During cellular respiration, the substrate is oxidized by losing electrons and reduced by gaining electrons in a series of redox reactions.
NAD is reduced during cellular respiration.
NADH is reduced compared to NAD+ because it gains electrons and a hydrogen ion to form NADH during cellular respiration. In this process, NAD+ acts as an electron carrier that accepts electrons and a hydrogen ion from substrates being oxidized, converting it to NADH.
The reactant that is oxidized in respiration is glucose. Glucose is broken down through a series of biochemical reactions to release energy in the form of ATP, and in the process, it loses electrons, which is characteristic of oxidation.
A fully reduced molecule would be a better cellular energy source because it has more energy stored in its chemical bonds compared to a fully oxidized molecule. Oxidation leads to the release of energy stored in chemical bonds, while reduction stores energy in those bonds.
In photosynthesis, the carbon dioxide molecules are being reduced, while the water molecules are being oxidized In photosynthesis, the carbon dioxide molecules are being reduced, while the water molecules are being oxidized
NAD is reduced during cellular respiration.
NAD is reduced to NADH during cellular respiration.
Glucose is. In cell respiration, the carbon atoms of glucose are oxidized.
Yes, NADH is oxidized to NAD during cellular respiration.
Glucose is oxidized in cellular respiration to produce energy in the form of ATP. During the process, glucose is broken down into carbon dioxide and water, releasing electrons that are used in the electron transport chain to generate ATP.
yes it is oxidized substrate reduces itself and oxidize others
During cellular respiration, glucose gets oxidized to form carbon dioxide and water, while oxygen gets reduced to form water. Glucose loses electrons and hydrogen atoms, which are transferred to oxygen during the process, resulting in the reduction of oxygen to water.
because they become oxidized and reduced when glucose is broken down in photosynthesis and cellular respiration.
Yes, NAD is reduced to NADH during cellular respiration.
NADH is reduced compared to NAD+ because it gains electrons and a hydrogen ion to form NADH during cellular respiration. In this process, NAD+ acts as an electron carrier that accepts electrons and a hydrogen ion from substrates being oxidized, converting it to NADH.
The reactant that is oxidized in respiration is glucose. Glucose is broken down through a series of biochemical reactions to release energy in the form of ATP, and in the process, it loses electrons, which is characteristic of oxidation.
The oxidized form of Nicotinamide Adenine Dinucleotide (NAD) is NAD+. NAD+ is a coenzyme involved in redox reactions, accepting electrons and becoming reduced to NADH. NAD+ plays a crucial role in cellular respiration and energy production in organisms.