1. Nervous System AP Biology Chapter 48
Nervous System
AP Biology Chapter 48
Watch BioFlix on Nervous System
***Adapted from Kim Foglia’s powerpoint-Ch 48

2. Parts of a Neuron Cell Body Dendrites Receive stimuli Axon
Transmits the nerve impulse
Myelin sheath
Made of Schwann cells
insulation
Nodes of Ranvier

3. The Neuron

4. Myelin Sheath

5. Nerve Impulse Direction
The nerve impulse always travels FROM the dendrites TO the ends of the axon.

6. Basic Vertebrate Nervous System
Controls mental/physical activity and homeostasis
process information in 3 stages
Sensory input, integration, motor output

7. Rapid involuntary stimulus
Reflex Arc
Rapid involuntary stimulus
Bypasses the brain
Involves
Sensory and motor neuron
Maybe neurons in spinal cord, but not brain

9. The Transmission of the Nerve Impulse
Transmission occurs as a result of polarization across a neuron’s membrane
Polarization
difference in electrical charge which exists between the inside and outside of a membrane
Cell Membrane of Axon

10. Cells: surrounded by charged ions (+ and -)
Cells live in a aqueous solution of charged ions
anions (negative ions )
more concentrated within the cell
Cl-, charged amino acids, large marcromolecules
cations (positive ions)
more concentrated in the extracellular fluid OUTSIDE cell (or think “out” t for +)
K+, Na+
channel leaks K+ K+
Na+ K+
Cl-
aa- + K+ –

11. Cells have Voltage!
Opposite charges on opposite sides of cell membrane
membrane is polarized (polar = 2 different charges on each side)
negative inside; positive outside
charge gradient
stored energy (like a battery) +
This is an imbalanced condition.
The positively + charged ions repel each other as do the negatively - charged ions. They “want” to flow down their electrical gradient and mix together evenly.
This means that there is energy stored here, like a dammed up river.
Voltage is a measurement of stored electrical energy. Like “Danger High Voltage” = lots of energy (lethal). – – +

12. Transmission of Nerve Impulse
An unstimulated (resting) neuron is said to be polarized
The inside of the membrane is negative (-)
The outside of the membrane is positive (+)
Voltage (difference in charges) measured across a membrane = membrane potential
unstimulated neuron = has a resting potential of -70mV

13. How is polarization maintained across the neuron’s membrane?
Some Na+ and K+ are always “leaking” through cell
Na/K Pumps are embedded in membrane and actively restoring ions to the appropriate side
Na+ K+
Cl-
aa-

14. STEP #1: How does a nerve impulse travel?
Stimulus: nerve is stimulated
open Na+ channels in cell membrane
reached threshold potential
membrane becomes very permeable to Na+
Na+ ions diffuse into cell (from High  Low [ ])
charges reverse at that point on neuron
positive inside; negative outside
cell becomes depolarized – +
Na+
Think: “in” is a 2 letters and so it “Na+”

15. STEP #2: How does a nerve impulse travel?
Wave occurs: impulse travels down neuron
change in charge opens other Na+ gates in next section of cell
“voltage-gated” ion channels
Na+ ions continue to move into cell
“wave” moves down neuron = action potential – +
Na+
wave (action potential) 

16. STEP #3: How does a nerve impulse travel?
Re-set: 2nd wave travels down neuron
K+ channels open up slowly
K+ ions diffuse out of cell
charges reverse back at that point
negative inside; positive outside + –
Na+ K+
wave (action potential) 
Opening gates in succession =
- same strength
- same speed
- same duration

17. Nerve Impulse Travels One Direction
Combined waves travel down neuron
wave of opening ion channels moves down neuron
signal moves in one direction   
flow of K+ out of cell stops activation of Na+ channels in wrong direction + –
Na+
wave (action potential)  K+

18. How does the nerve re-set itself?
After firing a neuron has to re-set itself
Na+ needs to move back out
K+ needs to move back in
both are moving against concentration gradients
need a pump for active transport!! + –
Na+ K+
wave (action potential) 

19. How does the nerve re-set itself?
Na+ / K+ pump
active transport protein in membrane
requires ATP
3 Na+ pumped out
2 K+ pumped in
re-sets charge across membrane
Dominoes set back up again.
Na/K pumps are one of the main drains on ATP production in your body. Your brain is a very expensive organ to run!
That’s a lot of ATP!
Feed me some sugar quick!

20. Neuron is ready to fire again
Na+ K+
Amino acids-
aa-
resting potential + –

21. Events of the Nerve Impulse

24. Note: action potential is an ALL or NOTHING
Note: action potential is an ALL or NOTHING
If stimulus fails to produce depolarization that exceeds threshold value, then NO action potential results
If the threshold value is met, then complete depolarization occurs

25. ALL Gates closed! hyperpolarization
K+ gate opens; Na+ gates remain open
Na+ gate opens
Hyperpolarization is called an “Undershoot”
When more K+ has moved out of the cell than is actually needed to repolarize it
K+ gate remain open; Na+ gates close
hyperpolarization
ALL Gates closed!

26. Ending the Nerve Impulse
Refractory Period
When membrane is polarized but Na+/ K+ are on wrong sides of membrane
neuron will NOT fire
How to restore Na+ and K+ to proper positions?
Na/K pumps
Once the Na+ and K+ are restored, the refractory period is over and the neuron may respond to another stimulus

27. Speed of a Neuron Signal Transmission
Extra Animations
cin=9&rg=animated_biology&at=animated_biology&var=animated_bi ology

28. Multiple Sclerosis (MS) immune system (T cells) attack myelin sheath
Multiple Sclerosis (MS)
immune system (T cells) attack myelin sheath
loss of signal

29. What happens at the end of the axon?
Impulse has to jump the synapse!
junction between neurons
has to jump quickly from one cell to next
How does the wave jump the gap?
Synapse

30. from an electrical signal
Synaptic terminal
Chemicals stored in vesicles
release neurotransmitters (LIGANDS)
diffusion of chemical across synapse conducts the chemical signal across connecting neurons
stimulus for receptors on dendrites of next neuron
synaptic terminal
We switched…
from an electrical signal
to a chemical signal
neurotransmitter
chemicals

32. Many different types of molecules.
Many different types of molecules.
Mostly small molecules — must diffuse across synapse.

34. Neurotransmitters Weak point of nervous system
any substance that affects neurotransmitters or mimics them affects nerve function 
gases: nitric oxide (NO), carbon monoxide (CO)
mood altering drugs:
stimulants
amphetamines, caffeine, nicotine
depressants
hallucinogenic drugs
Prozac
Poisons, venom
Since acetylcholinesterase has an essential function, it is a potential weak point in our nervous system. Poisons and toxins that attack the enzyme cause acetylcholine to accumulate in the nerve synapse, paralyzing the muscle. Over the years, acetylcholinesterase has been attacked in many ways by natural enemies. For instance, some snake toxins attack acetylcholinesterase.

35. The Nervous System: 2 Divisions
Central Nervous System (CNS)
Brain and Spinal Cord
Peripheral Nervous System (PNS)
Nerves
**All animals except sponges
Have some type of nervous system

36. Motor Neuron System Two main parts Somatic nervous system
Directions contraction of skeletal muscles
Autonomic nervous system
Controls activities of organs and various involuntary muscles

38. Brainstem The “lower brain” Functions medulla oblongata pons midbrain
Homeostasis (ex: breathing)
coordination of movement
conduction of impulses to higher brain centers

39. Medulla oblongata & Pons
Controls autonomic homeostatic functions
breathing
heart & blood vessel activity
swallowing
vomiting
digestion
Relays information to & from higher brain centers

40. Midbrain Involved in the integration of sensory information
regulation of visual reflexes
regulation of auditory reflexes

42. Lateralization of Brain Function
Left hemisphere
language, math, logic operations, processing of serial sequences of information, visual & auditory details
detailed activities required for motor control
Right hemisphere
pattern recognition, spatial relationships, non-verbal ideation, emotional processing, parallel processing of information

43. http://outreach.mcb.harvard.edu/animations/a ctionpotential_short.swf