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PUBMED FOR HANDHELDS

Journal Abstract Search


1010 related items for PubMed ID: 27760570

  • 21. Factors influencing rumen fermentation: effect of hydrogen on formation of propionate.
    Schulman MD, Valentino D.
    J Dairy Sci; 1976 Aug; 59(8):1444-51. PubMed ID: 956483
    [Abstract] [Full Text] [Related]

  • 22. In Vitro Response of Rumen Microbiota to the Antimethanogenic Red Macroalga Asparagopsis taxiformis.
    Machado L, Tomkins N, Magnusson M, Midgley DJ, de Nys R, Rosewarne CP.
    Microb Ecol; 2018 Apr; 75(3):811-818. PubMed ID: 29018917
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  • 23. The genome sequence of the rumen methanogen Methanobrevibacter ruminantium reveals new possibilities for controlling ruminant methane emissions.
    Leahy SC, Kelly WJ, Altermann E, Ronimus RS, Yeoman CJ, Pacheco DM, Li D, Kong Z, McTavish S, Sang C, Lambie SC, Janssen PH, Dey D, Attwood GT.
    PLoS One; 2010 Jan 28; 5(1):e8926. PubMed ID: 20126622
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  • 24. Rumen responses to dietary supplementation with cashew nut shell liquid and its cessation in sheep.
    Kang S, Suzuki R, Suzuki Y, Koike S, Nagashima K, Kobayashi Y.
    Anim Sci J; 2018 Nov 28; 89(11):1549-1555. PubMed ID: 30182380
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  • 25. Effects of disodium fumarate on ruminal fermentation and microbial communities in sheep fed on high-forage diets.
    Zhou YW, McSweeney CS, Wang JK, Liu JX.
    Animal; 2012 May 28; 6(5):815-23. PubMed ID: 22558929
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  • 26. Dietary selection of metabolically distinct microorganisms drives hydrogen metabolism in ruminants.
    Li QS, Wang R, Ma ZY, Zhang XM, Jiao JZ, Zhang ZG, Ungerfeld EM, Yi KL, Zhang BZ, Long L, Long Y, Tao Y, Huang T, Greening C, Tan ZL, Wang M.
    ISME J; 2022 Nov 28; 16(11):2535-2546. PubMed ID: 35931768
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  • 27. Assessing the impact of rumen microbial communities on methane emissions and production traits in Holstein cows in a tropical climate.
    Cunha CS, Veloso CM, Marcondes MI, Mantovani HC, Tomich TR, Pereira LGR, Ferreira MFL, Dill-McFarland KA, Suen G.
    Syst Appl Microbiol; 2017 Dec 28; 40(8):492-499. PubMed ID: 29113689
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  • 28. Methane production and substrate degradation by rumen microbial communities containing single protozoal species in vitro.
    Ranilla MJ, Jouany JP, Morgavi DP.
    Lett Appl Microbiol; 2007 Dec 28; 45(6):675-80. PubMed ID: 17944841
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  • 29. Microbiome-informed study of the mechanistic basis of methane inhibition by Asparagopsis taxiformis in dairy cattle.
    Indugu N, Narayan K, Stefenoni HA, Hennessy ML, Vecchiarelli B, Bender JS, Shah R, Dai G, Garapati S, Yarish C, Welchez SC, Räisänen SE, Wasson D, Lage C, Melgar A, Hristov AN, Pitta DW.
    mBio; 2024 Aug 14; 15(8):e0078224. PubMed ID: 38953639
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  • 30. Application of meta-omics techniques to understand greenhouse gas emissions originating from ruminal metabolism.
    Wallace RJ, Snelling TJ, McCartney CA, Tapio I, Strozzi F.
    Genet Sel Evol; 2017 Jan 16; 49(1):9. PubMed ID: 28093073
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  • 31. The effect of pectin, corn and wheat starch, inulin and pH on in vitro production of methane, short chain fatty acids and on the microbial community composition in rumen fluid.
    Poulsen M, Jensen BB, Engberg RM.
    Anaerobe; 2012 Feb 16; 18(1):83-90. PubMed ID: 22193552
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  • 32. Enhancing Butyrate Production, Ruminal Fermentation and Microbial Population through Supplementation with Clostridium saccharobutylicum.
    Miguel M, Lee SS, Mamuad L, Choi YJ, Jeong CD, Son A, Cho KK, Kim ET, Kim SB, Lee SS.
    J Microbiol Biotechnol; 2019 Jul 28; 29(7):1083-1095. PubMed ID: 31216841
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  • 33. Rumen protozoa and methanogenesis: not a simple cause-effect relationship.
    Morgavi DP, Martin C, Jouany JP, Ranilla MJ.
    Br J Nutr; 2012 Feb 28; 107(3):388-97. PubMed ID: 21762544
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  • 34. Dynamic changes in rumen fermentation and bacterial community following rumen fluid transplantation in a sheep model of rumen acidosis: implications for rumen health in ruminants.
    Liu J, Li H, Zhu W, Mao S.
    FASEB J; 2019 Jul 28; 33(7):8453-8467. PubMed ID: 30973755
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  • 35. Lower methane emissions were associated with higher abundance of ruminal Prevotella in a cohort of Colombian buffalos.
    Aguilar-Marin SB, Betancur-Murillo CL, Isaza GA, Mesa H, Jovel J.
    BMC Microbiol; 2020 Nov 27; 20(1):364. PubMed ID: 33246412
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  • 36. A restriction enzyme reduced representation sequencing approach for low-cost, high-throughput metagenome profiling.
    Hess MK, Rowe SJ, Van Stijn TC, Henry HM, Hickey SM, Brauning R, McCulloch AF, Hess AS, Kirk MR, Kumar S, Pinares-Patiño C, Kittelmann S, Wood GR, Janssen PH, McEwan JC.
    PLoS One; 2020 Nov 27; 15(4):e0219882. PubMed ID: 32243481
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  • 37. Distinct microbial hydrogen and reductant disposal pathways explain interbreed variations in ruminant methane yield.
    Li Q, Ma Z, Huo J, Zhang X, Wang R, Zhang S, Jiao J, Dong X, Janssen PH, Ungerfeld EM, Greening C, Tan Z, Wang M.
    ISME J; 2024 Jan 08; 18(1):. PubMed ID: 38365243
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  • 38. Differences in the Composition of the Rumen Microbiota of Finishing Beef Cattle Divergently Ranked for Residual Methane Emissions.
    Smith PE, Kelly AK, Kenny DA, Waters SM.
    Front Microbiol; 2022 Jan 08; 13():855565. PubMed ID: 35572638
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  • 39. Animal, feed and rumen fermentation attributes associated with methane emissions from sheep fed brassica crops.
    He Y, Sun X, You P.
    J Anim Physiol Anim Nutr (Berl); 2021 Mar 08; 105(2):210-218. PubMed ID: 33025597
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  • 40. Effect of different forage-to-concentrate ratios on ruminal bacterial structure and real-time methane production in sheep.
    Li R, Teng Z, Lang C, Zhou H, Zhong W, Ban Z, Yan X, Yang H, Farouk MH, Lou Y.
    PLoS One; 2019 Mar 08; 14(5):e0214777. PubMed ID: 31116757
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