1. 1. Fate of drugs in the body 1.1 absorption 1.2 distribution - volume of distribution 1.3 elimination - clearance 2. The half-life and its uses 3. Repeated administration of drugs 4. Plasma concentration-effect relationship

2. ABSORPTION DISTRIBUTION ELIMINATION Clearance Volume of distribution WHAT HAPPENS TO DRUGS INSIDE THE BODY Administered Absorbed „Hidden“ Eliminated Acting

3. protein binding -plasma proteins -tissue proteins ONLY A FREE DRUG ACTS! The bound drug is inactive. Free and bound drug are in equilibrium. Displacement: drug-drug interactions VOLUME OF DISTRIBUTION Depends on:

4. Because the result of the calculation may be a volume greater than that of the body, it is an APPARENT (imaginary, not actual) volume For example, V d of digoxin is about 645 liters for a 70 kg man (i.e. about 9 times bigger that his actual volume) VOLUME OF DISTRIBUTION V d = Amount of drug in body / Concentration of drug in plasma

5. Clinical importance of volume of distribution: When V d of a drug is big it takes long time to achieve effective plasma concentration of the drug. In such cases a loading dose may be given to boost the amount of drug in the body to the required level. This is followed by administration of lower maintenance dose.

6. CLEARANCE Clearance (CL) is the volume of plasma totally cleared of drug in unit of time (ml/min/kg) CL tot total CL R renal CL H hepatic CL NR nonrenal (= Cl tot - CL R )

7. Clinical importance of clearance Determines the maintenance dose Drugs eliminated mainly through the kidney need measures (e.g. dosage adjustment) in renal insufficiency Drugs eliminated mainly through the liver need protective measures in liver insufficiency

8. the half-life is the time taken for the plasma concentration to fall by half [plasmatic half-life]

9. Linear kinetics (First order) [t 1/2 is stable] In most drugs after therapeutic doses: plasma concentration falls exponentially The rate of elimination is proportional to the concentration

10. In most drugs after therapeutic doses: plasma concentration falls exponentially because elimination processes are not saturated [some robustness to dose increase] Elimination is the bigger the higher is the level C max C min Linear kinetics (First order) The rate of elimination is proportional to the concentration

11. Elimination processes are saturated e.g. in alcohol, after higher doses of phenytoin, theophyllin [unstable t 1/2 ] Non-linear (Zero-order, saturation) kinetics For example, in alcohol the rate of metabolism remains the same at about 1 g of alcohol for 10 kg of body weight per hour The rate of elimination is constant

12. In a few drugs at therapeutic doses or in poisoning, elimination processes are saturated [low robustness to dose increase] elimination is constant, limited C max C min Non-linear (Zero-order, saturation) kinetics

14. T 1/2 as a guide to asses: 1/ At a single-dose: duration of drug action 2/ During multiple dosing: to asses whether a drug is accumulated in the body (it is - if the drug is given at intervals shorter than 1,4 half-lifes) and when a steady state is attained (in 4-5 half- lifes) 3/ After cessation of treatment: to asses the time taken for drug to be eliminated from the body (in 4-5 half-lifes) THE USES OF THE HALF-LIFE

15. [t 1/2 = 1 - 2 h] Ampicillin - single dose

16. T 1/2 as a guide to asses: 1/ At a single-dose: duration of drug action 2/ During multiple dosing: to asses whether a drug is accumulated in the body (it is - if the drug is given at intervals shorter than 1,4 half-lifes) and when a steady state is attained (in 4-5 half- lifes) 3/ After cessation of treatment: to asses the time taken for drug to be eliminated from the body (in 4-5 half-lifes) THE USES OF THE HALF-LIFE

17. „PRINCIPLE OF 4-5 HALF-LIFES“: If a drug is administered in intervals shorter than 1.4 half-life, then a steady state is attained after approximately 4-5 half-lifes This time is independent of dose. Steady state t 1/2 Plasma concentration

18. Attainment of steady state (SS) during multiple dosing of drug at intervals of 1 half-life Why SS is attained after 4-5 half-lifes?

19. T 1/2 as a guide to asses: 1/ At a single-dose: duration of drug action 2/ During multiple dosing: to asses whether a drug is accumulated in the body (it is - if the drug is given at intervals shorter than 1,4 half-lifes) and when a steady state is attained (in 4-5 half- lifes) 3/ After cessation of treatment: to asses the time taken for drug to be eliminated from the body (in 4-5 half-lifes) THE USES OF THE HALF-LIFE

20. Elimination of a drug during 5 half-lifes of initial level % of total elimination

21. STEADY STATE attained after 4-5 half-lifes FLUCTUATIONS proportional to dose intervals blunted by slow absorption STEADY-STATE CONCENTRATIONS proportional to dose t 1/2

22. Fluctuations of concentrations are the bigger the longer are intervals between administrations (of parts of total dose) Time (h)

23. Administration of parts of total dose at short intervals produces smaller fluctuations of drug concentrations (levels) an omission of a particular dose* does not need to cause an undesirable fall in drug concentrations (levels) *noncompliance

24. How to reduce fluctuations in drug concentrations? The total dose in parts at short intervals – mostly inconvenient Sustained-release preparations, infusions by administering:

25. Steady-state concentrations are proportional to dose Linear kinetics - diazepam plasma concentrations daily Time (days) toxic therapeutic

26. Time (days) therapeutic toxic plasma concentrations Non-linear, saturation kinetics - phenytoin daily

27. Effects of drug correlate with plasma concentrations Therapeutic Drug Monitoring (TDM) do not correlate with plasma concentrations - „hit and run“ - tolerance or sensitisation - active metabolites