Synaptic cleft: Difference between revisions

A Synaptic cleft is the gap between the [[Presynaptic membrane|presynaptic membrane]]&nbsp;and the [[Postsynaptic membrane|postsynaptic membrane]]&nbsp;of [[Neurones|neurones]], it is used to transfer a signal triggered by [[Action Potentials|Action Potentials]]&nbsp;through the body to initiate a response from a stimulus. This gap is approximately 50 nm in size.&nbsp;<ref>Jeremy M. Berg et al. Biochemistry, 6th edition, 2007, W.H Freeman and Company, New York. Chapter 13 – Membrane channels and pumps, page 370.</ref> The process begins when an Action Potential is initiated that exceeds threshold potential and&nbsp;[[Depolarises|depolarises]]&nbsp;the presynaptic membrane causing the&nbsp;[[Voltage-gated Calcium channels|Voltage-gated Calcium&nbsp;channels]]&nbsp;to open. This in turn causes an influx of [[Calcium|calcium]]&nbsp;[[Ions|ions]]&nbsp;and&nbsp;causes the [[Synaptic Vesicles|Synaptic Vesicles]] to fuse with the [[Presynaptic membrane|Presynaptic membrane]] by [[Exocytosis|Exocytosis]]&nbsp;allowing the&nbsp;[[Neurotransmitter|neurotransmitter]]&nbsp;within the&nbsp;[[Vesicles|vesicles]]&nbsp;diffuses across the Synaptic Cleft and bind to the receptors on the post-synaptic membrane. This causes the voltage gated ion channels to open, which depolarise the neurone. Drugs and hormones also act on receptors/ vesicles e.c.t in the cleft, which allows regulation of the signal.&nbsp;If there was no synaptic cleft, there would be no transport medium for the transfer of [[Neurotransmitters|neurotransmitters]]&nbsp;from one neurone to the next.