Show:
Unit One
Unit Two
Part One
Unit Two
Part Two
Unit Two
Part Three
Unit Two
Part Four
100

What are the three subcategories of neurocrines?

Neurotransmitters, neuromodulators, neurohormones 

100

Which neuroglia are found in the CNS

astrocytes, microglia, ependymal cells, oligodendrocytes

100

what is the resting membrane potential?

-70mV

100

What is propagation?

the AP moves from the axon hillock down the entire axon length toward the axon terminal. the movement of signals b/w neurons 


100

What is the new name(s) for graded potentials 

EPSP: excitatory postsynaptic channels

IPSP: inhibitory postsynaptic channels 

200
What are connexins?

A gap junction forms from the union of membrane-spanning proteins on two adjacent cells.

200

Which two neuroglia are myelin producing cells

oligodendrocytes and Schwann cells

200
What is the purpose of the sodium-potassium pump?

- stabilizes and maintains resting membrane potential

- maintains concentration gradients for Na+ and K+

- three Na+ are pumped out of cell while two K+ are pumped back in

200

Rate of AP propagation depends on two factors

1. axon diameter 

2. degree of myelination 

- continuous conduction

- saltatory conduction 

200

Name the neurotransmitters that are amino acids and if they are excitatory or inhibitory 

- glutamate (excitatory)

- glycine (inhibitory) 

- GABA, gamma aminobutyric acid (inhibitory)

300

Which signalling pathway is considered a secondary messenger system and why?

GPCRs because it does not open up gates but instead changes the subunits  

300

Characteristics of neurons (3)

- extreme longevity 

- amitotic with limited exceptions 

- high metabolic rate

300

What is the difference between depolarization and hyperpolarization

Depolarization: decrease in membrane potential (moves toward zero and above)

  • Inside of membrane becomes less negative than the resting membrane potential
  • Probability of producing an action potential increases

Hyperpolarization: increase in membrane potential (away from zero) 

  • Inside of membrane becomes more negative than resting membrane potential
  • Probability of producing impulse decreases
300

What are the two phases of absolute and relative refractory period. 

Absolute refractory period:

- Time from opening of Na+ channels until resetting of the channels

- Enforces one-way transmission of nerve impulses

Relative refractory period: 

- Occurs in an area of the axolemma that has just completed the absolute refractory period

  • Na+ channels are returning to their resting state
  • Some K+ channels still open
  • Repolarization is occurring
300
Compare and contrast the two types of summation

Temporal summation

- A theoretical example: one presynaptic neuron firing rapidly

- First impulse produces EPSP, and before it can dissipate another EPSP is triggered, adding more excitation to the first impulse

Spatial summation

- Postsynaptic neuron is stimulated once by large number of axon terminals at approximately the same time

- Many EPSP are produced and then summate

400

Name and describe the steps for a simple neural reflex pathway/

1. Stimulus – a change in a physical variable

2. Sensor or receptor - Sensory receptors detect change in a physical stimulus

3. Input signal “pathway”

4. Integration Centre (central nervous system)

5. Output signaling

6. Targets 

7. Responses 




400

What is BBB and which neuroglia regulates it?

A network of blood vessels and tissue that is made up of closely spaced cells and helps keep harmful substances from reaching the brain. The blood-brain barrier lets some substances, such as water, oxygen, carbon dioxide, and general anesthetics, pass into the brain.

Astrocytes regulates BBB

400

Why does diffusion at the axon hillock NOT go backwards to its original occurrence (dendrites)?


  • The plasma membrane difference is ligand gated and voltage gated 

  • No backfire because chemical parts is between cells, and electrical within cells

400

Differentiate b/w Group A, B, and C

Group A fibers

- Largest diameter

- Myelinated somatic sensory and motor fibers of skin, skeletal muscles, and joints

- Transmit at 150 m/s (~300 mph)

Group B fibers

- Intermediate diameter

- Lightly myelinated fibers

- Transmit at 15 m/s (~30 mph)

Group C fibers

- Smallest diameter

- Unmyelinated 

- Transmit at 1 m/s (~2 mph)


400

Explain what happens during presynaptic inhibition and post-synaptic inhibition.

1. Presynaptic inhibition

- the size of the AP is reduced in the presynaptic cell by an axoaxonic IPSP 

- Less neurotransmitter is released leading to fewer EPSPs in post-synaptic cell

2. Post-synaptic inhibition 

- Inhibition of the AP occurs due to axosomatic IPSP at the axon hillock of the post-synaptic cell

- No AP occurs

500

Name all Cannon's Postulates 


  1. The nervous system regulates the “fitness” of the internal environment 

  2. Some bodily systems are under tonic control

  1. Some bodily systems are under antagonistic control

  2. One chemical signal can have different effects in different tissues


500
a) What is Ohm's Law 

b) define the variables and explain the relation b/w them

a) Current (I) = Voltage (V)/Resistance (R)

b)

- Voltage: a measure of potential energy generated by separated charge measured between two points in volts (V) or millivolts (mV)

- Current: flow of electrical charge (ions) between two points

- Resistance: hindrance to ionic movement

- Current is directly proportional to voltage

The greater the voltage (potential difference), the greater the current

- Current is inversely proportional to resistance

The greater the resistance, the smaller the current


500

Steps of Action Potential

- An action potential begins when a depolarization increases the membrane voltage so that it crosses a threshold value

- At this threshold, voltage-gated Na+ channels in the membrane open, allowing many sodium ions to rush into the cell. This influx of sodium ions makes the membrane potential increase very rapidly

- After a short time, the sodium channels self-inactivate (close and become unresponsive to voltage), stopping the influx of sodium. A set of voltage-gated potassium channels open, allowing potassium to rush out of the cell down its electrochemical gradient. These events rapidly decrease the membrane potential, bringing it back towards its normal resting state.

- The voltage-gated potassium channels stay open a little longer than needed to bring the membrane back to its resting potential. This results in a phenomenon called “undershoot,” in which the membrane potential briefly dips lower (more negative) than its resting potential.

- Eventually, the voltage-gated potassium channels close and the membrane potential stabilizes at resting potential. The sodium channels return to their normal state (remaining closed, but once more becoming responsive to voltage). The action potential cycle may then begin again.

500

What are the six stages of a chemical synapse?


1. ap arrives at axon terminal 

2. voltage-gated Ca2+ channels to open Ca2+ enters the axon terminal

3. Ca2+ entry cases synaptic vesicles to release neurotransmitter

4. Neurotransmitter diffuses across the synaptic cleft and binds to specific receptors on chemically-gated ion channels 

5. binding of neurotransmitter opens chemically-gated ion channels, creating graded potentials 

6. Neurotransmitter effects are terminated 

500
What are the four types of circuits and give brief explanation of each.

 1. diverging

2. converging

3. reverberating

4. parallel after-discharge