Deck 29: Nervous Systems

A) are electrically excitable.
B) provide electrical output to neurons.
C) are nourished by neurons.
D) provide electrical insulation.
E) receive input from the environment.

A) sensory neurons carry information from enteroreceptors whereas motor neurons carry information from exteroreceptors.
B) motor neurons carry information away from the central nervous system whereas sensory neurons carry information towards the central nervous system.
C) sensory neurons function as efferent pathways whereas motor neurons function as afferent pathways.
D) motor neurons have long axons whereas the axons of sensory neurons are relatively short.
E) All the answers are correct.

A) ion pumps actively transport Na⁺ to the outside of the membrane.
B) Na⁺ leaks through the membrane faster than any other ion.
C) the outside of the membrane is usually negative with respect to the inside.
D) the potential difference across the membrane is maintained by the diffusion of ions.
E) the membrane is more permeable to Na⁺ than to K⁺.

A) ion pumps actively transport K⁺ to the outside of the cell.
B) K⁺ channels open and K⁺ leaves the cell.
C) Na⁺ channels open and Na⁺ leaves the cell.
D) K⁺ channels open and K⁺ enters the cell.
E) Na⁺ channels open and Na⁺ enters the cell.

A) to generate an action potential.
B) to propagate an action potential.
C) to maintain a nerve cell membrane at resting potential.
D) to transport K⁺ out of the cell.
E) All of the answers are correct.

A) hyperpolarisation.
B) inhibition.
C) the refractory period.
D) the saltatory period.
E) the resting period.

A) Na⁺ channels open and Na⁺ flows out.
B) K⁺ channels open and K⁺ flows out.
C) Cl^- channels open and Cl^- flows in.
D) K⁺ channels open and K⁺ flows in and Na⁺ flows out.
E) the Na⁺-K⁺ pump is activated, transporting Na⁺ out and K⁺ in.

A) 5, 1, 4, 2, 3.
B) 2, 5, 4, 1, 3.
C) 2, 5, 3, 4, 1.
D) 2, 4, 5, 1, 3.
E) 2, 3, 5, 1, 4.

A) make it easier to trigger action potentials in the neuron.
B) inhibit the conduction of action potentials along the neuron.
C) cause the membrane to hyperpolarise.
D) make it more difficult for the neuron to respond to repeated stimuli.
E) prevent depolarisation of the membrane.

A) a decrease in the insulation of the axon.
B) an increase in the length of the axon.
C) an increase in the diameter of the axon.
D) the number of Na⁺ channels in the axon.
E) a decrease in the concentration of Na⁺ ions inside the axon.

A) Synaptic vesicles fusing with the cell membrane.
B) Membrane-bound Na⁺ channels opening.
C) Neurotransmitter binding to membrane-bound receptors.
D) Ca²⁺ entering the synaptic terminal.
E) Release of the transmitter into the synaptic cleft.

A) type of receptor on the postsynaptic membrane.
B) molecular structure of the neurotransmitter.
C) amount of neurotransmitter released.
D) permeability of the post-synaptic membrane.
E) number of receptors on the postsynaptic membrane.

A) Adrenaline
B) Noradrenaline
C) Acetylcholine
D) Adrenaline and noradrenaline
E) Adrenaline, noradrenaline and acetylcholine

A) bilateral symmetry.
B) metameric segmentation.
C) complex behaviour.
D) nerve nets.
E) autocrine receptors.

A) cerebellar cortex.
B) thalamus.
C) corpus callosum.
D) cerebral cortex.
E) cerebellum.

A) Nerve cell bodies
B) Dendrites
C) Initial parts of axons and synaptic inputs
D) Areas of sensory connections
E) Axons that pass up and down the cord

A) Segmental ganglion
B) Dorsal root ganglion.
C) Suboesophageal ganglion
D) Encephalisation
E) Optic ganglion

A) nerve nets.
B) neural circuits.
C) reflex arcs.
D) ganglia.
E) peripheral nervous system.

A) The tentacles shoot forward to grasp a small fish and then withdraw it to the mouth.
B) An extended tentacle suddenly contracts in immediate response to a tactile stimulus.
C) The rate of the regular in and out movements of the mantle, that ventilate the gills, increases in response to a decrease in the oxygen concentration of the surrounding water.
D) A sudden forceful contraction of the mantle muscles expels water through the siphon, propelling the animal backwards, away from a predator.
E) The release of ink in response to fear.

A) rhythmically generated pattern modified by conscious input.
B) consciously generated pattern modified by a rhythmic pattern generator.
C) monosynaptic reflex.
D) polysynaptic reflex.
E) response to adrenaline release.

A) recognise patterns.
B) form a clear image of an object.
C) focus light onto a layer of photopigment.
D) detect the direction of a light source.
E) form images that are subsequently combined physically.

A) they have a single lens.
B) they can form an image.
C) they focus light.
D) the final image is constructed by the nervous system.
E) some detect polarised light.

A) distinguish soundwaves of different frequencies.
B) conduct and amplify soundwaves.
C) collect and concentrate soundwaves.
D) concentrate sound waves to a small area.
E) convert soundwaves into electrical impulses.

A) auditory ossicles.
B) scala tympani.
C) pinna.
D) tectorial membrane.
E) scala vestibuli.

A) activation of stretch receptors.
B) the deformation of Pacinian corpuscles.
C) adrenaline released in response to the damage.
D) chemicals released by damaged or irritated tissue.
E) the release of endorphins.

A) Chemoreceptors
B) Mechanoreceptors
C) Photoreceptors
D) Enteroreceptors
E) Exteroreceptors

A) thyroid hormones.
B) the hypothalamus.
C) the autonomic nervous system.
D) the somatic nervous system.
E) the sympathetic nervous system.

A) Sympathetic nervous system.
B) Parasympathetic nervous system.
C) Enteric nervous system.
D) No division can function without the central nervous system.
E) Somatic nervous system.

A) they are connected to different regions of the central nervous system.
B) they innervate different organs.
C) sympathetic nerves are under voluntary control whereas parasympathetic nerves are involuntary.
D) parasympathetic nerves are motor nerves whereas sympathetic nerves are sensory.
E) the sympathetic nerves control cardiovascular activity while the parasympathetic nerves control body metabolism.

A) detect signals from the external environment.
B) monitor blood pressure.
C) receive information from muscle cells to initiate a response.
D) control the activity of several glands.
E) require enteroreceptors and exteroreceptors for function.

A) the processing of sensory information.
B) the control of movement.
C) memory.
D) emotional responses.
E) All of these functions.

A) The thalamus.
B) The temporal lobe.
C) The left frontal lobe in Broca's area.
D) The pons.
E) The pineal gland.

A) animals have strong avoidance behaviour to painful stimuli.
B) special neural networks control the automatic function of many internal organs.
C) the complex reflex circuits of the enteric nervous system is embedded in the walls of the digestive system.
D) that some groups of autonomic neurons fire action potentials continually and so control the level of activity of the organ they innervate.
E) autonomic neurons have axons which project to peripheral ganglia to control activity.

A) mimicking the action of peptide transmitters in the central nervous system.
B) inhibiting the transmission of information from the brain to the spinal cord.
C) binding to chemoreceptors and controlling cellular secretions involved in pain detection.
D) inhibiting the signal carried from the site of the pain to the brain.
E) stimulating the release of steroid signalling hormones which override the pain receptors.

A) guide neuronal development and repair.
B) provide electrical insulation for neurons.
C) provide mechanical and nutrient support for neurons.
D) maintain the extracellular environment of neurons.
E) All options listed here are correct.

A) afferent neurons.
B) efferent neurons.
C) effectors.
D) affectors.
E) All options listed here are incorrect.

A) The voltage difference across the neuronal membrane would decrease.
B) The voltage difference across the neuronal membrane would increase slightly.
C) The voltage difference across the neuronal membrane would be unchanged.
D) The voltage difference across the neuronal membrane would increase significantly.
E) The neuronal membrane would become unstably polarised.

A) excited, increasing Brownian motion.
B) degraded, due to denaturation of transmembrane proteins.
C) relaxed, facilitating ion transport.
D) hyperpolarised.
E) hypopolarised.

A) mechanoreception.
B) chemotaxis.
C) chemoreception.
D) chemotropism.
E) mechanoflux.

A) opaque internal amplitris.
B) nodules of Rovemina.
C) islets of Dyssius.
D) these phrases are all just plain gibberish.
E) ampullae of Lorenzini.

A) Drosophila melanogaster
B) Procambrus (crayfish)
C) Locusta (Orthopteran)
D) Mus musculus (mouse)
E) Helix (Gastropod)

A) Brain stem
B) Frontal lobe
C) Cerebellum
D) Parietal lobe
E) Central sulcus

A) Cranio-electroconductivity
B) The hormonal output of neurons.
C) The energy level of the neuronal electrochemical gradient
D) The electrical properties of neuronal membranes
E) The distance of environmental input signalling from external receptors