A growing number of studies now suggest that the cellular mechanisms which normally participate in signaling in the central nervous system (CNS) can be transformed by disease into instruments of neuronal cell destruction. Excitatory synaptic transmission in the mammalian CNS is principally mediated by L-glutamate. In fact, glutamate excites virtually all central neurons and is present in nerve terminals at millimolar levels (Curtis and Johnston, 1974). Normally, the extracellular levels of glutamate rise to high levels only in the brief and spatially localized fashion appropriate to synaptic transmission. This is fortunate, because as Lucas and Newhouse first showed in 1957, sustained exposure to glutamate can destroy retinal neurons. In a subsequent set of pioneering experiments, Olney (Olney and Sharpe, 1969; Olney et al., 1971) established that this toxicity, which he later called excitotoxicity, was not unique to glutamate or to retinal neurons, but was a feature common to the actions of all excitatory amino acids on central neurons. He postulated therefore that glutamate, or related compounds, might be the cause of the neuronal cell loss found in certain neurological diseases. In recent years, this hypothesis has gathered considerable support, fueled by new insights into glutamate receptor function and the development of effective glutamate antagonist drugs. The evidence is most convincing in diseases involving an acute insult to the brain, as occurs in a stroke, with abrupt deprivation of blood supply. But neurotoxicity due to excitatory amino acids may also be involved in slowly progressive degenerative diseases such as Huntington’s disease. Although the detailed molecular basis of glutamate neurotoxicity is not known, it appears that Ca2+ influx may play a critical role.