If all of th 120 g of glucose are converted to energy, how many grams of h2o and co2 will be produced?
Vandalyn Sulfate increases the amount of glucose and amino acids driven into the muscle. Works like insulin.
Chromium is a trace mineral. It plays an important role in the burning of fats and carbohydrates in the body. It helps fight obesity, diabetes, and heart disease.
PC is an abbreviation for phosphocreatine. PC, like ATP, is stored in the muscle cells, and when it is broken down, a large amount of energy is released. The energy released is coupled to the energy requirement necessary for the resynthesis of ATP.The total muscular stores of both ATP and PC are very small. Thus, the amount of energy obtainable through this system is limited. In fact, if you were to run 100 meters as fast as you could, the phosphagen stores in the working muscles would probably be empty by the end of the sprint. However, the usefulness of the ATP-PC system lies in the rapid availability of energy rather than quantity. This is extremely important with respect to the kinds of physical activities that we are capable of performing
Cells that do not require oxygen go through anaerobic respiration, which is a form of cellular respiration that uses fermentation to turn energy into useful energy. There are two types of anaerobic respiration, lactic acid fermentation and alcohol fermentation. Muscle cells do this when they run out of oxygen and go through fermentation instead. The product of this type of fermentation from muscle cells is lactic acid. Lactic acid is toxic and causes soreness and fatigue. Anybody who has been sore after exercise has experienced lactic acid fermentation.
mucosa, thick layer of circulas muscle, thin layer of longitudinal muscle, serosa
Glucose is also converted to energy in muscle cells. When it comes to producing energy from glucose, muscle cells are, well, double-jointed
glucose
The body breaks down muscle tissue into amino acids, which are then converted in the liver to blood glucose. This process is called gluconeogenesis.
glycogen
glucose is oxidised in 2 ways -with oxygen (aerobic) -without oxygen(anaerobic) aerobic respiration takes place in mitochondria . glucose in cytoplasm forms pyruvic acid is converted into carbon di oxide 38 ATP of energy and water anaerobic respiration may take place in muscle cells or RBCs in this glucose is converted into pyruvic acid in cytoplasm which changes to -lactic acid, water and 2 ATP of energy in muscle cells and RBCs -in yeast anaerobic respiration takes place pyruvic acid formed from glucose is converted to form alchohol and water as well as 2 ATP of energy
The heart pumps all of the nutrients around the body for the body to use. This is generally glucose (sugars), proteins, oxygen and any waste chemicals produced by the body.
Eventually, the end product of glycogenolysis in skeletal muscle will be ATP in order to produce energy for muscle activity. Unlike the glycogenolysis in the liver, the produced glucose from glycogenolysis in the skeletal muscle is not released in the blood stream, because it will directly go to the glycolysis pathway to be consumed to generate pyruvate. Pyruvate will be converted to acetyl-coA to be used in citric acid cycle for production of ATP.
It has large amounts of mitochondria, which are used to release energy.
conversion of glucose to energy, glucose molecule. Muscle and brain cells like this, because they use lots of ATP.
fat, calories, sugar, and energy or glucose
yes
Muscle cells need a specific form of energy for contraction and cannot use the energy released directly from breaking down glucose or triglycerides. Rather, body cells must first convert food to adenosine triphosphate (ATP). So to answer simply, yes. But glycogen isn't used directly. Glycogen is converted to glucose, and then that is converted to ADP+pi, and that is converted finally to ATP, which is actually what fuels locomotion of the muscles when exercising. This is a very non-detailed answer, but I hope it provides the answer you were looking for. Muscle cells need a specific form of energy for contraction and cannot use the energy released directly from breaking down glucose or triglycerides. Rather, body cells must first convert food to adenosine triphosphate (ATP). Food is digested and processed into ATP through sever different stages. Glycogen is converted to glucose, and then that is converted to ADP+pi, and that is converted finally to ATP, which is actually what fuels locomotion of the muscles when exercising. This is a non-detailed answer, but provides the basics of how muscles get energy.