Potential energy Spontaneous Coenzymes 1st Law of Thermodynamics Allosteric regulation Endergonic Kinetic energy Noncompetitive inhibitors Lowering activation energy Chemical, transport, mechanical Gibb’s free energy Chemical energy Enzyme inhibitors Quick, specific, re- useable Exergonic Metabolism Transition state - ΔG Cooperativity Heat Thermal energy Substrates Contorted to unstable state Catabolic 7.3 kcal/mol Anabolic Activation energy Metabolic pathway 2nd Law of Thermodynamics Temperature and acidity Equilibrium Thermo- dynamics Cofactors + ΔG ATP Enzyme Feedback inhibition Competitive inhibitors Negative Energy coupling Potential energy Spontaneous Coenzymes 1st Law of Thermodynamics Allosteric regulation Endergonic Kinetic energy Noncompetitive inhibitors Lowering activation energy Chemical, transport, mechanical Gibb’s free energy Chemical energy Enzyme inhibitors Quick, specific, re- useable Exergonic Metabolism Transition state - ΔG Cooperativity Heat Thermal energy Substrates Contorted to unstable state Catabolic 7.3 kcal/mol Anabolic Activation energy Metabolic pathway 2nd Law of Thermodynamics Temperature and acidity Equilibrium Thermo- dynamics Cofactors + ΔG ATP Enzyme Feedback inhibition Competitive inhibitors Negative Energy coupling
(Print)
Potential energy
Spontaneous
Coenzymes
1st Law of Thermodynamics
Allosteric regulation
Endergonic
Kinetic energy
Noncompetitive inhibitors
Lowering activation energy
Chemical, transport, mechanical
Gibb’s free energy
Chemical energy
Enzyme inhibitors
Quick, specific, re-useable
Exergonic
Metabolism
Transition state
- ΔG
Cooperativity
Heat
Thermal energy
Substrates
Contorted to unstable state
Catabolic
7.3 kcal/mol
Anabolic
Activation energy
Metabolic pathway
2nd Law of Thermodynamics
Temperature and acidity
Equilibrium
Thermo-dynamics
Cofactors
+ ΔG
ATP
Enzyme
Feedback inhibition
Competitive inhibitors
Negative
Energy coupling
