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Absorption, distribution, metabolism and excretion

This article explores the processes of absorption, distribution, metabolism, and excretion (ADME) of drugs, and how these processes can affect the outcome of patient treatment. It discusses the frequent causes of treatment failure and non-compliance, as well as the potential toxic effects of drugs. The article also examines how differences in ADME processes between patients can impact therapy and highlights strategies that have been used to improve treatment.

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Absorption, distribution, metabolism and excretion

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  1. Absorption, distribution, metabolism and excretion • relevant to ALL drugs • large research/development area • frequent cause of failure of treatment • failure of compliance • failure to achieve effective level • produce toxic effects • can enhance patient satisfaction with treatment

  2. Learning objectives • Know the processes involved in ADME of drugs • Know how these processes may affect the action of xenobiotics • Appreciate how these processes can affect the outcome of the treatment of patients with drugs • Appreciate how differences in these processes between patients can affect therapy • Know how these processes have been exploited to improve therapy • Be able to exemplify the above

  3. Passage through lipid membranes • diffusion through gaps between cells (glomerulus = 68K; capillary 30K) • passage through the cell membrane • diffuse through pore (very small; use dependent) • carrier mediated transport (specific, saturable; Fe in gut; L-DOPA at blood-brain barrier; anion/cation transport in kidney) • pinocytosis (insulin in CNS; botulinum toxin in gut) • diffusion through lipid of cell membrane (depends on AREA, DIFFUSION GRADIENT, DIFFUSION COEFFICIENT, LIPID SOLUBILITY)

  4. Weak acids and weak bases HA <==> H+ + A- B + HCl <==> BH+ + Cl- [ UI ] [ I ] [ UI ] [ I ] pKa=pH+log(HA/A-) pKa=pH+log(BH+/B) pKa = 4.5 (a weak acid) pH = 2 pH = 7.4 0.1 = [ I ] [ I ] = 9990 100 = [ UI ] [ UI ] = 100 100.1 = total drug = 10090

  5. Routes of administration • Enteral;oral, sub-lingual (buccal), rectal • Parenteral;iv, im, sc, id, it, etc. • Surface; of skin, of lungs? for local or systemic effect? • Inhalation; local or systemic effect? • Vaginal;(usually local) • Eye; (usually local)

  6. Factors affecting oral absorption • Disintegration of dosage form • Dissolution of particles • Chemical stability of drug • Stability of drug to enzymes • Motility and mixing in GI tract • Presence and type of food • Passage across GI tract wall • Blood flow to GI tract • Gastric emptying time

  7. Bioavailability • the proportion of the drug in a dosage form available to the body i.v injection gives 100% bioavailability. Calculated from comparison of the area under the curve (AUC) relating plasma concentration to time for iv dosage compared with other route. Says nothing about effectiveness.

  8. Bioavailability Destroyed in gut Not absorbed Destroyed by gut wall Destroyed by liver Dose to systemic circulation

  9. Sustained release preparations • depot injections (oily, viscous, particle size) • multilayer tablets (enteric coated) • sustained release capsules (resins) • infusors(with or without sensors) • skin patches (nicotine, GTN) • pro-drugs • liposomes Targeted drugs , antibody-directed

  10. Distribution into body compartments • Plasma 3.5 litres, heparin, plasma expanders • Extracellular fluid 14 litres, tubocurarine, charged polar compounds • Total body water 40 litres, ethanol • Transcellular small, CSF, eye, foetus (must pass tight junctions) Plasma protein binding; Tissue sequestration

  11. Alter plasma binding of drugs 1000 molecules 90.0 99.9 % bound 1 100 molecules free 100-fold increase in free pharmacologically active concentration at site of action. EffectiveTOXIC

  12. Biotransformation of drugs • Mutations allowing de-toxification of natural toxic materials are advantageous and are selected • Drugs are caught up in these established de-toxification processes • Drugs may converted to less toxic/effective materials more toxic/effective materials materials with different type of effect or toxicity

  13. Sites of biotransformation • where ever appropriate enzymes occur; plasma, kidney, lung, gut wall and LIVER • the liver is ideally placed to intercept natural ingested toxins (bypassed by injections etc) and has a major role in biotransformation

  14. The liver Hepatocytes smooth endoplasmic reticulum bile portal venous blood microsomes contain cytochrome P450 dependent mixed function oxidases systemic arterial blood venous blood

  15. Cytochrome P450 dependent mixed function oxidases DRUG METABOLITE =DRUG+O O2 microsome NADP+ NADPH WATER H+

  16. PHASE 1 reactions Hydroxylation -CH2CH3 -CH2CH2OH Oxidation -CH2OH -CHO -COOH O-de-alkylation -CH2OCH2- -CH2OH + -CHO N-de-alkylation -N(CH3)2 -NHCH3 + CH3OH N-oxidation -NH2 -NHOH Oxidative deamination -CH2CHCH3 | -CHCOCH3 + NH3 NH2

  17. Phase I in action 4-OH; active; cardiotoxic 4-OH; active; cardiotoxic 0 0 N CH2 CH2 N CH3 CH3 desmethyl; active; antidepressant +Conjugates; phase II

  18. PHASE 2 reactions(not all in liver) CONJUGATIONS • -OH, -SH, -COOH, -CONH with glucuronic acid to give glucuronides • -OH with sulphate to give sulphates • -NH2, -CONH2, aminoacids,sulpha drugs with acetyl- to give acetylated derivatives • -halo, -nitrate, epoxide, sulphate with glutathione to give glutathione conjugates all tend to be less lipid soluble and therefore better excreted (less well reabsorbed)

  19. Other (non-microsomal) reactions • Hydrolysis in plasma by esterases (suxamethonium by cholinesterase) • Alcohol and aldehyde dehydrogenase in cytosolic fraction of liver (ethanol) • Monoamine oxidase in mitochondria (tyramine, noradrenaline, dopamine, amines) • Xanthene oxidase (6-mercaptopurine, uric acid production) • enzymes for particular drugs (tyrosine hydroxylase, dopa-decarboxylase etc)

  20. Inhibitors and inducers of microsomal enzymes • INHIBITORS cimetidine prolongs action of drugs or inhibits action of those biotransformed to active agents (pro-drugs) • INDUCERS barbiturates, carbamazepineshorten action of drugs or increase effects of those biotransformed to active agents • BLOCKERS acting on non-microsomal enzymes (MAOI, anticholinesterase drugs)

  21. Factors affecting biotransformation • age (reduced in aged patients & children) • sex (women more sensitive to ethanol?) • species (phenylbutazone 3h rabbit, 6h horse, 8h monkey, 18h mouse, 36h man); route of biotransformation can also change • race (fast and slow isoniazid acetylators, fast = 95% Eskino; 50% Brits; 13% Finns; 13% Egyptians. • clinical or physiological condition • first-pass (pre-systemic) metabolism

  22. Excretion of drugs • Glomerular filtration allows drugs <25K MW to pass into urine; reduced by plasma protein binding; only a portion of plasma is filtered. • Tubular secretion active carrier process for cations and for anions; inhibited by probenicid. • Passive re-absorption of lipid soluble drugs back into the body across the tubule cells. Note effect of pH to make more of weak acid drug present in ionised form in alkaline pH therefore re-absorbed less and excreted faster; vica-versa for weak bases.

  23. Special aspects of excretion • lactating women in milk • little excreted in faeces unless poor formulation or diarrhoea • volatile agents (general anaesthetics) via lungs • the entero-hepatic shunt glucuronic acid conjugates with MW >300 are increasingly excreted in bile; hydrolysis of say -OH conjugate by beta-glucuronidase in gut will restore active drug which will be reabsorbed and produce an additional effect.

  24. The enterohepatic shunt Drug Liver Bile formation Bile duct Biotransformation; glucuronide produced Hydrolysis by beta glucuronidase gall bladder Portal circulation Gut

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