Movement Across Cell Membrane

Question 1

Cell membrane

Answer 1

Allows for separation of an intracellular and extracellular environment

Cell membrane function determined by molecules in the membrane

Cell membrane excludes water soluble, charged molecules

Question 2

Cell permeability

Answer 2

Membrane is a lipid barrier

Fluid in nature

Molecules within membrane can serve as transmembrane carriers

Lipophilic molecules cross membrane because traverse the lipophilic center

If carry a charge don’t cross membrane readily

Diffusion barrier for selective movement

Question 3

Permeability

Answer 3

Ability of a molecule to cross the membrane

Question 4

Phospholipid

Answer 4

Hydrophilic head and hydrophobic tail

Question 5

Unsaturated fatty acid

Answer 5

Double bond

Question 6

Energetically unfavorable

Answer 6

Planar phospholipid bilayer with edges exposed to water

Favorable when sealed compartment formed by phospholipid bilayer

Question 7

Molecules that are permeable

Answer 7

Hydrophobic molecules, small uncharged polar molecules, large uncharged polar molecules, ions

Question 8

Cells control internal environment

Answer 8

Control transport of water soluble molecules in the external environment

Cells in aqueous environment those in contact with membrane will not cross hydrophobic lipid center

Lipid soluble cross hydrophobic lipid center

Transmembrane movement of molecules is either by diffusion or protein mediated transport

Regulation of diffusion and protein transport, cell regulates internal environment

Question 9

Transport by diffusion

Answer 9

Brownian motion

Molecules in constant motion, molecules move back and forth until equilibrium where still move but is equal

Net movement from high to low

Rate determined by Ficks law

Question 10

Fick’s Law

Answer 10

J= DA(C1-C2)/ X

Rate of diffusion per unit time

Constant is P=D/X

Question 11

D

Answer 11

Diffusion coefficient or diffusion constant

Diffusion, the concentration gradient is the driving force providing energy for net movement of molecules from 1 solution to another

Rates can vary

Question 12

J, rate of diffusion

Answer 12

If form high concentration J is negative because concentration is decreasing

Question 13

Ion diffusion

Answer 13

If molecule has electrical charge, it is an ion

Net flux is function of concentration and molecular potential difference if crosses

2 driving forces- concentration gradient and electrical potential gradient

Question 14

Electrical potential gradients

Answer 14

Dependent on attraction of opposite charge or repulsion from like charge

Question 15

If membrane impermeable to one type of ion

Answer 15

There are equal concentrations of ions on both sides of the membrane, then there will be zero potential difference and zero chemical difference

If conc. Of non permeable increases then electrical potential and chemical gradients exist, electrochemical gradient

Question 16

Positive ions

Answer 16

If can cross the membrane but it is still impermeable to negative ions, then + diffuse towards - potential down their electrical gradient

Creates chemical gradient for the positive ions in opposite direction of electrical gradient and positive diffuses until these are equal

Question 17

Electrical and chemical driving forces

Answer 17

Produce counter fluxes of ion with the net movement in the direction of the strongest driving force

When these two gradients are equal for the + ion there will be zero net flux across the membrane, electrochemical equilibrium

Question 18

Electrochemical equilibrium

Answer 18

Net flux of ions is zero but there remains an electrical potential difference and a conc. Difference

Equation shows related to concentration and electrical gradients

Question 19

Nernst equation

Answer 19

Ex= -(60/z)logXa/Xb

Positive value when for mM concentrations

For cell concentrations refer to inside or outside the cell Xo/Xi

Question 20

Ion diffusion

Answer 20

Na+ with chemical and electrical into cell

Cl- chemical into cell

K+ in and out, chemical out and electrical in

Question 21

Factors that influence movement of ions across a membrane

Answer 21

Need driving force

Concentration gradient, electrical gradient and permeability

Question 22

Movement of through membrane

Answer 22

Permeability to different ions varies, membrane has low permeability for all ions

Controlled by ion specific channels and depends on whether open or closed which is regulated by membrane potential or other molecules

Question 23

Distribution of small ions

Answer 23

K, Cl, and Na are influenced predominantly by large intracellular, membrane impermeable, negative charged ions like nucleotides and proteins

Question 24

Active pumping of Na out

Answer 24

Out of cytoplasm decreases the intracellular osmotic pressure and is important for cell water and volume regulation, metabolic inhibitors cause cells to swell by stopping the Na/K pump

Question 25

Resting membrane potential

Answer 25

With a semi permeable membrane and a concentration gradient for ions, there will be separation of charge if the membrane is impermeable to one ion

Ex: KCl
If membrane impermeable to both will diffuse down concentration gradient so have charge imbalance with inside of cell negative

Question 26

Major ions

Answer 26

Na, Cl and K

Permeability for each is very different

Question 27

Na+

Answer 27

Much less permeable than K+

Question 28

K+ and Cl-

Answer 28

Nearly equal

Also large amount of non diffusible anion inside the cell

Question 29

Nernst potential for ions

Answer 29

K+= -105 
Cl- = -96
Na+ = 67 

Electrode to muscle is about -90 inside the cell

Cl close to the electrochemical equilibrium

Question 30

Electrochemical equilibrium definition

Answer 30

The concentration gradient equals the electrical gradient

Requires ion selective semipermeable membrane

Net flux by diffusion is zero

Question 31

Na and K+

Answer 31

Not at electrochemical equilibrium

Large gradients for this to enter and exit cell

Net balance of the gradient results in negative inside

Question 32

Resting membrane potential

Answer 32

Intracellular is negative

Value varies with different types of cells

Results in alignment of ions along the surface of membrane with positive ions outside the cell and negative inside

Question 33

3 major influences on ion movement

Answer 33

Concentration gradient

Voltage gradient

Membrane permeability

Question 34

Changes in RMP

Answer 34

1. Depolarization, when RMP Becomes less negative
2. Hyperpolarization: when RMP is becoming more negative
3. Permeability changes for an ion, if this increases then RMP moves towards equilibrium
   K hyperpolarization and Na depolarization

Question 35

Ion permeability

Answer 35

Intrinsic proteins make channels through membrane for ions

Ion channels are specific for the type of the ion

Ion channels CNS be controlled by gates on the inside and outside of the channel

Question 36

Channel types

Answer 36

Voltage gated channels

Ligand gated channels- AA, Amines, Peptides

Mechanically gated channels- pressure

Question 37

Membrane permeability

Answer 37

Can add together permeability values for each ion

Question 38

Passive membrane properties

Answer 38

Membrane capacitance

Membrane resistor

Time constant (R x C)

Space Constant (Sq. Rt. Diameter)

Question 39

RC

Answer 39

Resistance x capacitance

Question 40

Space constant

Answer 40

Passive membrane properties

Distance that signal can travel before decreases to 37% of initial value

Amplitude of potential change as a function of distance and is proportional to the square root of axon diameter

Larger diameter is lower resistance

Question 41

Action potential

Answer 41

RMP to threshold then rapid depolarization Na channel activation and when reaches peak then Na channel deactivation which leads to depolarization below RMP and then repolarizes

Question 42

Threshold

Answer 42

Membrane voltage at which the action potential is initiated

Question 43

Rapid depolarization

Answer 43

Explosive depolarizing change in membrane potential

Question 44

Overshoot

Answer 44

Magnitude of the positive, above 0, Change in membrane potential

Question 45

Return to RMP

Answer 45

Repolarization of the membrane and termination of the action potential

Question 46

Hyperpolarizing after potential

Answer 46

When the membrane potential reporarizes, the potential becomes more negative than the normal RMP for a brief time

Question 47

All or none response

Answer 47

When the membrane potential reaches threshold, a stereotypic action potential occurs, if the threshold is not reached, no action potential occurs

Question 48

Absolute refractory period

Answer 48

Period of time when a second action potential cannot be produced at the membrane site

Question 49

Relative refractory period

Answer 49

Period of time when it is more difficult but not impossible to produce a second action potential at the membrane site

Question 50

K+ activation

Answer 50

Near overshoot