Stomach

Microbiota in the stomach contents of suckling kittens and adult cats were studied by Osbaldiston & Stowe⁽ Reference Osbaldiston and Stowe ^{22 )}. The samples were collected after euthanasia, laparotomy and incision of the stomach wall, and culture-plating techniques were used⁽ Reference Osbaldiston and Stowe ^{22 )}. In this part of the gastrointestinal tract, the microbiota mainly constituted of enterococci (log₁₀ 5·64 (sd 0·97)). Likewise, all kittens and six out of nine adult cats showed similar counts of lactobacilli (log₁₀ 5·55 (sd 0·67)). Comparable counts of five other genera of anaerobic micro-organisms were isolated from the stomach contents of some cats (Streptococcus spp., Staphylococcus spp., Proteus spp., Bacillus spp., Pasteurella spp., Mima spp., Escherichia spp., Clostridium spp., Catenabacterium spp., Eubacterium spp., Bacteroides spp. and Veillonella spp.). No effects of diet were observed between adult cats on a standard feline diet (Hill's Prescription Diet Feline c/d; Hill's Pet Nutrition Inc.) and adult cats on a chemically defined, liquid elemental diet (amino acids, carbohydrates, fats, vitamins and minerals), both fed for 6 weeks⁽ Reference Osbaldiston and Stowe ^{22 )}. In humans, the microbiota of individuals on elemental diets decrease both in number and diversity, due to a lack of continuous supply of nutrients to the large intestine, since these diets are highly digestible⁽ Reference Winitz, Adams and Sudman ^{23 )}. In cats, the reason for the lack of diet effect was postulated to be the different passage rates through the gastrointestinal tract compared with humans.

The elemental diet thus provided a sufficient and continuous supply of nutrients necessary for bacterial survival and replication throughout the whole feline gastrointestinal tract on both diets⁽ Reference Osbaldiston and Stowe ^{22 )}. No information on the number of meals was available in the above-mentioned study. However, this factor could influence the study outcome significantly. No raw meat or ‘natural’ diets were fed to the cats in this study.

Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: viscous fibres

Sunvold et al. performed in vivo investigations following in vitro fermentation trials⁽ Reference Sunvold, Fahey and Merchen ^{3 ,} Reference Sunvold, Fahey and Merchen ^{4 )}. These authors concluded that the in vitro method appeared to be a good estimator of in vivo fermentation with the exception of the most fermentable fibres (pectin and gums with high viscosity). However, the in vivo fermentation calculation, based on the comparison of organic matter in food and faeces, was lower than could be predicted in vitro because of a decrease in digestibility of the other nutrients in the diet⁽ Reference Sunvold, Fahey and Merchen ^{4 )}.

Besides difficulties of extrapolating in vitro data, another disadvantage of supplementing viscous fibres in vivo was an increased defecation frequency and a poor stool quality with a supplementation level of 9·5 % total dietary fibre⁽ Reference Sunvold, Fahey and Merchen ^{3 )}. Loose stools with a strong odour were also confirmed by Bueno et al. ⁽ Reference Bueno, Cappel and Sunvold ^{11 ,} Reference Bueno, Cappel and Sunvold ^{12 )} when a pectin–gum arabic blend was included in the diets (total dietary fibre 8·6 %). It has to be noted that the doses used in the above-mentioned experiments are very high. Barry et al. ⁽ Reference Barry, Wojcicki and Middelbos ^{51 )} supplemented a lower dose of pectin (4 % as fed) to domestic cats and observed softer faeces as compared with the control group, cellulose. The decrease was, however, small and the authors concluded that pectin, like FOS, might be a useful fibre source for the promotion of feline gastrointestinal health⁽ Reference Barry, Wojcicki and Middelbos ^{51 )}. Sunvold et al. ⁽ Reference Sunvold, Fahey and Merchen ^{3 )}, on the contrary, advised the use of a moderately fermentable fibre source, such as beet pulp, in feline diets (see the ‘Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: moderate (beet pulp) and less fermentable fibre sources’ section). In a recent feline study, another viscous fibre source, guar gum, was used as the sole source of fermentable soluble fibre, supplemented to a moderate-protein diet⁽ Reference Rochus, Janssens and Van de Velde ^{59 )}. The apparent protein digestibility coefficient tended to be lower in guar gum- (71·8 (sem 3·6) %) than in cellulose (79·7 (sem 1·0) %)-supplemented cats, and the faecal and plasma metabolites from protein fermentation (for example, faecal ammonia in mg/l: 390 for guar gum v. 227 for cellulose; plasma isovaleryl- +2-methylbutyrylcarnitine in μmol/l: 0·32 (sem 0·06) for guar gum v. 0·21 (sem 0·05) for cellulose) were higher in the former cats, which confirmed highly viscous fibres to be less suitable soluble fibre sources for in vivo use in domestic cats⁽ Reference Rochus, Janssens and Van de Velde ^{59 )}.

Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: fructans, mannanoligosaccharides, galacto-oligosaccharides and lactosucrose

Studies on the effect of fructans (FOS, oligofructose, inulin), mannano-oligosaccharides (MOS) and GOS on faecal characteristics (consistency score and pH) are shown in Table 5 ⁽ Reference Terada, Hara and Kato ^{50 –} Reference Biagi, Cipollini and Bonaldo ^{53 ,} Reference Hesta, Janssens and Debraekeleer ^{60 –} Reference Aquino, Saad and Santos ^{62 )}. Differences in results might be explained by differences in the levels of supplementation among studies: for example, up to 9·0 % as fed oligofructose in Hesta et al. ⁽ Reference Hesta, Janssens and Debraekeleer ^{60 )}; maximum 0·6 % DM MOS in Aquino et al. ⁽ Reference Aquino, Saad and Santos ^{62 )}; 1 % synbiotic in Biagi et al. ⁽ Reference Biagi, Cipollini and Bonaldo ^{53 )}.

Table 5 Overview of the effects of dietary fructans, mannanoligosaccharides (MOS), galacto-oligosaccharides (GOS) and lactosucrose on faecal characteristics in cats

OF, oligofructose; FOS, fructo-oligosaccharides; ↑ , increase; sc, short-chain.

* Consistency score: 1 represented watery diarrhoea; 3, normal consistency; and 5, constipation⁽⁶⁰⁾.

† Consistency score: 1 represented dry, hard pellets; 2, hard, dry, formed stool; 3, soft, formed, moist stool; 4, soft, unformed stool that assumes form of container; 5, watery liquid that can poured⁽ Reference Barry, Wojcicki and Middelbos ^{51 )}.

Decreased faecal consistency (looser stools) can have implications for the host animal, for the use of fibres in the pet food industry and for the appreciation of the foods by pet owners. On the contrary, the effects on stool consistency can be advantageous in the treatment of cats with constipation⁽ Reference Freiche, Houston and Weese ^{8 )}. A decrease in faecal pH is caused by an increased production of bacterial endproducts, such as lactic acid and SCFA, in the hindgut. This decrease can exert several effects both on the microbiota and the host animal, such as stimulation of the growth of beneficial bacteria like Lactobacillus spp.⁽ Reference Bergman ^{63 )} or an increased mineral absorption from the hindgut⁽ Reference Raschka and Daniel ^{64 ,} Reference Xiao, Li and Min ^{65 )}. Likewise, the absorption of ammonia from the hindgut can be reduced by decreasing pH. Lactic acid molecules produced can be converted to weaker acids, such as acetic, propionic and butyric acids, by cross-feeding bacteria⁽ Reference Duncan, Louis and Flint ^{66 )}, which prevents a severe decrease in pH and the development of lactic acidosis. The latter disease condition can be observed in cats with gastrointestinal disease⁽ Reference Packer, Moore and Chang ^{67 )}.

The above-mentioned SCFA have been associated with different beneficial effects on the hosts' general health⁽ Reference Salminen, Bouley and Boutron-Ruault ^{68 )} and the function of the gastrointestinal tract⁽ Reference Bueno, Cappel and Sunvold ^{11 ,} Reference Bueno, Cappel and Sunvold ^{12 )}. Besides faecal characteristics, the in vivo studies listed in Table 5 also investigated the effects of various oligosaccharides on nutrient digestibility. In the study of Hesta et al. ⁽ Reference Hesta, Janssens and Debraekeleer ^{60 )}, the apparent digestibility of protein decreased significantly as the level of fructan inclusion increased (from 87·0 % with 0 % inulin to 82·8 and 77·3 % with 3 and 6 % inulin inclusion, respectively; 83·1 % with 3 % oligofructose inclusion in the diet), which was confirmed with the supplementation of sc-FOS + GOS to feline diets⁽ Reference Kanakupt, Vester Boler and Dunsford ^{52 )} (from 84·2 % in control to 81·9 % in sc-FOS + GOS). The latter decrease⁽ Reference Kanakupt, Vester Boler and Dunsford ^{52 )} was lower than compared with the study of Hesta et al. ⁽ Reference Hesta, Janssens and Debraekeleer ^{60 )}, most probably caused by the lower inclusion levels of the fibres. The decreased protein digestibility was probably due to a higher faecal excretion of bacterial protein with a higher level of fructan in the diet⁽ Reference Hesta, Janssens and Debraekeleer ^{60 )} (from 25·4 % with 0 % inulin to 31·1 and 35·2 % with 3 and 6 % inulin inclusion, respectively; 32·8 % with 3 % oligofructose inclusion in the diet). Low-level MOS supplementation did not affect nutrient digestibility when supplemented to a wet diet, but slightly improved the DM digestibility if supplemented to a dry commercial diet⁽ Reference Aquino, Saad and Santos ^{62 )} (from 73 (sd 4) % in control to 76 (sd 4) % in a 0·6 % MOS diet). In addition, a beneficial effect on palatability was only seen with MOS supplementation to the dry diet (for example, 11 % increase in DM intake between control and the 0·6 % dry diet)⁽ Reference Aquino, Saad and Santos ^{62 )}. According to these authors, MOS is thus preferably supplemented to dry diets⁽ Reference Aquino, Saad and Santos ^{62 )}.

A decreased ileal protein digestibility might result in an increased large-intestinal protein and amino acid fermentation⁽ Reference Rochus, Janssens and Van de Velde ^{59 ,} Reference Hendriks, van Baal and Bosch ^{69 )}. Besides SCFA, microbial degradation of amino acids can result in putrefactive endproducts, such as branched-chain fatty acids, valeric acid, ammonia (NH₃) and phenolic compounds (for example, indole, p-cresol, phenol)⁽ Reference Mafra, Barros and Fouque ^{70 )}. Some putrefactive endproducts, such as polyamines, appear to be required for normal development and repair of the gastrointestinal tract⁽ Reference Wang and Johnson ^{71 ,} Reference Loser, Eisel and Harms ^{72 )}. However, many of these compounds are suggested to be related to colorectal disease in humans and rats⁽ Reference Corpet, Yin and Zhang ^{73 –} Reference Pedersen, Brynskov and Saermark ^{75 )}. Different sources of dietary fibres have, therefore, been applied in domestic cats in an attempt to reduce the production and excretion of these potentially harmful substances and to attempt the reduction of faecal odour⁽ Reference Terada, Hara and Kato ^{50 –} Reference Biagi, Cipollini and Bonaldo ^{53 ,} Reference Hesta, Hoornaert and Verlinden ^{61 ,} Reference Barry, Hernot and Van Loo ^{76 )}. Faecal concentrations of ammonia (339 (sd 210) μg/g wet faeces before supplementation), indole (48 (sd 19) μg/g wet faeces before supplementation), ethylphenol (20 (sd 6) μg/g wet faeces before supplementation) and urinary ammonia (17 (sd 8) mg/ml urine before supplementation) were reduced significantly on day 14 of lactosucrose administration⁽ Reference Terada, Hara and Kato ^{50 )} (to 162 (sd 34), 30 (sd 12), 8 (sd 3) μg/g wet faeces and 10 (sd 4) mg/ml urine, respectively). This decrease might be explained by the concomitant decrease in counts of Clostridia ( − 0·25 log numbers per g faeces for the average of lecithinase-positive and -negative Clostridia, difference between before and after 14 d of lactosucrose administration) and Enterobacteriaceae ( − 1·6 log numbers per g faeces, difference between before and after 14 d of lactosucrose administration) due to the lactosucrose supplementation, as both groups are known to produce these putrefactive substances. In addition, the environmental ammonia (ammonia in room from 22 (sd 2) parts per million (ppm) before administration to 16 (sd 1) ppm after 14 d of administration) and the faecal odour (no quantitative data available) decreased remarkably during administration⁽ Reference Terada, Hara and Kato ^{50 )}. Likewise, supplementation of oligofructose led to decreased faecal concentrations of histamine, spermidine and indole⁽ Reference Barry, Hernot and Van Loo ^{76 )} (quantitative data not available), and a synbiotic combination of GOS and a Bifidobacterium strain decreased faecal ammonia concentrations (in μmol/g faecal DM) even 10 d post-supplementation⁽ Reference Biagi, Cipollini and Bonaldo ^{53 )} (from 353 before to 288 at 1 d post- administration and 281 at 10 d post-administration). In contrast, Hesta et al. ⁽ Reference Hesta, Hoornaert and Verlinden ^{61 )} found no effects of FOS supplementation to cats on twenty-seven different odour components, and Kanakupt et al. ⁽ Reference Kanakupt, Vester Boler and Dunsford ^{52 )} observed no differences in faecal protein catabolites among control, sc-FOS-, GOS- and sc-FOS + GOS-supplemented cats. In the latter study, no differences in protein catabolite-producing bacteria were observed⁽ Reference Kanakupt, Vester Boler and Dunsford ^{52 )}. Increased faecal concentrations of ammonia (small differences), 4-methyl phenol and indole were observed when feline diets were supplemented with FOS (differences compared with cellulose in mmol or μmol/g of faecal DM: 0·1, 2·1 and 1·0, respectively) and pectin (differences compared with cellulose in mmol or μmol/g of faecal DM: 0·1, 1·9 and 0·7, respectively), possibly due to the fast fermentation of both supplements⁽ Reference Barry, Wojcicki and Middelbos ^{51 )}. Different outcomes in the studies might again be explained by different sources and inclusion levels of fibres.

Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: moderate (beet pulp) and less fermentable fibre sources

The effects of moderately and less-fermentable fibre sources on nutrient intake have been studied by different groups. Fekete et al. ⁽ Reference Fekete, Hullár and Andrásofszky ^{77 )} observed slightly different DM intake among diets supplemented with high levels (10 % DM) of beet pulp (263 (sd 42) g/4 d), peanut hulls (274 (sd 31) g/4 d) and alfalfa meal (257 (sd 37) g/4 d). In contrast, Sunvold et al. ⁽ Reference Sunvold, Fahey and Merchen ^{3 )} did not observe differences in DM, organic matter or N intake between beet pulp- and cellulose-supplemented cats and cats on a control diet without supplemented fibre. Both studies used a similar inclusion level of the dietary fibre sources. Likewise, the inclusion of cellulose at a high level (17 % DM) did not alter food intake in cats⁽ Reference Prola, Dobenecker and Mussa ^{78 ,} Reference Prola, Dobenecker and Kienzle ^{79 )} and the addition of psyllium husks and seeds did not decrease diet acceptance in cats with constipation⁽ Reference Freiche, Houston and Weese ^{8 )}.

In all the above-mentioned studies nutrient digestibility was studied as well. In peanut hull- and alfalfa meal-supplemented cats, a decreased DM digestibility ( − 22·4 and − 7·2 % compared with the control diet) was seen⁽ Reference Fekete, Hullár and Andrásofszky ^{77 )}, which was confirmed in healthy beet pulp-⁽ Reference Sunvold, Fahey and Merchen ^{3 )} and cellulose⁽ Reference Prola, Dobenecker and Mussa ^{78 )}-supplemented cats ( − 7·6 and − 15 % (average of the three types of cellulose used) compared with control). Likewise, another study confirmed a decreased DM digestibility when diets of overweight cats were supplemented with beet pulp ( − 11 % compared with control), wheat bran ( − 13 % compared with control) or sugarcane fibre ( − 21 % compared with control)⁽ Reference Fischer, Kessler and de Sá ^{9 )}. Only peanut hull and alfalfa meal supplementation decreased protein digestibility⁽ Reference Fekete, Hullár and Andrásofszky ^{77 )} ( − 10 and − 2 % compared with control, respectively). Likewise, Fischer et al. ⁽ Reference Fischer, Kessler and de Sá ^{9 )} observed different effects on protein and fat digestibility depending on the chemical composition of the supplemented fibre source. No other studies in which cats were supplemented with peanut hulls, alfalfa meal, wheat bran or sugarcane fibre were found. Conclusively, moderately fermentable fibre sources, such as beet pulp, appear to be beneficial for normal-weight cats. In contrast, low-fermentable fibres, such as sugarcane fibre, might have adequate properties in low-energy weight-loss diets⁽ Reference Fischer, Kessler and de Sá ^{9 )}. However, the high water-binding activity of the latter fibre source, comparable with that of long-fibre cellulose⁽ Reference Prola, Dobenecker and Kienzle ^{79 )}, can lead to extremely dry faeces, limiting the inclusion level in the diet⁽ Reference Fischer, Kessler and de Sá ^{9 )}. This problem might be overcome by using short-fibre or microcrystalline cellulose⁽ Reference Prola, Dobenecker and Kienzle ^{79 )}. An important factor in determining the outcome of the supplementation of fibres is the inclusion level, which was very high in the above-mentioned studies. Therefore, more research using lower levels is warranted.

Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: animal fibre

Differences in nutrient digestibility and fermentation endproducts between a high-protein, extruded feline diet and a raw and cooked beef-based diet, which is a source of animal fibre, were studied by Kerr et al. ⁽ Reference Kerr, Vester Boler and Morris ^{18 )}. The extruded diet had a much higher protein content (57 % crude protein) compared with a conventional extruded feline diet (for adult cats between 32 and 35 % crude protein) to mimic the composition of the beef-based diets. The effect of processing of the diets was investigated. However, due to a different ingredient composition between the extruded and beef-based diets, this comparison was biased. The extruded diet contained, for example, chicken meal as the major protein source. The latter might have contained a considerable amount of animal fibre from cartilage, for example, and might be considerably less digestible than beef meat. Two other studies that investigated the effects of feeding raw-meat diets on nutrient digestibility and faecal characteristics in domestic cats were found⁽ Reference Vester, Beloshapka and Middelbos ^{80 ,} Reference Kerr, Beloshapka and Morris ^{81 )}. Comparisons of results between both studies are again biased by the use of different ingredient sources, such as different sources of plant fibre. Further studies using diets with an equal ingredient composition of all diets are necessary to study the effects of animal fibre fermentation on nutrient digestibility, the host's metabolism and the interaction with plant fibres in domestic cats.

Effects of dietary fibre on colonic morphology and function

The influence of fibre fermentation and concomitant SCFA production on colonic morphology was studied in adult healthy cats by Bueno et al. ⁽ Reference Bueno, Cappel and Sunvold ^{11 ,} Reference Bueno, Cappel and Sunvold ^{12 )}, and in overweight cats by Fischer et al. ⁽ Reference Fischer, Kessler and de Sá ^{9 )}. Beneficial effects on morphology (colonic weight, mucosal cell density, crypt structure), function (mucosal tissue energetics, transport of SCFA, etc.) and microbiota of the colon (less pathogenic bacteria) were observed⁽ Reference Bueno, Cappel and Sunvold ^{11 ,} Reference Bueno, Cappel and Sunvold ^{12 )}. According to these authors, the supplementation of a moderately fermentable fibre source to feline diets generated the best combination of beneficial effects on morphology, function and microbiota. In contrast, in overweight cats, the supplementation of beet pulp, wheat bran or sugarcane fibre did not affect the histological image of the colon biopsies⁽ Reference Fischer, Kessler and de Sá ^{9 )}. Nevertheless, these fibres demonstrated other beneficial properties upon in vivo fermentation, as stated in other parts of the present review.

Effects of dietary fibre on nitrogen and energy metabolism

The principle of the N trap is that blood urea concentrations decrease when fermentable fibre is supplemented to the diet. Fermentable fibre stimulates the growth of and provides energy to the anaerobic micro-organisms in the large intestine⁽ Reference Younes, Garleb and Behr ^{82 )}. For bacterial protein anabolism, not only an energy source, such as fermentable fibre, but also a source of N should be available⁽ Reference Bliss ^{83 )}. N sources include undigested dietary protein entering the large intestine, endogenous protein and blood urea⁽ Reference Younes, Garleb and Behr ^{82 )}. Bacterial protein is not absorbed in the large intestine, but is excreted in the faeces⁽ Reference Rutgers, Biourge, Pibot, Biourge and Elliott ^{7 )}. When blood urea is the major N source to the intestinal microbiota, blood urea concentrations decrease and a decreased N excretion by the kidneys is observed, while N excretion in the faeces increases. Furthermore, fermentable fibre increased caecal blood flow in rats⁽ Reference Younes, Garleb and Behr ^{82 )}, which might enhance the passive diffusion of urea from the blood to the intestine. The N trap hypothesis has been proven in the rat⁽ Reference Younes, Garleb and Behr ^{82 ,} Reference Younes, Rémésy and Behr ^{84 )} and dog⁽ Reference Howard, Kerley and Sunvold ^{85 )}, whereas in the cat tendencies towards an N shift from urine to faeces were found using diets supplemented with oligofructose⁽ Reference Hesta, Hoornaert and Verlinden ^{61 ,} Reference Barry, Hernot and Van Loo ^{76 )}. Verbrugghe et al. ⁽ Reference Verbrugghe, Hesta and Gommeren ^{86 –} Reference Verbrugghe, Hesta and Daminet ^{88 )} studied the effects of oligofructose and inulin on glucose and amino acid metabolism in domestic cats. In the first study⁽ Reference Verbrugghe, Hesta and Gommeren ^{86 )}, a control diet was tested against a prebiotic diet with 2·5 % of a blend of oligofructose and inulin. Diets did not affect fasting plasma glucose and insulin concentrations, blood glucose and insulin responses to glucose administration, or area under the glucose and insulin curves. In contrast, a decreased mean blood glucose concentration and area under the curve were achieved by supplementing sugarcane fibre to diets of overweight cats⁽ Reference Fischer, Kessler and de Sá ^{9 )}. Despite an apparent absence of effects on carbohydrate metabolism in the study of Verbrugghe et al. ⁽ Reference Verbrugghe, Hesta and Gommeren ^{86 )}, analysis of plasma acylcarnitine profiles revealed higher propionylcarnitine concentrations when the prebiotic diet was fed, suggesting colonic fermentation and propionate absorption. Prebiotic supplementation reduced methylmalonylcarnitine and aspartate aminotransferase concentrations, both indicating reduced gluconeogenesis from amino acids⁽ Reference Verbrugghe, Hesta and Gommeren ^{86 )}. Further studies confirmed the amino acid-sparing potential of propionic acid from dietary fructan fermentation⁽ Reference Verbrugghe, Janssens and Meininger ^{87 )} and signs of sparing of the amino acid valine with propionylated high-amylose maize starch supplementation provided that protein intake was sufficient⁽ Reference Rochus, Janssens and Cools ^{89 )}. The quantification of the amino acid-sparing potential of propionic acid in healthy and disease-inflicted cats remains to be done. In contrast, this mechanism was not confirmed with guar gum supplementation, due to its high viscosity⁽ Reference Rochus, Janssens and Van de Velde ^{59 )}. The guar gum's high viscosity impaired the small-intestinal protein digestion, causing a large load of undigested protein being fermented in the large intestine, which biased the proper assessment of the amino acid sparing by the produced propionic acid⁽ Reference Rochus, Janssens and Van de Velde ^{59 )}. Further research using guar gum with lower viscosity might be warranted. The applicability of low-viscous guar gum might be restricted to dry extruded feline diets or homemade diets, since, for the production of canned diets, the gelling properties of highly viscous guar gum are advantageous.

Effects of dietary fibre on diseases with dietary protein restriction as a treatment cornerstone, such as chronic kidney and liver disease

CKD is a very common disease in middle-aged to elderly cats⁽ Reference Ross, Osborne and Kirk ^{90 )}. The cornerstones of the dietary management of CKD are a modification of the quantity (decrease) and quality (increase) of protein and a restriction of the dietary P intake⁽ Reference Polzin, Osborne and Ross ^{91 )}. Liver disease encompasses a range of different aetiologies, such as hepatic lipidosis and portosystemic shunts. The symptomatic treatment of liver disease, specifically in case of hyperammonaemia and hepatic encephalopathy, is based on dietary protein restriction⁽ Reference Bunch, Nelson and Guillermo Couto ^{92 ,} Reference Center ^{93 )}. Additionally, the supplementation of dietary fibre can exert beneficial effects on these disease conditions and the mechanisms behind these effects are explained in the next paragraphs.

The N trap principle, explained in the previous section, might be advantageous in animals suffering from hyperammonaemia (liver disease) or azotaemia (CKD), since an increase in the faecal N excretion and decreases in blood urea and ammonia concentrations can be achieved⁽ Reference Younes, Garleb and Behr ^{82 )}. Until now, no studies investigating the N trap principle have been performed in cats with CKD. As mentioned above (‘Effects of dietary fibre on nutrient intake, nutrient digestibility and faecal characteristics: fructans, mannanoligosaccharides and galacto-oligosaccharides’ section), a decrease in large-intestinal pH occurs when SCFA and lactate are produced upon fermentation of dietary fibre. Another consequence of this decrease, besides the ones mentioned above, is that the overload of protons (H⁺), that are present in a more acidic environment, leads to the ionisation of the ammonia (NH₃) molecules present to ammonium (NH₄ ⁺) ions⁽ Reference Younes, Garleb and Behr ^{82 )}. The absorption of NH₄ ⁺ ions from the intestine to the bloodstream is far less effective, and the majority of these ions are excreted in the faeces⁽ Reference Cummings ^{94 )}. That way, the ammonia concentration in the blood decreases, which benefits patients with hyperammonaemia⁽ Reference Rutgers, Biourge, Pibot, Biourge and Elliott ^{7 )}. Furthermore, less urea will be produced in the liver, resulting in lower blood urea N concentrations, beneficial to azotaemic patients. Additionally, the recently suggested amino acid-sparing potential of propionic acid⁽ Reference Verbrugghe, Hesta and Gommeren ^{86 –} Reference Rochus, Janssens and Cools ^{89 )} (see above) might be advantageous to patients whose diseases urge a dietary protein restriction, such as kidney⁽ Reference Polzin, Osborne and Ross ^{91 )} or liver⁽ Reference Bunch, Nelson and Guillermo Couto ^{92 ,} Reference Center ^{93 )} disease patients with evidence of hyperammonaemia or hepatic encephalopathy.