Glucose is broken down and used in the process called cellular respiration. Basically the glucose is converted to ATP, which is used as energy by the cell. Carbon dioxide is released as a product and expelled as waste from the body.
the glucose is break down in the cell by 1)glycolysis 2)preparation of pyruvic acid 3) kreb's cycle or citric acid cycle or CAC or tricarboxylic acid cycle 4)oxidative phosphorylation and after that ATP is produced which is the energy currency of our body
Excess glucose is stored in liver cells and muscle cells in the form of glycogen. When blood glucose levels are high, insulin signals these cells to take up glucose and convert it into glycogen for storage. This glycogen can later be broken down back into glucose when energy is needed.
the glucose is break down in the cell by 1)glycolysis 2)preparation of pyruvic acid 3) kreb's cycle or citric acid cycle or CAC or tricarboxylic acid cycle 4)oxidative phosphorylation and after that ATP is produced which is the energy currency of our body
For energy, they need energy to keep the organism they're part of going. Cells use oxygen (if possible) to break down the glucose into carbon dioxide and water. This is called aerobic respiration. If not oxygen is available (if your using a lot like during exercise) then the cells will break down the glucose anaerobically to make lactic acid which can hard your cells. This all happens in the mitochondria of your cells.
If blood glucose levels are too high, the pancreas will secrete insulin. Insulin helps lower blood glucose levels by promoting the uptake of glucose into cells for energy production and storage.
the glucose is break down in the cell by 1)glycolysis 2)preparation of pyruvic acid 3) kreb's cycle or citric acid cycle or CAC or tricarboxylic acid cycle 4)oxidative phosphorylation and after that ATP is produced which is the energy currency of our body
The molecule that stores the high energy removed from glucose in glycolysis is adenosine triphosphate (ATP). ATP is the main energy currency of cells and is generated during glycolysis through a series of enzymatic reactions that ultimately result in the conversion of glucose to pyruvate.
glucokinase. glucokinase has a high km(low affinity for glucose) so glucokinase only phosphorylates glucose when blood glucose is high, such as after a meal. As such, it makes sense that this would be sensor for B-cells
The purpose of the glucose receptors is to detect blood glucose levels. The Islets of Langerhorn dispatch alpha cells to detect low blood glucose and beta cells to detect high blood glucose levels.
ATP
ATP
Glycogen is the main energy storage molecule found in liver and muscle cells. It is a polysaccharide made up of glucose units and serves as a readily available source of energy during periods of high energy demand, such as exercise or fasting.
Glucose.
Excess glucose is stored in liver cells and muscle cells in the form of glycogen. When blood glucose levels are high, insulin signals these cells to take up glucose and convert it into glycogen for storage. This glycogen can later be broken down back into glucose when energy is needed.
The energy from foods that is not used directly is stored in a high-energy molecule called ATP (adenosine triphosphate). ATP serves as the primary energy currency in cells and is used to fuel various cellular processes and activities.
the glucose is break down in the cell by 1)glycolysis 2)preparation of pyruvic acid 3) kreb's cycle or citric acid cycle or CAC or tricarboxylic acid cycle 4)oxidative phosphorylation and after that ATP is produced which is the energy currency of our body
The molecule with approximately 90 times the energy of ATP is phosphocreatine (PCr), which is used by cells to rapidly regenerate ATP during high-intensity activities like muscle contraction. PCr donates its high-energy phosphate group to ADP to form ATP in a reaction catalyzed by the enzyme creatine kinase.