Forage fermentation patterns and their implications for herbivore ingesta retention times

Hummel, Jürgen; Südekum, Karl‐Heinz; Streich, W. Jürgen; Clauß, Marcus

doi:10.1111/j.1365-2435.2006.01206.x

Cited by 122 publications

(138 citation statements)

References 114 publications

(131 reference statements)

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“…Although it is generally accepted that the fermentation rate of browse is faster than it is of grass (du Toit and Yetman 2005; Hummel et al, 2006) because of the differences in insoluble fibre content, the rate of VFA production from DM in giraffes is similar to that of other wild ruminants including grazers Gordon and Illius, 1994). Reduction in particle size by rumination in giraffes to increase digestibility occupies a relatively short part of their day: they allocate a disproportionate time to feeding compared to rumination (du Toit and Yetman 2005), which implies that the size of the particles that enter the rumen stimulate the rumination reflex relatively infrequently.…”

Section: Discussionmentioning

confidence: 99%

The digestive morphophysiology of wild, free-living, giraffes

Mitchell

Roberts

Sittert

2015

Comparative Biochemistry and Physiology Part A: Molecular &

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We have measured rumen-complex (rumen, reticulum, omasum, abomasum) and intestine (small and large combined) mass in 32 wild giraffes of both sexes with body masses ranging from 289 -1441kg, and parotid gland mass, tongue length and mass, masseter and mandible mass in 9 other giraffes ranging in body mass from 181 to 1396kg. We have estimated metabolic and energy production rates, feed intake and home range size. Interspecific analysis of mature ruminants show that components of the digestive system increase linearly (Mb 1 ) or positively allometric (Mb >1 ) with body mass while variables associated with feed intake scale with metabolic rate (Mb .75 ). Conversely, in giraffes ontogenetic increases in rumen-complex mass were negatively allometric (Mb <1 ), and increases in intestine mass, parotid gland mass, masseter mass, and mandible mass were isometric (Mb 1 ). The relative masseter muscle mass (0.14% of Mb) and the relative parotid mass (0.03% of Mb) are smaller than in other ruminants. Increases in tongue length scale with head length 0.72 and Mb .32 and tongue mass with Mb .69 . Absolute mass of the gastrointestinal tract increased throughout growth but its relative mass declined from 20% to 15% of Mb. Rumen-complex fermentation provides ca43% of daily energy needs, large intestine fermentation 24% and 33% by digestion of soluble carbohydrates, proteins, and lipids. Dry matter intake (kg) was 2.4 % of body mass in juveniles and 1.6% in adults.Energy requirements increased from 35Mj/day to 190 Mj/day. Browse production rate sustains a core home range of 2.2-11.8 km 2 .

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Section: Discussionmentioning

confidence: 99%

The digestive morphophysiology of wild, free-living, giraffes

Mitchell

Roberts

Sittert

2015

Comparative Biochemistry and Physiology Part A: Molecular &

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“…Grass should yield more energy from fermentation per unit forage (Codron et al 2007a), which explains why both in vivo and in vitro overall digestibility (generally measured as digestibility after fermentation times >24 h) are often found to be higher in grass than in woody browse (Wofford and Holechek 1982;Wilman and Riley 1993;Van Wieren 1996b;Hummel et al 2006). However, the evidence is equivocal, as some other references give higher digestibilities for woody browse than for grass (Short et al 1974;Blair et al 1977;Holechek et al 2004).…”

Section: Digestion/fermentation Characteristicsmentioning

confidence: 99%

“…Grass contains more fibre, and a greater proportion of this fibre is cellulose, while browse has less total but more lignified fibre (Short et al 1974;Oldemeyer et al 1977;Owen-Smith 1982;McDowell et al 1983; Cork and Foley 1991;Robbins 1993; Van Wieren 1996b;Iason and Van Wieren 1999;Holechek et al 2004;Hummel et al 2006; Codron et al 2007a). These differences are more pronounced if C4 grasses are compared to browse (Caswell et al 1973).…”

Section: Grass and Browsementioning

confidence: 99%

The Morphophysiological Adaptations of Browsing and Grazing Mammals

2008

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(2008). The morphophysiological adaptations of browsing and grazing mammals. In: Gordon, I J [et al.]. The ecology of browsing and grazing. Berlin, 47-88. Postprint available at: http://www.zora.uzh.ch Posted at the Zurich Open Repository and Archive, University of Zurich. http://www.zora.uzh.ch Originally published at: Gordon, I J [et al.] 2008. The ecology of browsing and grazing. Berlin, 47-88. The morphophysiological adaptations of browsing and grazing mammals AbstractThere has been a continous debate whether there are fundametal morphophysiological differences in the ingestive apparatus (head, teeth) and the digestive tract between browsing and grazing herbivores. A particular characteristic of this debate appears to be that while there is a wealth of publications on such potential differences, the supposed undelying differences between browse and grass have rarely been analysed quantitatively. In this chapter, we first review the actual state of knowledge on those properties of browse and grass that appear relevant for the ingestive and digestive process, and then deduct hypotheses as to how one would assume that browsers and grazers differ due to these characteristics. We address the methodological issues involved in actually testing these hypotheses, with emphasis on the influence of body mass and phylogenetic descent. Finally, we present a literature compilation of statistical tests of differences between the feeding-types. Although in general, the published tests support many hypothesized differences, there is still both a lack of comparative data, and a lack of analyses with phylogenetic control, on different taxonomic levels. However, the published material appears to indicate that convergent evolutionary adaptations of browsing and grazing herbivores to their diet represent a rewarding area of research. The Morphophysiological Adaptations of Browsing and Grazing MammalsMarcus Clauss, Thomas Kaiser, and Jürgen Hummel IntroductionAnimals represent adaptations to particular ecological niches they occupy or once occupied.Studying the correlation between a given set of characteristics of an ecological niche and the morphological and physiological adaptations of organisms to these characteristics is one of the most basic approaches to comparative biology, and has fuelled scientific interest for generations (Gould 2002). However, current scientific standards cannot be met by mere descriptions of both the characteristics of the niche and the organism, and a (hypothetical) intuitive explanation for the adaptive relevance of the latter; the presence or absence of a characteristic must be demonstrated in sound statistical terms (Hagen 2003) 1 ideally supported by experimental data (from in vivo, in vitro, or model assays) on its adaptive relevance.In this chapter, we adopt an approach that first presents the relevant characteristics of the ecological niche of the 'grazer' (GR) and of the 'browser' (BR), outlines hypotheses based on these characteristics, and finally addresses examples where such hypotheses h...

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“…Various authors suggested that the method of microhistological analyses of faeces has limitations to determine ungulate diet compositions, as differential digestion may result in differences between what is ingested and what is excreted (Leslie et al 1983;Mukhtar and Hansen 1983;Barker 1986). Shorter ingesta retention times and slow plant fermentation rates such as for grasses (Clauss et al 2005;Hummel et al 2006) might create a bias in the estimation of the diet composition. No correction for digestibility, however, was necessary as plant cuticle, which is used in this study for plant identification, is indigestible in any animal's guts (Stace 1965).…”

Section: Diet Composition: Backtracking and Faecal Analysismentioning

confidence: 99%

A comparison of faecal analysis with backtracking to determine the diet composition and species preference of the black rhinoceros (Diceros bicornis minor)

et al. 2009

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The diet of black rhinoceros (Diceros bicornis minor) was studied using backtracking and faecal analysis in South Africa. Both methods yielded different results, with a large bias for dominant species. Results of backtracking showed that the rhinos browsed on 80 plant species. Grasses comprised 4.5% of the diet in the faecal analysis, but were not recorded during the backtracking. The backtracking method, along with a measure of forage availability, was used to identify two groups of plant species, those species taken in a higher proportion than available in the field and those taken in a lower proportion. Chemical analyses showed that these two species groups were similar in in vitro digestibility, macro-elements and fibre constituents. Mean bite size and species contribution to the diet were not correlated with any of the forage quality parameters, indicating that rhinos were not maximising nutrient intake or minimising fibre intake of these consumed plant species.

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Forage fermentation patterns and their implications for herbivore ingesta retention times

Cited by 122 publications

References 114 publications

The digestive morphophysiology of wild, free-living, giraffes

The digestive morphophysiology of wild, free-living, giraffes

The Morphophysiological Adaptations of Browsing and Grazing Mammals

A comparison of faecal analysis with backtracking to determine the diet composition and species preference of the black rhinoceros (Diceros bicornis minor)

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