Sequence the events in neuromuscular action potential conduction: 1. Sodium channels open in the end plate 2. Calcium enters at the nerve terminal 3. Release of acetylcholine

$2 \rightarrow 3 \rightarrow 1$

$1 \rightarrow 2 \rightarrow 3$

$1 \rightarrow 3 \rightarrow 2$

$3 \rightarrow 2 \rightarrow 1$

Which of the following statements about the Na-K pump is false?

It is located on the apical membrane of cell

It is not directly involved in the generation of action potentials.

It needs ATP for its functioning

Absolute refractoriness of a neuron is due to?

Hyperpolarization of Cl channels

Opening of rectifier K+ channels

Closure of activated Na channels

Assertion: RMP depends on proteins and phosphate ions. Reason: Diffusion potential can be calculated using nernst equation. Choose the best statement regarding the assertion and reason.

Both true, Reason is not the explanation of assertion

Both true, Reason is the explanation of assertion

In multiple sclerosis, slow conduction of motor and sensory pathways is due to?

Dysfunction of calcium channels

Type I muscle fibers are rich in myosin heavy chain. What is their characteristic property?

Slow contracting, resistant to fatigue

Fast contracting, susceptible to fatigue

Slow contracting, susceptible to fatigue

Fast contracting, resistant to fatigue

What is the primary function of cyclic AMP (cAMP)?

Activation of Ryanodine receptors

Bioelectric Phenomena for NEET-PG: High-Yield Physiology Lessons

Resting Membrane Potential - Cell's Electric Chill

Electrical potential difference across a non-excited cell membrane; inside negative.
Typical: -70 mV to -90 mV (neurons).
Key Determinants:
- High K⁺ permeability (K⁺ efflux): Primary driver. K⁺ Nernst Potential ($E_K$) approx. -90 mV.
  - Nernst Eq: $E_{ion} = (61.5/z) \log ([ion]{out}/[ion]{in})$
- Na⁺/K⁺ ATPase: 3 Na⁺ out / 2 K⁺ in (electrogenic). 📌 "PUMPKIN": Pump K⁺ IN.
- Intracellular anionic proteins (A⁻).
Goldman-Hodgkin-Katz (GHK) equation: Calculates RMP using multiple ion permeabilities.

⭐ The Na+/K+ ATPase pump contributes significantly to RMP by pumping 3 Na+ ions out for every 2 K+ ions in, making the inside more negative (electrogenic pump, contributes ~-4mV).

Action Potential - Nerve's Electric Spike

Rapid, transient, 'all-or-none' electrical spike in excitable cells (neurons, muscle).
Triggered when stimulus depolarizes membrane to threshold potential (approx. -55 mV).

Action potential graph with ion channel states

Phases & Ionic Basis:

Depolarization:
- Voltage-gated Na+ channels (VGSCs) open rapidly → Na+ influx.
- Membrane potential reverses (overshoot, e.g., to +30 mV).
Repolarization:
- VGSCs inactivate.
- Voltage-gated K+ channels (VGKCs) open → K+ efflux.
Hyperpolarization (Afterpotential):
- VGKCs close slowly → RMP transiently more negative (undershoot).

Properties:

All-or-None Law: AP fires at full amplitude if threshold is met, or not at all.
Refractory Periods:
- Absolute (ARP): No new AP. VGSCs inactivated.
- Relative (RRP): Stronger stimulus needed. Some VGSCs recovered, K+ efflux continues.
📌 Mnemonic: "Salt (Na+) IN for Depolarization, Potato (K+) OUT for Repolarization."

⭐ Tetrodotoxin (TTX) from pufferfish selectively blocks voltage-gated Na+ channels, preventing action potential generation.

Key Channel Blockers:

Voltage-gated Na+ channels:
- Tetrodotoxin (TTX)
- Lidocaine (local anesthetic)
Voltage-gated K+ channels:
- Tetraethylammonium (TEA)

Synaptic & Receptor Potentials - Signals Across Gaps

Synaptic Potentials: Graded postsynaptic Vm changes.
- EPSP (Excitatory Postsynaptic Potential): Depolarization ($Na^+$ influx via glutamate). Moves Vm to threshold.
- IPSP (Inhibitory Postsynaptic Potential): Hyperpolarization ($Cl^-$ influx / $K^+$ efflux via GABA, glycine). Moves Vm from threshold.
- Summation:
  - Temporal: Single presynaptic neuron, rapid stimuli.
  - Spatial: Multiple presynaptic neurons, simultaneous stimuli.
Receptor/Generator Potentials: Graded sensory receptor potentials.
- Stimulus alters ion permeability.
- Amplitude ~ stimulus intensity.
- Triggers AP if threshold reached.
- Adaptation: ↓ response to sustained stimulus.

⭐ Temporal summation involves multiple stimuli from a single presynaptic neuron close in time, while spatial summation involves stimuli from multiple presynaptic neurons at the same time.

Clinical Correlations - Bioelectric Insights

Diagnostic tools utilize body's bioelectric signals.
ECG (Electrocardiogram):
- Assesses heart's electrical activity.
- Key for arrhythmias, ischemia detection.
EEG (Electroencephalogram):
- Records brain's electrical rhythms.
- Aids in epilepsy, sleep disorder diagnosis.
EMG (Electromyogram) & NCS (Nerve Conduction Studies):
- Assess nerve & muscle electrical activity.
- Crucial for diagnosing neuropathies, myopathies.

⭐ Channelopathies are diseases caused by disturbed function of ion channel subunits or the proteins that regulate them, e.g., Liddle's syndrome (ENaC).

High‑Yield Points - ⚡ Biggest Takeaways

RMP: Primarily due to K+ efflux; maintained by Na+/K+ ATPase.

Action Potential: All-or-none; Na+ influx (depolarization), K+ efflux (repolarization).

Nernst potential for single ion; Goldman equation for RMP with multiple ions.

Chronaxie: Excitability measure; time for 2x Rheobase current to cause excitation.

Saltatory conduction: Myelinated nerves; AP jumps Nodes of Ranvier, ↑ conduction velocity.

Donnan equilibrium: Explains effect of non-diffusible ions on ion distribution.

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