Deck 3: Cells and Circuits

A) They contain specialized ion channels.
B) They consist of two layers of phospholipids.
C) They are impermeable.
D) Their exterior is hydrophillic.

A) a membrane potential.
B) dendrites.
C) an axon.
D) mitochondria.

A) selectively allow ions to enter or leave the neuron.
B) provide nutrients for the neuron.
C) synthesize neurotransmitters.
D) form an impermeable barrier.

A) action
B) resting
C) threshold
D) reversal

A) Ions
B) Neurotransmitters
C) Second messengers
D) G proteins

A) intracellular
B) extracellular
C) extracellular and intracellular
D) hyperpolarized

A) electrical gradient.
B) concentration gradient.
C) repulsion.
D) the law of electrostatic repulsion.

A) Chloride ions
B) Sodium ions
C) Potassium ions
D) Water

A) Chloride ions
B) Calcium ions
C) Potassium ions
D) Water

A) 90%
B) 25%
C) 50%
D) 40%

A) electrical gradient.
B) release of neurotransmitters.
C) concentration gradient.
D) ion flux.

A) astrocytes
B) oligodendrocytes
C) sodium-potassium pumps
D) microglia

A) Depolarizations
B) Hyperpolarizations
C) Action potentials
D) Refractory potentials

A) making the inside of a neuron less negative.
B) making the inside of a neuron more negative.
C) A weaker action potential.
D) changes in signal speed of myelinated axons.

A) making the inside of a neuron less negative.
B) making the inside of a neuron more negative.
C) a stronger action potential.
D) changes in signal speed of myelinated axons.

A) 3mV
B) 5mV
C) 10mV
D) 15mV

A) sodium channels.
B) chloride channels.
C) potassium channels.
D) second messengers.

A) neuronal injury.
B) the application of a local anesthetic.
C) multiple sclerosis.
D) an action potential.

A) reuptake pump.
B) receptor.
C) neurotransmitter cleft
D) synaptic cleft.

A) opens postsynaptic ion channels directly or indirectly via G-protein generated second messengers.
B) opens postsynaptic ion channels directly via G-proteins.
C) releases sodium ions from inside postsynaptic neurons.
D) initiates an action potential.

A) ionotropic receptors
B) metabotropic receptors
C) astrocytes
D) a G-protein

A) Axodendritic
B) Axosomatic
C) Axoaxonic
D) Axospinal

A) thicker, slower
B) thicker, faster
C) longer, slower
D) thinner, faster

A) amygdala
B) pons
C) area postrema
D) insula

A) Andrew Huxley
B) Alan Hodgkin
C) John Hughlings Jackson
D) Von Economo

A) hyperpolarization.
B) hyperexcitability.
C) seizurbility.
D) epileptogenesis.

A) hijack and strengthen excitatory neural networks.
B) inhibit the activation and expression of genes.
C) decrease activation of brain growth factors.
D) weaken the strength of excitatory neural networks.

A) intense pain.
B) strong odors.
C) rapidly changing lights.
D) sudden movements.

A) Mirror neurons
B) Unipolar neurons
C) Spindle cells
D) Von Economo neurons

A) "gut feelings" and intuition.
B) facial recognition.
C) anticipating the actions of others.
D) sensory gating.

A) noninvasive imaging method.
B) neural network modeling tool.
C) noninvasive activity recording procedure.
D) perturbation technique

A) electrolytic lesion
B) permanent lesion.
C) visualization of brain activity.
D) virtual lesion

A) not change their gaze durations between objects and people.
B) maintain eye contact with others.
C) not feel emotions.
D) have overactive mirror neurons.

A) difficulty imitating gestures or facial expressions.
B) difficulty standing.
C) difficulty walking.
D) difficulty processing visual input.

A) pilocarpine.
B) serotonin.
C) γ-Aminobutyric acid (GABA).
D) dopa decarboxylase.

A) convulsant drug.
B) neurotransmitter.
C) vitamin.
D) second messenger.

A) By enveloping the terminals of neurons.
B) By consuming energy diverted away from neurons.
C) They normally secrete an enzyme that is critical for serotonin synthesis.
D) A reduction in myelin could cause a short-circuiting of action potentials.

A) Schwann cells
B) Oligodendrocytes
C) Astrocytes
D) Microglia

A) facilitator of synapse formation.
B) substitute for myelin.
C) neurotransmitter.
D) metabolic energy source.

A) the binding of a neurotransmitter to a ligand-gated channel
B) the binding of a neurotransmitter to a metabotropic receptor.
C) G-protein activation.
D) acetylcholine.

A) the binding of a neurotransmitter to a ligand-gated channel
B) the binding of a neurotransmitter to a metabotropic receptor.
C) G-protein activation.
D) acetylcholine.

A) sodium ions entering the postsynaptic membrane.
B) potassium ions entering the postsynaptic membrane.
C) chloride ions entering the postsynaptic membrane.
D) G-protein activation.

A) sodium ions entering the postsynaptic membrane.
B) potassium ions entering the postsynaptic membrane.
C) chloride ions entering the postsynaptic membrane.
D) G-protein activation.

A) acetylcholine.
B) norepinephrine.
C) carbon dioxide.
D) calcium.

A) The first heart had depleted the oxygen in the solution.
B) The first heart had released waste products into the solution.
C) The solution had been heated by the first heart's activity.
D) The solution contained neurotransmitters released by the vagal nerve stimulation.

A) A lack of sodium channels in the spaces previously occupied by the myelin halts action potentials.
B) The loss of myelin causes action potentials to move slower than they should.
C) The loss of myelin allows too much sodium to enter, overwhelming the sodium-potassium pump.
D) The loss of myelin allows too much potassium to enter, overwhelming the sodium-potassium pump.

A) The refractory period.
B) Internal sodium (Na⁺) levels
C) The number of voltage dependent ion channels.
D) None of the above options are correct.

A) sodium (Na⁺)
B) calcium (Ca⁺⁺)
C) chloride (Cl^-)
D) potassium (K⁺)

A) sodium (Na⁺)
B) calcium (Ca⁺⁺)
C) chloride (Cl^-)
D) potassium (K⁺)

A) increased dendritic spine density but decreased dendritic length
B) increased dendritic spine density with increased dendritic length.
C) decreased dendritic spine density with decreased dendritic length
D) decreased dendritic spine density but increased dendritic length

A) Exercise
B) Physical restraint
C) Bystander stress
D) Social housing

A) hydrophobic.
B) hydrophillic
C) lipophillic.
D) impermeable.

A) Charles Sherrington
B) Santiago Ramón y Cajal
C) Camillo Golgi
D) Andrew Huxley.

A) have an autonomic reaction to risk before they are consciously aware of risk.
B) have an autonomic reaction to risk only after they are consciously aware of risk.
C) never show an anticipatory autonomic response to risk or avoid risk.
D) behaved identically to healthy, normal subjects.

A) are always consciously aware of the risks they are taking.
B) are in conscious control of their autonomic responses to risk.
C) have an autonomic reaction to risk before they are consciously aware of risk.
D) have an autonomic reaction to risk only after they are consciously aware of risk.

A) mirror neurons
B) unipolar neurons
C) von Economo
D) connexon

A) mirror neurons.
B) unipolar neurons.
C) spindle cells.
D) connexons.

A) gates.
B) ion channels.
C) phospholipid bilayers.
D) passages.

A) sodium (Na⁺)
B) calcium (Ca⁺⁺)
C) chloride (Cl^-)
D) Potassium (K⁺)

A) spike potential.
B) initiation potential.
C) threshold.
D) depolarization potential.

A) changes in the membrane potential.
B) changes in neurotransmitter binding.
C) changes in myelin coverage.
D) changes in adenosine triphosphate (ATP) levels.

A) axon hillock.
B) soma.
C) axon terminal.
D) dendritic spine.

A) spike-initiation zone.
B) soma.
C) axon terminal.
D) dendritic spine.

A) exocytosis.
B) emesis.
C) emission.
D) excitation.

A) an action potential.
B) a seizure.
C) temporal summation.
D) spatial summation.

A) an action potential.
B) transmitter release.
C) temporal summation.
D) spatial summation.

A) creation of synapses.
B) release of neurotransmitter into a chemical synapse.
C) microglia clearing debris from the site of brain injury.
D) activation of astrocytes.

A) presynaptic terminals and postsynaptic dendrites.
B) the sympathetic and parasympathetic nervous systems.
C) connexons to form gap junctions.
D) astrocytes and neurons.

A) the fight-or-flight response.
B) The exchange of electrical currents between two adjacent neurons.
C) release of neurotransmitters from presynaptic to postsynaptic neurons.
D) sending neural messages across long distances.

A) strengthen inhibitory brain networks.
B) raise levels of γ-Aminobutyric acid (GABA).
C) decrease activity of brain growth factors.
D) strengthen excitatory brain networks.

A) dopamine (DA).
B) serotonin (5-HT).
C) γ-Aminobutyric acid (GABA).
D) pain tolerance.

A) mirror-reversed images of one's own face.
B) the observed actions of others.
C) unexpected sounds or sensations.
D) emotional facial expressions.

A) imitation deficits in children with ASD.
B) balance deficits in children with ASD.
C) sensory deficits in children with ASD.
D) visual processing deficits in children with ASD

A) stimulant drugs.
B) applied behavior analysis.
C) transcranial magnetic stimulation (TMS)
D) antidepressants.

A) Functional magnetic resonance imaging (fMRI)
B) Magnetic resonance imaging (MRI)
C) Positron emission tomography (PET)
D) Transcranial magnetic stimulation (TMS