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In the muscle cells in your body what energy is changed into what energy?
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.
What are examples of adapted cells?
Red blood cells are adapted for oxygen transport due to their concave shape and lack of a nucleus, allowing for more space to carry oxygen. Nerve cells are adapted for rapid transmission of electrical impulses with their long axons. Muscle cells are adapted for contraction with abundant mitochondria for energy production.
Can muscle cells release glucose to the blood?
No, muscle cells do not release glucose into the blood. Instead, they take up glucose from the blood to use as fuel for energy production during muscle contraction. Glucose release into the blood is primarily regulated by the liver through a process called gluconeogenesis.
What happens to certain nutrient molocules after they pass into muscle cells?
they are acted on by enzymea and release the energy they contain
What makes muscle cells specialized?
Muscle cells, like all cells, are specialised to carry out their specific functions. Muscle cells need relatively large numbers of mitochondria. This is because they respire more than most other types of cell, in order to release the energy for muscle contraction, and hence movement.
How are intestine wall muscle cells adapted to release a lot of energy?
They have more mitochondria
In the muscle cells in your body what energy is changed into what energy?
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.
What are examples of adapted cells?
Red blood cells are adapted for oxygen transport due to their concave shape and lack of a nucleus, allowing for more space to carry oxygen. Nerve cells are adapted for rapid transmission of electrical impulses with their long axons. Muscle cells are adapted for contraction with abundant mitochondria for energy production.
How do the muscle cells get energy needed to make glycogen?
They use glucose to release energy using respiration.
When a person exercises change occur in the muscle cells as they release more energy?
Yes.
Why muscle cells have more mitochondria than other kinds of eukaryotic cells have?
mitochondria supply the energy to the cells. Muscle cells require a lot of energy for contraction. Therefore muscle cells need a lot of mitochondria.
Can muscle cells release glucose to the blood?
No, muscle cells do not release glucose into the blood. Instead, they take up glucose from the blood to use as fuel for energy production during muscle contraction. Glucose release into the blood is primarily regulated by the liver through a process called gluconeogenesis.
What happens to certain nutrient molocules after they pass into muscle cells?
they are acted on by enzymea and release the energy they contain
How do muscle cells use energy?
Since the mitochondria produces energy and the muscle cells are part of the mitochondria, they use the energy so they can move the joints.
Where do muscle cells get energy from?
k
Why are muscle cells good at their job?
Muscle cells, like all cells, are specialised to carry out their specific functions. Muscle cells need relatively large numbers of mitochondria. This is because they respire more than most other types of cell, in order to release the energy for muscle contraction, and hence movement.
What makes muscle cells specialized?
Muscle cells, like all cells, are specialised to carry out their specific functions. Muscle cells need relatively large numbers of mitochondria. This is because they respire more than most other types of cell, in order to release the energy for muscle contraction, and hence movement.
