1 / 19

The Nervous Syste m

The Nervous Syste m. The Neuron. Two main cell types in the nervous system -> Neurons and Glial Cells Neurons transmit nerve messages Glial Cells surround Neurons and give rise to myelin 100 million Neurons in the Human brain alone. The Neuron.

jaimin
Download Presentation

The Nervous Syste m

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. The Nervous System

  2. The Neuron Two main cell types in the nervous system -> Neurons and Glial Cells Neurons transmit nerve messages Glial Cells surround Neurons and give rise to myelin 100 million Neurons in the Human brain alone

  3. The Neuron • The Neuron consists of three parts: Dendrites, Soma and the Axon • Dendrites receive information and transfer it to the soma • The Soma (or Cell Body) contains nucleus, mitochondria and other organelles • The Axon carries the message away from the soma

  4. The Neuron Three main types of neurons in the Human body: Sensory neurons, Motor neurons, and Interneurons. Sensory Neurons carry messages to the central nervous system Motor Neurons transmit messages from central nervous system to muscles and glands Interneuronsare only found in the central nervous system and connect neuron to neuron

  5. The Leaky Axon • Axons contain many ion channels used to transmit an electrical signal • These work to keep internal [K+] high and [Na+] low.

  6. Myelination • The majority of human neurons are encased in an electrically insulating material known as myelin (derived from glial cells) • Myelination greatly increases the conduction velocity of a neuron by covering many ion channels, allowing the current to “jump” from gap to gap. • This jumping process is known as Saltatory Conduction

  7. Myelination cntd... • The unmyelinated sections are known as the Nodes of Ranvier • These Nodes contain a high [ ] of ion channels, allowing for a massive influx of positive current. • This works to spread the signal down the neuron

  8. How DOES This Signal Travel? At rest, the intercellular space of a neuron has a negative charge A neuron can be stimulated to conduct a signal when it receives enough neurotransmitter from its neighbours. It responds by systematically opening ion channels, allowing an influx of Na+ ions which serves to depolarize the cell.

  9. Ion Channels Stimulated At rest • Inactivated

  10. The Action Potential (AP)

  11. AP cntd... • After an AP, the cell now contains more [Na+] than [K+]. • A pump known as Na/K/ATP-ase works to remove Na+ and bring in K+. • As seen above, the Na+ channel is briefly inactivated, meaning the neuron cannot undergo another AP until this resting period is over

  12. AP cntd... • When this signal reaches the axon terminal, it stimulates the release of neurotransmitter molecules into the synaptic cleft. • These neurotransmitters are taken up by the next neuron and the process repeats itself.

  13. AP cntd... • Once a neurotransmitter is taken up by the post-synaptic neuron, it stimulates that cell’s Na+ channels to open, leading to subsequent depolarization, providing that enough neurotransmitter is received. • This last part is very important; stay tuned.

  14. Synapse NOTE: The neuron releasing neurotransmitter is referred to as “pre-synaptic” while the neuron taking up neurotransmitter is “post-synaptic” • This is the connection between the nerve cells • The space between is called the synaptic cleft • Messages that travel inside the neuron are ‘electrical action potential,’ and neurotransmitters are required to cross the synaptic cleft

  15. Neurotransmitters • Very small molecules, sometimes hormones • Cross the synaptic cleft and join the receptor molecules on the next cell • Used neurotransmitters are taken back into the axon and recycled by the cell

  16. All Or Nothing Principle • Neurons are highly branched at their terminus. One AP can thus release neurotransmitter at many synapses. • In turn, one dendrite may receive input from many axons. • As such, a single burst of neurotransmitter is often not enough to stimulate the post-synaptic neuron to AP.

  17. All Or Nothing cntd... • If enough neurotransmitter is received, then sufficient Na+ channels will open, allowing the cell to depolarize past its threshold level and generate its own AP. • If this threshold level is not met, then the neuron will NOT generate an AP • Once this threshold is crossed, the neuron will ALWAYS generate an AP

  18. All Or Nothing cntd... • The post-synaptic neuron can receive enough input in one of two ways: • Temporal Summation – The pre-synaptic neuron generates enough APs in a given time span that they summate (ie. “add together”) and stimulate the post-synaptic neuron. • Spatial Summation – The post-synaptic neuron receives input from multiple cells which push it past the threshold, generating an AP.

  19. All Or Nothing cntd...

More Related