Lecture 3 - personal.kent.edu
... B. Drug metabolism VI. Tolerance A. Cross tolerance B. Tolerance develops to some chars (effects) but not others C. Types of tolerance 1. decreased drug binding (sequestering) 2. binding has less effect 3. membrane loses permeability 4. tolerance due to learning -conditioned compensatory responses V ...
... B. Drug metabolism VI. Tolerance A. Cross tolerance B. Tolerance develops to some chars (effects) but not others C. Types of tolerance 1. decreased drug binding (sequestering) 2. binding has less effect 3. membrane loses permeability 4. tolerance due to learning -conditioned compensatory responses V ...
mechanisms for activation and inactivation of endorphins
... The concept that the population of receptor sites for the enkephalins and endorphins is heterogeneous, is based on the following experimental approaches. When the peptides are assayed in two pharmacological and two binding models, the rank order of activity differs in the four systems. The antagonis ...
... The concept that the population of receptor sites for the enkephalins and endorphins is heterogeneous, is based on the following experimental approaches. When the peptides are assayed in two pharmacological and two binding models, the rank order of activity differs in the four systems. The antagonis ...
Hypertension
... angiotensin inhibitors Most effective in patients with elevated plasma renin levels (but this condition is rare) Still effective in hypertensive patients with normal or even low levels of renin Useful for treating hypertension associated with other cardiovascular risk factors, like heart failu ...
... angiotensin inhibitors Most effective in patients with elevated plasma renin levels (but this condition is rare) Still effective in hypertensive patients with normal or even low levels of renin Useful for treating hypertension associated with other cardiovascular risk factors, like heart failu ...
ppt
... [LR] Rate of reaction proportional to [ ] reactants K1=[L]*[R] K2=[LR] At equilibrium, k1=k2. Substituting, k1/k2=[L]*[R]/[LR]=kD, the equilibrium dissociation constant ...
... [LR] Rate of reaction proportional to [ ] reactants K1=[L]*[R] K2=[LR] At equilibrium, k1=k2. Substituting, k1/k2=[L]*[R]/[LR]=kD, the equilibrium dissociation constant ...
