Transporters and Channels

Question 1

How can we increase solute movement across a membrane or cell layer

Answer 1

• increase area of flux (microvilli, alveoli)
• decrease x
• increase rate of cell metabolism
• increase D (alter bilayer composition or introduce pores)

Question 2

What is a solute flux

Answer 2

• predicted by passive diffusion
• down a concentration gradient
• avoids bilayer

Question 3

Examples of substrate-specific pores

Answer 3

• e.g. glucose transporter
• e.g. hexoses, amino acids, lactate

Question 4

Important characteristics of pores

Answer 4

• solute flux
• substrate specific
• saturable
• specific inhibitors/inactivators (antagonists)

Question 5

What is the transportome

Answer 5

• Human Genome Organisation recognises 1289 genes as transporters and channels
• 406 ion channels
• 863 transporters
• classified into structurally related super-families and families

Question 6

Importance of transporters in gut

Answer 6

• vital to absorption of micro and macro nutrients, and also drug absorption
• digestion

Question 7

Principle sites of carrier-mediated drug transport

Answer 7

• blood-brain barrier
• GI tract
• placenta
• renal tubule
• biliary tract

Question 8

Why is carrier-mediated transport important

Answer 8

• can transport drugs that are chemically related to endogenous substances such as neurotransmitters
• e.g. dopamine is transported through blood-brain barrier by transporters

Question 9

Ohms Law

Answer 9

I = V/R (current or charge flow)

Question 10

Poiseuille equation

Answer 10

blood flow = change in P/Peripheral resistance (blood flow)

Question 11

Define Kp

Answer 11

lipid-water partition coefficient
= change in cm / change in c

Question 12

Kp for a hydrophobic molecule

Answer 12

Kp > 1

Question 13

Kp for hydrophilic molecule

Answer 13

Kp < 1

Question 14

What is ‘R’

Answer 14

Gas constant (8.3 J/K.mol)

Question 15

What is ‘T’

Answer 15

Absolute temperature (K)

Question 16

What is ‘n’

Answer 16

Viscosity of barrier

Question 17

What is ‘r’

Answer 17

Radius of diffusing molecule (related to molecular weight)

Question 18

Stokes’ Law

Answer 18

a perfect sphere travelling through a viscous liquid feels a drag force proportional to the frictional coefficient

Question 19

Rate of solute diffusion (J) is proportional to

Answer 19

• permeability of coefficient P
• surface area A of membrane
• concentration difference (change in c)

Question 20

How frictional effects predict passive permeability

Answer 20

• molecular size -> small, increase P; large, decrease P
• molecular shape - straight, increase P; globular, decrease P
• membrane viscosity - short R chains, -C=C-, inc. T0, increase P

Question 21

How lipid solubility predicts passive permeability

Answer 21

• Kp high (e.g. O2, CO2, anaesthetics, lipophilic group), increase P
• Kp low (e.g. sugars, amino acids, ions, polar charged groups) decrease P

Question 22

How unstirred layers predict passive permeability

Answer 22

increases overall “thickness” of barrier

Question 23

How charge effects predict passive permeability

Answer 23

• molecular charge affects Kp
• hydrogen-bonding alters effective molecular size / shape, Kp

Question 24

What is osmosis

Answer 24

(net solvent flow) water moving from region of higher to lower water potential, showing bulk flow

Question 25

Osmolarity is …

Answer 25

• proportional to concentration of dissolved solutes
• inversely proportional to osmotic potential

Question 26

Osmotic potential

Answer 26

zero for pure water, increasing negative as solute concentration increases

Question 27

How drugs move across the plasma membrane

Answer 27

For many drugs the non-ionised form can permeate the membrane

Question 28

Acid ionisation reaction

Answer 28

AH <-> A- + H+

Question 29

Base ionised reaction

Answer 29

BH+ <-> B + H+

Question 30

Asprin (pKa = 3.5) crossing the GI tract membrane

Answer 30

negatively charged asprin diffuses across the membrane of the gastric mucosa and is trapped in the plasma -> good absorption

Question 31

How can the proportion of drug ionisation be determined

Answer 31

• the proportion of ionisation of a drug depends upon both the pKa of the drug and the local pH
• the pKa = pH at which 50% of drug is ionised and 50% is un-ionised