1.5.8
Action Potentials
Resting Potential
Resting Potential
When a neurone has not been stimulated, it is at resting state.
Potential difference
Potential difference
- At resting state there is a difference in charge across the neurone membrane: the inside of the neurone is more negatively charged than outside.
- This is because there are more positive ions outside the cell than inside.
- The difference in charge is called a potential difference.
Sodium-potassium pumps
Sodium-potassium pumps
- The resting potential is maintained by sodium-potassium pumps in the neurone membrane.
- Three Na+ ions are actively transported out of the neurone by the pumps for every two K+ ions that are transported in.
- This leads to a build-up of positive ions outside the cell.
Potassium ion channels
Potassium ion channels
- There are potassium ion channels in the neurone membrane. This means it is permeable to K+ ions.
- When K+ ions are transported into neurones, they can diffuse back out.
- The neurone membrane is also impermeable to Na+ ions so the ions cannot diffuse back into the cell after they have been transported out.
Resting potential
Resting potential
- Together the action of sodium-potassium pumps and potassium ion channels leads to a potential difference across the neurone membrane.
- This potential difference is called the resting potential.
- The neurone is said to be polarised.
- Resting potential is about −70mV.
Depolarisation of the Neurone Cell Membrane
Depolarisation of the Neurone Cell Membrane
When a resting neurone is stimulated, its membrane experiences a change in potential difference. This change is called depolarisation. The steps are:
Stimulation
Stimulation
- Na+ ion channels in the cell membrane open when a neurone is stimulated.
- Na+ ions flood into the neurone.
- The potential difference across the membrane changes to become more positive inside the neurone.
Depolarisation
Depolarisation
- If the potential difference increases above the threshold value (about −55mV) then the membrane will become depolarised.
- More sodium channels open and there is a sharp increase in potential difference to about +30mV.
All-or-nothing
All-or-nothing
- Depolarisation is an all-or-nothing response.
- If the potential difference reaches the threshold, depolarisation will always take place and the change in potential difference will always be the same.
- If the stimulus is stronger, action potentials will produced more frequently but their size will not increase.
Repolarisation
Repolarisation
- After the neurone membrane has depolarised to +30mV, the sodium ion channels close and potassium ion channels open.
- Na+ ions are transported back out of the neurone and the potential difference becomes more negative.
- This is called repolarisation.
Hyperpolarisation
Hyperpolarisation
- There is a short period after depolarisation of a neurone where the potential difference becomes slightly more negative than the resting potential.
- This is called hyperpolarisation.
- Hyperpolarisation prevents the neurone from being restimulated instantly. This is called the refractory period.
Resting potential
Resting potential
- After the refractory period, the potassium ion channels close and the membrane returns to its resting potential.
- The process where a neurone is depolarised and returns to resting potential is called an action potential.
Action Potential
Action Potential
The stages involved in the depolarisation of a neurone membrane are called an action potential. Action potentials move along the neurone in a wave.
Sodium ions
Sodium ions
- When an action potential is generated, there are more Na+ ions inside the neurone than outside.
- Some of these Na+ ions diffuse sideways along the neurone axon.
Sodium ion channels
Sodium ion channels
- The presence of Na+ ions creates a change in potential difference further along the neurone membrane.
- If this reaches the threshold value, sodium ion channels at this part of the membrane open.
- Na+ ions diffuse into the neurone.
- This part of the neurone now becomes depolarised.
Wave of depolarisation
Wave of depolarisation
- Na+ diffuse all along the neurone in this way.
- Depolarisation takes place along the neurone membrane. This creates a wave of depolarisation.
Refractory period
Refractory period
- The period of hyperpolarisation in an action potential is called the refractory period.
- The ion channels are recovering during the refractory period. This means an action potential cannot be stimulated again instantly.
- This ensures that the wave of depolarisation travels in one direction.
1Principles of Science I
1.1Structure & Bonding
1.1.1Atomic Model
1.1.2Electron Shells, Sub-Shells & Orbitals
1.1.3Ionic Bonding
1.1.4Representing Ionic Bonds
1.1.5Covalent Bonding
1.1.6Representing Covalent Bonds
1.1.7Metallic Bonding
1.1.8Intermolecular Forces
1.1.9Intermolecular Forces 2
1.1.10End of Topic Test - Bonding
1.1.11Relative Masses
1.1.12The Mole
1.1.13Molar Calculations
1.1.14Molar Calculations 2
1.1.15Empirical & Molecular Formulae
1.1.16Balanced Equations
1.1.17Percentage Yield
1.1.18End of Topic Test - Amount of Substance
1.2Properties of Substances
1.2.1The Periodic Table
1.2.2Ionisation Energy
1.2.3Factors Affecting Ionisation Energies
1.2.4Trends of Ionisation
1.2.5Trends in the Periodic Table
1.2.6Polarity
1.2.7Metals & Non-Metals
1.2.8Alkali Metals
1.2.9Alkaline Earth Metals
1.2.10Reactivity of Alkaline Earth Metals
1.2.11Redox
1.2.12Transition Metals
1.2.13Redox Reactions of Transition Metals
1.3Cell Structure & Function
1.4Cell Specialisation
1.5Tissue Structure & Function
1.5.1Human Gas Exchange
1.5.2Blood Vessels
1.5.3Atherosclerosis
1.5.4Skeletal Muscle
1.5.5Slow & Fast Twitch Fibres
1.5.6Neurones
1.5.7Speed of Transmission
1.5.8Action Potentials
1.5.9End of Topic Test - Neurones & Action Potentials
1.5.10Synapses
1.5.11Types of Synapse
1.5.12Medical Application
1.5.13End of Topic Test - Synapses
1.5.14Chemical Brain Imbalances
1.5.15Effect of Drugs on the Brain
1.6Working with Waves
1.7Waves in Communication
2Practical Scientific Procedures and Techniques
3Science Investigation Skills
3.1Scientific Processes
3.2Data Handling & Analysis
3.3Enzymes in Action
3.4Diffusion
3.5Plants & Their Environment
3.6Energy Content in Fuels
4Principles of Science II
4.1Extracting Elements
4.2Relating Properties to use of Substances
4.3Organic Chemistry
4.4Energy Changes in Industry
4.5The Circulatory System
4.5.1The Circulatory System
4.5.2Blood Vessels
4.5.3Blood Transfusion & the ABO Rhesus System
4.5.4The Heart
4.5.5The Cardiac Cycle
4.5.6Cardiac Output
4.5.7Coordination of Heart Action
4.5.8Heart Dissection
4.5.9Controlling Heart Rate
4.5.10Electrocardiograms
4.5.11Cardiovascular Disease
4.5.12Investigating Heart Rates
4.6Ventilation & Gas Exchange
4.7Urinary System
4.9Thermal Physics
4.9.1Power & Efficiency
4.9.2Work & Energy
4.9.3Conservation of Energy
4.9.4Pressure
4.9.5First Law of Thermodynamics
4.9.6Second Law of Thermodynamics
4.9.7Heat Engines, Heat Pumps & Refrigerators
4.9.8Non-Flow Processes
4.9.9p-V Diagrams
4.9.10Ideal Gases
4.9.11Ideal Gases 2
4.9.12Thermal Energy Transfer
4.9.13Thermal Energy Transfer Experiments
4.10Materials
5Contemporary Issues in Science
5.1Contemporary Issues in Science
5.2Analysing Scientific Information
Jump to other topics
1Principles of Science I
1.1Structure & Bonding
1.1.1Atomic Model
1.1.2Electron Shells, Sub-Shells & Orbitals
1.1.3Ionic Bonding
1.1.4Representing Ionic Bonds
1.1.5Covalent Bonding
1.1.6Representing Covalent Bonds
1.1.7Metallic Bonding
1.1.8Intermolecular Forces
1.1.9Intermolecular Forces 2
1.1.10End of Topic Test - Bonding
1.1.11Relative Masses
1.1.12The Mole
1.1.13Molar Calculations
1.1.14Molar Calculations 2
1.1.15Empirical & Molecular Formulae
1.1.16Balanced Equations
1.1.17Percentage Yield
1.1.18End of Topic Test - Amount of Substance
1.2Properties of Substances
1.2.1The Periodic Table
1.2.2Ionisation Energy
1.2.3Factors Affecting Ionisation Energies
1.2.4Trends of Ionisation
1.2.5Trends in the Periodic Table
1.2.6Polarity
1.2.7Metals & Non-Metals
1.2.8Alkali Metals
1.2.9Alkaline Earth Metals
1.2.10Reactivity of Alkaline Earth Metals
1.2.11Redox
1.2.12Transition Metals
1.2.13Redox Reactions of Transition Metals
1.3Cell Structure & Function
1.4Cell Specialisation
1.5Tissue Structure & Function
1.5.1Human Gas Exchange
1.5.2Blood Vessels
1.5.3Atherosclerosis
1.5.4Skeletal Muscle
1.5.5Slow & Fast Twitch Fibres
1.5.6Neurones
1.5.7Speed of Transmission
1.5.8Action Potentials
1.5.9End of Topic Test - Neurones & Action Potentials
1.5.10Synapses
1.5.11Types of Synapse
1.5.12Medical Application
1.5.13End of Topic Test - Synapses
1.5.14Chemical Brain Imbalances
1.5.15Effect of Drugs on the Brain
1.6Working with Waves
1.7Waves in Communication
2Practical Scientific Procedures and Techniques
3Science Investigation Skills
3.1Scientific Processes
3.2Data Handling & Analysis
3.3Enzymes in Action
3.4Diffusion
3.5Plants & Their Environment
3.6Energy Content in Fuels
4Principles of Science II
4.1Extracting Elements
4.2Relating Properties to use of Substances
4.3Organic Chemistry
4.4Energy Changes in Industry
4.5The Circulatory System
4.5.1The Circulatory System
4.5.2Blood Vessels
4.5.3Blood Transfusion & the ABO Rhesus System
4.5.4The Heart
4.5.5The Cardiac Cycle
4.5.6Cardiac Output
4.5.7Coordination of Heart Action
4.5.8Heart Dissection
4.5.9Controlling Heart Rate
4.5.10Electrocardiograms
4.5.11Cardiovascular Disease
4.5.12Investigating Heart Rates
4.6Ventilation & Gas Exchange
4.7Urinary System
4.9Thermal Physics
4.9.1Power & Efficiency
4.9.2Work & Energy
4.9.3Conservation of Energy
4.9.4Pressure
4.9.5First Law of Thermodynamics
4.9.6Second Law of Thermodynamics
4.9.7Heat Engines, Heat Pumps & Refrigerators
4.9.8Non-Flow Processes
4.9.9p-V Diagrams
4.9.10Ideal Gases
4.9.11Ideal Gases 2
4.9.12Thermal Energy Transfer
4.9.13Thermal Energy Transfer Experiments
4.10Materials
5Contemporary Issues in Science
5.1Contemporary Issues in Science
5.2Analysing Scientific Information
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