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