Protein sources

Raw soybeans also maybe used as a supplemental protein source. Dry beans, ie, beans normally harvested in the green / imm a tiire state, fava beans, lupins, field peas, lentils, and other grain legumes are potential supplemental protein sources however, several of these may have deleterious effects, predominantly enzyme inhibition, on the animal. The supply of each is limited (5). 

Legume forages, such as alfalfa or clover, are considered high quaHty, readily available protein sources. Animal sources of supplemental protein include meat and bone meal blood meal, 80% CP fish meal other marine products and hydroly2ed feathermeal, 85—90% CP. Additionally, synthetic amino acids are available commercially. Several sources (3,9,19) provide information about the protein or amino acid composition of feedstuffs. 

The mmen is not functional at birth and milk is shunted to the abomasum. One to two weeks after birth, the neonate consumes soHd food if offered. A calf or lamb that is nursing tends to nibble the mother s feed. An alternative method of raising the neonate is to remove it from its mother at a very young age, <1 week. A common example of an early weaning situation is the dairy calf that is removed from the cow soon after birth so that the cow s milk supply might be devoted entirely to production. In this instance, the neonate requires complete dietary supplementation with milk replacer. Sources of milk replacer protein have traditionally included milk protein but may also include soybean proteins, fish protein concentrates, field bean proteins, pea protein concentrates, and yeast protein (4). Information on the digestibiUty of some of these protein sources is available (4). 

Leaf protein Source Protein Fat Cmde fiber Ash Reference... 

Economic coaditioas ia the United States have not favored the production of EPC and EPI having desirable functional and nutritional characteristics at prices competitive with those of conventional protein sources. 

In general, nonconventional protein foods must be competitive with conventional plant and animal protein sources on the bases of cost delivered to the consumer, nutritional value to humans or animals, functional value in foods, sensory quality, and social and cultural acceptability. Also, requirements of regulatory agencies in different countries for freedom from toxins or toxic residues in single-cell protein products, toxic glycosides in leaf protein products, pathogenic microorganisms, heavy metals and toxins in fish protein concentrates, or inhibitory or toxic peptide components in synthetic peptides must be met before new nonconventional food or feed protein products can be marketed. 

Future Uses. The most recent uses for methanol can be found in the agricultural sector. Test studies are being carried out where methanol is sprayed directly onto crops to improve plant growth. Methanol can be used as a carbon source for the production of single-cell protein (SCP) for use as an animal feed supplement. The process has been commercially demonstrated by ICl at their BiUingham, U.K., faciUty. However, the production of SCP is not commercially practical at this time, in comparison to more conventional protein sources. 

Formulas tend to contain isolates as the protein source to eliminate or reduce the presence of carbohydrates that ate the cause of flatulence and abnormal stools. Care is taken to provide adequate nutrition and to use proteins processed in such a way as to minimize or eliminate any antinutritional factors. The formulation of a typical soy-based infant formula is also given in Table 17. 

In this chapter we examine the processes that have been developed to produce micro-organisms as a source of food protein. We will examine the reasons why micro-organisms have been considered as alternative protein sources, the substrates on which they have been grown, the various process technologies developed and the comparative economics of these processes. One process will be examined in depth, to illustrate how a team composed of such diverse people as microbiologists, process engineers, patent lawyers and cost analysts work together to develop a marketable product. 

You may be wondering why anyone should ever have considered using micro-organisms as a protein source. Let us consider why this should have been. 

When the Myco-protein project was planned in the 1960s it was assumed the product would form a valuable protein source, needed to meet expected protein shortages. By the early 1980s, when the project had reached production, the protein shortage had not developed (at least in Europe). However, dietary habits had changed, and there was a move away from meat consumption to other healthier foods. There was also a move towards convenience foods such as deep-frozen prepared meals. It was to these markets that Myco-protein was directed. 

Table 4.6 Essential amino acids content of a variety of protein sources...

Bacteria, yeast and algae are produced in massive quantities of protein sources as food for animals and humans.1 SCP is considered a major source of feed for animals. The production of valuable biological products from industrial and agricultural wastes is considered through the bioconversion of solid wastes to added-value fermented product, which is easily marketable as animal feedstock. The waste streams that otherwise would cause pollution and threaten the environment can be considered raw material for CSP production using suitable strains of microorganisms. 

To sell well, the shampoo must look good, must feel thick or creamy in the hands, and must produce a nice-feeling lather. It must smell good, and it must not be too expensive. Other selling points might be the currently popular herbal extracts, or amino acids from exotic protein sources such as silk or the milk of pygmy goats. 

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