What effect does an excitatory synapse have on a post-synaptic neuron?

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Study for the AQA Biopsychology Exam. Review key concepts with flashcards and multiple-choice questions, complete with hints and explanations. Get ready for your exam!

Multiple Choice

What effect does an excitatory synapse have on a post-synaptic neuron?

Explanation:
An excitatory synapse plays a crucial role in neural communication by increasing the likelihood that the post-synaptic neuron will fire an action potential. This occurs through the release of excitatory neurotransmitters that bind to specific receptors on the post-synaptic membrane. When these neurotransmitters bind, they typically lead to depolarization of the post-synaptic neuron, making it more likely to reach the threshold needed to initiate an action potential. In the context of neural circuitry, the activation of excitatory synapses is essential for processes such as learning and memory, as it facilitates the transmission of signals between neurons. This mechanism is vital in the nervous system, where coordinated activity between neurons is required for various functions, including reflexes and complex behaviors. While stabilizing neural connections and neurotransmitter release are important for overall brain function, they describe different aspects of synaptic activity and are not specifically related to the primary effect of excitatory synapses.

An excitatory synapse plays a crucial role in neural communication by increasing the likelihood that the post-synaptic neuron will fire an action potential. This occurs through the release of excitatory neurotransmitters that bind to specific receptors on the post-synaptic membrane. When these neurotransmitters bind, they typically lead to depolarization of the post-synaptic neuron, making it more likely to reach the threshold needed to initiate an action potential.

In the context of neural circuitry, the activation of excitatory synapses is essential for processes such as learning and memory, as it facilitates the transmission of signals between neurons. This mechanism is vital in the nervous system, where coordinated activity between neurons is required for various functions, including reflexes and complex behaviors.

While stabilizing neural connections and neurotransmitter release are important for overall brain function, they describe different aspects of synaptic activity and are not specifically related to the primary effect of excitatory synapses.

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