Electrophysiology – MCQs

1. The resting membrane potential of a typical mammalian neuron is approximately:
(A) –40 mV
(B) –55 mV
(C) –70 mV
(D) –90 mV

2. The Nernst equation is used to calculate:
(A) Membrane resistance
(B) Equilibrium potential for an ion
(C) Threshold potential
(D) Synaptic delay

3. Which ion is primarily responsible for depolarization during an action potential?
(A) Potassium (K⁺)
(B) Sodium (Na⁺)
(C) Calcium (Ca²⁺)
(D) Chloride (Cl⁻)

4. Repolarization of the action potential is mainly due to:
(A) Influx of sodium
(B) Efflux of potassium
(C) Influx of calcium
(D) Efflux of chloride

5. The Goldman-Hodgkin-Katz equation accounts for:
(A) Single ion concentration
(B) Multiple ion permeabilities
(C) Only sodium channels
(D) Resting potential in plants

6. Voltage-gated sodium channels are blocked by:
(A) Tetrodotoxin (TTX)
(B) Ouabain
(C) Curare
(D) Lidocaine

7. Which ion triggers neurotransmitter release at the synapse?
(A) Na⁺
(B) K⁺
(C) Ca²⁺
(D) Cl⁻

8. Patch-clamp technique is used to:
(A) Measure single ion channel activity
(B) Record brain imaging signals
(C) Study protein folding
(D) Detect neurotransmitters directly

9. The refractory period ensures that:
(A) Action potentials travel in one direction
(B) Neurons fire continuously
(C) Membrane potential is always depolarized
(D) Synapses do not release neurotransmitters

10. Myelination increases conduction velocity by:
(A) Continuous conduction
(B) Saltatory conduction
(C) Increasing ion leakage
(D) Removing refractory periods

11. Nodes of Ranvier are rich in:
(A) Na⁺ channels
(B) K⁺ channels only
(C) Ca²⁺ pumps
(D) Cl⁻ transporters

12. The synaptic delay is typically:
(A) 0.01 ms
(B) 0.1–0.5 ms
(C) 1–2 ms
(D) 10 ms

13. The Hodgkin-Huxley model describes:
(A) Ion channel kinetics in squid axon
(B) Synaptic plasticity
(C) Glial cell functions
(D) Muscle contraction

14. Which current dominates during the plateau phase of cardiac action potential?
(A) Na⁺ influx
(B) K⁺ efflux
(C) Ca²⁺ influx
(D) Cl⁻ influx

15. Which electrode technique measures extracellular potentials?
(A) Intracellular sharp electrodes
(B) Field potential recording
(C) Patch-clamp whole-cell
(D) Voltage clamp

16. The QRS complex in ECG represents:
(A) Atrial depolarization
(B) Ventricular depolarization
(C) Atrial repolarization
(D) Ventricular repolarization

17. The P wave in ECG corresponds to:
(A) Atrial depolarization
(B) Ventricular depolarization
(C) Ventricular repolarization
(D) SA node activity only

18. The T wave in ECG represents:
(A) Atrial depolarization
(B) Ventricular depolarization
(C) Ventricular repolarization
(D) SA node firing

19. The threshold potential in most neurons is around:
(A) –90 mV
(B) –70 mV
(C) –55 mV
(D) –30 mV

20. Inhibitory postsynaptic potentials (IPSPs) are often mediated by:
(A) Na⁺ influx
(B) K⁺ efflux or Cl⁻ influx
(C) Ca²⁺ influx
(D) ATP hydrolysis

21. Excitatory neurotransmitters typically cause:
(A) Depolarization
(B) Hyperpolarization
(C) No change in membrane potential
(D) DNA synthesis

22. Electroencephalography (EEG) measures:
(A) Extracellular electrical activity of brain
(B) Single ion channel currents
(C) Action potentials in muscle
(D) Cardiac potentials

23. Electromyography (EMG) records:
(A) Brain activity
(B) Skeletal muscle electrical activity
(C) Cardiac activity
(D) Synaptic vesicle release

24. Calcium-induced calcium release (CICR) is important in:
(A) Neuronal transmission
(B) Cardiac muscle contraction
(C) Skeletal muscle relaxation
(D) Nerve regeneration

25. The conduction velocity of unmyelinated axons is typically:
(A) 0.1–1 m/s
(B) 1–2 m/s
(C) 10–20 m/s
26. Axonal conduction velocity increases with:
(A) Increased diameter
(B) Decreased diameter
(C) Higher membrane resistance
(D) Lower temperature

27. The end-plate potential (EPP) is generated at:
(A) Neuromuscular junction
(B) Axon hillock
(C) Dendritic spine
(D) Myelin sheath

28. The role of the sodium-potassium pump is to:
(A) Maintain resting potential by pumping 3 Na⁺ out and 2 K⁺ in
(B) Pump Na⁺ into cell
(C) Pump K⁺ out only
(D) Generate action potential directly

29. Which ion channel type is critical for pacemaker activity in the heart?
(A) Funny (If) channels
(B) Voltage-gated Na⁺ channels
(C) Voltage-gated K⁺ channels
(D) Ligand-gated Cl⁻ channels

30. Long-term potentiation (LTP) requires activation of:
(A) NMDA receptors
(B) GABA receptors
(C) Glycine receptors
(D) Nicotinic receptors

31. Which current is responsible for the afterhyperpolarization phase?
(A) Na⁺ influx
(B) K⁺ efflux
(C) Ca²⁺ influx
(D) Cl⁻ efflux

32. Voltage clamp technique allows:
(A) Control of membrane potential to study ionic currents
(B) Measurement of intracellular resistance only
(C) Direct imaging of ion channels
(D) Recording of synaptic vesicles

33. Which toxin blocks voltage-gated K⁺ channels?
(A) Tetraethylammonium (TEA)
(B) Tetrodotoxin
(C) Curare
(D) Bungarotoxin

34. In the heart, Purkinje fibers are specialized for:
(A) Fast conduction of action potentials
(B) Slow pacemaker activity
(C) Synaptic integration
(D) Neurotransmitter release

35. Action potentials are generated at the axon hillock because:
(A) High density of voltage-gated Na⁺ channels
(B) Low resistance
(C) Large surface area
(D) Presence of myelin

36. Local anesthetics block action potentials by:
(A) Blocking voltage-gated Na⁺ channels
(B) Blocking K⁺ leak channels
(C) Blocking Ca²⁺ channels
(D) Blocking ATP pumps

37. The refractory period prevents:
(A) Backward propagation of action potentials
(B) Saltatory conduction
(C) Synaptic transmission
(D) Myelin formation

38. The unit of conductance is:
(A) Siemens
(B) Ohm
(C) Volt
(D) Ampere

39. Electrical synapses transmit signals via:
(A) Gap junctions
(B) Chemical neurotransmitters
(C) Voltage-gated Na⁺ channels
(D) Ligand-gated K⁺ channels

40. Chemical synapses differ from electrical synapses by:
(A) Presence of neurotransmitter release and synaptic delay
(B) Bidirectional signaling
(C) Zero delay transmission
(D) Passive conduction

41. Ionotropic receptors mediate:
(A) Fast synaptic transmission
(B) Slow synaptic transmission
(C) DNA replication
(D) Action potential conduction in myelin

42. Metabotropic receptors act via:
(A) G-proteins and second messengers
(B) Direct ion channel opening
(C) Gap junctions
(D) Synaptic vesicle release

43. Electrooculography (EOG) records:
(A) Eye movement-related electrical activity
(B) Skeletal muscle activity
(C) Heart potentials
(D) Brain waves

44. Electroretinography (ERG) measures:
(A) Retinal electrical responses to light
(B) Corneal resistance
(C) Optic nerve blood flow
(D) Pupil constriction

45. Which current is responsible for neurotransmitter vesicle fusion?
(A) Ca²⁺ influx through voltage-gated channels
(B) Na⁺ influx
(C) K⁺ efflux
(D) Cl⁻ influx

46. Hyperpolarization occurs when:
(A) Membrane potential becomes more negative than resting potential
(B) Na⁺ channels open
(C) K⁺ channels close
(D) Threshold is crossed

47. Which current maintains the plateau in ventricular action potentials?
(A) Slow inward Ca²⁺ current
(B) Fast Na⁺ current
(C) Delayed K⁺ current
(D) Funny current

48. EPP at neuromuscular junction is caused by:
(A) Acetylcholine binding to nicotinic receptors
(B) Na⁺ influx via voltage-gated channels
(C) ATP hydrolysis
(D) K⁺ efflux

49. Electrocardiography (ECG) records:
(A) Electrical activity of the heart
(B) Skeletal muscle contraction
(C) Brain waves
(D) Synaptic potentials

50. The main role of electrophysiology in neuroscience is to:
(A) Measure electrical properties of cells and tissues
(B) Measure mechanical properties of tissues
(C) Visualize macromolecules
(D) Sequence nucleic acids