"Chemistry" of the brain: from neurotransmitters to psychedelics. General structure of the brain; nerve cells and substances that make up nerve cells About the course of lectures "Chemistry of the brain"

Tuesday, November 20, 2018, 19:30–21:00, Moscow, Arche Cultural and Educational Center.

The cultural and educational center "Arkhe" invites you to the course of lectures by Vyacheslav Dubynin "Chemistry of the Brain".

Topic of the eighth lecture: "Serotonin".

Vyacheslav Albertovich Dubynin

Doctor of Biological Sciences, Professor of the Department of Human and Animal Physiology, Faculty of Biology, Moscow State University: “The surest way to happiness is to try the maximum number of different activities and find those that give you the most pleasure (of course, socially approved).”

Serotonin, sometimes called the "happiness hormone", as a neurotransmitter inhibits the centers of negative emotions in our brain and fights depression.

Substances that disrupt the activity of serotonin in the cerebral cortex can cause hallucinations (LSD and other psychedelic drugs).
In the periphery, drugs that affect serotonin signaling are used to regulate vascular tone (eg, in migraines).
In the nervous system, serotonin is also involved in the regulation of pain sensitivity and the sleep-wake cycle.

Consideration of all these issues, as well as a story about the properties of antidepressants, the history of the study of ergot alkaloids, the specifics of the influence of psychedelics and other hallucinogens on the human brain, constitute the content of the next lecture of the cycle.

About the course of lectures "Brain Chemistry":

As part of the course, it is planned to talk in a popular form about the principles of the nervous system at the structural, cellular and molecular levels. The main attention will be paid to those chemicals, with the help of which various information flows are transmitted in the human brain - from the senses, to the muscles, in the centers of memory, emotions, etc. It is these substances (“neurotransmitters”) that are the basis for the creation of psychopharmacological drugs; many poisons and drugs are similar to them.

In parallel, there will be a conversation about the general principles of the functioning of our body, various neuro- and psychopathologies, the impact of hormones on the brain, the immune system, and much more. Will be considered: glutamate and gamma-aminobutyric acid (the main neurotransmitters of the CNS); dopamine, serotonin and opioid peptides (neurotransmitters most closely associated with the sphere of positive emotions); acetylcholine and norepinephrine (mediators of the peripheral nervous system) and dozens of other interesting and important molecules, including glycine and strychnine, nicotine and cannabinoids, caffeine and alcohol.

Course plan:

General structure of the brain (briefly); nerve cells, substances that make up nerve cells
Electrical activity of neurons
Synapse
Acetylcholine
Norepinephrine
Glutamate and GABA
Dopamine
Serotonin
Other mediators
Mediators, hormones, cytokines

Ticket price: 600 rub. Students - 250 rubles; schoolchildren - 150 rubles.

For those who do not have time or do not have the opportunity to come to the lecture, there is the opportunity to watch Internet broadcasts. The cost of broadcasting is 250 rubles.
To register, please email: [email protected] or you can pay immediately through TimePad.

You can register for the course by email: [email protected](when registering for the course, indicate the name and name of the course) or through

"Chemistry" of the brain: from neurotransmitters to psychedelics
Labor intensity: 24 classroom hours (12 lectures).
Reporting Form- offset.
Lecturer: Dubynin Vyacheslav Albertovich, Doctor of Biological Sciences, Professor of the Department Physiology of Humans and Animals, Faculty of Biology, Moscow State University
Responsible for IFC: Dubynin Vyacheslav Albertovich, [email protected]

annotation

The author's interfaculty course is a continuation of the IFC "The Brain and Human Needs", read in the fall of 2015 (http://media.msu.ru/?cat=373; attracted the attention of more than 300 listeners). As part of the course, it is planned to talk in a popular form about the principles of the nervous system at the structural, cellular and molecular levels. The main attention will be paid to those chemicals that transmit various information flows in the human brain - from the senses, to the muscles, to the centers of memory, emotions, etc. It is these substances (“neurotransmitters”) that are the basis for the creation of psychopharmacological drugs; many poisons and drugs are similar to them. In parallel, the conversation will continue on the general principles of the functioning of our body, various neuro- and psychopathologies, the impact of hormones on the brain, the immune system, and much more. Most lectures of the course are devoted to the ability of neurotransmitters not only to determine the mental state of a person, but also to influence the fate of groups of people and entire states. Will be considered:

acetylcholine: the first of the discovered neurotransmitters, thanks to which our muscles contract, the work of internal organs and the brain normalizes; nicotine is similar to acetylcholine, on the example of which the mechanisms of the formation of drug addiction will be considered;
norepinephrine: mediator of stress and excitement; it makes the heart beat faster in anticipation of trouble or a fight, helps to preserve the memory of victories and defeats; based on it, drugs have been created that help fight many diseases - from hypertension and asthma to the common cold;
glutamate: a substance known as a "flavor enhancer" is also the main neurotransmitter in our brain; with the help of glutamate, memory centers work and information is transmitted from the sense organs, and its excess destroys nerve cells (epilepsy, Alzheimer's disease);
GABA (gamma-aminobutyric acid): a neurotransmitter that blocks unnecessary information flows, providing our attention and motor control; drugs similar to GABA can calm and lull, but they also stop breathing in case of an overdose;
dopamine: responsible for many types of positive emotions; it is his action that imitates cocaine and amphetamines - the most dangerous drugs; excessive activity of dopamine in the brain can provoke schizophrenia and mania, for which antipsychotics were invented to contain;
serotonin: a substance sometimes called the "happiness hormone" actually inhibits the centers of negative emotions and fights depression; drugs that disrupt the functioning of serotonin in the brain can cause hallucinations (LSD and other psychedelic drugs);
opioid peptides: effectively control pain and positive emotions; substances similar to them (morphine, heroin) are the most powerful analgesics and the most “desirable” drugs, causing intense euphoria and almost instant addiction;
adenosine: produced during fatigue, and its appearance is interpreted by the brain as a signal of fatigue; the action of adenosine on nerve cells is hindered by caffeine, the most commonly used psychotropic drug by mankind; etc.

A special lecture of the cycle will be devoted to alcohol (ethyl alcohol). Although it is not a mediator, the effects of ethyl alcohol on the brain are mediated by GABA and dopamine, which are also responsible for the formation of alcohol dependence. The causes of individual reaction to alcohol, alcohol intolerance, etc. will be considered.

Questions for offset

Why does our brain need carbohydrates and lipids? What are the features of their functions in the nervous system?
What functions do proteins perform in the nervous system (enzymes, transport, receptor, etc.)?
Describe the general structure of a nerve cell and the functions of its processes. What are the functions of neuroglial cells?
What is resting potential (RP)? Due to what processes does it arise and what is it usually equal to?
What plant toxins can "discharge" PP? How do they do it and what does it lead to?
What is an action potential (AP)? What ions determine the launch of AP and the return to the PP level?
What drugs can block PD? How do they do it and what does it lead to?
How does PD propagate throughout the nerve cell? Why is this happening so slowly and what factors speed up this process?
Synapse: general structure, diversity and principles of functioning. What are neurotransmitters?
How does AP trigger neurotransmitter release at the synapse? The key role of calcium ions.
Influence of magnesium ions, botulinum toxin ("Botox") and karakurt spider toxin on the functioning of the synapse.
Principles of the effect of a neurotransmitter on a receptor protein; triggering excitation or inhibition of the next cell.
Fast (ionotropic) and slow (metabotropic) types of receptor proteins; concept of molecules - second messengers.
Why is it necessary to inactivate a neurotransmitter after it affects the receptor? How does this happen?
Agonists and antagonists of neurotransmitter receptors: general principle of action and practical application.
Acetylcholine as the main mediator of the peripheral nervous system; variety of acetylcholine receptors.
Acetylcholine and neuromuscular synapses (control of skeletal muscle contractions).
Acetylcholine and the parasympathetic system of the human body; ways and means of controlling the work of internal organs.
Nicotine, its physiological activity, mechanisms of formation of addiction and dependence.
Acetylcholine inactivation and its practical applications (from insecticides to drugs).
Norepinephrine as a mediator of the sympathetic nervous system and brain; variety of receptor types.
Norepinephrine, adrenaline and stress: reactions of internal organs and central nervous system (emotions, memory, etc.).
Agonists and antagonists of norepinephrine receptors as the most important groups of drugs (hypertension, asthma, etc.).
Glutamic acid (glutamate) as a "flavor enhancer" and the main excitatory mediator of the central nervous system; variety of receptor types.
GABA (gamma-aminobutyric acid) - the main inhibitory mediator of the central nervous system; variety of receptor types.
Disruption of the balance of glutamate and GABA is the most important cause of neuropathologies; Genesis and treatment of epilepsy.
Effects of plant poisons-convulsants. Neurotoxic effect of excess glutamate activity.
Alzheimer's disease: causes, consequences and attempts at correction; the role of glutamate and acetylcholine.
How to induce sleep and anesthesia: the role of GABA receptor agonists and glutamate receptor antagonists.
Increased anxiety: causes and consequences; tranquilizers (anxiolytics) and problems of their use.
Nootropic action of GABA and its derivatives; attention deficit hyperactivity disorder (ADHD).
Dopamine as a CNS mediator, main functions, connection with the generation of positive emotions; dopamine receptors.
Dopamine and movement; the role of the substantia nigra of the midbrain. Parkinsonism: causes, consequences and correction attempts (L-DOPA).
Dopamine and information processing in the cerebral cortex. Schizophrenia and antipsychotic drugs.
Dopamine and the needs centers of the brain. Manic states, lobotomy and antipsychotics.
Dopamine and psychomotor stimulants (history of amphetamines; amphetamines as narcotic drugs).
Narcotic action of cocaine: mechanisms, background, formation of addiction and dependence, consequences and treatment.
Serotonin as a hormone and neurotransmitter; diversity of receptors and peripheral effects (migraines, etc.).
A variety of serotonin functions in the central nervous system: control of sleep and wakefulness, pain sensitivity, the level of negative emotions; the role of raphe nuclei.
Depression: causes, consequences, correction. Variety of antidepressants; the key role of serotonin.
Serotonin and psychedelic drugs. LSD: background, mechanisms of action and consequences of use.
Variety of hallucinogenic drugs. Ecstasy: mechanisms of action and consequences of use. Spice and their danger.
Neurotransmitters-peptides: diversity of structure and effects. Main groups. substance R.
Neurotransmitters-peptides: features and prospects of pharmacological application; nootropic activity.
Opioid peptides (endorphins and enkephalins): variety of receptors and variety of functions.
Morphine and its derivatives as painkillers: application specifics; other groups of analgesics.
Opioids are like drugs. Opium, morphine, heroin: the history of the issue, the formation of addiction and dependence, consequences and treatment.
Adenosine as a mediator of the nervous system (fatigue signal) Mechanisms of action of caffeine and related compounds.
Glycine as an auxiliary inhibitory mediator of the CNS. Therapeutic effect of glycine. Strychnine as a convulsant poison.
Histamine as a hormone and neurotransmitter. Antihistamines: Allergy and effects on the central nervous system.
Anandamide as one of the neurotransmitters (main functions). Effects of cannabinoids - anandamide receptor agonists.
Nerve growth factors: their importance for the formation and functioning of the brain, nootropic and neurotrophic effects.
Alcohol (ethyl alcohol): mechanisms of action on the human body (including the nervous system).
Formation of alcohol dependence; consequences and treatment; alcoholism as a medical and social problem.
Variety of addictions: summary classification; drug addiction as a medical and social problem.
Variety of psychotropic drugs: a summary classification. Main groups and scopes.
Ways, mechanisms and consequences of the action of the nervous system on the endocrine system (brain and control of hormone release).
Ways, mechanisms and consequences of the action of the nervous system on the immune system (the brain and various types of immunity).
Ways, mechanisms and consequences of the action of the endocrine system on the nervous system (hormones that control the brain).
Ways, mechanisms and consequences of the action of the immune system on the central nervous system (from normal regulation to multiple sclerosis).

Course program

Lecture 1. Overview of the structure and functions of the human brain. Chemical and cellular levels of its organization (everyone should know this).

Tuesday, October 2, 2018, 19:30–21:00, Moscow, Arche Cultural and Educational Center.

The cultural and educational center "Arkhe" invites you to the course of lectures by Vyacheslav Dubynin "Chemistry of the Brain".

Topic of the first lecture: “The general structure of the brain; nerve cells and the substances that make up nerve cells.

Vyacheslav Albertovich Dubynin

The first lecture of the cycle will be devoted, first of all, to a brief anatomical and functional review of the nervous system - from the cellular level to the main blocks of the central nervous system.

At the lecture we:

Let's get acquainted with the structure of neurons and the purpose of their processes.
Let us analyze (on the example of the spinal cord) the reflex principles of the activity of the nervous system.
Consistently "rise" from the stem structures of the brain to the cerebral cortex. To understand the features of the brain, it is also important to understand the structure and functions of a single nerve cell.
We will consider, first of all, the role of protein molecules - enzymes, channels, pumps, receptors. Only their continuous coordinated work ensures both the very existence of the nerve cell and its activity as a device that transmits information.

About the course of lectures "Brain Chemistry":

Course plan:

General structure of the brain (briefly); nerve cells, substances that make up nerve cells
Electrical activity of neurons
Synapse
Acetylcholine
Norepinephrine
Glutamate and GABA
Dopamine
Serotonin
Other mediators
Mediators, hormones, cytokines

Ticket price: 600 rub. Students - 250 rubles; schoolchildren - 150 rubles.
Subscription for 5 lectures - 2700 rubles. (allows you to attend any five lectures of the course) [students - 1250 rubles; schoolchildren - 750 rubles.]
Subscription for the course (10 lectures) - 5000 rubles. [students - 2500 rubles; schoolchildren - 1500 rubles.]