5.1.3

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    Created by
    Anisah Yusuf

    Cards (50)

    • Sensory receptors
      Groups of specialised cells that detect changes in the surroundings and convert them to neuronal signals by initiating or changing the frequency of action potentials
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    • Sensory receptors
      • Rods and cones in the eye (photoreceptors)
      • Chemoreceptors, such as the olfactory receptors in the nose
      • Thermoreceptors in the end-bulbs of Krause in the tongue
      • Vibration receptors in the cochlea of the ear
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    • Pacinian corpuscle
      A mechanoreceptor—detecting pressure and movement—found in the epidermis of the skin. It comprises a neuron with concentric layers of connective tissue. When pressure is placed on the skin, this deforms the layers of connective tissue, and because the membrane of the neuron contains stretch-mediated sodium ion channel, the neuron is depolarised when the connective tissue is deformed, generating a generator potential, which, by positive feedback, will generate an action potential which is transmitted along neurones to the central nervous system.
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    • Sensory neurons
      • Carry the action potential from a sensory receptor to the central nervous system. They have a long dendron carrying the action potential from a sensory receptor to the cell body, which is position just outside the CNS. They have a short axon carrying the action potential into the CNS.
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    • Relay neurons
      • Connect sensory and motor neurons, mainly in the central nervous system. They have many short dendrites to receive impulse transmissions from a number of sensory receptors and a short axon with variable numbers of synaptic endings to carry the action potential to the cell bodies of motor neurones in the CNS.
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    • Motor neurons
      • Carry an action potential from the central nervous system to an effector such as cells in a muscle or gland. They have their cell body in the CNS and have a long axon that carries the action potential to effector cells.
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    • Cell body
      Contains the nucleus, surrounded by cytoplasm containing large amounts of endoplasmic reticulum and mitochondria to produce neurotransmitters used at the synapses of all three neurones.
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    • Dendrons
      Short extensions which carry action potentials toward the cell body where dendrites of relay neurons synapse with sensory receptors, or relay neurons synapse with motor neurones.
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    • Axons
      Singular, elongated nerve fibres that carry action potential potentially long distances away from the cell body.
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    • Peripheral neurones in vertebrates
      • Are myelinated. Most sensory and motor neurones are associated with many Schwann cells which wrap around the neurone creating a multi-layered fatty sheath, which insulates the neurone from adjacent ones, and preventing the membrane from depolarising. Every 1-3 mm, there are gaps in the myelin sheath—the nodes of Ranvier, where the membrane can be depolarised.
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    • Neurones in the CNS and unmyelinated peripheral neurones
      • Are associated with Schwann cells, but several neurones may be enshrouded in one loosely-wrapped Schwann cell, insulting adjacent neurones, but not the axonal membrane.
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    • Resting potential
      At -70mV across the membrane, caused by the movement of sodium and potassium ions across the axonal membrane, with the sodium-potassium pump actively transporting three sodium ions out of the axon for every two potassium ions that are pumped in.
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    • Action potential generation
      1. Stimulus detected by sensory receptor
      2. Temporary depolarisation of axonal membrane
      3. Voltage-gated sodium ion channels open
      4. Sodium ions diffuse into axon
      5. Positive feedback loop further depolarises membrane
      6. Voltage-gated sodium ion channels close, voltage-gated potassium ion channels open
      7. Potassium ions diffuse out of axon, repolarising membrane
      8. Sodium-potassium pump restores resting potential
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    • Threshold
      +40mV, the potential difference at which an action potential is generated
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    • Action potential propagation
      1. Depolarisation acts as stimulus for depolarisation further down axon
      2. Sodium ions diffuse laterally, creating local current
      3. Voltage-gated sodium ion channels open, generating next action potential
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    • Refractory period
      Period after an action potential is generated where another cannot be generated, due to high internal sodium ion concentration and external potassium ion concentration
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    • Saltatory conduction
      In myelinated neurons, the action potential 'jumps' from node of Ranvier to node of Ranvier, increasing transmission speed
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    • Factors affecting transmission speed
      • Wider axon diameter
      • Higher temperature (before denaturation)
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    • All-or-nothing principle
      Action potentials are either generated at threshold or not at all, but their intensity is communicated by frequency
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    • Synapse
      Junction between two or more neurones, where one neurone can communicate an action potential across the 20nm-wide synaptic cleft using neurotransmitters
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    • Cholinergic synapse structure
      • Pre-synaptic bulb contains vesicles of acetylcholine and voltage-gated calcium channels
      • Post-synaptic membrane contains acetylcholine-responsive sodium ion channels
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    • Synaptic transmission
      1. Action potential depolarises pre-synaptic membrane
      2. Calcium ions diffuse into pre-synaptic bulb
      3. Acetylcholine-containing vesicles fuse with membrane, releasing acetylcholine
      4. Acetylcholine binds to post-synaptic receptors, opening sodium ion channels
      5. Sodium ions diffuse into post-synaptic neurone, depolarising membrane
      6. Acetylcholinesterase hydrolyses acetylcholine in synaptic cleft
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    • Summation
      Several excitatory post-synaptic potentials must combine to reach threshold and generate an action potential, either through temporal summation or spatial summation
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    • Inhibitory post-synaptic potentials
      Reduce the effect of summation and prevent an action potential in the post-synaptic neurone
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    • Sensory receptors
      Groups of specialised cells that detect changes in the surroundings and convert them to neuronal signals by initiating or changing the frequency of action potentials
      View source
    • Transducers
      Convert one type of energy, or a change in the magnitude of frequency of a type of energy, and converting it to chemical, and then electrical, energy
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    • Sensory receptors
      • Rods and cones in the eye (photoreceptors)
      • Chemoreceptors, such as the olfactory receptors in the nose
      • Thermoreceptors in the end-bulbs of Krause in the tongue
      • Vibration receptors in the cochlea of the ear
      View source
    • Pacinian corpuscle
      • A mechanoreceptor—detecting pressure and movement—found in the epidermis of the skin
      • Comprises a neuron with concentric layers of connective tissue
      • When pressure is placed on the skin, this deforms the layers of connective tissue, and because the membrane of the neuron contains stretch-mediated sodium ion channel, the neuron is depolarised when the connective tissue is deformed, generating a generator potential, which, by positive feedback, will generate an action potential which is transmitted along neurones to the central nervous system
      View source
    • Sensory neurons
      Carry the action potential from a sensory receptor to the central nervous system
      View source
    • Relay neurons
      Connect sensory and motor neurons, mainly in the central nervous system
      View source
    • Motor neurons
      Carry an action potential from the central nervous system to an effector such as cells in a muscle or gland
      View source
    • Neuron structures
      • Cell body
      • Dendrons
      • Axons
      View source
    • Cell body
      Contains the nucleus, surrounded by cytoplasm containing large amounts of endoplasmic reticulum and mitochondria to produce neurotransmitters used at the synapses
      View source
    • Dendrons
      Short extensions which carry action potentials toward the cell body where dendrites of relay neurons synapse with sensory receptors, or relay neurons synapse with motor neurones
      View source
    • Axons
      Singular, elongated nerve fibres that carry action potential potentially long distances away from the cell body
      View source
    • Peripheral neurones in vertebrates
      • Myelinated
      • Most sensory and motor neurones are associated with many Schwann cells which wrap around the neurone creating a multi-layered fatty sheath, which insulates the neurone from adjacent ones, and preventing the membrane from depolarising
      • Every 1-3 mm, there are gaps in the myelin sheath—the nodes of Ranvier, where the membrane can be depolarised
      View source
    • Neurones in the CNS and unmyelinated peripheral neurones
      • Associated with Schwann cells, but several neurones may be enshrouded in one loosely-wrapped Schwann cell, insulting adjacent neurones, but not the axonal membrane
      • Speed is less imperative with unmyelinated neurones carrying action potentials over small distances, or coordinating bodily functions, such as breathing and the action of the digestive system
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    • Resting potential
      • 70mV across the membrane, caused by the movement of sodium and potassium ions across the axonal membrane, with the sodium-potassium pump actively transporting three sodium ions out of the axon for every two potassium ions that are pumped in
      View source
    • Action potential generation
      1. Stimulus detected by sensory receptor
      2. Temporarily depolarises axonal membrane
      3. Voltage-gated sodium ion channels open, allowing sodium ions to diffuse into the axon
      4. Positive feedback loop further depolarises the membrane until +40mV
      5. Voltage-gated sodium ion channels close, and voltage-gated potassium ion channels open, allowing potassium ions to diffuse out of the axon
      6. Axon repolarises and hyperpolarises before sodium-potassium pump restores resting potential
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    • Threshold
      +40mV, when reached an initial action potential is generated
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