Every time you swallow a bite of sandwich or slurp a smoothie, your body works hard to process the nutrients you've eaten. Long after the dishes are cleared and the food is digested, the nutrients you've taken in become the building blocks and fuel needed by your body. Your body gets the energy it needs from food through a process called metabolism.
What Is Metabolism?
Metabolism (pronounced: meh-TAB-uh-lih-zem) is a collection of chemical reactions that takes place in the body's cells. Metabolism converts the fuel in the food we eat into the energy needed to power everything we do, from moving to thinking to growing.
Specific proteins in the body control the chemical reactions of metabolism, and each chemical reaction is coordinated with other body functions. In fact, thousands of metabolic reactions happen at the same time — all regulated by the body — to keep our cells healthy and working.
Metabolism is a constant process that begins when we're conceived and ends when we die. It is a vital process for all life forms — not just humans. If metabolism stops, living things die.
Here's an example of how the process of metabolism works in humans — and it begins with plants:
- First, a green plant takes in energy from sunlight. The plant uses this energy and a molecule called chlorophyll (which gives plants their green color) to build sugars from water and carbon dioxide. This process is called photosynthesis, and you probably learned about it in biology class.
- When people and animals eat the plants (or, if they're carnivores, they eat animals that have eaten the plants), they take in this energy (in the form of sugar), along with other vital cell-building chemicals. Then, the body breaks the sugar down so that the energy released can be distributed to, and used as fuel by, the body's cells.
- After food is eaten, molecules in the digestive system called enzymes break proteins down into amino acids, fats into fatty acids, and carbohydrates into simple sugars (e.g., glucose). Like sugar, amino acids and fatty acids can be used as energy sources by the body when needed.
- These compounds are absorbed into the blood, which carries them to the cells. In the cells, other enzymes act to speed up or regulate the chemical reactions involved with "metabolizing" the compounds. The energy from these compounds can be released for use by the body or stored in body tissues, especially the liver, muscles, and body fat.
A Balancing Act
The process of metabolism is really a balancing act involving two kinds of activities that go on at the same time — the building up of body tissues and energy stores and the breaking down of body tissues and energy stores to generate more fuel for body functions:
- Anabolism (pronounced: uh-NAB-uh-lih-zem), or constructive metabolism, is all about building and storing: It supports the growth of new cells, the maintenance of body tissues, and the storage of energy for use in the future. During anabolism, small molecules are changed into larger, more complex molecules of carbohydrate, protein, and fat.
- Catabolism (pronounced: kuh-TAB-uh-lih-zem), or destructive metabolism, is the process that produces the energy required for all activity in the cells. In this process, cells break down large molecules (mostly carbohydrates and fats) to release energy. This energy release provides fuel for anabolism, heats the body, and enables the muscles to contract and the body to move. As complex chemical units are broken down into more simple substances, the waste products released in the process of catabolism are removed from the body through the skin, kidneys, lungs, and intestines.
Several of the hormones of the endocrine system are involved in controlling the rate and direction of metabolism. Thyroxine (pronounced: thigh-ROK-seen), a hormone produced and released by the thyroid (pronounced: THIGH-royd) gland, plays a key role in determining how fast or slow the chemical reactions of metabolism proceed in a person's body.
Another gland, the pancreas (pronounced: PAN-kree-us) secretes (gives off) hormones that help determine whether the body's main metabolic activity at a particular time will be anabolic or catabolic. For example, after eating a meal, usually more anabolic activity occurs because eating increases the level of glucose — the body's most important fuel — in the blood. The pancreas senses this increased level of glucose and releases the hormone insulin (pronounced: IN-suh-lin), which signals cells to increase their anabolic activities.
Metabolism is a complicated chemical process, so it's not surprising that many people think of it in its simplest sense: as something that influences how easily our bodies gain or lose weight. That's where calories come in. A calorie is a unit that measures how much energy a particular food provides to the body. A chocolate bar has more calories than an apple, so it provides the body with more energy — and sometimes that can be too much of a good thing. Just as a car stores gas in the gas tank until it is needed to fuel the engine, the body stores calories — primarily as fat. If you overfill a car's gas tank, it spills over onto the pavement. Likewise, if a person eats too many calories, they "spill over" in the form of excess fat on the body.
The number of calories someone burns in a day is affected by how much that person exercises, the amount of fat and muscle in his or her body, and the person's basal metabolic rate (BMR). BMR is the rate at which the body "burns" energy, in the form of calories, while at rest. BMR can play a role in a person's tendency to gain weight. For example, someone with a low BMR (who burns fewer calories while at rest or sleeping) will tend to gain more pounds of body fat over time compared with a similar-sized person with an average BMR who eats the same amount of food and gets the same amount of exercise.
What things affect BMR? To some extent, BMR is inherited — passed on through the genes we get from our parents. Sometimes, health problems can affect someone's BMR. But people can change their BMR in some ways. For example: by exercising more, a person burns more calories during the extra activity and becomes more physically fit, thus increasing his or her BMR. BMR is also influenced by body composition — people with more muscle and less fat generally have higher BMRs.
Things That Can Go Wrong With Metabolism
Most of the time, your metabolism works well without you giving it any thought. But sometimes a person's metabolism can cause major mayhem in the form of a metabolic disorder. In a broad sense, a metabolic disorder is any disease that is caused by an abnormal chemical reaction in the body's cells.
Most disorders of metabolism involve either abnormal levels of enzymes or hormones or problems with how those enzymes or hormones work. When the metabolism of body chemicals is blocked or defective, it can cause a buildup of toxic substances in the body or a lack of substances needed for normal body function, either of which can cause serious symptoms.
Metabolic diseases and conditions include:
Hyperthyroidism (pronounced: hi-per-THIGH-roy-dih-zum). Hyperthyroidism is caused by an overactive thyroid gland. The thyroid releases too much of the hormone thyroxine, so a person's BMR is high. It causes symptoms such as weight loss, increased heart rate and blood pressure, protruding eyes, and a swelling in the neck from an enlarged thyroid (goiter). The disease may be controlled with medicines or through surgery or radiation treatments.
Hypothyroidism (pronounced: hi-po-THIGH-roy-dih-zum). Hypothyroidism is caused by a nonexistent or underactive thyroid gland. The thyroid releases too little thyroxine, so a person's BMR is low. Untreated hypothyroidism can lead to brain and growth problems in infants and children. Hypothyroidism slows body processes and causes tiredness, slow heart rate, weight gain, and constipation. Teens who have it can be treated with oral thyroid hormone.
Inborn errors of metabolism. Metabolic diseases that are inherited are called inborn errors of metabolism. When babies are born, they're tested for many of these. Inborn errors of metabolism include galactosemia (babies born with this do not have enough of the enzyme that breaks down the sugar in milk, called galactose) and phenylketonuria (this is due to a defect in the enzyme that breaks down the amino acid phenylalanine, needed for normal growth and protein production). Inborn errors of metabolism can sometimes lead to serious problems if they're not controlled with diet or medicine from an early age.
Type 1 diabetes (pronounced: dye-uh-BEE-teez).Type 1 diabetes happens when the pancreas doesn't make and secrete enough insulin. Symptoms of this disease include excessive thirst and peeing, hunger, and weight loss. Over time, the disease can cause kidney problems, pain due to nerve damage, blindness, and heart and blood vessel disease. Teens with type 1 diabetes need regular insulin injections and should control their blood sugar levels to reduce the risk of developing problems from diabetes.
Type 2 diabetes. Type 2 diabetes happens when the body can't respond normally to insulin. Symptoms are similar to those of type 1 diabetes. Many children and teens who develop type 2 diabetes are overweight, and this is thought to play a role in their decreased responsiveness to insulin. Some teens can be treated successfully with dietary changes, exercise, and oral medicine; others will need insulin injections. Controlling blood sugar levels reduces the risk of developing the same kinds of long-term health problems that happen with type 1 diabetes.
Metabolism And Energy: Catabolism And Anabolism
Metabolism is defined the sum of all chemical reactions which occur and are involved in sustaining life of a cell, and thus an organism. Metabolism is of two types: Catabolism: in this process molecules break down producing energy
Anabolism: in this process synthesis of essential compounds needed by the cells are produced (such as DNA, RNA, and protein synthesis).
Bioenergetics describes the metabolic pathways by which a cell obtains energy. Nutrition science studies the relation between the food substance and living things. The study deals with:
1) Body requirements of various substances.
2) The function of various substances in the body.
3) The amount of the substances needed.
4) The lower levels below which health gets affected.
The food which we eat supplies energy (calories) and supplies essential chemicals which the body cannot synthesize by itself. Food provides substances that are essential for building and repair of body tissues. Food provides substances for efficient functioning of the body.
Energy is trapped in complex chemical compounds and nutrients. These compounds are broken down to obtain energy. Humans acquire energy from carbohydrates, lipids and proteins. The chemical energy in these molecules is altered into thermal, kinetic, and other chemical forms.
Lipids, Carbohydrates, and proteins serve as a fuel for the human body. The nutrients are broken down into smaller units in the alimentary tract and are absorbed into the blood. The chemical energy of digestive end products is transformed into useful work by the tissues and the cells. The majority of the absorbed products contain monosaccharides, glucose, and monoacylglycerol, long chain of fatty acids, peptides and amino acids. Once these products are into the bloodstream, the different cells metabolize them.
MECHANISM OF ATP SYNTHESIS
The living cells obtain energy and use them to live, grow and reproduce. The process involved is called as energy metabolism. Energy is released when the chemical bonds of the nutrient molecules break and form high-energy compounds such as ATP. The main chemical energy carrier in all the cells is the ATP. ATP synthesis can occur by two mechanisms:
1) Synthesis from ADP and inorganic phosphate that takes place in the mitochondrion.
2) Synthesis by transfer of high-energy phosphoryl groups to ADP. Both mitochondria and the cytoplasm can carry out the synthesis process.
OXIDATIVE PHOSPHORYLATION: THE MAIN MECHANISM OF ATP SYNTHESIS IN MOST HUMAN CELLS
In ATP synthesis, oxidation-reduction reactions are very essential. The electrons are transferred to two major electron carrier enzymes. The protein complexes transport the electrons. The protein complexes are present in the inner mitochondrial membrane. The complexes contain attached chemical groups that are capable of accepting or donating one or more electrons. The protein complexes are known as the electron transfer system (ETS). The ETS allow distribution of the free...
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