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Kitten nutrition
Abstract
: The evolution of the cat – from opportunistic rodent-eating hunter to indoor companion with ready access to meals – has coincided with an increased lifespan and health. However, the cat remains unique in many of its dietary needs and in the way it generates energy, with specific requirements for certain nutrients. Its carnivorous metabolism, reinforced by historical access to a diet of animal-based tissues and very little carbohydrate, have meant that some of its enzyme systems are limited in their capacity – or lacking altogether. This has led to an absolute need for certain essential nutrients from animal flesh in the food and supplementation with others. The growth life-stage phase sees some further requirements, with an increased need for energy and protein, along with certain nutrients. Many commercial diets now provide an easy-to-feed, balanced way of providing these essential nutrients to take the kitten from a vulnerable post-weaning stage through to a healthy adult.
... The immunomodulatory effects of livestock animal colostrum in humans have been demonstrated in several studies, including infectious diseases [76,77], exercise-induced immune suppression [78,79], wound healing involving gastrointestinal damage [53,80,81] and bone density [82]. This has led to several investments in antimicrobial molecules that are currently at various development stages by biotechnology companies [83]. With the use of milk as a food on one side, and the development of novel drugs based on isolated colostrum compounds on the other, the nutraceutical use of colostrum extracts in health management is an expanding niche [84] and is receiving interest as a complement to or substitutes for vaccines and pharmaceutical drugs [85,86]. ...
The present review aims toward a better understanding of the nutrition of newborn puppies and kittens. The post-natal period is very sensitive in dogs and cats, as in other animal species. During the first two weeks of life, puppies and kittens are at high risk of dehydration, hypothermia, and hypoglycemia, as well as infectious diseases as they start to acquire the physiological functions of the adult. Neonatal hepatic glycogen storage is low, and newborns depend on colostrum intake to survive. Colostrum provides immunoglobulins and other important substances such as lipids and carbohydrates. Immunoglobulins are central to the immunological link that occurs when the mother transfers passive immunity. The mechanism of transfer varies among mammalian species, but in this review, we focused our attention on dogs and cats. Furthermore, there are components of colostrum which, although their presence is not absolutely necessary, play an important role in nutrition. These components have received considerable interest because of their presumed safety and potential nutritional and therapeutic effects both in humans and animals; however, unfortunately, there are few recent studies in companion animals. Here, we have gathered the published articles that describe studies involving different species of animals, emphasizing companion animals. In particular, the purpose of this narrative of the nutritional and functional proprieties of queens’ and bitches’ colostrum.
Cat food production is a billion-dollar industry in the United States, with most pet owners trusting pet food companies to provide their pets with complete nutrition. Moist or canned cat food is healthier than dry kibble for cats due to its higher water content promoting healthy kidney function, but ingredient labels on canned cat food are lengthy with ambiguous terminology including 'animal by-products.' Forty canned cat food samples were collected from grocery stores and were processed using routine histologic methods. Hematoxylin and eosin-stained tissue sections were evaluated microscopically to determine the cat food content. Many brands and flavors were composed of well-preserved skeletal muscles admixed with various animal organs, which closely approximates nutritional components found in natural feline prey. However, several samples demonstrated marked degenerative changes suggesting a delay in food processing and potential decrease in nutrient content. Four samples contained cuts consisting of skeletal muscle only with no organ meat. Surprisingly, 10 samples contained fungal spores and 15 demonstrated refractile particulate matter. A cost analysis demonstrated that although the overall quality of canned cat food increases as the average cost per ounce increases, low-cost high-quality canned cat food is available.
From the foregoing discussion of the nutritional requirements and some of the metabolic anomalies of the cat, it is clear that the cat is adapted to eating a carnivorous diet. It may, however, have less capability than omnivores and herbivores to adapt to wide ranges in dietary composition. For example, the lack of ability to synthesize sufficient vitamin A from carotene, ornithine from glutamic acid, arachidonate from linoleate, and taurine from cysteine results from a complete deletion or severe limitation of the enzyme or pathway that makes each nutrient. Other nutrient requirements, such as the absolute requirement for niacin and the high protein requirement, appear to result from the high activity of one or more enzymes and the fact that these enzymes are not adaptive in the cat. For example, the cat cannot decrease picolinic carboxylase in order to force tryptophan toward the niacin-synthetic pathway (244) nor can it decrease the urea cycle enzymes when dietary protein is decreased in the diet in order to conserve nitrogen (209). Indeed, the cat appears to have less capability to adapt to most changes in dietary composition because it cannot change the quantities of enzymes involved in the metabolic pathways (209). This evolutionary development has resulted in more stringent nutritional requirements for cats than for omnivores such as the rat, dog, and man. What little evidence exists for other carnivore species leads us to suggest that this pattern may well be common among other strict carnivores. The metabolic differences between the cat and omnivores provide the researcher with a useful animal model for studying the biochemical basis of some nutrient requirements. For example, because there is no significant conversion of linoleate to arachidonate in cat liver (101, 150, 231), the physiological functions of linoleate can be determined independent of it having a role as a precursor of arachidonate (150). This has not been possible with other species. It is anticipated that further studies of the nutrition of the cat will increase our understanding of metabolic adaptation and nutrient functions.
A study was carried out in domestic felines to determine whether corn oil-based maternal diets are an adequate source of essential fatty acids to support normal accumulation of long-chain polyunsaturated fatty acids in the brains and retinas of offspring and whether these diets have any subsequent effect on visual function. Female domestic felines were acclimated to one of six different defined diets 1 mo before mating and maintained on the diets throughout pregnancy and lactation. Four diets contained only corn and hydrogenated coconut oils as their source of fat in ratios of 1:9, 3:7, 6:4, and 9:1, respectively. Two reference diets also contained the long-chain polyunsaturated fatty acids arachidonate (20:4n-6) and docosahexaenoate (22:6n-3). When the offspring were 8 wk old, electroretinograms were obtained and the a- and b-wave implicit times were determined. The results showed that animals raised in litters in which the maternal diets were devoid of 20:4n-6 and 22:6n-3 had an increase in a- and b-wave implicit times compared with the controls. In the rod outer segments and brains of these animals, there were lower amounts of 22:6n-3 and higher amounts of long-chain n-6 polyunsaturated fatty acids compared with control animals. These findings showed that although corn oil-based diets were capable of maintaining 20:4n-6 concentrations in the developing brain and retina, only those diets containing 22:6n-3 could support a high accumulation of docosahexaenoic acid in these tissues. Moreover, low amounts of 22:5n-6 in the brains of animals in all of the corn oil-diet groups suggested that young felines have a low biosynthetic capacity to produce this fatty acid or 22:6n-3. These findings suggest that in juvenile felines, maintenance of 22:6n-3 status in the nervous system is important for optimal retinal function.
Effect of dietary fish oil on puppy trainability
- R L Kelley
- A J Lepine
- J R Burr