5097829
Description
Quiz by Amelia Claire, updated more than 1 year ago
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Created by Amelia Claire
almost 9 years ago
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Question 1
Answer
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Dendrites
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Axons
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Nucleus
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Cell Body (soma)
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Dendrite
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Synapse
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Nucleolus
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Axon Terminal
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Rough Endoplasmic Reticulum
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Nucleus
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Axon Hillock
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Dendrite
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Axon Hillock
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Axon Terminal
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Synapse
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Axon
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Synapse
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Myelin Sheath
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Neurolemma and Myelin
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Axon Hillock
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Dendrites
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Axon Terminal
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Dendrite
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Centriole
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Schwann Cell
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Schwimmer Cell
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Node of Ranvier
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Myelin
Question 2
Question
A Synapse is a junction between two nerve cells, consisting of a minute gap across which impulses pass by diffusion of a neurotransmitter.
Answer
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axon
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dendrite
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neurotransmitter
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synaptic vesicle
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receptor
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nucleus
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synapse
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axon hillock
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vesicles
Question 3
Question
Excitatory neurotransmitters:
Answer
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depolarise the membrane
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hyperpolarise the membrane
Question 4
Question
inhibitory neurotransmitters:
Answer
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hyperpolarise the membrane
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depolarise the membrane
Question 5
Answer
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Unipolar
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Multipolar
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Bipolar
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Anaxonic
Question 6
Answer
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anaxonic
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unipolar
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bipolar
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multipolar
Question 7
Answer
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multipolar
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bipolar
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unipolar
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anaxonic
Question 8
Answer
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bipolar
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unipolar
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anaxonic
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multipolar
Question 9
Question
This is an Ependymal Cell. It is found in the Central Nervous System. What does it do?
Answer
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Line the central cancel and ventricles where they form an epithelium known as ependyma, and monitor Cerebrospinal Fluid.
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Myelinate the CNS axons and provide structural framework.
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Perform phagocytosis to remove cell debris from the CNS.
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Myelinate PNS axons and participate in repair after injury.
Question 10
Question
This is an Astrocyte. It is found in the Central Nervous System. Which describes the function of this particular neuroglia?
Answer
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Maintain the blood brain barrier, provide structural support by creating a three-dimensional framework for the CNS through their microfilaments. Repair damaged neural tissue and control the interstitial environment by regulating ion and nutrient concentrations.
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Myelinate axons in the CNS.
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Myelinate axons in the PNS.
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Produce epithelium called ependyma, circulate and produce Cerebrospinal Fluid.
Question 11
Question
This neuroglia is an ogliodendrocyte. It is found in the Central Nervous System. Which best describes it's function in the CNS?
Answer
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Myelinate axons by forming a myelin sheath along the length of each axon.
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Provide the blood-brain barrier.
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Form Cerebral Spinal Fluid and manage the concentration of ions and nutrients.
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Remove myelin from axons and perform phagocytosis within the interstitial fluid, removing pathogens and dead or damaged neurons for recycling.
Question 12
Question
This is microglia, the smallest of the neuroglia. It is found in the Central Nervous System. It has a very important role. What is it?
Answer
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Perform phagocytosis to remove pathogen, cell debris and waste.
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Myelinate the axons of the neurons in the central nervous system.
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Myelinate the axons of the neurons in the peripheral nervous system.
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Remove the myelin form axons and release neurotransmitters to make skeletal muscle contract.
Question 13
Question
This is a satellite cell, abundant in the Peripheral Nervous System. Which statement describes their function?
Answer
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Satellite cells surround the neuron cell bodies in ganglia. They regulate the environment around the neurons of the PNS
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Satellite cells produce myelin for the axons of the neurons in the PNS.
Question 14
Question
This is a Schwann Cell. It is found in the Peripheral Nervous System. What is it's function?
Answer
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Non-myelinating Schwann cells surround the axons in the PNS, while myelinating Schwann Cells are responsible for the myelination of the peripheral axons and participate in repair process after injury.
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Remove debris from the interstitial fluid via phagocytosis.
Question 15
Question
The Organisation of the Nervous System
Answer
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Central Nervous System
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Peripheral Nervous System
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Somatic Receptor
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Peripheral Nervous System
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Central Nervous System
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Refractory Nervous System
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Special Sensory Receptors
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Visceral Sensory Receptors
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Somatic Sensory Receptors
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Visceral Sensory Receptors
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Somatic Sensory Receptors
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Special Sensory Receptors
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Somatic Sensory Receptors
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Special Sensory Receptors
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Visceral Sensory Receptors
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Somatic Nervous System (SNS)
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Autonomic Nervous System (ANS)
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Sympathetic Division
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Sympathetic Division
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Somatic Sensory Receptor
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Somatic Nervous System
Question 16
Answer
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Vesicle
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Neurotransmitter
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Calcium Channel
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Neurotransmitter
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Vesicle
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Synaptic Cleft
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Synaptic Terminal
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Synaptic Cleft
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Neurotransmitter
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Receptor for neurotransmitter
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Vesicle
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Neurotransmitter
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Synaptic Cleft
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Receptor for Neurotransmitter
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Axon terminal
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Calcium channel
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Neurotransmitter
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Synaptic cleft
Question 17
Answer
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Repolarisation
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Depolarisation
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Hyperpolarisation
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Depolarisation
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Repolarisation
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Hyperpolarisation
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Hyperpolarisation
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Repolarisation
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Depolarisation
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Resting potential
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Hyperpolarisation
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Depolarisation
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Return to resting potential
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Hypopolarisation
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Depolarisation
Question 18
Question
Select the correct name for the channels below:
Answer
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Chemically Gated
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Voltage Gated
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Mechanically Gated
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Chemically Gated
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Voltage Gated
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Mechanically Gated
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Chemically Gated
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Voltage Gated
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Mechanically Gated
Question 19
Question
Generation of Action Potentials.
Step 1: Depolarisation of the threshold.
* The stimulus that initiates an action potential is a [blank_start]graded depolarisation[blank_end] large enough to open the channels.
* A graded depolarisation brings an [blank_start]area of excitable membrane[blank_end] to threshold [blank_start](-60mV)[blank_end]
Step 2: Activation of Sodium Channels and Rapid Depolarisation.
* The [blank_start]Voltage-Gated[blank_end] sodium channels open (sodium channel activation)
* Sodium Ions, driven by [blank_start]electrical attraction[blank_end] and the chemical gradient, flood into the cell
* The transmembrane potential goes from -60mV (the threshold level) to [blank_start]+30mV[blank_end] (the sodium equilibrium potential)
* The membrane cannot respond to any other stimulation during this time, the [blank_start]Refectory Period[blank_end]
Step 3: Inactivation of Sodium Channels and Activation of Potassium Channels.
* The Voltage-Gated sodium channels [blank_start]close[blank_end] (sodium channel inactivation occurs) at +30mV
* The [blank_start]Voltage-Gated[blank_end] potassium channels are now open, and positively charged potassium ions [blank_start]diffuse out[blank_end] of the cell, shifting the membrane potential back toward [blank_start]resting levels[blank_end].
* [blank_start]Repolarisation[blank_end] begins.
Step 4: Closing of Potassium Channels
* The Voltage-Gated sodium channels regain their normal properties
* The membrane is now capable of generating another action potential if a larger-than-normal stimulus is provided
* The Voltage-Gated potassium channels begin closing at [blank_start]-70mV[blank_end]. Because they do not all close at the same time, potassium loss continues and a [blank_start]temporary hyperpolarisation[blank_end] occurs, bringing the membrane to approximately [blank_start]-90mV[blank_end].
* At the end of the relative Refractory Period, all Voltage-Gated channels have closed and the membrane is back to it's resting state.
Answer
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graded depolarisation
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graded repolarisation
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area of excitable membrane
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the entire cell membrane
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(-60mV)
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(-90mV)
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Voltage-Gated
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mechanically-gated
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electrical attraction
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diffusion
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+30mV
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-90mV
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Refectory Period
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Refractory Period
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close
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remain open
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Voltage-Gated
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chemically gated
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diffuse out
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are actively transported into
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resting levels
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+60mV
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Repolarisation
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Hyperpolarisation
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-70mV
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+30mV
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temporary hyperpolarisation
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ongoing hypopolarisation
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-90mV
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+30mV
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