The present book is the outcome of a symposium on magnesium and excitable membranes, held in September 1989 on the occasion of the 12th annual meeting of the European Neuroscience Associ ation in Torino. Leading specialists from around the world met in order to discuss the physiological and clinical effects of magne sium on excitable cells. Magnesium ions are known to playa key role in the regulation of a variety of cell functions and, as such, have been implicated in the control of neuronal excitability and cardiovascular diseases. In the last decade, the advent of new electro physiological techniques has provided important details on the modulatory action of mag nesium on ion channels and the receptor proteins of neurotrans mitters. Thus, in neuronal and muscle cells, extracellular and in is shown to block ion passage through open tracellular magnesium channels in a voltage- and time-dependent manner. The mecha nism appears to be common for voltage- and receptor-operated channels, and it is thought to be an important cofactor in the long-term potentiation of synaptic transmission, brain aging, and cardiac activity. Recent findings show that the action of internal magnesium has additional features. High and low affinity sites for internal magnesium are involved in the regulation of channel gat ings and ion permeation. Biochemical studies suggest that internal magnesium interferes with G-protein subunits, GTP-ase activity, and second messengers involved in channel phosphorylation.

Use of Ion Selective Microelectrodes to Measure Intracellular Free Mg2+

Voltage-Gated Ionic Channels: Diversity and Modulation by Mg2+
ATP-Dependent K+ Channels of Excitable Membranes
Voltage-Dependent Blockage of Cardiac Inwardly Rectifying K+ Channels by Internal Mg2+
Regulation of the Voltage-Gated Ca2+ Current by Intracellular Free Mg2+ Studied by Internal Perfusion of Single Cardiac Myocytes
Blockage of Neuronal Low-Threshold Ca2+ Channels by Extracellular Mg2+
Dual Blockage by Mg2+ of the N-Methyl-D-Aspartate-Activated Channel
Excess Mg2+ and Central Nervous System Metabolism
Mg2+ in Neurotrauma: Its Role and Therapeutic Implications.