05 Membrane Dynamics.pdf

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Total Body Water Distribution
• Water: the only molecule that moves freely among all fluid compartments
• Osmotic equilibrium

what %-age?
3

Solutes on the other hand…
• …are not equally distributed
throughout all
compartments

• chemical disequilibrium
• and many of those solutes
are ions

• electrical disequilibrium

4

Age and Sex Matter

6

Osmosis
• Osmosis is the movement of water
across a membrane

• Occurs in response to a solute concentration
gradient

• Movement through the membrane, aquaporins
and water-filled ion channels

• Osmotic pressure
• mm Hg

• Osmolarity
• Osmolarity expresses number of osmotically
active particles in a solution

7

Comparing Osmolarities (OsM or mOsM)
• isosmotic
• hyperosmotic
• hyposmotic (hypo-osmotic)

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Calculating Osmolarity
solute

= concentration

• volume
• Are the two fluid compartments below isosmotic, hyposmotic, or hyperosmotic?

9

Tonicity
• The change in the volume of a cell
• Always comparative (qualitative rather than quantitative)
• what a cell will do when placed in solution X
• therefore, solution X is ___ (compared to the cell)

10

Tonicity
• Tonicity is determined by solutes in each compartment that cannot cross the
membrane

• osmotically active solutes (Silverthorn refers to these as nonpenetrating solutes)

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Transport
• Bulk flow
• “mixtures moving”
• fluids (gases or liquids) within fluid compartments
• blood flow in vessels
• air flow in bronchi
• interstitial fluid flow into lymphatic vessels

• down pressure gradients

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Transport Across Membranes
• Membranes are selectively permeable

14

Basic Principles of Diffusion
• Passive process
• High concentration to low concentration
• Chemical gradient

• Net movement until concentration is equal
• Equilibrium

•
•
•
•
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Rapid over short distances
Directly related to temperature
Inversely related to molecular weight and size
In open system or across a partition (some
form of membrane in living systems)

Which Diffusion Factor?
• Of those previously discussed factors, which is in play in this scenario?

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Fick’s
Law

Adolf Fick
1829 - 1901

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Most Soluble/Permeable?

• What types of molecules will most easily diffuse across a cell membrane?
• Does H2O?
• Ions?
• PhysioPro Tip: Ions do not diffuse
• diffusion is random and directed only towards a lower concentration of a given particle
• ions are moved by electrochemical gradients (i.e., ion movement is directed, not random)
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Protein-Mediated Transport

• Facilitated diffusion
• Active transport
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Categories of Membrane Proteins

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Channel Proteins
•
•
•
•

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…form open, water-filled passageways
faster transport
Water channels
Ion channels

Channel Proteins
• Open channels
• Leak channels
• Pores (for example, water pores)

• Gated channels
• Chemically gated channels
• Voltage-gated channels
• Mechanically gated channels

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Carrier Proteins
• …change conformation to move

molecules across the membrane

• slower than channels, but can move
larger substrates

• Number of molecules transported
• Uniport carriers
• Cotransporters
• Symport carriers
• Antiport carriers

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Carrier Proteins
• Transport down concentration gradients
• No energy input
• Facilitated diffusion uses carrier molecules
• GLUT transporters

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• Classify each of the following as uniporter, cotransporter, or antiporter

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Secondary Active Transport
•

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Uses Na+ gradient established by the NKA.

Tm and Competition

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The Cell @ Rest

• Is the cell at equilibrium?
• Is it a chemical or electrical disequilibrium?
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A Hypothetical Example

• Is our hypothetical cell at equilibrium?
• Yes and no
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• equilibrium?

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How ‘bout now?

• electrochemical equilibrium
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What Would It Take?
• What electrical charge would be needed to exactly oppose any additional
chemical diffusion of an ion into or out of a cell?

• to reach an electrical equilibrium

• What would be the voltage of the membrane potential if the membrane were
permeable only to one of the ions?

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The Nernst Equation
[Xout]
61
Ex =
log
z
[Xin]
+

• Let’s try it with K
• What does that number mean?
+

• that is called the equilibrium potential for K (EK)

• Now, calculate the ENa
• Are either of these realistic?
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The Resting Membrane Potential
• Steady state of living cells
• Potential energy stored in the
electrochemical gradient

• The membrane is 40X more permeable
+
+
to K than to Na
• So, the actual resting membrane potential is
closer to the EK than that of ENa

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Changes in Permeability
• at rest = “polarized”
• …change the membrane

potential by changing the
permeability of individual
ions

• hyperpolarization
• depolarization

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