SUMMARY

Created by

Ramisah Zahra

Cards (268)

Week 2 
Surface area of small intestine
Mucous membrane
Villi
Microvilli - brush border give high SA for absorption of drugs and can help control what comes in and out
Why is large SA important
Dissolved drugs can move from gut lumen via passive diffusion, transport proteins and paracellular diffusion
Blood perfuses via hepatic portal vein to intestine to to liver to move drug into systemic circulation - hence why large SA and good blood supply important
Cells then have a system to push the drug out
Function of the pancreas
Pancreatic juice for lipid digestion
Proteolytic enxzyme trypsin and chymotrypsin for protein digestion
Biscarvonate for stomach acid neutralisation
Why is water reabsorption important
Important for dissolution of oral administered drugs
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Drug solubility 
Efficacy dependent on site of administration
Relevant solubility
Highest conc of drug that can be in biological fluid
Bioavailaibility of drug - determined by it solubility influencing its dissolution rate
Poor aq solubility - leads to lower bioavailability so lower conc of drug in blood- lower efficacy
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Dissolution 
1. Liberation
2. Migration through the boundary layer
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Melting point 
Higher the mp higher rate of solubility
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Enthalpy of fusion 
Energy needed to break solid-solid bonds to form the liquid
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Enthalpy of mixing 
Energy required to break solvent-solvent bonds AND form the new bonds between solute and water
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Enthalpy of solution 
Add enthalpy of fusion and enthalpy of mixing together
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pKa and log D
Ionisation affects lipophilicity and permeability of a drug
Drugs have to be in their UNIONISED form to pass through membrane
Acidic drugs have higher permeability in pH 6.5 or below
Basic drugs have higher when pH 7.4 or above
But in vivo is 7.4 so drugs have to adjust pH to be effective
Stomach - conc of unionised drug high because of the pH however less absorption because of its thick muscular walls and low SA of stomach
Higher logP lower solubility - rather not dissolve in polar environment
Higher logP have better membrane permeability
A good drug needs to be lipid soluble but still dissociate to form ionised water soluble form
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Movement of drug molecules across membrane
1. Diffusion
2. Transcellular
3. Paracellular
4. Carrier mediated transport
5. Endocytosis
6. Transcytosis
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Oral solubility 
Minimum vol for a drug to dissolve fully in stomach
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Absorption 
Solute soaked into substance - particles through substance
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Adsorption 
Dependent on container - particles accumulate at surface
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Importance of interfacial phenomena in pharmacy
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Interface 
Boundary between the phases
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Surface tension 
When gas and liquid are in contact - water meets air
Tension at the surface of the water
Try to reduce SA to minimise tension but liquid has hydrogen bonds
To reduce increase temp
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Emulsions 
Oil and water
Large SA so don't mix well
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Surfactants 
Need surfactants to reduce surface tension
Adsorption of surfactants allow the insoluble particles to disperse in suspension
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Spreading or wetting 
Diff skin reacts different
Reduce surface tension on skin for better wettability y using chemical enhancer
Allows it to penetrate stratum corner
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Contact angle 
Measure of angle at interface between solid and liquid
Smaller than 90 degrees - better spreading therefore increased wettability
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Solid wettability and why this is important
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Adsorption 
Irreversible chemiadsorption
Reversible physiadsorption
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Examples of adsorption 
Overdose - haemoperfusion
TLC
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Week 2
Powder: diameters less than 1mm
Powder flow:ability of powder to flow in specific manner
Need a smooth consistent flow from bulk to tablet machines
Uniform particle packings = consistent mass
Each get same amount - dosage accuracy
Prevent air bubbles in the powder tablet formation
Capping and lamination - tablet breaking and layers separate
Die-wall friction - lubrication problems
Dust contamination risks
Manufacturing
Gravity feeding
Mechanically assisted feeding
Pneumatic air pressure
Hydraulic
Fluidisation
Adhesion
Cohesion
Between two different particles
Between like particles
Between particle and wall
Same components in bulk
Forces
Van der Waals
Surface tension
Electrostatic forces
IMF increase as particle size decrease
Between adsorbed layer and container
Contact and frictional charge between substance and walls
Force balance
Sum driving - sum drag
Particle size
Wider = less good flowability
Too small leads to agglomerates due to more IMF
355um to 125 very fine
Larger
Smaller
More gravitational
Less gravitational
Less surface tension
More surface tension
Stronger adhesion
Lower adhesion
Particle shape - affects flow
Spheres
Rods flake shaped
Irregular interlocking
Minimum contact - low SA
High contact - high surface area
Highest contact due to interlocking
Low electrostatic attraction
High electrostatic attraction
High electrostatic
Good flowability
Low flowability
Low flowability - particles present
True density and bulk
Bulk less true
True - how much drug NO AIR GAPS
Bulk - how much drug including air gaps
Higher density - less adhesive - less adhesive forces - less likely to stick - improved flowability
Powder density AVERAGE of ALL particles together
Different bulk densities - dependent on how particles packed into container
Very poor flow is above 38
Hopper
Hopper width
Height of powder in hopper
Hopper wall angle
Angle of repose - smaller the angle the better flowability
Max angle at which pile of powder remains stable without slumping
Flow through orifice
Measure rate of flow with laser beam or digital balance
Improving powder flow
Particle size and distribution
Particle shape and texture
Additives
Process design
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LADME 
Liberation, absorption, distribution, metabolism and excretion
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Bioavailability 
Cmax, tmax, t1/2, volume and clearance and protein binding as they apply to medicines administration
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ADME processes 
1. Liberation - release of drug from dosage form
2. Absorption - how drug moves in to systemic
3. Steep increase in plasma conc- drug absorbed from GI tract
4. Until Cmax is reach
5. Decline because drug DISTRUBUTES and ELIMINATES FROM body
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Drug absorption mechanisms for common administration routes
Explain which routes are suitable for different drug modalities
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Drug metabolism and excretion
1. Metabolism - biotransformation into another chemical species
2. From parent drug to metabolite
3. Change in physicochemical properties
4. Pro-drug - inactive needs activating in liver
5. Because they're less permeable in active state
6. Metabolites more POLAR and less LIPOPHILIC than parent
7. Oral GI tract and lumen - enterocytes - hepatic pearl vein and liver - systemic circulation
8. Using cP450 liver enzyme for catalysis
9. Decreased lipophilicity
10. Increased lipophilicity
11. Increased permeability
12. Decreased permeability
13. More aq solubility
14. Decreased aq solubility
15. More likely to be excreted
16. Less likely to be excreted
Excretion - irreversible loss of drug
17. Glomerular filtration
18. Bloodstream - renal tubules - kidneys - eliminated in urine
19. Bile in liver - faeces
20. Pulmonary excretion
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Capecitabine is an oral prodrug that undergoes metabolism to generate its active form , 5-fluorouracil and this 5FU is a chemotherapy agent used to treat cancer
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Using relevant examples encountered in this unit, demonstrate how the drug interacts with its biological target(s)
Functional groups determine how molecule binds to target
Conformational chair not receptor
What happens to cell
How the drug is formulated and administered
Specificity of drug
Adverse effects
Metabolism and excretion
Agonists are a
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Lipophilicity 
Increased lipophilicity leads to increased permeability, decreased lipophilicity leads to decreased permeability
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Aqueous solubility 
Increased aqueous solubility leads to being more likely to be excreted, decreased aqueous solubility leads to being less likely to be excreted
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Capecitabine 
An oral prodrug that undergoes metabolism to generate its active form, 5-fluorouracil, which is a chemotherapy agent used to treat cancer
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Excretion 
Irreversible loss of drug
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Excretion process 
1. Bloodstream - renal tubules - kidneys - eliminated in urine
2. Bile in liver - faeces
3. Pulmonary excretion
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Clinical endpoints 
Measure concentration of drug in biological fluid and spaces by taking plasma to see concentration of drug in plasma
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How drug interacts with biological target(s)
1. Functional groups determine how molecule binds to target
2. Conformational changes, not just receptor binding
3. What happens to the cell
4. How the drug is formulated and administered
5. Specificity of drug
6. Adverse effects
7. Metabolism and excretion
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Agonists 
Activating drugs that mimic the natural ligand
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Affinity 
Attraction between drug and receptor
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Efficacy 
Response produced by the drug
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