. H., Choi, Y. J., Lee, C., ... & Lee, S. S. 2018. Effects of illite supplementation on in vitro and in vivo rumen fermentation, microbial population and methane emission of Hanwoo steers fed high concentrate diets. Animal Science Journal, 89(1), 114-121.
  • Bentonite와 맥반석의 급여가 반추위내 완충능력과 발효양상에 미치는 영향
    김수홍 손용석 이성호 홍성호 한국낙농학회지 21:21 [1998]
  • Basic Principles of Bioconversions in Anaerobic Digestion and Methanogenesis . In : Sofer S. S. , Zaborsky O. R. ( eds ) Biomass Conversion Processes for Energy and Fuels .
    [1981]
  • Assessing rumen biohydrogenation and its manipulation in vivo , in vitro and in situ
    109 ( 8 ) , 740-756 [2007]
  • Antimethanogenic drugs and Heliotropium europaeum poisoning in penned sheep
    29 ( 6 ) , 1281-1292 . [1978]
  • Animal products grading statistical yearbook
    [2018]
  • Anderson, R. C., Callaway, T. R., Van Kessel, J. A. S., Jung, Y. S., Edrington, T. S., & Nisbet, D. J. 2003. Effect of select nitrocompounds on ruminal fermentation; an initial look at their potential to reduce economic and environmental costs associated with ruminal methanogenesis. Bioresource Technology, 90(1), 59-63.
  • Analysis of acetogenic bacteria in human feces with formyltetrahydrofolate synthetase sequences
    [2007]
  • An automated method for measuring time-course of gas production of feedstuffs incubated with buffered rumen fluid
    40 ( 4 ) , 401-407 [1992]
  • An Introduction to Rumen Studies
    [1986]
  • Adsorption measurements in Devonian shales
    74 ( 4 ) , 599-603 . [1995]
  • Acetate production from hydrogen & 13C carbon dioxide by the microflora of human feses
    54 : 2723-2727 [1988]
  • A. L. and Marbach , E. P. 1962 . Modified reagents for determination of urea and ammonia
  • 2009 . Effects of the methane-inhibitors nitrate , nitroethane , lauricaciD, Lauricidin and the Hawaiian marine algae Chaetoceros on ruminal
    Technol . 100 :