To store energy, muscles use a phosphorylated form of creatine. This occurs because during normal metabolism there is no way for the body to produce enough energy to keep up with the muscleâ??s need to use it.
Fat cells, also known as adipocytes, store energy in the form of fat. Muscle cells, or myocytes, are responsible for generating force and movement. Fat cells have a lower metabolic rate compared to muscle cells, which burn more energy and contribute to overall metabolic health.
Mitochondria is the part of cells that generate energy by turning nutrients and oxygen into fuel for the body. Muscle cells need this ability more because they are constantly working; fat cells do not need it as much.
Cells convert the energy from glucose into ATP (adenosine triphosphate) through a series of chemical reactions in a process called cellular respiration. ATP is the primary molecule used by cells to store and transfer energy for various cellular functions.
Muscle cells are very active relatively to the skin cell. So it has more mitochondria
Cells store energy in the form of ATP (adenosine triphosphate) molecules, which are produced during cellular respiration. The energy stored in ATP molecules is released when the bonds between phosphate groups are broken, providing energy for various cellular functions. Cells use this energy to perform activities like muscle contraction, cell division, and the synthesis of molecules.
fat
Fat cells, also known as adipocytes, store energy in the form of fat. Muscle cells, or myocytes, are responsible for generating force and movement. Fat cells have a lower metabolic rate compared to muscle cells, which burn more energy and contribute to overall metabolic health.
Liver cells store chains of glucose in a molecule called glycogen, while muscle cells store glucose in the form of glycogen as well. Glycogen acts as a reserve of energy that can be broken down into glucose when needed for energy production.
Muscle cell energy refers to the energy required for muscle cells to function and contract. This energy is primarily produced through the breakdown of ATP (adenosine triphosphate) derived from nutrients like glucose and fatty acids. Additionally, muscle cells can store energy in the form of glycogen for quick access during exercise.
Mitochondria is the part of cells that generate energy by turning nutrients and oxygen into fuel for the body. Muscle cells need this ability more because they are constantly working; fat cells do not need it as much.
Cells store energy in bonds.
Cells convert the energy from glucose into ATP (adenosine triphosphate) through a series of chemical reactions in a process called cellular respiration. ATP is the primary molecule used by cells to store and transfer energy for various cellular functions.
Cells store energy in the form of carbohydrates.
mitochondria supply the energy to the cells. Muscle cells require a lot of energy for contraction. Therefore muscle cells need a lot of mitochondria.
In muscle cells, chemical energy stored in ATP molecules is converted into mechanical energy during muscle contraction. This process involves the hydrolysis of ATP to release energy that powers the interactions between proteins within muscle cells, leading to muscle movement.
Since the mitochondria produces energy and the muscle cells are part of the mitochondria, they use the energy so they can move the joints.
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