Neuro Exam 1.5 Part 2

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brau2308
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196805
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Neuro Exam 1.5 Part 2
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2013-01-31 00:52:25
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neurology neuroscience anatomy
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review of lecture 5 for neuro exam 1
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  1. How does neuronal communication occur?
    • passage through the plasma membrane
    • -glucose and its derivatives involved w/ ATP production
    • -growth hormone/regular hormones to produce protein (insulin to transport glucose, metabolic rate-thyroxin)
    • -gases (CO2, O2)
    • -insulin
  2. What are the different passages of neuronal communication through the plasma membrane?
    • simple diffusion
    • osmosis
    • facilitated diffusion
    • active transport
    • exocytosis
    • endocytosis
  3. What is another name for simple diffusion?
    passive transport
  4. Simple diffusion:
    movement of ions (K+, Na+, Cl-) from high concentration to low concentration, establishing a resting membrane potential and action potential
  5. Diffusion is referred to as:
    conductance from high concentration to low
  6. Concentration gradient:
    passive movement of ions
  7. Where do molecules want to go?
    where there is less energy to reach equilibrium
  8. What 3 types of channels may simple diffusion occur in?
    • non-gated channels
    • voltage-gated channels
    • ligand-gated channels
  9. What are the 3 types of simple diffusion channels referred to as?
    ionophores (pores)
  10. Where are the non-gated channels?
    protein molecules embedded in the cell membrane
  11. Are non-gated channels open or closed?
    always open
  12. When can ions pass through a non-gated channel?
    always
  13. What controls which ion can go through?
    chemical nature (i.e., Na+ channel only allows Na+ to go through)
  14. Where are voltage-gated channels?
    embedded in the cell membrane
  15. Are voltage-gated channels open or closed?
    always closed in resting membrane
  16. What allows a voltage-gated channel to open?
    change in voltage (the action potential moving through a membrane creates a voltage difference)
  17. What happens to protein molecules in response to voltage change?
    undergo conformational change (changes its shape on a molecular level)
  18. Are ligand-gated channels open or closed?
    normally closed
  19. How do ligand-gated channels undergo a conformational change?
    by interacting w/ ligand
  20. What do ligands contain?
    chemicals (neurotransmitters or neuromodulators) that attach to receptor site on protein pore and cause a conformational change to open the channel
  21. What do ligand-gated channels respond to?
    presence of molecule or chemical(neurotransmitters/neuromodulators)
  22. Ligand=
    chemicals
  23. Ions can go through each type of channel, it just depends on:
    the circumstances
  24. Osmosis:
    movement of water through semipermeable membrane (since the water can diffuse, but other molecules can't)
  25. What are the 2 biological fluids?
    • intracellular compartment
    • extracellular compartment
  26. Where is the intracellular compartment?
    w/in confines of the cell membrane
  27. Where is the extracellular compartment?
    outside cell membrane
  28. What are the two sub-sections of the extracellular compartment?
    • intravasular
    • interstitial
  29. intervascular
    confines of vessels
  30. interstitial:
    • tissue fluid
    • outside vessels, but b/w cells
  31. Osmosis is the tendency of water to move outside the cell to area of what?
    high concentration of solute. Water moves w/ concentration gradient to try and achieve equilibrium
  32. Facilitated Diffusion:
    movement of ions (or molecules) from high concentration to low concentration, but faster than simple diffusion b/c it utilizes carrier molecules
  33. What are carrier molecules?
    • protein molecules embedded in cell membrane
    • movement is bi-directional (inside->outside; outside->inside)
    • concentration gradient provides energy for movement
    • in order for it to open, there must be a conformational change)
  34. Active transport:
    movement of ions or molecules against concentration gradient (uphill/backwards)
  35. What does active transport require?
    energy expenditure that comes from hydrolysis of ATP (ATP->ADP+P)
  36. What does the active transport system use?
    transporter molecules (protein molecules) embedded in cell membrane that are specific for what they transport
  37. Under certain conditions, active transport can maintain:
    ionic differences b/w intracellular and extracellular fluid (concentration gradient w/in cells)
  38. Exocytosis:
    • neuron releases macromolecules (neurotransmittors and neuromodulators) by diffusion of vesicles w/in plasma membrane
    • vesicles form a fusion pore complex on membrane
    • when Ca+ influx in, pores open and release chemicals into synaptic cleft
    • chemicals function as NTM/neuromodulators
  39. Endocytosis:
    • engulfment process
    • plasma membrane surrounds and engulfs materials into plasma membrane as vesicles
    • preserves some of NTM dumped into synaptic cleft to recycle them
    • don't have to continually process NTM
  40. Resting membrane Potential:
    neurons are charged, but not conducting AP
  41. What causes the resting membrane potential?
    a potential electrical difference (voltage), which exists across a cell membrane, causing excitability of muscle cells and neurons
  42. At resting membrane potential, what is the charge outside of the cell?
    positive
  43. At resting membrane potential, what is the charge inside the cell?
    negative
  44. What accounts for the potential difference inside and outside of the cell?
    • physiological factors
    • biological factors
  45. What physiological factors account for the potential difference between the inside and outside of a cell?
    diffusion of ions through cell membrane
  46. What biological factors account for the potential difference b/w the inside and outside of a cell?
    membranes relative (selectively) permeability to various ions
  47. Equilibrium of a cell is reached when:
    more Na+ (inside or outside)
    more Cl- (inside or outside)
    more K+ (inside or outside)?
    • more (x10) Na+ outside
    • more (x14) Cl- outside
    • more (x30) K+ inside
  48. There is a tendency fo ions to go from:
    high concentration to low concentration to diffuse across concentration gradient to reach equilibrium
  49. Diffusion of Na+ is high on the:
    outside and low on the inside
  50. Na+ and Cl- diffuse...
    into the cell
  51. K+ diffuses...
    outside the cell
  52. What do ions use to reach equilibrium?
    non-gated specific pores
  53. Anions don't go through based on concentration gradients b/c:
    they are too big to go through the pores
  54. A membrane at rest is not conducting an AP, so it is:
    50-100x more permeable to K+ than Na+ (biological factor)
  55. Is it easy or difficult for Na+ to get into the cell?
    difficult
  56. Is it easy or difficult for K+ to get out of the cell?
    easy
  57. As K+ diffuses outside of the cells:
    excessive negative ions (albumin) are left behind, inside the cell, maintaining negativity due to loss of positive ions
  58. Migration of K+ continues until:
    excess of negativity inside and additional K+ outside of the cell restrains continued K+ diffusion (K+ ions reach equilibrium)
  59. There is a limited diffusion of Na+ into the cell because:
    the membrane is not very permeable to it (more permeable to K+)
  60. Does Na+ play a major role in establishing resting membrane potential?
    no
  61. Does K+ play a major role in establishing resting membrane potential?
    yes
  62. Due to the dynamics of Na+/K+, there is a __ charge on the outside and a ___ charge inside.
    • positive outside
    • negative inside
  63. What is the nernst equation used for?
    used to calculate equilibrium potential for ions (used for each ion involved)
  64. What does the Nernst equation take into account?
    • charge of ion
    • temperature
    • ratio of interval/external [ion]
  65. Nernst equation
    K+= ?
    Na+= ?
    • K=-80mV
    • Na=+60mV
  66. What does the K+ value establish?
    RMP driving force that sets the value of RMP for normal human neuron (-70mV)
  67. What is the threshold of activation for a neuron according to the Nernst equation?
    -60mV
  68. What does the Goldman equation find?
    • RMP value for normal human neuron (-70mV)
    • value at which a neuron rests
  69. What is the goldman equation based on?
    all the individual ion equilibrium potentials
  70. What is the driving force that determines RMP?
    the K+ ion
  71. If conductance of ions naturally takes place through pores, why is there a need for concentration gradient?
    • due to active transport system
    • Na/K pump is active transport that occurs against the concentration gradient
  72. In the Na/K pump for each ATP how many Na are out per K into the neuron to maintain concentration gradient?
    • 3Na out
    • 2K in
  73. Why does the Na/K pump maintain the concentration gradient?
    to allow an AP
  74. RMP Review:
    • requires semipermeable membrane
    • certain ions passively pass (conductance) along a concentration gradient in non-gated channels (Na, K, Cl)
    • K is principle ion due to its significant permeability as compared to Na and Cl
    • Presence of Na/K pump maintains the concentration gradient of Na/K
    • Nernst equation calculates the equilibrium potential for each ion
    • sum of equilibrium potentials=RMP (-70mV)--Goldman's formula
    • when a neuron reaches a resting charged state, it is polarized

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