Adenosine and brain function

BB Fredholm, JF Chen, RA Cunha… - Int Rev …, 2005 - books.google.com
BB Fredholm, JF Chen, RA Cunha, P Svenningsson, JM Vaugeois
Int Rev Neurobiol, 2005books.google.com
A. Cellular and Subcellular Localization B. Pharmacological Tools to Study Adenosine
Receptors C. Signaling Via Adenosine Receptors D. Regulation of Receptor Expression and
Signaling IV. Functions of Adenosine Receptors A. Regulation of Nerve Activity B.
Regulation of Transmitter Release C. Other Functions D. Interaction with Other Transmitter
Systems V. Adenosine–Dopamine Interactions in Brain A. General Considerations B.
Heterodimerization of Adenosine–Dopamine Receptors as a Molecular Basis for Direct …
A. Cellular and Subcellular Localization B. Pharmacological Tools to Study Adenosine Receptors C. Signaling Via Adenosine Receptors D. Regulation of Receptor Expression and Signaling IV. Functions of Adenosine Receptors A. Regulation of Nerve Activity B. Regulation of Transmitter Release C. Other Functions D. Interaction with Other Transmitter Systems V. Adenosine–Dopamine Interactions in Brain A. General Considerations B. Heterodimerization of Adenosine–Dopamine Receptors as a Molecular Basis for Direct Receptor–Receptor Interaction in the Striatum C. Endogenous Adenosine Acting on A2A Receptors Can Also Exert Excitatory Tone on Striatal Neurons by D2 Receptor–Independent Mechanisms D. DARPP-32 as a Potential Molecular Target for Integrating Adenosine and Dopamine Signaling at the Cellular and Network Levels in the Striatum VI. Phenotypes of Knockout Mice VII. Adenosine Receptors and Protection against Ischemic and Excitotoxic Brain Injuries A. A1 Receptor Activation Produces Predominantly Neuroprotective EVects B. Blockade or Inactivation of A2A Receptors OVers Neuroprotection C. Neuroprotection by A2A Receptor Agonists May Be Mediated through Modulation of Inflammation
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