Neuron Structure and Action Potential
Neural Control and Coordination: Neuron Structure and Action Potential
Neuron Structure and Action Potential
Neuron Structure and Action Potential
What you'll learn
- Identify and label the structural components of a neuron
- Explain how resting membrane potential is maintained at -70 mV
- Describe the ionic events during an action potential (depolarisation → repolarisation → hyperpolarisation)
- Define threshold potential, all-or-nothing law, and refractory period
- Compare saltatory vs. continuous conduction and myelinated vs. unmyelinated fibres
Key concepts
Level 1 — Foundations
A neuron (nerve cell) is the structural and functional unit of the nervous system. It has three main regions:
- Cell body (soma): contains the nucleus, Nissl granules (rough ER for protein synthesis), and most organelles. Metabolic centre of the neuron.
- Dendrites: short, branched projections that receive signals and carry them towards the cell body (afferent to soma).
- Axon: single long projection that carries signals away from the cell body (efferent from soma). Ends in axon terminals (synaptic knobs).
The axon of many neurons is wrapped in a myelin sheath formed by Schwann cells (PNS) or oligodendrocytes (CNS). Myelin is a lipid-rich insulating layer. Gaps between adjacent Schwann cells are called nodes of Ranvier — the only places where ionic exchange occurs in myelinated fibres.
Types of neurons by function:
- Sensory (afferent) — carry impulses from receptors to CNS
- Motor (efferent) — carry impulses from CNS to effectors
- Interneurons (association) — connect sensory and motor neurons within CNS
Level 2 — JEE / NEET depth
Resting Membrane Potential (RMP) = −70 mV
The inside of the neuron is negative relative to outside. Maintained by:
- Na⁺/K⁺ ATPase pump — actively pumps 3 Na⁺ out and 2 K⁺ in (electrogenic, net outward positive charge).
- Selective permeability — at rest, membrane is ~100× more permeable to K⁺ than Na⁺; K⁺ leaks out down concentration gradient, leaving fixed anions (proteins) inside.
- Concentration gradients: [K⁺] inside >> outside; [Na⁺] outside >> inside.
Action Potential — ionic sequence:
| Phase | Ions | Membrane potential |
|---|---|---|
| Resting | K⁺ out, Na⁺ pump running | −70 mV |
| Depolarisation | Na⁺ channels open; Na⁺ rushes IN | −70 → +40 mV (overshoot) |
| Repolarisation | Na⁺ channels inactivate; K⁺ channels open; K⁺ rushes OUT | +40 → −70 mV |
| Hyperpolarisation (after-potential) | K⁺ channels slow to close; excess K⁺ out | dips below −70 mV (~−80 mV) |
| Recovery | Na⁺/K⁺ pump restores gradients | back to −70 mV |
Threshold potential = −55 mV (15 mV depolarisation from rest). All-or-nothing law: if stimulus reaches threshold, a full action potential fires; sub-threshold stimuli produce only local graded potentials that decay. Refractory period: absolute refractory (no AP possible — Na⁺ channels inactivated) followed by relative refractory (larger stimulus can trigger AP).
Conduction velocity:
- Myelinated fibres: saltatory conduction — impulse "jumps" node to node; velocity 70–120 m/s (A fibres).
- Unmyelinated fibres: continuous conduction along entire membrane; velocity 0.5–2 m/s (C fibres).
- Larger axon diameter → faster conduction (less resistance).
Worked example
Problem: At rest, the membrane potential is –70 mV. A stimulus opens voltage-gated
Na⁺ channels. Trace the potential change and explain what stops depolarisation.
Step 1 — Resting state:
Na⁺/K⁺ ATPase maintains –70 mV; Na⁺ channels CLOSED; K⁺ leak channels open.
Step 2 — Stimulus reaches threshold (–55 mV):
Voltage-gated Na⁺ channels open → Na⁺ floods IN (high [Na⁺] outside + positive
outside both drive Na⁺ in).
Step 3 — Peak depolarisation (+40 mV):
Na⁺ channels inactivate (inactivation gate closes) → Na⁺ entry STOPS.
Voltage-gated K⁺ channels now open (they open slowly).
Step 4 — Repolarisation:
K⁺ exits rapidly (high [K⁺] inside + membrane now positive inside) → potential
falls back toward –70 mV.
Step 5 — Hyperpolarisation (–80 mV):
K⁺ channels close slowly → slight overshoot below –70 mV.
Step 6 — Recovery:
Na⁺/K⁺ ATPase pump restores concentration gradients → resting –70 mV restored.
Answer: Depolarisation is stopped by Na⁺ channel inactivation (inactivation gate),
NOT by the reversal of the driving force alone.
Common mistakes
| Mistake | Why it happens | Fix |
|---|---|---|
| Saying Na⁺/K⁺ pump "creates" the action potential | Confusion between maintenance and generation | The pump maintains RMP; the AP is generated by voltage-gated channels during a stimulus. |
| Forgetting that threshold is −55 mV (not −70 mV) | Memorising only RMP | Remember: threshold is 15 mV more positive than RMP; stimulus must bridge this gap. |
| Thinking myelinated = faster because "more ions move" | Intuition about conduction | Speed comes from saltatory conduction (jumping nodes), not more ion movement — actually fewer ions move. |
| Confusing absolute and relative refractory periods | Similar names | Absolute: zero AP possible (inactivated Na⁺ gates). Relative: possible with extra-large stimulus (some K⁺ gates still open). |
Board exam drill
- Draw and label a multipolar neuron; identify Nissl bodies and nodes of Ranvier.
- Write the sequence of ionic events during an action potential with membrane potential values.
- Differentiate myelinated from unmyelinated nerve fibres (table: speed, Schwann cells, nodes of Ranvier, examples).
- State the all-or-nothing law and explain its significance.
- Name the ions involved in RMP and the mechanism that maintains it.
NCERT diagrams to know
- Fig. 21.1: Structure of a neuron — soma, dendrites, axon, myelin sheath, nodes of Ranvier, axon terminals. Label all parts.
- Fig. 21.2: Transmission of nerve impulse — show ionic movement at node of Ranvier during saltatory conduction.
- Graph: Action potential vs. time curve showing depolarisation peak (+40 mV), repolarisation, and after-hyperpolarisation.
Quick check
- What is the resting membrane potential of a neuron and what ion pump maintains it?
- Name the ion that enters the axon during depolarisation.
- Why is conduction in myelinated fibres faster than in unmyelinated fibres?
- What happens during the absolute refractory period?
- Stretch: If the Na⁺/K⁺ ATPase is blocked by ouabain, will the very next action potential fire? What will happen after many firings? Explain using ion gradients.
NCERT Chapter 21 link: Chapter 21 "Neural Control and Coordination" covers neuron structure, nerve impulse, synapse, and CNS/PNS organisation — the action potential section maps to pages 336–341.
Exam connections: NEET frequently asks numerical/value-based questions on RMP (−70 mV), threshold (−55 mV), and peak depolarisation (+40 mV). Expect one MCQ on saltatory conduction and one on refractory period every year.
Study strategy: Draw the action potential curve from memory daily for 3 days; annotate ion movements at each phase. Use flashcards for numerical values. Solve previous 10 years' NEET Qs on this topic.
Interactive Exploration Suggestions (Drishti Live Worlds)
- Use the platform-native neuron simulator to adjust stimulus intensity below and above threshold and observe all-or-nothing behaviour; vary myelin thickness and observe conduction velocity changes.
- Mirror / body / home activity: Use a long rubber tube to model saltatory conduction — mark nodes of Ranvier with tape, tap each node in sequence and compare to tapping every point (unmyelinated). Photograph and add to portfolio.
- Voice or text reflection with AI Mentor: Explain to a younger sibling why a neuron is like a "switch" (all-or-nothing) rather than a "dimmer" (graded), using a light-switch example from home.
AI Mentor Prompts (Socratic, Board-Adaptive)
- "Explain the resting membrane potential to a Class 6 student using a crowded room (Na⁺) versus an empty room (K⁺) analogy from a school or market setting."
- "What is one common mistake students make when answering 'what stops depolarisation?', and how would you catch yourself making it?"
- Stretch: "How does the principle of the action potential connect to nerve conduction disorders like multiple sclerosis, or to how pain-killers (local anaesthetics) work? Link this to a future career in medicine or biotech."
Gamification, Portfolio & Parent Visibility
- Complete the core practice + one extension activity (photo, table, short reflection, or mini-project) for base XP + topic badge.
- 5-7 day streak or family discussion note = multiplier + visible artifact in parent/principal dashboard.
- Best real-world application stories (anonymised) featured on class or national leaderboard.
Robotics, STEM & Future Skills Bridges
- Build a simple electrical circuit with a switch to model the all-or-nothing firing; measure voltage across resistor to represent membrane potential. Document with multimeter readings.
- Direct link to AI Mastery (neural network architectures are inspired by neurons), Health & Medicine (pharmacology of Na⁺ channel blockers), and Cyber Defenders (signal encryption analogy).
- Coding extension: Write a Python script that simulates action potential firing (binary: fires if input ≥ threshold, silent otherwise) and prints the membrane potential sequence.
NEP 2020 & Full Education OS Alignment
This material emphasises experiential "learning by doing", competency (apply/create/analyse), vocational exposure, critical thinking, and multidisciplinary connections. Designed to feed live worlds, AI Mentor (with memory), gamification, robotics, parent analytics, and future skills — not just exam prep.
Portfolio Evidence Idea: Your photo/table/reflection/project + one sentence on "How this helps me in real life or a possible future path."
Open the Practice tab for aligned questions (easy/medium/hard + case-based) with full AI scaffolding.
See curriculum for cross-links and the full future-skills/robotics chapters.
Key Takeaways (TL;DR)
- What you'll learn
- Key concepts
- Worked example
- Common mistakes
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