Abstract
Food residues are often fed to dogs in private households and might also be a potential “new” ingredient for pet food in the future. As food residues might contain not only digestible, but also fermentable substrates, an effect on the intestinal microbiota can be assumed. In the present study, two batches of dried food residues (DFR) collected from hotels in Crete were microbially fermented in an in vitro batch culture system with canine fecal inoculum: non-sterile DFR including meat (DFRm), sterile DFR including meat (DFRms) and sterile DFR without meat (DFRwms). Different non-digestible carbohydrate sources (beet pulp, wheat bran, inulin, carrot pomace, brewer´s spent grains, cellulose and lignocellulose) were included for comparison. Inulin, cellulose and lignocellulose were only used as raw materials, while the other test substrates were incubated as raw and enzymatically pre-digested substrates. After incubation for 24 hours, the raw food residues markedly increased the concentrations of bacterial metabolites in the fermenters, although smaller effects were observed for the DFRwms. When the enzymatically pre-digested food residues were incubated, the effects were more pronounced for the DFRms and DFRwms. In general, when compared with the other test substrates, the food residues were microbially fermented to a comparable or partly higher extent. Interestingly, high n-butyrate concentrations were measured in the inocula, both after incubation of the raw and pre-digested food residues. In conclusion, the food residues contained enzymatically digestible and microbially fermentable substrates. If considered as a potential future ingredient for pet food, a standardization of the collection and processing of food residues might be necessary in order to reduce compositional variability and varying effects on the intestinal microbiota.
Highlights
Given that 1.3 billion tons of food are lost or wasted every year [1], new strategies for food waste reduction are of increasing interest
A low gas production was observed, when cellulose and lignocellulose were incubated, while especially the incubation of dried food residues (DFR), beet pulp, wheat bran and carrot pomace resulted in a high gas production (P < 0.05, when these test substrates were compared with the blank control and cellulose incubation)
The highest ammonium concentrations were measured in the inocula, when the DFR including meat (DFRm) and DFRms were incubated, with group differences compared to inulin, beet pulp and DFRwms
Summary
Given that 1.3 billion tons of food are lost or wasted every year [1], new strategies for food waste reduction are of increasing interest. The project “Food for Feed (F4F)” (LIFE15 ENV/GR/000257) aims to investigate the potential use of dried food residues (DFR) for animal nutrition. Legal restrictions currently exist, food residues might be interesting as a potential future ingredient for pet food. Dogs often receive table scraps by their owners [2, 3], making the commercial use of food residues conceivable. One major concern of feeding catering waste to animals is its hygienic quality, as several pathogens that could be potentially present in recycled food leftovers may be harmful for the animals, and for human consumers throughout the food chain [4]. A heat treatment of food residues designated for animal nutrition is necessary to ensure the hygienic safety of this material [4]
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