한우에서 사료의 급여체계가 반추위 발효성상, 메탄 발생량, 미생물 다양성, 영양소 소화율 및 체내 대사체에 미치는 영향 = The Effect of Feeding Strategy on Rumen Fermentation, Methane Emission, Microbial Diversity, Nutrient Digestibility and Biofluid Metabolite in Hanwoo

이유경 2020년

활용도
공유도
영향력

논문상세정보

- 저자 이유경
- 형태사항 26 cm: xv, 176 p.
- 일반주기 지도교수: 이성실
- 학위논문사항 응용생명과학부 응용생명과학전공, 경상대학교 대학원, 학위논문(박사)-, 2020. 2
- 발행지 진주
- 언어 kor
- 출판년 2020
- 발행사항 경상대학교 대학원
- 주제어 대사체 메탄 미생물 다양성 반추위 발효 사료 한우
- 참고문헌( 191)
유사주제 논문( 243)

인용/피인용

한우에서 사료의 급여체계가 반추위 발효성상, 메탄 발 ...

' 한우에서 사료의 급여체계가 반추위 발효성상, 메탄 발생량, 미생물 다양성, 영양소 소화율 및 체내 대사체에 미치는 영향 = The Effect of Feeding Strategy on Rumen Fermentation, Methane Emission, Microbial Diversity, Nutrient Digestibility and Biofluid Metabolite in Hanwoo' 의 주제별 논문영향력

논문영향력 요약
동일주제 총논문수	논문피인용 총횟수	주제별 논문영향력의 평균
주제	대사체 메탄 미생물 다양성 반추위 발효 사료 한우
249	0	0.0%

논문영향력
주제		주제별 논문수	주제별 논문영향력
주제어	대사체	14	0.0%
	메탄	74	0.0%
	미생물 다양성	7	0.0%
	반추위 발효	12	0.0%
	사료	39	0.0%
	한우	103	0.0%
계		249	0.0%
* 다른 주제어 보유 논문에서 피인용된 횟수

' 한우에서 사료의 급여체계가 반추위 발효성상, 메탄 발생량, 미생물 다양성, 영양소 소화율 및 체내 대사체에 미치는 영향 = The Effect of Feeding Strategy on Rumen Fermentation, Methane Emission, Microbial Diversity, Nutrient Digestibility and Biofluid Metabolite in Hanwoo' 의 참고문헌

온실가스 종합정보센터. 국가 온실가스 인벤토리 보고서. 환경부. 서울
온실가스 대한민국 [2019]
반추동물영양생리학. 서울대학교출판문화원. 서울
김창현 문양수 백명기 서성원 이상석 이성실 이세영 이왕식 장종수 최낙진 하종규 대한민국 [2013]
등 The association of serum metabolites in the transition period with milk production and early-lactation reproductive performance
Capel M Carson ME Chapinal N Godden S LeBlanc SJ Leslie KE J Dairy Sci. ; 95: 1301∼1309 [2012]
등 Plasma metabolites associated with residual feed intake and other productivity performance traits in beef cattle
Karisa BK Li C Miller SP Montanholi YR Thomson J Wang Z Livest Sci. ; 165:200∼211 [2014]
등 Metabolomic profiling of urine:response to a randomised, controlled feeding study of select fruits and vegetables, and application to an observational study
Hogan J May DH Navarro SL Ogata Y Ruczinski I Schwarz Y Br J Nutr. ; 110: 1760∼1770 [2013]
등 Metabolomic profiles indicate distinct physiological pathways affected by two loci with major divergent effect on Bos taurusgrowth and lipid deposition
Albrecht E Altmaier E Hammon HM Suhre K Weikard R Weinberger KM Physiol Genomics. ; 42A: 79∼88 [2010]
등 Investigating associations between milk metabolite profiles and milk traits of Holstein cows
Hartwig S Jakubowski S Kesting U Melzer N Willmitzer L Wittenburg D J Dairy Sci. ; 96: 1521∼1534 [2012]
국립기상과학원. 한반도 100년의 기후변화. 국립기상과학원. 제주
국립기상과학원 대한민국 [2018]
관계부처 합동. 이상기후보고서. 기상청. 서울
관계부처 대한민국 [2018]
Widmann P. Metabolomics : a pathway for improved understanding of genetic modulation of mammalian growth and tissue deposition
1∼6 [2014]
Volatile fatty acid analyses of blood and rumen fluid by gas chromatography
44 ( 9 ) :1768-1771 [1961]
Volatile fatty acid analyses of blood and rumen fluid by gas chromatography
44 ( 9 ) :1768-1771
Validation of the sulphur hexafluoride ( SF6 ) tracer gas technique for measurement of methane and carbon dioxide production by cattle
[2002]
Use of ‘ natural ’ products as alternatives to antibiotic feed additive in ruminant production
Vol . 1 , No . 10 , pp . 1443-1446 [2007]
Urine metabolomics combined with the personalized diagnosis guided by Chinese medicine reveals subtypes of prediabetes
[2012]
Transport of coenzyme M ( 2-mercaptoethanesulfonic acid ) in Methanobacterium ruminantium
137 ( 1 ) : 264-273 . [1979]
The stimulatory effects of sodium butyrate and sodium propionate on the development of rumen mucosa in the young calf
Vol . 42 , No . 9 , pp . 1600-1605 [1959]
The ruminant animal ; Digestive physiology and nutrition
[1998]
The role of methane in atmospheric chemistry and climate
[1995]
The influence of treatment with dual-purpose bacterial inculants or soluble carbohydrates on the fermentation and aerobic stability of bemudagrass
Vol . 87 , No . 10 , pp . 3407-3416 [2004]
The importance of methanogens associated with ciliate protozoa in ruminal methane production in vitro
21 , 230-234
The importance of methanogens associated with ciliate protozoa in ruminal methane production in vitro
21 , 230-234 [1995]
The emerging field of quantitative blood metabolomics for biomarker discovery in critical illnesses
184 , 647 ? 655 [2011]
The effects of fructose and phosphate infusions on dry matter intake of lactating cows
Vol . 100 , No . 4 , pp . 2651-2659 [2017]
The effects of dietary inclusion of yeast culture ( Yea-Sacc ) on patterns of rumen fermentation , food intake and growth of intensive fed bulls
55 : 35-40 . [1992]
The effect of concentrate type on energy utilization in lactating cows .
No 43:33 . [1989]
The effect of a condensed tannin-containing forage on methane emission by goats . ?
83 ( 1 ) , 182-186 . [2005]
Supplementation of Acacia mearnsii tannins decreases metanogenesis and urinary nitrogen in forage-fed
[2005]
Studies on ruminant saliva . 1 . The composition and output of sheep 's saliva
[1948]
Some rumenCiliates have endosymbiotic methanogens
[1994]
Shearer J. Metabolomic response to exercise training in lean and diet-induced obese mice
110 : 1311∼1318 [2011]
Sharpea and Kandleria are lactic acid producing rumen bacteria that do notChange their fermentation products whenCo-cultured with
Anaerobe , Vol . 54 , pp
Separation and purification of antioxidant activity acidic polysaccharide from Red Ginseng Marc
Vol . 34 , No . 4 , pp . 915-923 [2017]
Screening of the liver , serum , and urine of piglets fed zearalenone using a NMR-based metabolomic approach.
Vol . 45 , No . 3 , pp . 447-454 [2018]
Savadi-Shiraz E. Metabolomics fingerprinting of the human seminal plasma of asthenozoospermic patients
81 : 84∼86 [2014]
Sarsaponin effects on in vitroContinuous flow fermentation of a high grain diet
Vol . 33 , pp . 64-66 [1982]
Saito K. Modern plant metabolomics : advanced natural product gene discoveries , improved technologies , and future prospects
32 : 212∼229 . [2015]
S. Jang ,C. W.Choi , M. K. Song , “ Effects of feeding wholeCrop barley silageor wholeCrop rye silage based-TMR and duration of TMR
of hanwoo steers ” , Journal of Animal Science and Technology
Ruminant nutrition and physiology
pp . 203-207 [2013]
Ruminal metabolism of plant toxins with emphasis on indolicCompounds
Vol . 58 , No . 4 , pp . 1040-1049 [1984]
Rumen microbialCommunities influence metabolic phenotypes in lambs
Vol . 6 , pp . 1060 [2015]
Rumen Fluid Metabolomics Analysis Associated with Feed Efficiency onCrossbred Steers
2.280555556 [2017]
Response of early lactation dairyCows fed diets varying in sources of nonstructuralCarbohydrate andCrude protein
Vol . 73 , No . 4 , pp . 1039-1050 [1990]
Repsilber D. Integrating milk metabolite profile information for the prediction of traditional milk traits based on SNP information for HolsteinCows
8 [2013]
Relations between passage rates of rumen fluid and particulate matter and foam production in rumenContents ofCattle fed on different diets ad lib
61 ( 2 ) , 387-395 [1989]
Rehage , S. Danicke , “Changes of ruminal pH , rumination activity and feeding behaviour during early lactation as affects by different energy and fibreConcentration
, Archives of Animal Nutrition , Vol . 72 , No
Reducing rumen methane emissions through elimination of rumen protozoa
50 ( 8 ) , 1321-1328 [1999]
Reducing methane emissions from ruminant animals
14 , 1-28 . [1998]
Redirecting rumen fermentation to reduce methanogenesis
48 ( 2 ) :7-13 [2008]
Quantitative H-1 NMR-based metabolomics of plasma and urine in type 1 diabetic humans : the effects of insulin deprivation
[2008]
Protein and energy as an integrated system . Relationship of ruminal protein andCarbohydrate availability to microbial synthesis and milk production
71 ( 8 ) , 2070-2107 [1988]
Pluvinage , T. A. McAllister , R. J. Forster , A. Tsang , L. B. Selinger , D. W.
of family 39 glycoside hydrolases from rumen anaerobic fungi with polyspecific activity
Plane of nutrition and season effects on energy maintenance
[1989]
Physicochemical , structural , pasting , and rheological properties of potato starch isolated from differentCultivars
Vol . 49 , No . 4 , pp . 360-368 [2017]
Phylogenetic analysis of methanogens from the bovine rumen
[2001]
Persistence of differences between sheep in methane emission under generous grazing conditions . ?
140 ( 2 ) , 227-233 . [2003]
Pasture Feeding Changes the Bovine Rumen and Milk Metabolome
8 ( 2 ) [2018]
Omholt S. Phenomics : the next challenge
11 : 855∼566 . [2010]
Official mehods of analysis of AOAC INTERNATIONAL
19th edition [2012]
Nutritional requirements of the predominant rumen celluloytic bacteria
Vol . 32 , pp . 1809-1813 [1973]
Nutritional metabolomics : progress in addressing complexity in diet and health
32 : 183∼202 . [2012]
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]
Nutrient requirements of domestic animals : Nutrient requirements of beef cattle
[2000]
Nuclear magnetic resonance metabonomics reveals strong association between milk metabolites and somatic cell count in bovine milk
96 : 290∼299 [2013]
Nitrogen balance , blood metabolites and milk fatty acid composition of dairy cows fed pomegranate-peel extract
164 : 72∼80 . [2014]
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 , 1458-1468 [2002]
Multivariate analysis on 1H-NMR Spectroscopy of olive flounder paralichthys olivaceus serum
Vol . 45 , No . 4 , pp . 367-371 [2012]
Multiple range and multi F test
[1955]
Mode of action of the yeast Sacchararomyces cerevisiae as a feed additive for ruminants
[1996]
Mitigation strategies to reduce enteric methane emissions from dairy cows : update review . ?
84 ( 3 ) , 319-335 [2004]
Methane suppression by coconut oil and associated effects on nutrient and energy balance in sheep
79 , 65 ? 72 [1999]
Methane production in dairy cows
[1979]
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 ruminants : its contribution to global warming
[2000]
Methane production and substrate degradation by rumen microbial communities containing single protozoal species in vitro
45 ( 6 ) , 675-680 [2007]
Methane production and its dietary manipulation in ruminants
[1997]
Methane mitigation in ruminants : from microbe to the farm scale
4 ( 3 ) : 351-365 . [2010]
Methane formation in faunated and ciliate-free cattle and its relationship with rumen volatile fatty acid proportions .
[1984]
Methane emissions from cattle
[1995]
Methane emissions from beef cattle : effects of monensin , sunflower oil , enzymes , yeast , and fumaric acid
82 ( 11 ) :3346-3356 [2004]
Methane emissions and digestive physiology of non-lactating dairy cows fed pasture forage
87 ( 4 ) , 601-613 [2007]
Metabolomics reveals unhealthy alterations in rumen metabolism with increased proportion of cereal grain in the diet of dairy cows
Metabolomics 6 , 583 ? 594 [2010]
Metabolomics of meat exudate : Its potential to evaluate beef meat conservation and aging
901 : 1∼11 [2015]
Metabolomics analysis reveals large effect of roughage types on rumen microbial metabolic profile in dairy cows
59 ( 1 ) , 79-85. doi:10.1111/lam.12247 [2014]
Metabolomics : applications to food science and nutrition research
19 , 482 ? 493 [2008]
Metabolomics : application to food science and nutrition research
19 : 482∼493 [2008]
Metabolic trajectories based on H-1 NMR spectra of urines from sheep exposed to nutritional challenges during prenatal and early postnatal life
6 , 489 ? 496 . [2010]
Metabolic predictors of displaced abomasum in dairy cattle
88 : 159∼170 . [2005]
M. C. Spooner , M. J. Haines , J. I. Harland
[1989]
Long-term effects of feeding monensin on methane production in lactating dairy cows
90 ( 4 ) :1781-1788 [2007]
Lipid-induced depression of methane production and digestibility in the artificial rumen system ( RUSITEC )
[1997]
Lee , “ The effects of sodium bicarbonate and liquid buffer on milk yield , milk composition and blood metabolites of
Life Science , Vol . 48 , No . 6
Kyoto Protocol to The United Nations Framework Convention on Climate Change
[1997]
Knox C. The human urine metabolome
[2013]
International NMR-based environmental metabolomics intercomparison exercise
43 , 219 ? 225 [2009]
Integrated pathway-based and network-based analysis of GCMS rice metabolomics data under diazinon stress to infer affected biological pathways
494 : 31∼36 . [2016]
Inhibition of ruminal methanogenesis by tropical plants containing secondary compouds
1293 : 156-163 [2006]
Induction of subsacute ruminal acidosis affects the ruminal microbiome and epithelium
[2016]
Improved extraction of PCR-quality community DNA from digesta and fecal samples
36 ( 5 ) , 808-812 . [2004]
Impact of pasture type on methane production by lactating beef cows
[1999]
Identification of predictive biomarkers of disease state in transition dairy cows
97 : 2680∼2693 [2014]
Hydrogen production and trasfer in the rumen
[1998]
Herbs and botanicals as feed additives in minigastric animals
16 : 282-289 . [2003]
H. P. S. and P. E. Vercoe . 2007
H-1 NMR based metabolomics of CSF and blood serum : a metabolic profile for a transgenic rat model of Huntington disease
[2011]
Good practice guidance and uncertainty management in national greenhouse gas inventories : IPCC national greenhouse gas inventories programme
[2000]
Global metabolomics profiling of human urine reveals change in endogenous metabolites after metformin and pioglitazone administration
93 , S15 [2013]
Gilany K. Metabolomics : a state-of-the-art technology for better understanding of male infertility .
48 : 609∼16 . [2015]
Garcia-Canas V. Metabolomics of genetically modified crops .
15 : 18941∼18966 . [2014]
Food metabolomics : from farm to human
37 : 16∼23 [2016]
Fish oils as potent rumen methane inhibitors and associated effects on rumen fermentation in vitro and in vivo . ? Animal Feed Science and Technology , ?
104 ( 1-4 ) , 41-58 [2003]
Ferret A. and Kamel C. 2005 . Screening for effects of plant extracts and active compounds of plants on dairy cattle rumen microbial
Ferret A. and Kamel C. 2005
Feed additives and other interventions for decreasing methane emissionsBiotechnology and Animal Feeds and Animal Feeding
pp . 329 [1995]
Evaluation of some insects as potential feed ingredients for ruminants : chemical compostion , in vitro rumen fermentation and methane emissions
Vol . 42 , No . 4 , pp . 247-254 [2017]
Evaluation of dietary strategies to reduce methane production in reminants : A modeling approach
[2001]
Estimation of methane production in ruminants
[1993]
Efficacy of using the face mask technique for the estimation of daily heat production of cattleEnergy Metabolism of Farm Animal
[1989]
Effects of total mixed rations on ruminal characteristics , digestibility and beef production of Hanwoo steers
45 ( 3 ) :387-396 [2003]
Effects of several inhibitors on pure cultures of ruminal
[2004]
Effects of organic acid and monensin treatment on in vitro mixed ruminal micro-organism fermentation of cracked corn
74 [1996]
Effects of ionophores on ruminal fermentation
55 ( 1 ) :1-6 [1989]
Effects of fractions contacting saponins from Yucca schidigera , Quillaja saponaria and Acacia auriculoformis on rumen fermentation
46 , 4324-4328 [1998]
Effects of feeding frequency on ruminal parameters , plasma insulin , milk yield , and milk composition in Holstein cows
73 ( 7 ) , 1857-1863 [1990]
Effects of extrusion of grain and feeding frequency on rumen fermentation , nutrient digestibility , and milk yield and composition in dairy cows
82 ( 6 ) , 1252-1260 [1999]
Effects of active dry yeasts on the rumen microbial ecosystems : Past , present and future
[2008]
Effect or diet on populations of three species of ruminal cellullytic bacteria in lactating dairy cattle
[1999]
Effect of the addition of fumarate on methane production by ruminal microorganisms in vitro
82 , 780- [1999]
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 supplementation of fresh and ensiledClovers to ryegrass on nitrogen loss and methane emission of dairyCows .
111 ( 1-2 ) , 57-69 . [2007]
Effect of roughage source and roughage to concentrate ratio on animal performance and rumen development in veal calves . ?
90 ( 5 ) , 2390-2403 . [2007]
Effect of methane inhibitors on rumen metabolism and feedlot performance of sheep . ?
54 ( 4 ) , 536-540 . [1971]
Effect of dietary nitrogen content on the urine metabolite profile of dairy cows assessed by nuclear magnetic resonance ( NMR ) -based metabolomics
59 , 12499 ? 12505 [2011]
Effect of adding acetogenic bacteria on methane production by mixed rumen microorganisms
[1999]
Early stage diagnosis of mastitis of dairy cows using H-1 NMR-based metabolomics
93 , 525 [2010]
Dietary environmental and microbiological aspects of methane production in ruminants
76 : 231-243 . [1996]
Determination and occur-rence of histamine in rumen liquor of sheep
Vol . 8 , pp . 50-70 [1967]
Deconvolution of two-dimensional nmr spectra by fast maximum likelihood reconstruction : application to quantitative metabolomics
83 , 4871 ? 4880 [2011]
Comparative metabolome analysis of ruminal changes in Holstein dairy cows fed low-or high-concentrate diets
Comparative metabolome analysis of ruminal changes in Holstein dairy cows fed low- or high- concentrate diets
Vol . 13 , pp.74 [2017]
Comparative efficiency of various fats rich in medium chain fatty acids to suppress ruminal methanogenesis as measured with RUSITEC
[2000]
Changes of protein composition of milk by ratio of roughage to concentrate
Vol . 63 , No . 5 , pp . 756-761 [1980]
Carotenoids for ruminants : From forages to dairy products
Vol . 131 , No . 3-4 , pp . 418-450 [2006]
Candidate genes and biological pathways associated with carcass quality traits in beef cattle
93 : 295∼306
C. J. and D. I. , DemeyerControl of rumen methanogenesis
[1996]
Buazar F. Impact of pharmaceutical impurities in Ecstasy tablets : gas chromatography-mass spectrometry study
15 : 221∼229 . [2016]
Biomarker discovery in animal health and disease : the application of post-genomics technologies
2 : 185∼196 . [2007]
B. N. Ametaj and D. S. WishartThe Bovine Ruminal Fluid Metabolome
9 ( 2 ) : 360-378 . [2013]
Assessing rumen biohydrogenation and its manipulation in vivo , in vitro and in situ . ? European Journal of Lipid Science and Technology
109 ( 8 ) , 740-756 [2007]
Animal and Human Calorimetry
[1987]
Analysis of biological networks and biological pathways associated with residual feed intake in beef cattle
85 ( 4 ) , 374-387 [2014]
An analytical method for the validation of a salt-enhancing petide using a liquidChromatography and a nuclear magnetic resonance ( NMR
Science , Vol . 27 , No . 11 , pp [2017]
Acetate dose-dependently stimulates milk fat synthesis in lactating Dairy cows
Vol . 147 , No . 5 , pp . 763-769 [2017]
ATP activation and properties of the methyl coenzyme M reductase system in Methanobacterium thermoautotrophicum . ? Journal of bacteriology , ?
135 ( 3 ) , 851-857 . [1978]
A versatile respirator pattern analyzer for studies of energy metabolism of livestock .
[1975]
A two-stage technique for the in vitro digestion of forage crops .
18 ( 2 ) , 104-111 . [1963]
A targeted metabolomics approach toward understanding metabolic variations in rice under pesticide stress
478 : 65∼72 . [2015]
A respiration apparatus for tracer trials with radiocarbon on cows , sows and sheep
[1958]
A protocol for the operation of open-circuit chambers for measuring methane output in sheep . Makkar , H. P. S. and Vercoe ( eds ) , P. E. Measuring Methane Production from Ruminants
[2007]
A net carbohydrate and protein system for evaluating cattle diets – I. Ruminal fermentation
70 ( 11 ) , 3551-3561 . [1992]
A metabolomics approach to uncover the effects of grain diets on rumen health in dairy cows
95 ( 11 ) : 6606-6623 [2012]
A metabolomics approach to uncover the effect of grain diets on rumen health in dairy cows
95 : 6606∼6623 [2012]
95. Hristov, A. N., J. Oh, F. Giallongo, T. W. Frederick, M. T. Harper, H. L. Weeks, A. F. Branco, P. J. Moate, M. H. Deighton and S. R. O. Williams (2015). "An inhibitor persistently decreased enteric methane emission from dairy cows with no negative effect on milk production." Proceedings of the National Academy of Sciences 112(34): 10663-10668.
9. Chaney A, Land Marbach E, P. 1962. Clinical Chemistry. 8:130.
[1962]
8. Fontanesi L. Metabolomics and livestock genomics: Insights into a phenotyping frontier and its applications in animal breeding. Anim Front. 2016. 6. 73∼79.
8. Blaxter, K. L. 1989. Energy metabolism in animals and Man. Cambridge University Press, New York.
72. Itabashi, H., E. Bayaru, S. Kanda, T. Nishida, S. Ando, M. Ishida, T. Itoh, Y. Isobe, K. Nagara and K. Takei. 2000. Effect of salinomycin (SL) plus fumaric acid on rumen fermentation and methane production in cattle. Asian Aust. J. Anim. Sci. 13(suppl.)287(Abstr.).
63. Tiemann, T. T., Lascano, C. E., Wettstein, H. R., Mayer, A. C., Kreuzer, M., & Hess, H. D. (2008). Effect of the tropical tannin-rich shrub legumes Calliandra calothyrsus and Flemingia macrophylla on methane emission and nitrogen and energy balance in growing lambs.?Animal,?2(5), 790-799.
6. Chaney A, Land Marbach E, P. 1962. Clinical Chemistry. 8:130.
[1962]
54. The rumen microbial ecosystem, 1997
53. Rumen Microbiology and Its Role in Ruminant Nutrition, James B. Russell
5. F. G. Jiang, X. Y. Lin, Z. G. Yan, Z. Y. Hu, G. M. Liu, Y. D. Sun, X. W. Liu, Z. H. Wang, “Effect of dietary roughage level on chewing activity, ruminal pH, and saliva secretion in lactating Holstein cows”, Journal of Dairy Science, Vol. 100, No. 4, pp. 2660-2671, 2017.
33. Blaxter K. L. 1962. The energy metabolism of ruminants. The energy metabolism of ruminants. 329
3. Saleem, F., Ametaj, B. N., Bouatra, S., Mandal, R., Zebeli, Q., Dunn, S. M., and Wishart, D. S. 2012. A metabolomics approach to uncover the effects of grain diets on rumen health in dairy cows. J Dairy Sci, 95(11), 6606-6623. doi:10.3168/jds.2012-5403
3. IPCC?second?assessment: climate change,?1995
27. Chaney A, Land Marbach E, P. 1962. Clinical Chemistry. 8:130.
[1962]
2. Leggett, J., Pepper, W. J., Swart, R. J., Edmonds, J., Meira Filho, L. G., Mintzer, I., & Wang, M. X. (1992). Emissions scenarios for the IPCC: an update. Climate change, 69-95.
1H NMR-Based urinary metabolic profiling of gender and diurnal variation in healthy Korean subjects
Vol . 25 , No . 4 , pp . 295-306 [2010]
18. Chaney A, Land Marbach E, P. 1962. Clinical Chemistry. 8:130.
[1962]
17. Fiehn O. MetabolomicsÐthe link between genotypes and phenotypes. Plant Mol Biol. 2002; 48: 155∼171.
16. Chaney A, Land Marbach E, P. 1962. Clinical Chemistry. 8:130.
[1962]
1302 The effects of a high-or low-plane of nutrition pre-weaning on growth and starter intake of group-housed calves . ? Journal of Animal Science , ?
94 ( suppl_5 ) , 627-628 [2016]
12. Sekine, J., Hanada, M., Okubo, M., MIURA, Y., & ASAHIDA, Y. (1986). Some considerations on estimating a value of the rumen degradability of protein of the mixed ration for early weaned calves from the values of ingredients. Journal of the Faculty of Agriculture, Hokkaido University= 北海道大學農學部紀要, 63(1), 54-57.
113. Grainger, C., T. Clarke, S. M. McGinn, M. J. Auldist, K. A. Beauchemin, M. C. Hannah, G. C. Waghorn, H. Clark, and R. J. Eckard. 2007. Methane emission from dairy cows meased using the sulfur hexafluoride(SF6) tracer and chamber techniques. J. Dairy Sci. 90:2755-2766.
111. WHO. Commission on Social Determinants of Health. Closing the gap i n a generation: health equity through action on the social determinant s of health. Geneva:World Health Organization; 2008.
109. Johnson K. A. and Johnson D. E. 1995. Methane emissions from cattle. Journal of Animal Science, 73(8):2483-2492.
1. National Research Council, 1996
1. I. K. Han, W. J. Maeng, K. K. Park, I. K. Baek, S. J. Oh, Y. J. Choi, Sunjin Publishing Company, Seoul, Repubic of Korea, 1993.
[1993]
. Effect of pasture type ( alfalfa vs. grass ) on methane andCarbon dioxide production
Journal of Animal Science , 86 (

유사주제 논문( 243)

주제별 논문영향력