Oh, dude, liver cells have a lot of mitochondria because they need a ton of energy to do all their fancy detoxifying and metabolic processes. It's like they're the powerhouses of the cell, keeping everything running smoothly while the liver does its thing. So yeah, all those mitochondria are basically the liver cell's way of saying, "I'm a busy bee, don't bother me."
Mitochondria because this releases energy from stored food molecules which is used for power growth, development, and movement. muscle cells have a greater demand for this than any other body cells.
It is in the mitochodria and speeds up the formation of ATP by breaking down ATP into ADP + energy. Muscle cells have many more mitochrondia than other cells.
This theory states that the organelles found in cells were once their own independent cells. Throughout time, these independent organelles were consumed by bigger cells and not digested, but used in exchanged for their services.
basiccly there are more than two simiraties and differnces but illl tell yhu just 2 : normal cells: tiny and many but only cover parts of yhur body muscle cells: cover most of yhur body andstrong like the other guy said
Describe some of the jobs that the cell performs to keep it alive
1102421242
Skeletal muscle cells, for instance, contain many mitochondria because the energy consumed in the contraction of the sarcomere is enormous. Skin cells, for instance, contain much less mitochondria as the cellular work the need to do is minimal compared to skeletal muscle cells.
White blood cells have. But erithrocytes lack many
Active cells such as muscle and liver cells have more mitochondria than others because they use up a lot more energy to carry out their roles and stay alive. Thus needing the extra mitochondria to produce more energy.
Cells that require the most energy contain the most energy generating mitochondria. The cells of the brain, the skeletal muscle and heart muscle, and the eye contain the highest number of mitochondria (as many as 10,000 per cell) while the skin cells, which do not require much energy, contain only a few hundred of them.
Muscle cells work hard and require a lot of energy so they contain many many mitochondria.
Muscle cells often contain many mitochondria because muscle cells often require a lot of energy, and since mitochondria create ATP which is the form of energy used by our bodies, it is essential to have many of them in cells that constantly require more energy than, as an example, skin cells.
Mitochondria is a cite in the cytoplasm also known as power house of the cell because of their energy generating ability in the cell. In humans there are many life activities that goes on in the body in order to make life possible. The prominent activity is that needs large amount of energy is reproduction. This occurs in the tissues, hence mitochondria are mostly found in muscle tissues for this life activity.
Cells with a high energy demand, such as muscle cells and liver cells, typically have a high number of mitochondria. Mitochondria produce energy in the form of ATP through cellular respiration, so cells that require a lot of energy to function efficiently will have more mitochondria.
Mitochondria in liver cells are responsible for generating energy through a process called oxidative phosphorylation. They help produce ATP, which is the main source of energy for cellular functions in the liver. Mitochondria also play a role in the metabolism of fatty acids and detoxification processes in liver cells.
Cells such as liver cells, sperm cells and muscle cells have more mitochondria. This is because they are more metabolically active and need a plentiful supply of ATP (adenosine triphosphate) for metabolic processes. For example, many chemical processes occur in liver cells and sperm cells are known for movement.
Mitochondria are double-membrane-bound organelles found in eukaryotic cells. They are known as the powerhouse of the cell because they generate most of the cell's energy through the process of cellular respiration. Mitochondria also play a role in regulating cell metabolism and apoptosis.