Review the Synapse

1. Review the Synapse • What is a synapse? • A synapse is the “gap” between the axon of one nerve and the dendrite of the next one. • The average neuron has 1,000 synapses with other neurons.

2. Neurotransmitters • There are dozens of different neurotransmitters (NT) in the neurons of the body. • NTs can be either excitatory or inhibitory • Each neuron generally synthesizes and releases a single type of neurotransmitter • The major neurotransmitters are indicated on the next slide.

3. Major Neurotransmitters in the Body NIH Publication No. 00-4871

4. Drugs Interfere with Neurotransmission • Drugs can affect synapses at a variety of sites and in a variety of ways, including: • Increasing number of impulses • Release NT from vesicles with or without impulses • Block reuptake or block receptors • Produce more or less NT • Prevent vesicles from releasing NT

5. Three Drugs (of many) which affect Neurotransmission Methamphetamine Nicotine Alcohol seattlepi.nwsource.com/ methamphetamines/ science.howstuffworks.com/ alcohol.htm

6. Illegal Drugs Click on the drug below to find out how it affects the brain. Marijuana Ecstasy Cocaine More information on drugs and the brain

7. Marijuana Marijuana contains a molecule, elta-9-tetrahydrocannabinol (THC for short), that binds to receptors found in brain neurons. The receptors are called cannabinoid receptors are found in the parts of the brain associated with memory, concentration, perception and movement. When THC binds to the receptors the nerve function is disrupted We produce a chemical called anandamide which binds to cannabinoid receptors just like THC does. Scientists are not sure what anandamide does in the brain. “Why do we have cannabinoid receptors in our brains? • sleepiness • Altered sense of space and time. • Lowered blood pressure • Difficulty concentrating • delusions • hallucinations • Reduced coordination • disorientation • relaxation • Impaired memory

8. Methamphetamine alters Dopamine transmission in two ways: 1. Enters dopamine vesicles in axon terminal causing release of NT 2. Blocks dopamine transporters from pumping dopamine back into the transmitting neuron seattlepi.nwsource.com/ methamphetamines/ NIH Publication No. 00-4871

9. Result: More dopamine in the Synaptic Cleft • This causes neurons to fire more often than normal resulting in a euphoric feeling.

10. Problems…… • After the drug wears off, dopamine levels drop, and the user “crashes”. The euphoric feeling will not return until the user takes more methamphetamine • Long-term use of methamphetamine causes dopamine axons to wither and die. • Note that cocaine also blocks dopamine transporters, thus it works in a similar manner. • To see an animation on cocaine and brain synapses, click here.

11. Ecstasy Ecstasy,3,4 methylenedioxymethamphetamine or "MDMA” is a dangerous drug to party with. There are risks of dying during use but this page will discuss long term affects on the brain. MDMA (Ecstasy) affects serotonin in the brain by causing the release of serotonin, keeping serotonin from being cleaned up, and depleting available serotonin. This leads to an elevated mood but the loss of serotonin will lead to a depression of the mood. Maybe even worse than the depression that follows ecstasy is the damage caused to brain cells. Did you know that ecstasy was first invented and used as a medicinal drug but the use was stopped after scientists found it caused brain damage.

12. Alcohol The images to the left shows an alcoholic man and a non-alcoholic man. Notice the ventricle space is much larger in the alcoholic man. Long-term drinking results in loss of brain tissue as well as causes other damage to the brain Alcohol is a small molecule that easily passes the blood brain barrier. (Remember the blood brain barrier protects your brain from internal invaders and chemicals) Alcohol is very easily absorbed by the body and the brain. Click here to see an animation of the effect of alcohol on nerve transmission. (Advanced)

13. How does alcohol affect synapses? • Alcohol has multiple effects on neurons. It alters neuron membranes, ion channels, enzymes, and receptors. • It binds directly to receptors for acetylcholine, serotonin, and gamma aminobutyric acid (GABA), and glutamate. • We will focus on GABA and its receptor.

14. GABA and the GABA Receptor • GABA is a neurotransmitter that has an inhibitory effect on neurons. • When GABA attaches to its receptor on the postsynaptic membrane, it allows Cl- ions to pass into the neuron. • This hyperpolarizes the postsynaptic neuron to inhibit transmission of an impulse.

15. Alcohol and the GABA Receptor • When alcohol enters the brain, it binds to GABA receptors and amplifies the hyperpolarization effect of GABA. • The neuron activity is further diminished • This accounts for some of the sedative affects of alcohol science.howstuffworks.com/ alcohol.htm

16. The Adolescent Brain and Alcohol From AMA pub 9416 • The brain goes through dynamic change during adolescence, and alcohol can seriously damage long- and short-term growth processes. • Frontal lobe development and the refinement of pathways and connections continue until age 16, and a high rate of energy is used as the brain matures until age 20. • Damage from alcohol at this time can be long-term and irreversible.

17. The Adolescent Brain (cont.) • In addition, short-term or moderate drinking impairs learning and memory far more in youth than adults. • Adolescents need only drink half as much as adults to suffer the same negative effects. • To see an animation of GABA receptors and the influence of alcohol, click here.

18. Drugs That Influence Neurotransmitters NIH Publication No. 00-4871

19. What about Nicotine? • Similar to methamphetamine and cocaine, nicotine increases dopamine release in a synapse. • However, the mechanism is slightly different. • Nicotine binds to receptors on the presynaptic neuron.

20. Nicotine binds to the presynaptic receptors exciting the neuron to fire more action potentials causing an increase in dopamine release. • Nicotine also affects neurons by increasing the number of synaptic vesicles released.