The electrophysiology of adenosine in the mammalian central nervous system
2.1. 2. Voltage sensitivity 2.1. 3. Effects of calcium and potassium antagonists 2.2.
Modulation of calcium and voltage dependent potassium currents 2.2. 1. Enhancement of
calcium dependent potassium current 2.2. 2. Lack of effect on IA and IQ 2.3. Indirect effects
on calcium current 3. Inhibition of evoked synaptic potentials 3.1. Site of action 3.2.
Mechanism of action 4. Mediators of electrophysiological effects 4.1. Receptor subtypes 4.1.
1. Postsynaptic responses 4.1. 2. Presynaptic responses 4.2. Second messengers 5 …
Modulation of calcium and voltage dependent potassium currents 2.2. 1. Enhancement of
calcium dependent potassium current 2.2. 2. Lack of effect on IA and IQ 2.3. Indirect effects
on calcium current 3. Inhibition of evoked synaptic potentials 3.1. Site of action 3.2.
Mechanism of action 4. Mediators of electrophysiological effects 4.1. Receptor subtypes 4.1.
1. Postsynaptic responses 4.1. 2. Presynaptic responses 4.2. Second messengers 5 …
2.1. 2. Voltage sensitivity 2.1. 3. Effects of calcium and potassium antagonists 2.2. Modulation of calcium and voltage dependent potassium currents 2.2. 1. Enhancement of calcium dependent potassium current 2.2. 2. Lack of effect on IA and IQ 2.3. Indirect effects on calcium current 3. Inhibition of evoked synaptic potentials 3.1. Site of action
3.2. Mechanism of action 4. Mediators of electrophysiological effects 4.1. Receptor subtypes 4.1. 1. Postsynaptic responses 4.1. 2. Presynaptic responses 4.2. Second messengers 5. Electrophysiolosy of endogenous adenosine 5.1. Antagonist evoked excitation 5.2. Antagonism of uptake and increased catabolism 5.3. Effects in low calcium, high magnesium 6. Activity in pathophysiological states 6.1. Epilepsy
Elsevier