Sodium floods in (phase 0: depolarization). Then, open, repolarizing you (phase 3). But a special class of calcium-dependent potassium channels ensures you have an afterhyperpolarization — a refractory period so you don't fire chaotically.
At the NMJ, the enzyme — sitting on the basal lamina — rapidly cleaves ACh into acetate and choline. Choline is taken back up into the LMN via the choline transporter (CHT1) , then reused.
The LMN fires. Its axon travels via the into the brachial plexus , then the radial nerve , finally reaching the neuromuscular junction (NMJ) of your biceps brachii . Step 3: The Neuromuscular Junction At the NMJ, the LMN releases acetylcholine (ACh) . ACh binds to nicotinic acetylcholine receptors (nAChRs) on the muscle fiber's motor end plate. These are ligand-gated ion channels — they let Na+ in, K+ out, creating an end-plate potential (EPP) .
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. brain bee study guide
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).
At the synapse onto the LMN, in the cleft take up excess glutamate via EAAT2 transporters , converting it to glutamine (via glutamine synthetase), sending it back to you to recycle.
Calcium binds to . Tropomyosin shifts away. Myosin heads — already loaded with ADP and Pi — bind to actin. Power stroke. Pi released. New ATP binds, myosin releases actin, then hydrolyzes ATP to recock the head. Sodium floods in (phase 0: depolarization)
Your action potential speeds down your (courtesy of oligodendrocytes in the CNS). The myelin sheaths are interrupted by Nodes of Ranvier , where saltatory conduction leaps the signal from node to node — much faster than unmyelinated axons. Step 2: The Synapse You arrive at the presynaptic terminal . Depolarization opens voltage-gated calcium channels (VGCCs) . Calcium rushes in. This triggers synaptic vesicles — loaded with glutamate — to dock at the active zone via SNARE proteins (synaptobrevin on vesicle, syntaxin and SNAP-25 on membrane).
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.
The hose is open.
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.
: Tight junctions between endothelial cells, supported by astrocyte end-feet. Circumventricular organs (area postrema, OVLT, etc.) lack BBB — they sample blood for toxins (vomiting center) or osmolality. Final Exam Question (Self-Test) A 65-year-old man has difficulty initiating movement, a resting "pill-rolling" tremor, and a shuffling gait. He is treated with L-DOPA. Which specific neuron population is degenerating, and what neurotransmitter do they normally release? Answer: Dopaminergic neurons in the substantia nigra pars compacta; neurotransmitter = dopamine. End of Deep Story. Use this narrative to anchor facts: imagine yourself as Pyra the pyramidal neuron, lifting the cup, and all the molecules and disorders that could help or hinder you. Good luck at the Brain Bee! 🧠🐝
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. At the NMJ, the enzyme — sitting on
Vesicles fuse. Glutamate spills into the synaptic cleft.
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.