A volley of signals races up through the of the thalamus. And then — you feel it. A massive excitatory postsynaptic potential (EPSP) arrives at your basal dendrites.
On the other side is your target: a in the ventral horn of the spinal cord, at the level of C5-C6 (imagine reaching for a cup). This LMN has ionotropic glutamate receptors — specifically, AMPA receptors (fast, Na+/K+) and NMDA receptors (slower, Ca2+ permeable, blocked by Mg2+ at rest).
The hose is open.
The muscle fiber fires an action potential. on the T-tubule sense the voltage change and mechanically open ryanodine receptors (RyRs) on the sarcoplasmic reticulum. Calcium floods the cytosol.
You are about to initiate movement. The EPSP travels down your dendrites, summing at the axon hillock — your decision zone. Here, voltage-gated sodium channels wait. The membrane potential crosses threshold (-55 mV from resting -70 mV). Bang. brain bee study guide
This is a — a narrative-style, memorable walkthrough of key Brain Bee concepts, designed to help you retain neuroscience competition material by embedding facts into a vivid scenario. The Synaptic Symphony: A Brain Bee Deep Story You are a neuron. Specifically, you are a pyramidal cell in Layer 5 of the primary motor cortex (Brodmann Area 4). Your name is Pyra.
One day, you receive an urgent message from the . A structure called the subthalamic nucleus has fired a burst of glutamate (excitatory) at your rival, an inhibitory neuron in the globus pallidus internus (GPi) . That GPi neuron normally clamps down on the thalamus like a hand squeezing a hose. But now, GPi is silenced. A volley of signals races up through the of the thalamus
Vesicles fuse. Glutamate spills into the synaptic cleft.