gluconeogenisis.
what is part of it: Glycolysis, Krebs cycle, and the ETC and oxidative phosphorylation.
The oxidation number of carbon in glucose is +4. This is because in glucose (C6H12O6), each oxygen atom has an oxidation number of -2 and each hydrogen atom has an oxidation number of +1, so the carbon atoms must have an oxidation number of +4 in order to balance the overall charge of the molecule.
The oxidation number of carbon (C) in glucose is +4. This is because in glucose (C6H12O6), each carbon atom is bonded to one oxygen atom, and oxygen is more electronegative than carbon, resulting in a higher oxidation state for carbon.
In glucose (C6H12O6), the oxidation number of carbon is +4 or -4, oxygen is -2, and hydrogen is +1. The overall charge of the molecule is neutral.
Glucose getconvertedto carbon bi oxide and water molecule, during oxidation in both the biological oxidation and chemical oxidation. One glucose molecule gives 6 carbon bi oxide and 6 water molecules.(C6H12O6 + 6 O2 = 6 CO2 + H2O.) In biological oxidation glucose is broken down in step wise manner. In about 22 steps, energy is released. So cell does not get burned due to sudden release of energy. So this is like, you come down from the two story building via staircase, step by step. So you do notinjure yourself. In chemical oxidation glucose burn in one step only. So it is like jumping from the two story building. You will get injured. In biological oxidation, you get the intermediate products of low energy. (At few times high energy.) As ultimate products of both biological oxidation and chemical oxidation are same, the energy released is same. Not a photon more or less, provided temperature of glucose and temperature and pressure of end products is same. In biological oxidation, you get some energy stored in body in the form of ATP molecules. Which is utilized for various metabolic processes, required by cell. Rest is released in the form of heat. That is also useful to maintain body temperature. This is in accordance to the Law ofconservationof energy in chemical reactions. It remains constant and can change the form of energy.
Beans
The common pathway for oxidation of products of glucose and fatty acids catabolism is the citric acid cycle (also known as the Krebs cycle). In this cycle, acetyl-CoA derived from both glucose (from glycolysis) and fatty acids (from beta-oxidation) is oxidized to produce NADH and FADH2, which are then used to generate ATP through oxidative phosphorylation in the electron transport chain.
NADPH is the key reducing agent formed in the pentose phosphate pathway during glucose oxidation. NADPH is used to fuel biosynthetic pathways and antioxidant defenses in the cell.
The oxidation pathway for breakdown of food into ATP occurs primarily in the mitochondria of cells. This process involves the breakdown of glucose and other nutrients through a series of reactions that ultimately lead to the production of ATP through the electron transport chain and oxidative phosphorylation.
Glycolysis
The oxidation number of carbon in glucose is +4. This is because in glucose (C6H12O6), each oxygen atom has an oxidation number of -2 and each hydrogen atom has an oxidation number of +1, so the carbon atoms must have an oxidation number of +4 in order to balance the overall charge of the molecule.
No. The oxidation of glycogen yields more energy than glucose. You need to put energy in formation of the glycogen from glucose. Naturally, this energy is released, when you get get glucose from glycogen.
by malate aspartate pathway
The oxidation number of carbon (C) in glucose is +4. This is because in glucose (C6H12O6), each carbon atom is bonded to one oxygen atom, and oxygen is more electronegative than carbon, resulting in a higher oxidation state for carbon.
6o2 + c6h12o6 ---> 6co2 + 6h2o
In glucose (C6H12O6), the oxidation number of carbon is +4 or -4, oxygen is -2, and hydrogen is +1. The overall charge of the molecule is neutral.
The complete oxidation of one molecule of glucose produces 36-38 ATP. Therefore, the complete oxidation of 3 molecules of glucose would produce 108-114 ATP in total.
krebs cycle