Nervous System IB Biology
Nervous System In order to survive and reproduce an organism must respond rapidly and appropriately to environmental stimuli in order to send the “right” messages at the “right” time to the “right” places. The nervous system provides a “speedy” communication system so the organism can quickly respond to internal and external stimuli.
The Neuron Neuron = Nerve cell – Functional unit of the nervous system Receives incoming messages and sends it to the cell body Plays role in summation and transmission of the signal Conveys outgoing message to other cells (neurons/muscles/glands) Insulating layer that helps propagate the signal Release neurotransmitters into the synapse (space between neuron and effector cell)
The Synapse Connects presynaptic and postsynaptic cells
3 overlapping functions of NS
The Brain (integration) … cerebrum Reasoning, Problem Solving Sends commands to skeletal muscle Receives and integrates signals from touch, pain, pressure, and temperature receptors The proportion of somatosensory or motor cortex devoted to a particular part of the body is correlated with the relative importance of sensory or motor information for that part of the body
The Homunculus This homunculus, or “little human”, is a visual representation that shows the connection between different body parts and brain devotion to those areas. The bigger the body parts in the picture or model, the more brainpower there is dedicated to detecting sensatory input received by the somatosensory cortex.
3 overlapping functions
Central and Peripheral NS 1)Sensory Input PNS – sensory receptors detect stimuli 2)Integration CNS (Brain and spinal cord) makes an interpretation and association with appropriate response 3)Motor output PNS – motor receptors to effector cells (muscle cells or glands)
Reflex vs. Response
Glial Cells Astrocytes – Structural and metabolic support – Tight junctions (blood brain barrier) Oligodendrocytes – Form insulating myelin sheaths around axons in the CNS Schwann cells – Form insulating myelin sheaths around axons in the PNS
Membrane Potential Arises from: 1)Difference in ion concentration on the inside and outside of the cell membrane 2)Selective permeability of the membrane
Excitable Cells Cells that have the ability to generate large changes in their membrane potentials. May result in an electrical impulse Examples: – Neurons – Muscles
Which way do the ions “want” to diffuse? Based on Concentration Sodium wants to go in Potassium wants to go out Based on Charge Sodium wants to go in Potassium wants to go in If Potassium were the only ion that could cross the membrane, which way would K + go and what would be the result in terms of membrane potential? It would become about – 85 mV. This is when the influx of K + down the electrical gradient is equal to the efflux of K + down its concentration gradient.
Action Potential (Nerve Impulse) This is an “all or nothing response” “Gated” ion channels open and close in response to stimuli (pressure, light, chemical) – Only one kind of ion can pass through – Chemically-gated ion channels – Voltage-gated ion channels
Action Potential Nerve impulse Strong enough stimulus causes depolarization to reach threshold
Resting Potential (-70 mV inside)
Activation Gate opens due to stimulus
Voltage gated channels open: more Sodium (Na + ) gates open in response to less negative charge
Potassium (K + ) channels open (voltage gated channel) Inactivation gate (Na + ) closes in response to voltage
Undershoot = refractory (sodium channels are closed … no more action potentials)
How does a neuron get back to it’s resting state where there is more Sodium outside and Potassium inside? Sodium – Potassium Pump 3 Na + out and 2 K + in Requires ATP!
Action Potential reaches the end of the axon /basics/basics-2.html /basics/basics-2.html
Nerve Impulse reaches synaptic terminal Depolarization causes voltage-gated Ca 2+ channels to open Ca 2+ enters the nueron and triggers synaptic vesicles to move to presynaptic membrane The vesicles release neurotransmitters into the synapse
Note: Voltage sensitive calcium channels open at the axon terminals and cause the synaptic vesicles to release neurotransmitters.
Neurotransmitters Relay Information If the neurotranmitter binds to and opens a Na+ channel, what will happen? – Depolarization … AP If the neurotransmitter binds to and opens a K+ channel, what will happen? – Hyperpolarization … no AP
When does the AP domino effect end? When it reaches a muscle or gland for a response.
What causes one stimulus to be stronger than another? More Action Potentials in the same amount of time.
Responding to Stimulus Hyperpolarization – becomes even more negativeDepolarization – becomes less negative Threshold – charge required to create action potential
Definitions: a)presynaptic cell before synapse b)postsynaptic cell after synapse c)synaptic cleft separates pre/post d)synaptic vesicle contains neurotransmitters e)neurotransmitter chemical messenger released into synapse f)presynaptic membrane synaptic terminal that faces the cleft g)postsynaptic membrane cell body or dendrite on other side of synapse