Wizard Recipes

Protein is an essential part of our diets. Proteins are large, complex molecules resembling tangled strings of beads. Each of the “beads” on the string is one of a group of smaller molecules called amino acids. Amino acids are composed of carbon, oxygen, hydrogen, and nitrogen, and some contain sulfur.

Using the amino acids from the protein you eat, the body makes more than 50,000 different proteins. These proteins are the main structural elements of our skin, hair, nails, cell membranes, muscles, and connective tissue.

Collagen, the main protein in our skin, provides a barrier to the invasion of foreign substances. Proteins in cell membranes determine what substances can enter and exit cells.

Our muscles, which contain some 65 percent of the body’s total protein, give our bodies their shape and strength.

Proteins in connective tissues such as tendons, ligaments, and cartilage enable our skeletons to function, form internal organs, and hold the organs in place. Proteins in the blood carry oxygen to all cells and remove carbon dioxide and other waste products.

The proteins in muscle, connective tissue, and blood make up most of the protein in the body. Other proteins called enzymes accelerate metabolic processes, and still other proteins and amino acids are hormones and neurochemicals, the substances that deliver signals throughout the body and regulate all metabolic processes.

During periods of growth, our bodies must manufacture and store large amounts of protein. Therefore, the requirement for protein in our diets is higher during growth.

But even when we are not growing, each of the unique proteins in the body has a finite lifespan and must be replaced continuously. So the need for protein never ends.

Dietary Protein and Body Protein

The thousands of proteins that make up our bodies are assembled on demand from some 20 different amino acids. What are these amino acids, and where do they come from?

The protein from the meat we ate last night is not directly incorporated into our muscles. The proteins in the foods we eat are digested first into small “peptides.” Some of these peptides are further digested into their constituent amino acids. Only amino acids and small peptides are actually absorbed by the small intestine into the bloodstream.

They are then delivered to the liver, muscles, brain, and other organs, where they are used to make new proteins or converted to other amino acids needed by those organs. Of the 20 amino acids that make up all proteins, 9 are considered “essential” because they cannot be made in our bodies and must be obtained from the foods we eat. Of the remaining 11, some are essential for infants and persons with certain diseases.

The rest of the amino acids are considered “nonessential,” because our bodies can make them in adequate amounts, if necessary. Nevertheless, they are easily supplied by eating a well-balanced diet that includes a variety of foods.

Most foods contain protein. Some foods are better sources of protein than others. “Complete” proteins are those that contain all the essential amino acids in amounts needed to synthesize our body’s proteins. The best sources of complete protein are lean meats and poultry, fish, low-fat dairy products, and eggs.

The grains and cereals group of foods, are excellent sources of protein, but because these proteins often lack one or more essential amino acids, they are called “incomplete” proteins.

For example, the proteins in corn are low in the essential amino acids lysine and tryptophan, and wheat is low in lysine. In contrast, legumes tend to be rich in lysine but a bit low in methionine. Among the legumes, soybeans contain the most complete protein.

Does this mean you must eat meat, eggs, and dairy products (foods of animal origin) to get all the amino acids you need? Not at all.By eating a variety of different foods, including grains and legumes, you are likely to get all the amino acids you need and in the correct amounts.

People of many cultures and vegans (vegetarians who eat no foods of animal origin) get adequate amounts and types of protein by eating various combinations of plant proteins including beans, corn, rice, and other cereal grains. Although it was once thought necessary to combine these foods at the same meal, nutrition experts now agree that they can be eaten at various times throughout the day.

When we eat grains and legumes, rather than foods of animal origin (a more frequent source of protein in our diets), we gain additional health benefits. Whole-grain foods and legumes are rich in vitamins, minerals, fiber, and other substances that optimize health.

If that does not seem like reason enough to make the trade, grains and legumes lack the high levels of saturated fat present in foods of animal origin, which, as you will learn below, are linked to many diseases.

Contrary to popular belief, simply eating more dietary protein, in excess of recommended amounts, will not result in bigger muscles. Our bodies do not store excess protein.

If we eat more protein than our bodies need to replenish the amino acids we have used during the day, the excess amino acids are converted to, and stored as, fat. Dietary protein, like carbohydrates, supplies about 4 calories of energy per gram.

Because our requirements for protein mainly depend on our body’s size, our need for protein increases during times of rapid growth. Therefore, the recommendations for protein are age-dependent and are slightly higher for pregnant and breastfeeding women than for other adults.

It is perhaps, in the cooking of meats, that a good understanding of the underlying science can provide the greatest and most immediate improvement in one’s own cooking; certainly this was true for me.

Meats are prepared (boned, minced, ground, chopped, etc.) and cooked (grilled, roast, stewed, etc.) in so many different ways, that it is to me astonishing that all these diverse cooking processes involve the same few scientific principles.

Cooking meat is all about producing the right textures and flavours. Once you understand how cooking alters the texture of meats you will quickly be able to control the process so as to produce tender meats all the time.

Equally, once you appreciate the complexity of the chemistry that goes into the development of the meaty flavours, you will soon learn that there are a few simple, but crucial steps that are essential to flavour development during the cooking process.

Before you can fully appreciate the changes that occur when meat is cooked, you need to have some knowledge of the structure and composition of meat before it is cooked.Weare all familiar with the texture of meats; meat has a ‘grain’ being made up from muscles which are in turn made up from bundles of protein fibres. These proteins contract, when appropriate chemical signals are sent to them, so operating the muscles.

Between the fibres and the fibre bundles there is some ‘connective tissue’, which holds the muscles together and connects them to the bones. Muscles that have to bear greater loads, such as thigh muscles that operate the legs, etc., tend to have more of this connective tissue.

All connective tissue needs to be very tough and strong (otherwise it would be no good at transferring the load from muscles to bones!) . So muscles that have lots of connective tissue will make for tough and gristly meats.

There are three main types of connective tissue: collagen, reticulin and elastin . Collagen is the most abundant and the most important for the cook to appreciate . Collagen is a complex molecule made up from three strands that are twisted together rather like a rope. Collagen derives its stiffness and strength from the arrangement of these intertwined helices.

However, if collagen is heated to temperatures above about 60°C, the three strands can separate and the material loses its strength. Once denatured into single strands collagen becomes a very soft material, and is given a different name, gelatin.  We know that gelatin is a soft, tender, material, since it is used as the basis of all jellies.

The collagen is mostly found around bundles of muscle fibres and helps to hold them together. The muscles are then joined to the bones with yet more sinews (yet more “connective tissue”), which cooks recognise as tough ‘gristly’ material.

These sinews are made from the proteins reticulin and elastin; reticulin and elastin can only be denatured and softened by heating for very long times at temperatures above 90°C.

Eggs contain all 8 essential amino acids and proteins, and also all the needed substances for adolescentin and adult development. Along with the amino acids and proteins, eggs are also high in vitamins (A, B, D, E), minerals (Phosphor, Calcium, Iron) and oligoelements.

Advantages:

- proteins from eggs are better used by our organism that meat proteins. This happens because eggs are rich in vitamins and minerals.

- vitamin D in eggs plays an essential role in Calcium absorption from other ingredients and for bone development. Even though most of vitamin D is produced when exposed to sun, children, pregnant women and elders need high quantities of vitamin D, eggs being a very important source.

- 1 egg means 10% of the daily needed quantity of Selenium and contributes to the quality of sperm.

- eggs maintain the well functioning of the nervous system through its B6 and B12 content.

- protects blood vessels due to antioxidant properties conferred by Selenium and D vitamin.

Disadvantages:

- the egg yolk contains a lot of cholesterol. People with high triglycerides shouldn’t consume more than 1 egg weekly.

- hard boiled eggs can cause indigestion to gall bladder suffering persons.

- it can contain salmonella (especially in goose or duck egg), so don’t consume it raw. Cook it, and the germ dies.

- It doesn’t contain vitamin C or glucids.