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📜 Product of citric acid cycle

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An exchange-traded commodity (ETC) is a form of protection that can provide traders and investors with exposure to commodities such as metals, oil, and livestock without having direct access to spot or derivatives commodities markets. An ETC can track a single commodity or a basket of commodities, and it can be a fun alternative to trading commodities in the futures market.
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🙄 Product of oxidative phosphory…

We’ll hear about the final stages of cellular respiration in this class. The electron transport chain completes the chemical reaction that converts our food into usable cellular energy by using products from the first two actions of glycolysis and the citric acid cycle.
The protons donated by NADH + H+ and FADH2 are now put to good use as the electrons move down the stairwell. Protein complexes I, III, and IV transport them to the other side of the inner mitochondrial membrane. They are transported from the mitochondrial matrix to the space between the inner and outer membranes of the mitochondria by active transport. They do this by harnessing the energy generated from electrons flowing down the electron transport chain’s stairwells.
The electron transport chain’s final’stair’ is oxygen. You were probably wondering when we’d put that to use, right? From the final protein complex, a single oxygen molecule accepts two electrons and two protons. This results in the formation of a water molecule. Why do we all need oxygen? To bring cellular respiration to a close! Synthesis of ATP Pumping all of these protons outside of the mitochondrial inner membrane produces a high concentration of protons between the inner and outer mitochondrial membranes, resulting in a proton concentration gradient. An enzyme called ATP synthase is used in the final step of the electron transport chain. This protein is found in the inner mitochondrial membrane as a channel protein. The protons rush back into the mitochondrial matrix through this pump at top speed, causing a portion of the enzyme to spin in circles like a whirling dervish. The final dance and song number of cellular respiration is given by this spinning motion. The phosphorylation of ADP is catalyzed by ATP synthase, which produces the final 28 molecules of ATP. What do you think about that for a final act? Summary of Cellular Respiration

📙 Electron transport chain summary

Cellular respiration is an aerobic (oxygen-dependent) mechanism that converts chemical energy from food into ATP. Glycolysis, the citric acid cycle (or Kreb’s cycle), and the electron transport chain are the three main phases of this chemical reaction. The inner mitochondrial membrane houses the electron transport chain.
We’ll hear about the final stages of cellular respiration in this class. The electron transport chain completes the chemical reaction that converts our food into usable cellular energy by using products from the first two actions of glycolysis and the citric acid cycle.
Within cells, there are hundreds of different chemical reactions. In this lesson, we’ll look at the pentose phosphate pathway, which is one of those reactions. Let’s look at what this reaction is, what it causes, and why it matters.
Many different measures can be used to diagnose and track diabetes. Can you recognize them? Do you know that there are long-term tests? As we go through tests like fructosamine, oral glucose tolerance, and more, you’ll find out!

🏅 Electron transport chain cellular respiration

In exergonic reactions, all cells use an electron transport chain (ETC) to oxidize substrates. The movement of electrons between the poles of a battery is analogous to the flow of electrons from reduced substrates through an ETC. The electron flow in a battery releases free energy to power a motor, lamp, mobile phone, and other devices. As reduced electrons (NADH, FADH2) are oxidized, electrons flow through the mitochondrial ETC. An ETC helps plants and other photosynthetic species oxidize NADPH (a phosphorylated version of the electron carrier NADH). When the redox reactions of an ETC are coupled to the active transport of protons (H+ ions) through a membrane, free energy is released in both situations. The effect is a pH gradient as well as a chemical gradient of H+ ions. The proton gradient is also an electrical gradient since protons are charged. We may assume, in a nutshell, that the free energy that used to be in reduced substrates is now in an electrochemical gradient. In the process known as oxidative phosphorylation, the gradient free energy is captured in ATP synthesis reactions coupled with the flow (diffusion) of protons back across the membrane. Electrons are moved from components at the end of the ETC to a final electron acceptor molecular oxygen, O2, in aerobic respiration, resulting in vapor. Electron transfer reduces CO2 to sugars during photosynthesis.

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