The connections between neurons in the brain are much more complex than those of the
artificial neurons used in the
connectionist neural computing models of
artificial neural networks. The basic kinds of connections between neurons are
synapses: both
chemical and
electrical synapses. The establishment of synapses enables the connection of neurons into millions of overlapping, and interlinking neural circuits. Presynaptic proteins called
neurexins are central to this process. One principle by which neurons work is
neural summation –
potentials at the
postsynaptic membrane will sum up in the cell body. If the
depolarization of the neuron at the
axon hillock goes above threshold an action potential will occur that travels down the
axon to the terminal endings to transmit a signal to other neurons. Excitatory and inhibitory synaptic transmission is realized mostly by
excitatory postsynaptic potentials (EPSPs), and
inhibitory postsynaptic potentials (IPSPs). On the
electrophysiological level, there are various phenomena which alter the response characteristics of individual synapses (called
synaptic plasticity) and individual neurons (
intrinsic plasticity). These are often divided into short-term plasticity and long-term plasticity. Long-term synaptic plasticity is often contended to be the most likely
memory substrate. Usually, the term "
neuroplasticity" refers to changes in the brain that are caused by activity or experience. Connections display temporal and spatial characteristics. Temporal characteristics refers to the continuously modified activity-dependent efficacy of synaptic transmission, called
spike-timing-dependent plasticity. It has been observed in several studies that the synaptic efficacy of this transmission can undergo short-term increase (called
facilitation) or decrease (
depression) according to the activity of the presynaptic neuron. The induction of long-term changes in synaptic efficacy, by
long-term potentiation (LTP) or
depression (LTD), depends strongly on the relative timing of the onset of the
excitatory postsynaptic potential and the postsynaptic action potential. LTP is induced by a series of action potentials which cause a variety of biochemical responses. Eventually, the reactions cause the expression of new receptors on the cellular membranes of the postsynaptic neurons or increase the efficacy of the existing receptors through
phosphorylation. Backpropagating action potentials cannot occur because after an action potential travels down a given segment of the axon, the
m gates on
voltage-gated sodium channels close, thus blocking any transient opening of the
h gate from causing a change in the intracellular sodium ion (Na+) concentration, and preventing the generation of an action potential back towards the cell body. In some cells, however,
neural backpropagation does occur through the
dendritic branching and may have important effects on synaptic plasticity and computation. A neuron in the brain requires a single signal to a
neuromuscular junction to stimulate contraction of the postsynaptic muscle cell. In the spinal cord, however, at least 75
afferent neurons are required to produce firing. This picture is further complicated by variation in time constant between neurons, as some cells can experience their
EPSPs over a wider period of time than others. While in synapses in the
developing brain synaptic depression has been particularly widely observed it has been speculated that it changes to facilitation in adult brains. == Development ==