Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Drug Interactions
Document related concepts
Psychopharmacology wikipedia , lookup
Polysubstance dependence wikipedia , lookup
Discovery and development of neuraminidase inhibitors wikipedia , lookup
Orphan drug wikipedia , lookup
Discovery and development of non-nucleoside reverse-transcriptase inhibitors wikipedia , lookup
Plateau principle wikipedia , lookup
Neuropsychopharmacology wikipedia , lookup
Discovery and development of ACE inhibitors wikipedia , lookup
Compounding wikipedia , lookup
Discovery and development of proton pump inhibitors wikipedia , lookup
Pharmaceutical industry wikipedia , lookup
Pharmacognosy wikipedia , lookup
Prescription costs wikipedia , lookup
Prescription drug prices in the United States wikipedia , lookup
Drug discovery wikipedia , lookup
Neuropharmacology wikipedia , lookup
Drug design wikipedia , lookup
Pharmacogenomics wikipedia , lookup
Transcript
Drug Interactions New Zealand College of Pharmacists Purpose of Presentation • This presentation supplements the course materials Risk Factors for Drug Interactions • High Risk Patients – Elderly, young, very sick, multiple disease – Multiple drug therapy – Renal, liver impairment • High Risk Drugs – Narrow therapeutic index drugs – Recognised enzyme inhibitors or inducers Some drugs with a low therapeutic index Lithium Digoxin Carbamazepine Cyclosporin Phenytoin Phenobarbitone Theophylline (Aminophylline) Warfarin Pharmacodynamic Drug Interactions One drug causes a change in patient response to another drug without altering that drug’s pharmacokinetics • Eg increase toxicity of digoxin caused by diuretic induced hypokalaemia • Additive effects of alcohol and benzodiazepines • Beta-blocker given with beta-agonist Pharmaceutical Interactions Interactions that occur prior to systemic administration. • For example incompatibility between two drugs mixed in an IV fluid. These interactions can be physical (e.g. with a visible precipitate) or chemical with no visible sign of a problem Pharmacokinetic Drug Interactions • One drug alters the rate or extent of absorption, distribution, metabolism or excretion of another drug. • A change in blood concentration causes a change in the drug’s effect. Altered Absorption (Availability) • Change in gastrointestinal pH – Ketoconazole needs acidic conditions in gut • Drug binding in GI tract – E.g. tetracycline and calcium • Change in gastrointestinal flora – Antibiotics with OCs • Change in gastrointestinal motility – Metoclopramide and digoxin • Malabsorption caused by other drugs – Orlistat (Xenical) and fat soluble vitamins CYP450 Nomenclature Family CYP2D6 Sub-Family Individual Gene CYP 450 System Definitions • Substrate: Drug is metabolised by the enzyme system • Inducer: Drug that will increase the synthesis of CYP450 enzymes • Inhibitor Drug that will decrease the metabolism of a substrate Enzyme Induction 1 • Leads to production of more enzyme, usually after 3-4 days of exposure to inducer • Most CYPs are inducible but not CYP2D6 • Time course of interaction depends on half-life of inducer. Enzyme Induction 2 • Rifampicin has short half-life and induction apparent with 24 hours • Phenobarbitone has longer half life so time to complete induction takes longer Enzyme Inducers Examples • • • • Rifampicin Phenobarbitone Carbamazepine Cigarette smoke Enzyme Inhibition • Often rapid, reversible and relatively short acting. E.g. erythromycin and cyclosporin NB erythromycin is a substrate and an inhibitor of CYP 3A4 • May be prolonged due to long half- life of drug. E.g. amiodarone and S-Warfarin NB amiodarone is an inhibitor of CYP2C9 but not a substrate for this CYP • • • • Enzyme characteristics % drugs metabolised by enzyme 3A4 2D6 1A2 2C9 60% 25% 15% Small no. but significant interactions • 2C19 Small no. but significant interactions • 2E1 ? EXCRETION Drug A increases or reduces the excretion (usually renal) of Drug B. Blood levels of B fall below or rise above normal therapeutic range. Becomes either ineffective or toxic. Excretion Interactions Mechanisms of urinary excretion: - Simple filtration - Active secretion Mechanisms for active secretion - Acids - Bases Excretion interactions Active secretion mechanisms have limited capacity. e.g. One acid drug may saturate the acid drug active secretion mechanism. Another acid drug will then be secreted less efficiently Excretion Interaction Lithium + Thiazides Probable mechanism: • Thiazides cause diuresis and initial sodium loss. • Compensatory sodium retention in proximal tubules. • Proximal tubules do not distinguish sodium from lithium. • Lithium also retained and accumulates. Excretion Interaction Change in renal blood flow • Methotrexate and NSAIDs NSAIDS can decrease renal blood flow by inhibition of renal prostaglandins. Reduced clearance of MTX and active (toxic) metabolite Protein Binding Drug Displacement Drug B Plasma Tissue Drug A protein bound Drug A free Drug A free Drugs A and B both bind to the same plasma protein Protein Binding Interactions • Importance has been over emphasised • Protein binding is a dynamic state • Increased availability of free drug displaced from plasma proteins ……….. But compensatory mechanisms maintain free drug concentration • Only important in interpretation of total drug concentrations e.g. phenytoin/VPA Some enzyme Inducers • Barbiturates (3A) • Carbamazepine (2C19, 3A) • Phenytoin (3A) • Rifampicin (2C19, 2C9, 3A) • • • • • • St Johns Wort (3A) Ethanol (2E1) Troglitazone (3A) Tobacco (1A2) Omeprazole (1A2) Nevirapine (3A) Where are these enzymes ? • Most cells • Predominantly in endoplasmic reticulum of hepatocytes • Also present in gut wall • Kidney lungs and brain • Liver is main site of drug metabolism Significance of Gut CYPs • CYP3A4 most important. Quite high concentrations in mucosa of small intestine • Activity is 20-300 fold less than in whole liver • Quantitatively significant if oral dose is small or rate of absorption very slow. Enzyme characteristics Genetic Polymorphism • CY2D6 PM- 5-10% Caucasians, <1% Asians (Also “super-fast metabolisers) • CYP2C9 PM 1-3% Caucasians • CY2C19 PM- 3-5% Caucasians, 15-20% Asians • • • • • • Enzyme Characteristics Interindividual Enzyme Content CYP3A4 CYP2D6 CYP1A2 CYP2C9 CYP2C19 CYP2E1 x5 > 50 x 20 x5 ? x 12 Interactions via Enterohepatic Circulation (EHC) Free drug Liver Conjugate Bile Free drug Bacteria Conjugate Gut Case 1 SSRI/TCA • What is the mechanism of the pharmacokinetic interaction ? • What possible pharmacodynamic interactions are there ? • What would be the most hazardous combination ? • What would be the safest combination ? • How would the interaction be managed ? Case 2 SSRI/Tramadol • What CYP enzyme is involved in the metabolism of both these drugs ? • What possible interactions are there ? • Where can you find information on this interaction ? • Are there any case reports in the literature ? • How would you find these case reports ? Case 3 Patient taking timolol eye drops (for more than six months).Complains of slow heart rate and dizziness shortly after taking cimetidine tablets which he had bought OTC. • What is the mechanism of this interaction ? • How could the interaction be managed ? ACE/Diuretics/NSAIDS • Prescriber Update July 2002 • Diuretics (hypovolaemia) • ACE Inhibition of RAA system therefore less constriction of efferent arteioles from glomerulus • NSAIDS/COX-2 inhibition of renal prostaglandins, therefore less dilataion of afferent arterioles.
