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Uncommon Scents Episode Three: Activity One | Teacher Pages A NEURON PLAY BACKGROUND TEACHER PAGES In this activity the students will model a neuron circuit to learn how it functions. Messages travel through the nervous system by means of an electrochemical process called neurotransmission. A key component in this process is the neuron, a nerve cell that is specialized to transmit and receive information. A typical neuron has a cell body that contains the nucleus and other cell organelles. Extending from the cell body are projections called dendrites that bring messages or signals into the cell from other neurons. A neuron also has a long extension called an axon that carries signals away from the cell. In neurotransmission, a signal received by a neuron’s dendrites can cause an electrical impulse known as an action potential to travel down the axon of the cell. Some axons are covered with myelin sheaths. Each myelin sheath is made by a single glial cell which wraps itself around the axon and produces many layers of a fatty tissue. Because of the fatty tissue’s insulating effect, the myelin sheaths help the action potential to travel faster. An action potential is produced when specific ion channels on the axon membrane open and positively charged ions stream into the axon. If the difference in charge between the inside of the cell and the outside of the cell reaches a critical level (threshold), the action potential is initiated. In an unmyelinated axon, all ion channels along the axon are opened, and it takes a relatively long time for the signal to travel down the axon (signal speed is approximately 2 meters per second). In a myelinated axon, only those ion channels in the gaps between the myelin sheaths are opened. The action potential “jumps” between the myelin sheaths, which is much faster - the signal reaches a speed of approximately 120 meters per second. Organic solvents alter neurotransmission by destroying the myelin sheaths. This destruction is responsible for some of the long-term effects produced by the drug, such as impairment of movement or even paralysis. > See PowerPoint “Uncommon Scents03_Activity01” Neurons are separated by a gap (synaptic cleft) that the action potential cannot cross. Once the action potential reaches the end of an axon (its terminal), it stimulates the release of chemicals called neurotransmitters. The neurotransmitters exit the terminal, cross the synaptic cleft, and relay the signal to a neighboring neuron by binding to specific protein receptors. Once the signal has been received, the neurotransmitters are released back into the synaptic cleft. They are either destroyed by enzymes or taken up by the neuron that released them (reuptake). Two different types of neurons are sensory neurons and motor neurons. Sensory neurons receive input from the environment. Motor neurons communicate with muscles and make them contract. LEARNING OBJECTIVES The students will: • Name two different types of neurons • Demonstrate the process of neurotransmission • Understand the relationship of neurotransmission and organic solvents 8 Uncommon Scents | Teaching Materials STANDARDS National Science Content Standards: 5-8 Standard C Students should develop understanding of structure and function in living systems. MATERIALS PREPARATION TEACHER PAGES • Signs with string to go around students’ necks ◊ Neuron 1 (sensory neuron) ◊ Neuron 2 (sensory neuron) ◊ Neuron 3 (motor neuron) ◊ Neuron 4 (motor neuron) ◊ Neurotransmitter (2 signs) • Signs that students hold ◊ Lightning bolt ◊ Brain • Roll of toilet paper • Basketball • Two bags with small objects such as marbles (preferably two different kind of objects) • Empty trash can to catch basketball at the end 1.Make the signs 2.Read through the Neuron Play script and insert your school’s and a rival school’s name in the appropriate blanks. PROCEDURE 1.Recruit students to take on the roles of the basketball player, neurons 1-4, the brain, and two neurotransmitters. 2.Give each neuron his/her appropriate sign. Wrap one arm of each “neuron” student in toilet paper to simulate the myelin sheath. 3.Hand the brain model to the brain person. 4.Give a bag of neurotransmitters to each neurotransmitter person. 5.Give the trash can to one student. 6.Line the students up at the front of the class with the basketball player at one end of the line and the brain at the other. Put neurons 1 and 2 between them. Have the dendrites of neuron 1 touch the player, and the axon close to but not touching the dendrites of neuron 2. Let the other students sit down until needed. 7.Point out to the students that their unwrapped arm is the dendrite, their body is the cell body, and the wrapped arm is the axon. Read the script, calling up the other players as they are mentioned in the script. 8.End the play by saying that this is how things work in a healthy nervous system. Ask students if they can name things or events that can cause the neurotransmission process to NOT work correctly. Students should brainstorm such things as: • damage to the brain (not wearing helmets or risky activities) • organic solvents (cause myelin destruction, model this by holding a can of some common organic solvent like spray paint and take away the toilet paper covering on the axons) • drug abuse (model this by using the neurotransmitters -- for example, drugs such as Ecstasy can cause an excess of serotonin by blocking serotinin re-uptake into the sending neuron; other drugs such as heroin and morphine bind to opioid receptors in the receiving neurons and mimic endogenous opioids) Uncommon Scents | Teaching Materials 9 A NEURON PLAY RESOURCES TEACHER PAGES “Once upon a time, a student was playing in a basketball game. The game was very close and everyone was tense. It was the final game for the coveted league championship title - _______________ (your school) vs ________________ (rival). One student found himself/herself out on the court in the final seconds of the game. His/her team was behind by one point. They needed a basket to win. Suddenly the student found that the basketball had somehow ended up in his/her hands. The whole world went into slow motion. Despite what some might say, this is what REALLY happened (put ball in hands of player). The dendrites in the sensory neurons of his/her hands were triggered by the touch of the ball in his/her hand. An electrical signal passed from the dendrites to the cell body of the neuron (move the lightning bolt along Neuron 1). From there the signal traveled at up to 250 miles per hour, down the axon carrying signals away from the cell body and on to other places. Suddenly, the signal reached a synapse (have first neurotransmitter person come up). This was it. There was a gap and the electrical signal could not go across it. All of a sudden though, some chemicals, neurotransmitters, went across the gap and on to the dendrites of the second neuron (have neurotransmitter person put some objects into the axon hand of Neuron 1 , then Neuron 1 hands them to the dendrite hand of Neuron 2). The electrical signal quickly moved along the second neuron towards the brain (move lightning bolt along Neuron 2). When it reached the brain stem, it traveled up to the thalamus. From there it was sent to the correct part of the brain. The brain sorted out all the information and in an instant, made the decision that the player must shoot the ball if the team would have any chance of winning the game. But wait a minute. It’s not that easy (move lightning bolt through brain). The brain had to get the message back to the player’s hands. Surely the game would be lost. But then, suddenly, from nowhere the motor neuron was located (have Neurons 3 and 4 come up - Neuron 3’s dendrites should touch the brain, and Neuron 4 is in line behind Neuron 3). Thank goodness for the many hours the player had spent shooting and going over just such a situation in the mind. The pathways in the brain were well connected and that made a quick response possible. The electrical signal traveled from the brain on its way to give the message to the distant body parts (move lightning bolt along Neuron 3). Oh no, another synapse! (Have second neurotransmitter person come up and put neurotransmitter into the axon hand of Neuron 3. Neuron 3 then hands the objects to the dendrite hand of Neuron 4). Fortunately, the electrical message was once again quickly translated into a chemical message and carried on to the next neuron where it changed back to an electrical signal and passed through the dendrites, a cell body, and axon (move lightning bolt along Neuron 4). This axon was a very long axon that went back to the arm muscle. The message to tell the muscles to contract and the player’s arm to shoot the ball was sent. The player released the ball just as the buzzer sounded. It swished through the hoop (have student with trashcan come up to catch the ball). What a great moment! _____(Your school) won the championship. • Making a Mad, Mad, Mad Neuron (University of Utah) Train with Dr. Dendristein to become an apprentice mad scientist by building your own monster neural circuit! http://learn.genetics.utah.edu/content/addiction/reward/madneuron.html • Crossing the Divide: How Neurons Talk to Each Other (University of Utah) Clear and colorful animations illustrate the complex communications carried on between neurons. http://learn.genetics.utah.edu/content/addiction/reward/neurontalk.html EXTENSION ACTIVITIES • Science: Compare and contrast the different types of neurons in the nervous system • Science: Investigate the chemical process that induces neurotransmitter release • History: Examine the history of the discovery of the neuron 10 Uncommon Scents | Teaching Materials A NEURON PLAY STUDENT ACTIVITIES Uncommon Scents Episode One: Activity Three | Student Activity Sheet In this activity, you will model a neuron circuit to learn how it functions. PROCEDURE 1.Your teacher will select some of you to play different roles in a neurotransmission cycle. The roles are: ◊ Brain ◊ Neurons 1 and 2 (sensory neurons) ◊ Neurons 3 and 4 (motor neurons) ◊ Neurotransmitter ◊ Basketball player 2.Your teacher will read A Neuron Play to you and give the players instructions what to do in their different roles 3.If you are part of the audience, pay close attention to what the different players do and how their actions affect the neurotransmission cycle. Uncommon Scents | Teaching Materials 11 A NEURON PLAY, RECAP 1 STUDENT ACTIVITIES Name ___________________________________ Class ________ Date __________________ Think about what happened in the play. Use the space below to create a simple drawing of the neurotransmission pathway. Make sure you include and LABEL the following: dendrite, cell body, axon, myelin, neuron, neurotransmitter, synapse. A NEURON PLAY, RECAP 2 In your own words, explain what happens when an organic solvent enters the body. How does it affect neurotransmission? Make sure you use the following words in your explanation: neuron, axon, myelin, organic solvent. __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ __________________________________________________________________________________________________ 12 Uncommon Scents | Teaching Materials