Term
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Definition
All biochemical events occuring in body at all times
1. Anabolism: build up; smaller molecules generate larger ones; ex: amino acids become proteins; prominent in growth/development
2. Catabolism: breakdown larger molecules--> smaller components; ex: glucose broken down to yield energy
3. Cellular (Internal) Respiration: purpose is to generate ATP; collection of catabolic events involved in breakdown of food products
4. Metabolic Flow: process of energy containing nutrients starting with digestion, passing to blood, and then to tissue; remainder broken down into ATP
Food--> ATP synthesis--> Existing Energy Stores |
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Term
Oxidation-Reduction (Redox) Reactions |
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Definition
-Oxidation: Gain O2 or lose H atoms/electrons
-Reduction: Lose O2 or gain H atoms/electrons
-Energy Transfer: energy is lost in the oxidized substance and gained by reduced substance
-Redox Enzymes: Dehydrogenases & oxidases
-Redox rxns require Cofactors; two types: NAD+ & FAD+ (derivatives of B vitamins Niacin & Riboflavin); these compounds transfer energy from one to another |
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Term
Substrate Phosphorylation Reactions |
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Definition
Direct phosphorylation; typically formation of ATP; to phosphorylize = activate something; Energy in phosphate bond; ex: X + P + ADP (+ enzyme) --> X + ATP |
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Term
Oxidative Phosphorylation Reactions |
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Definition
Mitochondrion: electron transport chain; mult-step process; indirect phosphorylation; requires O2 |
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Term
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Definition
Quickest sources of energy;
1. Stored ATP: in myosin head (pre-synthesized)
2. Creatine Kinase Reaction: substrate-level phosphorylation- Creatine + Phosphate + ADP --> ATP (& creatine left behind)
3. Glycolysis: glucose breakdown |
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Term
Glycolysis Location & Products Invested/Generated |
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Definition
-Location: Cytoplasm
-Products Invested: 1 molecule of Glucose (only partially broken down/oxidized); 2 ATP
-Products Generated: 2 Pyruvates (untapped energy), Net gain of 2 ATP (immediate energy), and 2 reduced forms of NAD+ (energy being transferred) |
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Term
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Definition
1. Sugar Activation: invest 2 ATP to activate (energize) glucose molecule (changes into fructose and phosphorylate)
2. Sugar Cleavage: break 6-carbon molecule into 2, 3-Carbon molecules (each carrying a phosphate)
3. Oxidation & ATP formation: extract energy out of glucose to get Net gain of 2 ATP; each molecule is oxidized (H atoms removed and transferred to NAD); forms 4 ATP from phosphorylation of 4 ADP |
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Term
Aerobic Respiration phases |
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Definition
In the mitochondria:
1. Conversion of 3C Pyruvate into 2C acetyl CoA (x2)
2. Krebs Cycle: Acetyl CoA broken down completely
3. Electron Transport Chain: extracts energy from reduced compounds & makes ATP |
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Term
Krebs Cycle Location & Products Invested/Generated |
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Definition
Location: Mitochondrial matrix
Products Invested:
Products Generated:
- 6 NADH + H+ (reduced cofactor)
- 2 FADH2 (reduced cofactor
- 2 ATP
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Term
Electron Transport Chain Location & Products Invested/Generated |
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Definition
-Location: Inner Mitochondrial Membrane
-Products Invested: reduced compounds;
-Products Generated: ~ 28 ATP & Water
*Process* removes H atoms from cofactors [NADH +H+] & [FADH2] and splits atom into proton [H+] & electron [e-]; e- passed down chain, energy from e- utilized to pump H+ into intermembrane space; creates concentration gradient of H+ outside of inner membreane and e- inside membrane; ATP synthase within membrane allows H+ ions to pass through along electrochemical gradient to mitochondrial matrix; Synthase harnesses this energy from diffusion to synthesize ATP as H+ diffuses across membrane and e- are picked up by O2 in mitochondria to form water with H+ |
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Term
Summary of Energy Produced |
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Definition
1. Glycolysis: 2 ATP (anerobic)
2. Krebs: 2 ATP (aerobic)
3. Electron Transport Chain: (aerobic)
-8 NADH + H+ from Krebs--> 24 ATP
-2 FADH2 from Krebs--> ATP
-2 NADH + H+ from Glycolysis--> 4-6 ATP
Total ATP from glucose ~ 32 |
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Term
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Definition
1. Anaerobic: does not require O2 to move forward; ex: creatine kinase reactions and glycolysis
2. Aerobic: does require O2; O2 is final electron acceptor in ETC
3. Anaerobic Threshold: during heavy exercise, an increase in blood lactate is seen; however, pyruvate is NOT converted to lactic acid instead of entering krebs cycle because of a lack of O2; O2 is present always in a healthy person; the reason for the buildup is because Krebs and ETC have slower velocity than glycolysis; therefore, creates back up of pyruvate which is then shuttled over to lactate to be used as fuel. This is NOT a conversion to anerobic production |
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Term
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Definition
Physiological inability to contract skeletal muscle
Causes:
- ATP prodcution fails to keep up pace with usage
- Psychological factors (don't feel like it)
- pH changes (lactic acid is an acid so pH drops, making enzymes less efficient)
- Neurological Transpission of AP, either through nerve or at neuromuscular junction itself
- Ionic imbalances (K+ loss)
- Mitochondrial function (chronic fatigue syndrome)
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Term
Excess Post-Exercise O2 Consumption |
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Definition
Panting; repayment of O2 debt; replenishment of oxygen reserves, glycogen stores, and ATP resynthesized |
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Term
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Definition
Only 20-25% efficient conversion of ATP bond energy converted to kinetic energy; remainder given off as heat |
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Term
Fuel Sources for ATP production |
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Definition
- Carbohydrates
- Lipids
- Proteins
Fuel Interconversion: Carbs, lipids, and proteins can be used as fuel for ATP production |
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Term
Carbohydrate Fuel sources |
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Definition
Glucose;
1. Glycogenesis: make glycogen from glucose
2. Glycogenolysis: break down glycogen to extract glucose
3. Gluconeogenesis: make new glucose from other source (ex: amino acid) |
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Term
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Definition
also used for fuel; products of breakdown can be fed into krebs & glycolysis pathways, where energy is extracted
1. Lipogenesis: storage of lipids
2. Lipolysis: break down of lipids to use as energy |
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Term
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Definition
Can also be used for fuel (usually in a starvation state)
1. Oxidation of Amino Acids
2. Protein Synthesis: making structures & enzymes to make cell function |
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