Short communication: Comparison of pH, volatile fatty acids, and microbiome of rumen samples from preweaned calves obtained via cannula or stomach tube

Terré, M.; Castells, L.; Fàbregas, F.; Bach, À.

doi:10.3168/jds.2012-5921

Cited by 38 publications

(35 citation statements)

References 14 publications

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“…Overall, we found that there was no impact of different sampling techniques and sampling sites on the composition of the rumen microbiome in the collected samples based on next-generation sequencing. This observation is similar to previous studies on rumen microbiomes in calves, sheep, goats, and beef cattle using the traditional PCR-DGGE method [3][4][5] and a recent study on rumen microbiomes in Holstein and Jersey cattle using next-generation sequencing [6]. Therefore, the stomach tube can be a feasible alternative method to collect representative samples of the rumen digesta from Hanwoo steers, which will contribute to investigating the composition of the rumen microbiome by increasing the number of animals that can be sampled.…”

Section: Figsupporting

confidence: 91%

“…Several studies have shown that the stomach tube is a feasible alternative to rumen cannulation in sheep, goats, calves, and cattle based on comparison of the composition of rumen microbiomes using the traditional polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) method [3][4][5]. In addition, Paz et al [6] showed that the rumen microbiome was similar between stomach…”

Section: Introductionmentioning

confidence: 99%

“…Keywords: 16S rRNA gene amplicon sequencing, fermentation parameters, rumen microbiome, stomach tube, cannulation S S tube and cannulization samples in Holstein and Jersey cattle using next-generation sequencing. Moreover, some studies showed similar rumen fermentation parameters such as pH, volatile fatty acids (VFA), and ammonia between the two sampling techniques [3][4][5]7], whereas others demonstrated differences [8,9]. Paz et al [6] indicated that discarding the first 200 ml of the rumen fluid could help to minimize saliva contamination that can influence the fermentation parameters.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Effects of Sampling Techniques and Sites on Rumen Microbiome and Fermentation Parameters in Hanwoo Steers

Song¹,

Choi²,

Jeong³

et al. 2018

Journal of Microbiology and Biotechnology

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Section: Figsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Effects of Sampling Techniques and Sites on Rumen Microbiome and Fermentation Parameters in Hanwoo Steers

Song¹,

Choi²,

Jeong³

et al. 2018

Journal of Microbiology and Biotechnology

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“…Access to surgically-modified animals is not universal, and therefore less invasive techniques, such as oral stomach probing, have been used as an alternative. In the relatively few studies that have compared sampling through the rumen cannula or by stomach probing, differences in fermentation profile and microbiota have been reported in some (e.g., Geishauser and Gitzel, 1996;Duffield et al, 2004) but not all cases (e.g., Lodge-Ivey et al, 2009;Shen et al, 2012;Terré et al, 2013). Part of the discrepancy between studies may reflect differences in the procedures used to avoid salivary dilution and contamination, the type of samples collected and rumen sampling site.…”

Section: Sampling Proceduresmentioning

confidence: 77%

Design, implementation and interpretation of in vitro batch culture experiments to assess enteric methane mitigation in ruminants—a review

Yáñez-Ruíz

Bannink

Dijkstra

et al. 2016

Animal Feed Science and Technology

136

120

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a b s t r a c tIn vitro fermentation techniques (IVFT) have been widely used to evaluate the nutritive value of feeds for ruminants and in the last decade to assess the effect of different nutritional strategies on methane (CH4) production. However, many technical factors may influence the results obtained. The present review has been prepared by the 'Global Network' FACCE-JPI international research consortium to provide a critical evaluation of the main factors that need to be considered when designing, conducting and interpreting IVFT experiments that investigate nutritional strategies to mitigate CH 4 emission from ruminants. Given the increasing and wide-scale use of IVFT, there is a need to critically review reports in the literature and establish what criteria are essential to the establishment and implementation of in vitro techniques. Key aspects considered include: i) donor animal species and number of animal used, ii) diet fed to donor animals, iii) collection and processing of rumen fluid as inoculum, iv) choice of substrate and incubation buffer, v) incubation procedures and CH 4 measurements, vi) headspace gas composition and vii) comparability of in vitro and in vivo measurements. Based on an evaluation of experimental evidence, a set of technical recommendations are presented to harmonize IVFT for feed evaluation, assessment of rumen function and CH 4 production.

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“…These symbionts are capable of fermenting host-indigestible feed into nutrient sources usable by the host, such as volatile fatty acids (1,2). Ruminants are born without a functional rumen and are thought to acquire their digestive microbes from the environment as the rumen develops (3)(4)(5)(6). Although the means by which ruminants acquire this ruminal microbial community remains unclear, the membership and stability of the ruminal community can have a direct and measurable impact on host function and health (7).…”

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confidence: 99%

Ruminal Bacterial Community Composition in Dairy Cows Is Dynamic over the Course of Two Lactations and Correlates with Feed Efficiency

Jewell

McCormick

Odt

et al. 2015

Appl Environ Microbiol

237

223

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bFourteen Holstein cows of similar ages were monitored through their first two lactation cycles, during which ruminal solids and liquids, milk samples, production data, and feed consumption data were collected for each cow during early (76 to 82 days in milk [DIM]), middle (151 to 157 DIM), and late (251 to 257 DIM) lactation periods. The bacterial community of each ruminal sample was determined by sequencing the region from V6 to V8 of the 16S rRNA gene using 454 pyrosequencing. Gross feed efficiency (GFE) for each cow was calculated by dividing her energy-corrected milk by dry matter intake (ECM/DMI) for each period of both lactation cycles. Four pairs of cows were identified that differed in milk production efficiency, as defined by residual feed intake (RFI), at the same level of ECM production. The most abundant phyla detected for all cows were Bacteroidetes (49.42%), Firmicutes (39.32%), Proteobacteria (5.67%), and Tenericutes (2.17%), and the most abundant genera included Prevotella (40.15%), Butyrivibrio (2.38%), Ruminococcus (2.35%), Coprococcus (2.29%), and Succiniclasticum (2.28%). The bacterial microbiota between the first and second lactation cycles were highly similar, but with a significant correlation between total community composition by ruminal phase and specific bacteria whose relative sequence abundances displayed significant positive or negative correlation with GFE or RFI. These data suggest that the ruminal bacterial community is dynamic in terms of membership and diversity and that specific members are associated with high and low milk production efficiency over two lactation cycles.R uminants, such as cattle, rely upon a rich and diverse community of symbiotic ruminal microbes to digest their feed. These symbionts are capable of fermenting host-indigestible feed into nutrient sources usable by the host, such as volatile fatty acids (1, 2). Ruminants are born without a functional rumen and are thought to acquire their digestive microbes from the environment as the rumen develops (3-6). Although the means by which ruminants acquire this ruminal microbial community remains unclear, the membership and stability of the ruminal community can have a direct and measurable impact on host function and health (7). Importantly, the host requires ruminal fermentation products for body maintenance and growth (8) and milk production (9).Of particular interest, both scientifically and agriculturally, is the impact of the ruminal microbial community on host milk production efficiency in dairy cattle. Two major methods are widely used to calculate milk production efficiency: gross feed efficiency (GFE) and residual feed intake (RFI). GFE is a more traditional measure that is based on the yield of milk produced (corrected to a constant-energy basis) per unit of intake of dietary dry matter (DM) (10). RFI was first applied to weight gain in steers but has more recently been adapted for use in dairy production (11); it is defined as the difference in feed consumption relative to that of other animals on the...

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Short communication: Comparison of pH, volatile fatty acids, and microbiome of rumen samples from preweaned calves obtained via cannula or stomach tube

Cited by 38 publications

References 14 publications

Effects of Sampling Techniques and Sites on Rumen Microbiome and Fermentation Parameters in Hanwoo Steers

Effects of Sampling Techniques and Sites on Rumen Microbiome and Fermentation Parameters in Hanwoo Steers

Design, implementation and interpretation of in vitro batch culture experiments to assess enteric methane mitigation in ruminants—a review

Ruminal Bacterial Community Composition in Dairy Cows Is Dynamic over the Course of Two Lactations and Correlates with Feed Efficiency

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