Answer :
In the brain, dendrites and axons play essential roles in transmitting signals between neurons. Here's how they function together:
1. Dendrites: Dendrites are branching extensions of neurons that receive signals from other neurons. They act like antennae, capturing incoming signals in the form of neurotransmitters released by neighboring neurons.
2. Signal Integration: Dendrites collect and integrate these signals, determining whether the neuron will generate its own signal called an action potential. If the combined signals are strong enough to reach a threshold, the neuron will fire an action potential.
3. Axon: Once the neuron generates an action potential, it travels down the axon, a long, tubular structure that acts like a wire, transmitting the electrical signal from the cell body to the axon terminals.
4. Myelin Sheath: In many neurons, the axon is insulated by a myelin sheath, which helps speed up the transmission of the action potential by allowing it to "jump" between gaps in the myelin called nodes of Ranvier.
5. Axon Terminals: At the end of the axon, the electrical signal triggers the release of neurotransmitters into the synapse, the tiny gap between the axon terminal of one neuron and the dendrite of another.
6. Synaptic Transmission: The released neurotransmitters then bind to receptors on the dendrite of the receiving neuron, continuing the signal transmission process. This sets off a new electrical signal in the receiving neuron's dendrites, continuing the communication between neurons.
In summary, dendrites receive signals, axons transmit signals over long distances, and together they form the basis of communication between neurons in the brain. This intricate interplay is fundamental to processes like learning, memory, and overall brain function.
1. Dendrites: Dendrites are branching extensions of neurons that receive signals from other neurons. They act like antennae, capturing incoming signals in the form of neurotransmitters released by neighboring neurons.
2. Signal Integration: Dendrites collect and integrate these signals, determining whether the neuron will generate its own signal called an action potential. If the combined signals are strong enough to reach a threshold, the neuron will fire an action potential.
3. Axon: Once the neuron generates an action potential, it travels down the axon, a long, tubular structure that acts like a wire, transmitting the electrical signal from the cell body to the axon terminals.
4. Myelin Sheath: In many neurons, the axon is insulated by a myelin sheath, which helps speed up the transmission of the action potential by allowing it to "jump" between gaps in the myelin called nodes of Ranvier.
5. Axon Terminals: At the end of the axon, the electrical signal triggers the release of neurotransmitters into the synapse, the tiny gap between the axon terminal of one neuron and the dendrite of another.
6. Synaptic Transmission: The released neurotransmitters then bind to receptors on the dendrite of the receiving neuron, continuing the signal transmission process. This sets off a new electrical signal in the receiving neuron's dendrites, continuing the communication between neurons.
In summary, dendrites receive signals, axons transmit signals over long distances, and together they form the basis of communication between neurons in the brain. This intricate interplay is fundamental to processes like learning, memory, and overall brain function.
