general outcome: explain how the nervous system controls physiological processes

General Outcome: Explain how the Nervous System controls physiological processes

The Nervous System A system of the body that coordinates & regulates the activities of the body

Control System Maintains homeostasis homeo/stasis (same/changing) changes in order to keep a balance

5 major components Stimulus receptor modulator/regulator effector Action Sensory Pathway Motor Pathway -highly specific -receive stimuli -Selects appropriate Response (spinal cord or brain) -carries out the response (muscle or gland)

The Nervous System & Homeostasis Organization of the Nervous System Structure of a neuron Action Potential Synaptic Transmission Structure of the Brain Senses: The Eye & Ear

Nervous System Organizational Tree! Peripheral Nervous System (PNS) Feeds into & out of CNS Central Nervous System (CNS) Decision maker Nervous System Somatic Pathway (Voluntary) under conscious control Examples? Autonomic Pathway (Involuntary) unconscious control Examples? Parasympathetic (Restores to normal) Restores balance! Restores Homeostasis! Sympathetic (Stimulatory) Speeds you up! Excites you! Brain & Spinal CordMotor PathwaySensory Pathway NS Overview

Sympathetic vs. Parasympathetic (to stimulate)(to restore) Dilates PupilsConstricts pupils Inhibits tears & salivation Stimulates the same Increases heart rateDecreases heart rate Increases respirationDecreases respiration Inhibits digestionStimulates digestion Relaxes bladder & bowelsContracts them(#1&2s) Inhibits genitalsStimulates genitals Initiates ejaculation Adrenaline Response

Anatomy of a Nerve Cell Two different types of cells are found in the nervous system: Glial Cells: non-conducting; important for support and metabolism of nerve cells Neurons: functional units of the nervous system (conduct nerve impulses)

The Neuron: Wires within a nerve! See diagram on p.410 of text

Types of Neurons see your handout! Motor Neuron Connects the central nervous system to a muscle or a gland (also called efferent neurons) Sensory Neuron Connects a sensory receptor to the central nervous system (also called afferent neurons) Interneuron (or Association Neuron) Connect sensory neurons to motor neurons Connects two or more neurons Found in CNS

The Neuron Dendrite receives information from receptors or other neurons and conducts nerve impulses toward the cell body. Cell Body contains nucleus and organelles Axon conducts nerve impulses away from the cell body Myelin a fatty protein that covers the axon Insulate the axon allowing nerve impulses to travel faster (Myelination is only found outside the brain and spinal cord) Nodes of Ranvier gaps within the myelin sheath Impulses jump from node-to-node therefore speeding up the impulses Neurillemma delicate membrane that promotes regeneration of damaged neurons Only found in myelinated neurons Schwann Cells special type of cell that produces the myelin sheath http://www.youtube.com/watch?v=36DSFSyxHw0

To Do: Read p. 408-411 from text and Complete 66 word summary Complete Sections A thru C in your Notes Package Color and Label Neuron Diagram

Structure of a Neuron From Nelson Biology

The Job of Schwaan cells = Wrap Axons ! Schwaan cells: Schwaan cells: Nourish the axon Provide insulation (myelin) Repair axon damage (neurilemma) Found mainly in PNS Neurilemma = concentric rings around axon created by the Schwaan cell makes the impulse fast (insulated)

Job of Myelin! Provide insulation like the covering on speaker wire Prevent loss of signal down axon! Damaged myelin results in a loss of signal down the axon! (Results in ) Multiple Sclerosis (MS)

Above is a map giving the geographical prevalence of Multiple Sclerosis (MS) world-wide. It has long been established that MS is more likely to occur in communities in the further Northern and Southern Lattitudes, possibly due to less sunlight, environmental factors or dietary reasons.sunlightenvironmental factorsdietary http://www.msrc.co.uk/index.cfm?fuseaction=show&pageid=2325

A beauty of a neuron!

Types of Neurons Sensory Neurons (Afferent Neurons) conducts nerve impulse from sense organs to the brain and spinal cord (CNS) Motor Neuron (Efferent Neurons) conducts nerve impulses from CNS to muscle fiber or glands (effectors) Interneuron (Association Neuron) found within the CNS No myelination Intergrates and interprets sensory information and relays information to outgoing neurons

To Do: Textbook Questions pg. 410 #1-4 Work on STS Assignment Remember: Purchase Key Booklet by next Friday Parent letter if I dont already have it

Daily Review

Returning involuntary body functions to normal after a period of stress is the function of which division of the nervous system? A.Central B.Somatic C.Sympathetic D.Parasympathetic

Syphilis is a STI that affects the central nervous system. The neurons damaged by syphilis are A.interneurons B.sensory neurons C.somatic motor neurons D.autonomic motor neuron

Common Reflexes Babinski reflex: a tickle of a babies foot causes the toes to curl Pupillary reflex: iris diameter changes in response to light conditions Cross extensor reflex: in a standing position, fatigue of one leg causes withdrawal of weight onto the other leg Stretch reflex: -the body senses the muscles shortening so the tendency is to stretch them out in order to perform motor functions properly Knee jerk reflex (patellar): a tap on the patellar tendon causes top leg muscles to contract & lower leg muscles to relax simultaneously Withdrawal reflex: defensive strategy in response to a painful stimuli like heat & cold or a cut or pinch of some kind Others include: Vomiting, coughing, defecation, & milk release some of which are voluntary reflexes.

Reflexes: are well established neural circuits that are pre- programmed to allow motor responses to certain stimuli some may be instinctual as in newborns some are learned as in repeated motor tasks involved in sport some are defensive to enhance survival and other reflexes help your eye to move as you read this page. Dont need to write yet

Reflex Arc A reflex that does not require the brain Reflexes may be innate or acquired

Reflex Arc Reflexes are autonomic responses to certain stimuli Involuntary/automatic They pathway that a nerve impulse takes is called a reflex arc

Anatomy of a Reflex Arc

How the Reflex Arc Functions: 1) Sensory organs (receptors) detect dangerous stimuli! 2) Impulse is passed from the sensory organ to a sensory neuron! 3) Sensory Neuron transfers the impulse to the Association neuron in the spinal cord!

4) The INTERNEURON links the SENSORY to the MOTOR neuron! 5) The MOTOR neuron takes the impulse to the EFFECTOR! 6) The effector (usually a muscle) reacts. 7) Simultaneously, interneurons send the signal up to the BRAIN for interpretation! How the Reflex Arc Functions

Reflex Arc Video

Learner Outcome: Describe the composition and function of reflex arcs Design and perform an experiment to investigate the physiology of reflex arcs

To Do: Reflex Lab Section E in your notes package P. 414 Questions # 2, 3, 5, 6

Action Potential how do nerves work??? In 1900 Bernstein hypothesized that nerve impulses where electrochemical in nature. Future experimentation proved this. Giant Squid Experiment: Cole and Curtis placed two tiny electrodes one inside the large axon of a squid and the second across from the first outside the axon.

Cole and Curtis measured the electrical potential across the membrane. The resting potential was found to be about 70mV. Squid Axon Giant Squid Experiment

When stimulated, the action potential jumped to about +40 mV. The action potential only lasted for a few milliseconds before the nerve cell returned to the resting potential. -70 +40 mV 1234 ms threshold

Definitions: Action Potential: the voltage difference across a nerve cell membrane when the nerve is excited (~40 mV) Resting Potential: Voltage difference across a nerve membrane when it is NOT transmitting a nerve impulse (almost always -70 mV)

Caused by an uneven distribution of positively charged ions across the membrane Set up and maintained by a Sodium-Potassium pump. 3 Na + are pumped out of the cell, 2 K + ions are pumped into the cell. Maintaining Resting Potential sodium/potassium ion pump sodium/potassium pump 2 http://www.youtube.com/watch?v=9euDb4TN 3b0 http://www.youtube.com/watch?v=yQ- wQsEK21E

These positive ions want to move with their concentration gradient by diffusion. More sodium moves out than potassium moves in leaving a relative negative charge inside the cell. The cell is polarized. resting potential clip

A Nerve impulse is an Action Potential When a neuron receives a stimulus it becomes more permeable to sodium than potassium When stimulated the ion gates for sodium open up. Positive ions flood into the cell making it positive. This rapid inflow is referred to as depolarization. Action Potential

After the impulse, the Na + channels close and the K + channels open. This is called repolarization. The flow of potassium ions out of the cell (with their concentration gradient) restores the resting potential. The potassium gates close relatively slowly which makes the inside of the neuron slightly more negative then resting potential (hyperpolarization) The Na+/K+ pump continues to pump the sodium and potassium across the membrane against the concentration gradient to restore the resting potential.

Diagram from Textbook

Summary of Impulse. 1. At rest Na+/K+ pump moving 2. Stimulation sodium gates open 3. The flood of sodium into the cytoplasm stimulates adjacent areas 4. Refractory potassium gates open sodium gates close 5. At rest Na+/K+ pump moving ions Action potential overview Electropotential graph

Movement of Action Potential Many action potentials are generated one after another along the cell membrane, causing a wave of depolarization (similar to falling dominos). When axons are myelinated, nerve impulses travel by saltatory conduction Gated ion channels are concentrated at the nodes of Ranvier Flow of ions across cell membrane can only happen at the nodes so action potentials jump from node to node This causes the signal to be transmitted down an axon much faster. myelinated vs. unmyelinated impuse

Refractory Period: The time it takes (~0.001 s) for a depolarized neuron to repolarize return to resting potential During the refractory period another impulse can NOT be sent along the neuron.

Threshold The amount of stimulus required to initiate an action potential (or, to cause depolarization to occur) Once threshold is reached the nerve impulse is passed along Draw diagram

All-or-None Response A neuron will fire either 100%, or not at all. There is no difference in strength of a nerve impulse

To Do: Read pages 415 419 in your textbook Complete Section D in your notes package Nerve impulse coloring diagram (pg. 7 notes package) Schwann Cell & Action Potential http://www.mcgrawhill.ca/school/applets/abbio/ch11/actionpotential_action.swf

Synaptic Transmission Neurons are not directly connected to each other. The electrochemical action potential cannot jump the synaptic cleft (or synapse). Synaptic transmission is entirely chemical in nature. Synapse movie clipmovie clip 1.http://www.youtube.com/watch?v=vGS7g uM1Gw0http://www.youtube.com/watch?v=vGS7g uM1Gw0

Synapse At the end of axons, tiny synaptic vesicles contain neurotransmitters When an impulse reaches the end of an axon, these synaptic vesicles migrate toward the end of the axon They then release their neurotransmitter and it diffuses across the synaptic cleft

Synapse Neurotransmitters attach to specific receptor sites and causes sodium channels to open resulting in a depolarization in the membrane. An action potential is created and the impulse travels down the neuron. Diffusion takes time, so the more synapses involved, the slower the response.

Synapse Synaptic transmission can only occur in one direction. Since only presynaptic neurons contain synaptic vesicles, and only post synaptic neurons have receptor sites for them, the messages cant be sent in the other direction This explains why impulses can only travel from sensory neuron to interneuron to motor neuron and never in the other direction

Figure 10(b), pg. 420 Synaptic vesicles in the end plate of the presynaptic neuron release neurotransmitters into the synaptic cleft. The neurotransmitters attach themselves to receptors on the postsynaptic membrane, causing it to depolarize. The action potential continues along the postsynaptic neuron.

Synapse action at muscular juction

Neurotransmitters Acetylcholine (Ach): (excitatory passes message along) neurotransmitter produced in the presynaptic knob and stored in vesicles. when an action potential reaches the presynaptic knob the vesicles rupture releasing their contents (acetylcholine) into the synaptic cleft The acetylcholine diffuses across the synapse and binds to receptor sites on the postsynaptic knob

Neurotransmitters How do we stop the message? Before another message can cross the cleft, it must be cleaned (remove the neurotransmitter) The enzyme acetyl cholinesterase removes acetylcholine from the receptor sites and breaks it into acetic acid & choline the acetic acid & choline are reabsorbed into the presynaptic knob to be reused

Neurotransmitters Neurotransmitters can be: excitatory - passes along message to the next neuron, or Inhibitory binds to the next neuron and inhibits the message from being passed on See figure 11 p. 422 Not all neurons cause depolarization in the post synaptic membrane. Some neurons are inhibitory.

Neurotransmitters Often it takes more than one neuron releasing its neurotransmitter into the synaptic cleft to elicit a response in the post synaptic neuron. This is referred to as SUMMATION

Figure 11, pg. 422 Action potentials must occur simultaneously in A and B to reach the threshold in D.

Other Types of Neurotransmitters: Serotonin Dopamine Norepinephrine GABA You will fill in some information regarding these in your notes package but do NOT have to memorize them. If used on a diploma you will be told what you need to know about them

13.2 Summary Electrochemical Impulse Nerves conduct electrochemical impulses from the dendrites along the axon to the end plates of the neuron. Active transport and diffusion of sodium and potassium ions establish a polarized membrane. An action potential is caused by the inflow of sodium ions. Nerve cells exhibit an all-or-none response. Neurotransmitters allow the nerve message to move across synapses.

To Do: Reflex/Synapse Worksheet Complete section F in your notes package Case Study Drugs and the Synapse p. 423-424 of text For Extra Practice: Pg. 418 # 1-4 Pg. 420 # 5-7 Pg. 425 #3-7

general outcome: explain how the nervous system controls physiological processes

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