It has been proposed that the small volume of a dendritic spine can amplify Ca2+ signals during synaptic transmission. Accordingly, we have performed calculations to determine whether the activation of N-methyl-D-aspartate (NMDA) type glutamate receptors during synaptic transmission results in significant elevation in intracellular Ca2+ levels, permitting optical detection of synaptic signals within a single spine. Simple calculations suggest that the opening of even a single NMDA receptor would result in the influx of approximately 310 000 Ca2+ ions into the small volume of a spine, producing changes in Ca2+ levels that are readily detectable using high affinity Ca2+ indicators such as fura-2 or fluo-3. Using fluorescent Ca2+ indicators, we have imaged local Ca2+ transients mediated by NMDA receptors in spines and dendritic shafts attributed to spontaneous miniature synaptic activity. Detailed analysis of these quantal events suggests that the current triggering these transients is attributed to the activation of <10 NMDA receptors. The frequency of these miniature synaptic Ca2+ transients is not randomly distributed across synapses, as some synapses can display a >10-fold higher frequency of transients than others. As expected for events mediated by NMDA receptors, miniature synaptic Ca2+ transients were suppressed by extracellular Mg2+ at negative membrane potentials; however, the Mg2+ block could be removed by depolarization.