The properties of dietary fibres may affect cats’ health, digestive processes and faecal characteristics( Reference Fahey, Flickinger, Grieshop, Van der Kamp, Asp, Miller Jones and Schaafsma 1 ). It is therefore important to consider the properties of dietary fibres including their potential fermentability by the intestinal microbiota. To characterise the fermentability of fibres, in vitro methods simulating intestinal fermentation have been developed. In vitro batch culture systems are commonly applied in which the fibrous substrate of interest is incubated with a faecal inoculum from the target animal species. There are, however, methodological aspects that can have an impact on the quality of the results obtained and these are not well described in the literature. For example, the number of faecal donors has been advised to be at least five to control for the effect of inter-individual variation( Reference Edwards, Gibson and Champ 2 ). Most studies have used three faecal donors( Reference Coles, Moughan and Darragh 3 ). However, some only used one( Reference Murray, McMullin and Handel 4 ). Furthermore, few studies focused on the repeatability and reproducibility of the method, which has been described for our laboratory in a companion article( Reference Bosch, Heesen and de Melo Santos 5 ). To gain knowledge on the precision of an in vitro method for characterisation of the fermentability of dietary fibres, this study aimed to evaluate the inter-individual variability in fermentation of five standard fibrous substrates by faecal inocula from ten cats.
Experimental methods
Substrates
Selected dietary fibres or fibre sources are used in dry and wet cat foods and contrast in chemical composition and anticipated fermentation characteristics, as shown in previous in vitro studies( Reference Flickinger and Fahey 6 – Reference Barry, Wojcicki and Bauer 8 ). Substrates included citrus pectin (CP; rapidly and highly fermentable, HM Rapid, TIC Gums), fructo-oligosaccharide (FOS; rapidly and highly fermentable; Orafti® IPS, BENEO-Orafti), guar gum (GG; rapidly and highly fermentable, 8/22, TIC Gums), molassed sugar beet pulp (SBP; slowly and highly fermentable; Research Diet Services) and wheat middlings (WM; slowly and moderately fermentable; Research Diet Services).
Animals, housing and care
A total of nine intact and one neutered female European shorthair cats (3 to 5 years old) with a mean body weight of 3·3 (sd 0·6) kg were used. Cats did not receive any antibiotics for at least 6 months prior to faecal collection. The cats were housed in two groups in rooms with an outside area and individually in a metabolic cage during parts of the day (12.00–13.30 and 16.30–09.30 hours). Details of the group rooms and metabolic cages as well the climate and light schedules have been provided by Van Rooijen et al. ( Reference Van Rooijen, Bosch and Butré 9 ). Litter trays were present in the cage and contained non-absorbent polyethylene litter (Katkor®; Rein Vet Products). On the day of faeces collection the litter and the tray were sterilised with 70 % ethanol. Cats were fed a nutritionally complete (i.e. meeting the FEDIAF standards) commercial dry extruded diet (Perfect Fit In-Home; Mars Petcare) for at least 4 weeks prior to faeces collection. Cats were adapted in 2 weeks to a daily regimen of feeding between 08.30 and 09.30 hours (about 45 % of their daily portion), 12.00 and 13.30 hours (about 10 %) and at 16.30 hours (about 45 %) in their cage and provided food to maintain optimal body weight. In the morning and afternoon, cats went to their group room. Water was available ad libitum during group housing and in the metabolic cages. The health status of the animals was monitored daily and cats were weighed weekly. Animal care and experimental procedures were approved by the Animal Care and Use Committee of Wageningen University, Wageningen, the Netherlands.
Preparation of inoculum and incubation
Within 15 min of defecation, faeces were transferred to sterile 250 ml plastic bottles prefilled with CO2 and 250 ml of CO2 was immediately added to the bottle to ensure anaerobic storage conditions. The bottle with faeces was closed and transported within 5 min to the analytical laboratory. Faeces from cats were not pooled but processed for each cat. All handling procedures and processing of faeces to the inoculum were carried out under a constant stream of CO2. All attached litter particles were manually removed from faeces and faeces were weighed and diluted 1:9 (w/v) in a 39°C anaerobic sterile physiological saline solution (9 g/l NaCl). The diluted mixture was homogenised for 60 s using a hand-blender and filtered through nylon fabric (pore size 40 µm, permeability 30 %; PA 40/30, Nybolt). The filtrate was mixed with a pre-warmed (39°C) N-containing medium( Reference Williams, Bosch and Boer 10 ) in a 5:84 mixture (v/v) and gently flushed for 5 min with CO2. The resulting medium/inoculum mixture was dispensed (89 ml) into pre-warmed and CO2-flushed 250 ml serum bottles (Schott) containing 0·5 g of substrate. Inoculated bottles were then immediately attached to fully automated gas production equipment( Reference Cone, Van Gelder and Visscher 11 ) and gas production was recorded for 48 h. This incubation time is longer than average total tract transit times observed in young adult (36 (sd 14) h) and senior cats (26 (sd 6) h)( Reference Peachey, Dawson and Harper 12 ) with a orocaecal transit time of approximately 5 h( Reference Papasouliotis, Sparkes and Gruffydd-Jones 13 ). However, 48 h was estimated to be required for characterising the fermentation kinetics of SBP and WM. After 48 h of incubation, fermentation liquids were sampled for the determination of SCFA (i.e. acetate, propionate, butyrate, iso-butyrate, valerate, iso-valerate) concentrations and for organic matter disappearance of SBP and WM. All incubations were done in triplicate. The study was performed in two runs, with maximally five inocula per run.
Chemical analyses
All substrates were analysed for DM and ash by drying to a constant weight at 103°C and combusting at 550°C, respectively. The SBP and WM were also analysed for crude protein (6·25 × N)( 14 ), for neutral-detergent fibre (NDF)( Reference Van Soest, Robertson and Lewis 15 , Reference Goelema, Spreeuwenberg and Hof 16 ), and for acid-detergent fibre (ADF) and acid-detergent lignin (ADL)( Reference Van Soest 17 ). SCFA analyses of fermentation liquids as well as organic matter disappearance were analysed as described by Bosch et al. ( Reference Bosch, Pellikaan and Rutten 18 ).
Calculations and data analyses
Cumulative gas production (ml) and SCFA production (mmol) were expressed per g organic matter. Monophasic models as described by Groot et al. ( Reference Groot, Cone and Williams 19 ) were fitted to the data for cumulative gas production and the maximum rate of gas production (R max in ml/(g organic matter h)) and the time at which it occurred (T max in h) were calculated( Reference Bauer, Williams and Voigt 20 ). Acetate, propionate and butyrate were expressed as percentage of total SCFA. Similarly, branched-chain proportion was iso-butyrate + iso-valerate on a total SCFA basis. Values of replicates for each substrate–cat combination were averaged and considered as the experimental unit. For each substrate, mean and standard deviation values were calculated and used to compute the CV (sd/mean × 100).
Results and discussion
All cats remained healthy throughout the study. Of the ten cats, nine produced faeces on the days of inoculum preparation and for one cat the SCFA analysis failed. DM and ash contents (as is) were CP 90·0 and 1·7 %, FOS 96·5 and 0·0 %, GG 89·4 and 0·7 %, SBP 89·3 and 6·3 % and WM 88·4 and 7·2 %, respectively. Crude protein, NDF, ADF and ADL contents were, respectively, 9·2, 32·2, 16·6 and 1·0 % for SBP and 15·7, 42·3, 14·0 and 3·9 % for WM. The substrates contrasted in terms of fermentation parameters measured, as anticipated (Fig. 1 and Table 1). Furthermore, the ranking of substrates (i.e. relative accuracy( Reference Coles, Moughan and Darragh 3 )) was consistent among cats (based on Spearman's rank correlations; results not shown).
CP, citrus pectin; FOS, fructo-oligosaccharide; GG, guar gum; SBP, molassed sugar beet pulp; WM, wheat middlings; BCP, branched-chain proportion; R max, maximum rate of gas production; OM, organic matter; T max, time at which R max occurred; OMD, organic matter disappearance.
* n 8.
Total SCFA production from CP, FOS, GG and SBP was similar and greater than the production from WM. Inter-individual CV of total SCFA was larger for SBP and WM than for CP, FOS and GG (Fig. 1(a)). Few other studies focused on inter-individual variation in in vitro fermentation of fibrous substrates using faecal inocula. The CV for in vitro total SCFA production after 24 h of incubation with faecal inocula from healthy human volunteers ranged from 9 % for GG to 15 % for wheat bran (n 6 individuals)( Reference McBurney and Thompson 21 ) and was 11 % for soyabean fibre (n 4)( Reference Barry, Hoebler and Macfarlane 22 ). In a large study with eight laboratories and number of faecal inocula from healthy human volunteers ranging from 4 to 7, inter-individual CV of total SCFA production after 24 h of incubation was larger for potato starch being pregelatinised (median 18, range 6–29 %), raw (22, 13–44 %) and retrograded (23, 15–55 %) and for glassy pea starch (22, 18–39 %)( Reference Edwards, Gibson and Champ 2 ). The SCFA composition differed between substrates with the greatest acetate and propionate proportions for CP and GG, respectively. The CV of the proportion of acetate was smaller than for propionate and butyrate (Fig. 1(b)), which was also found for soyabean fibre fermented by human faecal inocula( Reference Barry, Hoebler and Macfarlane 22 ), i.e. respectively 8, 16 and 45 %. The variation in absolute values was in particular small for butyrate in the present study. Inter-individual CV of gas production was like that for total SCFA: larger for SBP and WM than for CP, FOS and GG (Fig. 1(c)). McBurney & Thompson( Reference McBurney and Thompson 21 ) reported larger CV for gas production ranging from 9 % for kidney beans to 23 % for GG. Incubation with WM resulted in the largest branched-chain proportion (Table 1), which relates to the relatively high protein content, and was also observed in an in vitro study with faecal inocula from dogs( Reference Bosch, Wrigglesworth and Cone 23 ). The inter-individual variation in branched-chain proportion was in particular large for SBP and WM. Fitting of the model for gas production was not possible for SBP and WM. The R max and T max were similar for CP and FOS. For GG, R max was lower than for CP and FOS and inter-individual variation in R max and T max was in particular large for GG. Finally, WM had a lower organic matter disappearance than SBP after 48 h of incubation, but both substrates showed similar inter-individual variability.
The observed fibre source-dependent inter-individual variation in various fermentation parameters probably relates to differences in specific microbial taxa observed in cat faeces( Reference Ritchie, Burke and Garcia-Mazcorro 24 ). In healthy humans, variation in microbial taxa was also noted but the functionality of the microbiome (i.e. metabolic pathways) remained fairly stable among individuals( Reference Huttenhower, Gevers and Knight 25 ). Degradation of more complex and mixtures of non-digestible carbohydrates would require a larger array of microbial enzymes than that required for the degradation of relatively simple and pure carbohydrates. Differences in faecal microbial composition and its functional capacities among individual cats may therefore become more pronounced with the more complex fibrous substrates (SBP and WM) relative to the more simple and pure ones (CP, FOS and GG). The variability associated with the complexity of fibrous substrates presented in this study is instrumental for the calculation of the number of faecal donors required for precise in vitro characterisation of the fermentability of dietary fibres. In addition, the number of faecal donors should be adjusted to the specific fermentation parameters of interest.
Acknowledgements
We would like to thank D. Nijkamp-Van de Pol and S. Van Laar-Schuppen for assistance during the execution of the in vitro procedures and M. Breuer for SCFA analyses. This research was funded by Wageningen University.
G. B. contributed to all aspects of this research including research design, data collection, calculations and manuscript drafting. J. W. C., W. F. P. and W. H. H. contributed to research design, data interpretation and manuscript preparation and L. H. and K. M. S. to data collection, calculations, data interpretation and manuscript preparation.
There were no conflicts of interest.