Chemistry of Psilocybin and Synaptic Transmitters Involved

Chemical involvement of psilocybin and synaptic transmission Psilocybin is a hallucinogenic mushroom ingested by eating viable bacteria. You can also tea or drink mushrooms. In some recent studies on psirocibine, drugs were synthesized and then inhaled or injected intravenously. Because of the relative metabolic similarity of drugs to serotonin, drugs can enter the bloodstream and pass through the blood-brain barrier (Fuller 1985). This means that psicosin is chemically similar to the neurotransmitter serotonin, so that we can move psirocytin through a protein channel embedded in the vascular membrane in the same way as us.

Neurotransmission requires controlled release of neurotransmitters at synapses via synaptic vesicle exocytosis. The released emitter then diffuses through the synaptic cleft and binds to the homologous receptor of the postsynaptic neuron. They are ultimately removed from the extracellular medium by neural cells and glial cell membrane transporters. In the case of a classical (non-peptide) emitter, the presynaptic process involves the biosynthesis of emitter molecules in the cytosol, or their reuptake from extracellular media, which are then stored in synaptic vesicles. In this chapter we focus on transporters that are involved in the absorption of emitter vesicles.

The only synaptic process based on a particular quantum mechanism seems to be the role of Ca 2+ in emitter vesicles, as described in the hypothesis of Beck and Eccles. All other related mechanisms, in particular the combination of emitter and receptor, seem to obey the laws of classical chemistry. The process of primarily calling the quantum domain is the process after Ca ions have entered through the membrane channel (also the subject of this article, the metabotropic receptor that results in the release of cyclic AMP and the G protein receptor Activity). These processes are called "signaling pathways" (abbreviated STP) in the literature. They include the molecular binding mechanism of the classic "key and key", but there are also aspects that show the possibility of quantum communication / computation in that field (such as multiple protein conformation) .