The perhaps 1011 neurons in the human brain are specialized for receiving, integrating, and sending signals.
Neurons can be classified according to location, target, geometry, and number of processes.
Prinicpal neurons have long axons that connect to othe rparts of the nervous system.
Neurons receive information from up to tens of thousands of other neurons, processing and integrating them into a single new message. Neurons also have the capacity to remember information that flows through them.
The cell body, or perikaryon, contains the nucleus, protein-synthesizing machinery, and microtubules for their transplrt.
Dendrites are the primary site for a cell to receive information. They are full of receptors that respond to neurotransmitters. Excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs) combine in a graded manner. The sum of these signals is communicated to the cell body, where other inputs are communicated. Once threshold is reached, action potentials fire. Their timing is used to communicate a cell's thoughts.
Some dendrites, such as those of Purkinje cells in the cerebellum, have voltage-gated Ca2+ channels and can produce action potentials.
Axons are long (up to 1m) projections that leave the cell body. They begin in an unmyelinated initial segment.
The typical axon contains up to 1000x cytoplasm as the cell body and thus has special mechanisms to sustain it. It is packed with microtubules and microfilaments that provide stability and a means to rapidly transport materials to and from the cell body.
Some axons are covered with myelin, greatly increasing signal speed.
Materials are transported down axons in vesicles along microtubules with the help of a motor protein called kinesin at up to 1m/day, in an ATP-dependent manner. Soluble proteins move down neurofilament and microtubules much more slowly, at 1-5 mm/day.
Dyenin moves material from the axon terminal back to the cell body.
There is bidirectional communication at almost every synapse to maintain or modulate synaptic activity.
Synapses are located on the cell body and dendrites.
At the Neuromuscular Junction (NMJ) the whole thing is encased by Schwann cells.
ACh esterase is attached to the basal lamina in synaptic invaginations.
Calcium release induces vesicle fusion with the membrane, mediated by SNARE proteins. Botulinum and tetanus toxins paralyze SNARE proteins (check)
presynaptic inhibition (often GABAB receptors) can occur via phosphorylation of calcium channels, preventi
The post-synaptic membrane is frequently amplified through invagination or outfolding of the membrane. This significantly increases the receptor surface area.
ACh Receptors are affected in the autoimmune disease Myasthenia gravis; curare also affects the AChR.
a fast epsp is 10 ms
ionotropic mechanisms (fast)
the receptor is the channel
metabotropic mechanisms
coupled to a G protein and any number of signaling mechanisms (typically IP3, cAMP, and the alpha subunit of the G protein)
drugs or toxins that depress transmission
6 connexins form a hemichannel, while a hemichannel in each cell form a gap junction channel