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1 Illustrated Drug interaction By Mohie Al-Dien Elsayed (MD) 1 2 Definitions and Terms: -Adverse Event (AE): untoward, unintended, Effect or Experience possibly causing harm -ADE (AE associated with a Drug): an AE which happens in a patient taking a drug -ADR (Adverse Drug Reaction): ADE with Drug/event suspected causal association. -Drug Interactions: “The pharmacologic or clinical response to the administration of a drug combination different from that anticipated from the known effects of the two agents when given alone ”. Drug interactions represent 3–5% of preventable in-hospital ADRs. Drug-Drug Interactions classification: I) According to effect: A-Harmful Effects (potentiating/antagonism) B- Beneficial Effects (Additive or Synergistic) II) According to site of interaction: A) In-vitro: 1-Drug-laboratory tests interaction: 2 3 2) Mixing 2 drugs prior injection: B) IN-VIVO: ♣ Underlying factors; A) Patient factors: Old age changes: e.g. ↓ liver metabolism, kidney function, nerve transmission or the functioning of bone marrow. ↓sensation→ ↑ the chances of errors being made in the administration of drugs . Genetic factors: e.g enzyme genetic variability. Serious diseases that could worsen if the dose of the medicine is reduced. at High Risk for Drug Interactions e.g. Hepatic/renal diseases.;Autoimmune disorders.Cardiovascular disease.;Gastrointestinal disease; Infection ; Psychiatric disorders; Respiratory disorders.;Seizure disorders. pregnant women , Smoking ;Alcohol Diet/Nutrition ;Environment B) Drug dependent factors: *Polypharmacy: *Narrow therapeutic index = LD50 (Lethal dose in 50% of animals) / ED50 (Effective dose in 50% of animals) e.g. Aminoglycoside antibiotics (gentamicin, tobramycin) Anticoagulants (warfarin, heparins), Aspirin, Carbamazepine, Conjugated estrogens,Cyclosporine ,Digoxin,Esterified estrogens, Hypoglycemic agents, Levo-thyroxine Na, Lithium ,Phenytoin, Procainamide, Quinidine sulfate/gluconate, Theophylline,Tricyclic antidepressants ,Valproic acid. 2-Steep dose-response curve (Phenytoin, Aminoglycoside Vancomycin): Small changes in the dosage of a drug produce large changes in the drug's concentration in the patient’s blood plasma. 3-Saturable hepatic metabolism: In addition to dose effects the capacity to metabolize the drug is greatly decreased. 3 4 Plasma drug concentration Need to keep concentration of drug within the therapeutic range MTC MEC Time MEC=Minimum effective concentration MTC=Maximum therapeutic concentration ♣ Classified according to underlying mechanisms into: A) Pharmacokinetic drug-drug interaction: 4 5 1) Altered Absorption: a) Altered pH: *Gastric acidity: * Infection Absorption of weak acid drugs eg Aspirin & Phenobarbitone. * Antiacids ,H2 antagonists , PPIs, atazanavir, itraconazole (gastric alkalinity) →↓ Absorption of weak Acid (Aspirin,barbiturate,Ketoconazole ,quinolones & fluoroquinolones , tetracyclin)& ↑ absorption of weak base . *Intestinal Alkalinity Absorption of weak base drugs e.g. Ephedrine b) Altered Efflux Transporter (P-gp, MDR1) to intestinal lumen(↓ by Quinidine →↑digoxin plasma concentration . c) Altered motility; Gastric Emptying Time,GET (stomach emptying time): * GET ↓by food,morphine,Metoclopramide (antiemitic)→ ↑absorption of rapid dissolution drugs ( Paracetamol & Propranolol) & ↓ absorption of delay dissolution drug( Digoxin). *GET ↓by fasting ,antacids, opioid, antimuscarinic (propantheline atropine), antidiarrhoeal →↓ absorption of paracetamol & ↓ bioavailability of drugs that are degraded in the intestine (levodopa) and ↑Increased bioavailability of lipid soluble drugs . NB: The Reverse; Laxatives will cause drugs to move through the intestine so rapidly that they are poorly absorbed. d) Interactions during absorption. 1- Chelation : (Chelating agent forming a stable complex with a toxic metal): *Antacids (Ca2+, Mg2+, Al3+), iron salts (Fe2+) and milk (Ca2+) inhibit the absorption of tetracyclines *Bile acid binding resins: cholestyramine, cholestipol adsorps and inhibits the absorption of thyroxine , cardiac glycosides (digoxin, digitoxin), warfarin, corticosteroids, thiazides . *Kaolin-pectin decrease the absorption of digoxin *Tetracyclines and Quinolones chelate metals and form an insoluble complex that ↓their absorption. * EDTA chelates toxic metals such as lead and reduces toxicity. 2- Adsorption: nonspecific, physical,binding of a drug to another agent: -Cholestyramine adsorbs dicumarol,methotrexate and digitoxin and decreases their absorption. -Antacids decrease digoxin and iron absorption by adsorption. d) Altered intestinal bacterial flora: Antibiotics (Chloramphenicol, tetracyclines) kill a large number of the normal flora of the intestine, * →↓synthesis of vit K by bacteria, →↑the efects of oral anticoagulants which compete with vit K. * →↓ enterohepatic recycling of estrogens, → the efficacy of oral contraceptives * →↑ absorption of drugs that are metabolized by gut bacteria e.g.digoxin. (In 10% 0f patients receive digoxin 40% or more of the administered dose is metabolized by the intestinal flora). e) Altered blood flow: NE with local anaesthetic 5 6 B) Altered distribution: 1) Plasma protein (e.g. albumin acidic drugs) & a1-acid glycoprotein, basic drugs) displacement: Depends on the affinity of the drug to plasma protein. The most likely bound drugs are capable to displace others. It is clinically important if displaced drug is highly PP binding, with LONG T ½, small Vd, narrow therapeutic range. The free drug is increased by displacement by another drug with higher affinity. e.g Aspirin, Phenylbutazone, Clofibrate & Sulfa Displace: - Oral Anti-coagulants (Dicumarol, Warfarin) Bleeding - Oral Hypoglycemics (Tolbutamide) Hypoglycemia -Bilirubin in Neonate Jaundice & Kernictrus 2) Interactions due to disturbances in fluid and electrolyte balance: Primary drug -Digoxin -Lignocaine -Diuretics -Tubocurarine -Lithium -ACEIs Interacting drug effect -Diuretic-induced hypokalemia -Diuretic-induced hypokalemia -NSAID-induced salt and water retention -Diuretic-induced hypokalemia -Thiazide-induced reduction in renal clearance -Kcl and/or patassium-retaining diuretic-induced hyperkalemia 6 Result of interaction -Digoxin toxicity -Antagonism of antiarrhythmic effects -Antagonism of diuretic effects -Prolonged paralysis -Raised plasma lithium -Severe hyperkalemia 7 3) Altered Elimination: A) Altered transporters (which transport drugs to different organs): P-gp= p-glycoprotein;MDR=multidrug resistance;;OATP=,organic anion transporting polypeptide;OCT[organic cation transporter; OAT, organic anion transporter 7 8 1-Altered Eflux transporter (Pgp) B) Altered Uptake transporter Inhibitor Substrate effect ↓ PCT acidic drug excretion→↓ renal excretion &↑systemic toxicity ↓ hepatic uptake take →↑systemic toxicity OAT1 OCT1 Probencide.novobiocin Cimitidine, desipramine, phenoxy-benzamine,quinine Pencillin, cephalosporones ,cidofover amantadine, cimetidine, memantine, Procainamide ,metformin OATP Gemfibrazol ,cyclosporine squinavir ,retoniver ,squinavir rifampicin Statins, repaglinide, digoxin 8 9 Competitive drug interaction in renal tubules: Primary drug *Penicillin *Methotrexate *Salicylate *Indomethacin *Chlorpropamide *Digoxin Competing drug Effect of interaction *Probenecid *Increased penicillin blood level *Salicylates *Bone-marrow suppression *Sulfonamides *Salicylate toxicity *Probenecid *Indomethacin toxicity *Probenecid *Hypoglycemia *Phenylbutazone Spironolactone *Increased plasma digoxin Amiodarone Verapamil - Alkalinization of urine (NaHCO3) Excretion of weak acid drugs e.g. Aspirin -acidification by Vit. C Excretion of weak base drugs e.g. quinidine, amphetamine Drugs that act as weak acids or bases : Weak acids.:Acetylsalicylic acid ,Furosemide ,Ibuprofen ,Levodopa ,Acetazolamide ,Sulfadiazine, Ampicillin ,Chlorothiazide ,Paracetamol ,Chloropropamide ,Cromoglicic acid ,Ethacrynic acid ,alphaMethyldopamine ,Phenobarbital ,Warfarin ,Theophylline ,Phenytoin. Weak bases: Reserpine ,Amphetamine ,Procaine ,Ephedrine ,Atropine ,Diazepam ,Hydralazine ,Pindolol 9 10 B) Altered Metabolism: Enzyme inhibitors/inducers HME Inducers: Phenytoin, Phenobarbitone, Rifampicin, Testosterone & Tobacco smoking Their own metabolism & Other drugs. HME Inhibitors: MAO-I, Cimetidine, Estrogen, Na Valproate & Chloramphenicol 10 11 Cytochrome P 450 enzymes: Common drug substrates CYP1A2 Clozapine, clomipramine, estrogen, fluvoxamine, haloperidol , tacrine, theophylline, CYP2C9 Phenytoin, warfarin, tolbutamide, glipizide CYP2D6 Alprenolol, bufuralol, carvedilol, metoprolol, propranolol, timolol, amitriptyline,clomipramine,desipr amine, imipramine, nortriptyline ,flecainide ,mexiletine, fluoxetine, propafenone, haloperidol , paroxetine , perphenazine, venlafaxine , codeine ,dextromethorphan CYP2E1 Paracetamol, benzene, ethanol, isoflurane,theophylline CYP3A Diltiazem, felodipine, nifedipine, verapamil,ciclosporin, tacrolimus, alprazolam, midazolam, triazolam, atorvastatin, lovastatin, clarithromycin,erythromycin, indinavir, nelfinavir, ritonavir, saquinavir, losartan, sildenafil Inhibitors (↑drug level of substrate) Amiodarone, cimetidine, fluoroquinolones, ticlopidine, Ciprofloxacin, enoxacin,fluvoxamine Amiodarone, fluconazole, miconazole,phenylbutazone, sulphinpyrazone Clomipramine, quinidine, fluoxetine, haloperidol, paroxetine, Bupropion, paroxetine, quinidine Inducers (↑drug level of substrate) Polycyclic aromatic hydrocarbons,Omeprazole , ritonavir, phenobarbital Disulfiram, diethyldithiocarbamate Diltiazem, verapamil, itraconazole, ketoconazole, clarithromycin, erythromycin,troleandomyci n, Delavirdine , indinavir, ritonavir,saquinavir,grapefru it juice,mifepristone, nefazodone, Amprenavir, aprepitant,atazanavir,ciprofl oxacin,darunavir/ritonavir, , fluconazole, fosamprenavir, grapefruit juice,imatinib, Ethanol, isoniazid 11 Carbamazepine, phenobarbital, rifampin,, St John’s Wort Not inducible Rifabutin, rifampin, rifapentine,carbamazepine, phenobarbital, phenytoin, topiramate, efavirenz, nevirapine, St John’s Wort, Avasimibe, phenytoin, rifampin, 12 II- Pharmacodynamic Drug-Drug interaction: A) Additive, synergistic or summation interactions Drugs Anticholinergics + anticholinergics (anti-parkinsonian agents, butyrophenones, phenothiazines , tricyclic antidepressants, etc.) Antihypertensives + drugs causing hypotension (antianginals, vasodilators, phenothiazines) CNS depressants + CNS depressants (alcohol, antiemetics, antihistamines, hypnosedatives, etc.) QT prolonging drugs + other QT prolonging drugs (Amiodarone + Disopyramide) Methotrexate + co-trimoxazole Nephrotoxic drugs + nephrotoxic drugs (gentamicin or tobramycin with cefalotin (cephalothin) Neuromuscular blockers + drugs with neuromuscular blocking effects (e.g. aminoglycoside antibacterials) Potassium supplements + potassium-sparing diuretics (triamterene) Aminoglycoside +B-lactam Result Increased anticholinergic effects; heat stroke in hot and humid conditions; a dynamic ileus; toxic psychoses Increased antihypertensive effects; orthostasis Impaired psychomotor skills, reduced alertness, drowsiness, stupor, respiratory depression, coma, death Additive prolongation of QT interval, increased risk of torsade de pointes Bone marrow megaloblastosis due to folic acid antagonism Increased nephrotoxicity Increased neuromuscular blockade; delayed recovery, prolonged apnoea Marked hyperkalaemia Synergim Potentiation: . - Barbiturates (NOT analgesic) potentiate the analgesic effect of aspirin. - Change pH: *alkalinize urine by NaCo3 efficacy of aminoglycoside, sulphonamid *Acidify urine by vit, C efficacy of B lactam, nitrofurantoin. - hypokalemia digitalis toxicity B-Antagonism: *Chemical e.g. Heparin(Ac.) +Pr.So4(base) *Physiological e.g. Ad& H on bronchi *Pharmacological One Agonist + One Blocker + One Receptor. Iatrogenic Disease: Drug-induced disease. - Large dose of Reserpine & Chlorpromazine (Iatrogenic Parkinsonism) -Large dose of Cortisol (Iatrogenic Cushing’s disease) 12 13 Drug-food interaction 13 14 Food High-carbohydrate meals Acidic foods/juices and sodas (e.g., cola) antacids (Mg , aluminium ) , iron products and calcium in vitamin-mineral products and liquid enteral nutritional supplements vitamin B6 (pyridoxine) found in avocados, beans, peas, sweet potatoes, bacon, beef liver, pork, tuna & some nonprescription vitamin-mineral products Avocado ;Brassicas (brussel sprouts, broccoli, cabbage) Grape fruit juice Soya Hypericum perforatum (St John’s wort) vitamin K found in green leafy vegetables(spinach, collard greens),, tomatoes coffee, beef liver, green tea, , Alfalfa tablets Broccoli ,Brussels sprouts, Cabbage, Cauliflower (raw), Green tea ,Liver, Soybean, Vegetable oils (canola, soybean) , Watercress Consuming foods high in sodium (i.e licorice, processed meats, canned foods) The drug may increase appetite thus increasing nutrient intake The drug may decrease appetite thus decreasing nutrient intake Foods Containing High Amounts of Tyramine Ale , Avocados,Bananas,Beans (lima beans, butter beans, bean pods),Caviar, aged Cheese, Chocolate Coffee,Figs,Fish ,meat (bologna, fermented meat, salami, pepperoni, summer sausage),Liver (beef or chicken), Raspberries, Raisins, Sour cream,Soy beans or sauce, Tofu, Wines (especially red),Yeast preparations, Yogurt Drugs Iron, levodopa, penicillins (most), tetracycline, erythromycin Ketoconazole Fluoroquinolones (ciprofloxacin, levofloxacin, ofloxacin, trovafloxacin), Tetracycline ↑ absorption ↓ absorption ↓blood levels of dopamine &antiparkinsonism effects Enzymatic inducer (effect↓) levodopa,; Oral anticoagulant Amlodipine,nifedipine, Cyclosporine, tacrolimus Terfenadine, astemizole ,Cisapride , Pimozide Carbamazepine, Saquinavir, Midazolam, Alprazolam, Triazolam Clozapine, Haloperidol, Olanzapine, caffeine, NSAIAs, Phenytoin, Zafirlukast, warfarin Warfarin, Digoxin, Theophylline, cyclosporine, phenytoin and antiretrovirals Oral Anti-coagulant Antihypertensives effect ↓ absorption Enzymatic inhibition (Toxicity) Enzymatic inhibition(Toxicity) Enzymatic inductor (CYP450) Interfere with efficacy ↓effectiveness of the drug. Cortico-steroid Diuretic MAOIs acute exacerbation of blood pressure. Effect of Drugs in nutrient body content Food Taking large amounts of these drugs will cause a loss of Vitamin C in the body. Women who take these drugs often have low levels of folic acid and B6 in the blood. Vitamin D and folic acid levels in the body are ↓by the taking of these types of drugs. Ginseng Kava (Piper methysticum) Chamomile Hawthorn 14 drug Aspirin Oral contraceptives Anticonvulsant Warfarin, Heparin, Aspirin and NSAIA Levodopa Benzodiazepines, barbiturates , opioid Beta-adrenergic antagonists, Cisapride, Digoxin, Quinidine 15 HERBALS AND DRUG INTERACTIONS Activity Commonly Used Herbs* Anti-coagulant chamomile, dong quai (tang-kuei), horse chestnut Anti-platelet bilberry, bromelain, cayenne, feverfew, flaxseed oil, garlic, ginger, ginkgo, ginseng, green tea, meadowsweet, motherwort, and turmeric Pro-coagulant goldenseal, Oregon grape root, shepherd's purse *other anticoagulant and antiplatelet herbs, white atracytlodes, cnidium (chuanxiong), salvia, garlic, zedoaria, pueraria, carthamus, lysimachia, cinnamon bark, tien-chi (sanqi), and capillaris (also listed: tangkuei and turmeric). Herb Cayenne Some Common Uses Possible Side Effects or Drug Interactions External: used for muscle spasm and soreness Internal: GI tract disorders External: potential for skin ulceration and blistering with greater than 2 days of use. Internal: overuse may cause severe hypothermia. Echinacea boosts the immune system & Echinacea may cause inflammation of the liver if used with helps fight colds and flu. Aids certain other medications, such as anabolic steroids, wound healing. methotrexate or others. Ephedra (MaHuang) It is used in many over-thecounter diet aids as an appetite suppressant. Or used for asthma or bronchitis. Ephedra may interact with certain antidepressant medications or anthypertensive medications to cause dangerous elevation in blood pressure or heart rate. It could cause death in certain individuals. MAOI, central nervous system stimulants, alkaloids ergotamines and xanthines Feverfew الينسون ↓migraine headaches and for arthritis, rheumatic disease & allergies. Feverfew may increase bleeding, especially in patients already taking certain anti-clotting drugs. ↓ Blood cholesterol, TG levels and blood pressure. Garlic may increase bleeding, especially in patients already taking Anticoagulants ,NSAIA, acetylsalicylic acid certain. Ginger is used for reducing nausea, vomiting and vertigo Ginger may ↑bleeding, potentiate anticoagulant sulfaguanidine (enhance absorption) ↑blood circulation & oxygenation and for improving memory and mental alertness. Ginkgo may increase bleeding especially in patients already taking warfarin, Aspirin and NSAIA Garlic Gingerزنجبيل Ginkgo (ginkgo biloba) الجنكة الصينية 15 16 Ginseng increases physical stamina and mental concentration. warfarin (to cause bleeding or to ↓ effectiveness. It may cause bleeding in women post- menopause . ↑ heart rate or blood pressure. antidepressants such as phenelzine sulfate (to cause manic episodes, headaches);); corticosteroids (potentiation); estrogens (potentiation) mild laxative and also reduces inflammation. Goldenseal may worsen swelling and/or high blood pressure. nervousness, anxiety or restlessness; it is also a muscle relaxant. ↑the effects of certain anti-seizure, prolong the effects of certain anesthetics ,↑ the effects of alcohol. It may ↑the risk of suicide for people with certain types ofdepression. Licorice is used for treating stomach ulcers. Certain licorice compounds may cause high blood pressure, swelling or electrolyte imbalances.corticosteroids and thiazide diuretics (potentiation); digitalis or other cardiac glycosides (increased sensitivity) used for enlarged prostate and urinary inflammations. People using saw palmetto may see effects with other hormone therapies. St. John's Wort is used for mild to moderate depression or anxiety and sleep disorders. prolong the effect of certain anesthetic agents. warfarin (to cause bleeding); serotonin-uptake inhibitors (to cause mild serotonin syndrome); indinavir (decreased bioavailability); digitoxin, theophylline, cyclosporin, phenprocoumon, and oral contraceptives (all with reduced bioavailability) Mild sedative or sleep-aid. It is also a muscle relaxant. ↑the effects of certain anti-seizure or prolong the effects of certain anesthetic agents. Ginseng Goldenseal Kava-kava Licorice Saw Palmetto St. John's Wort القديس Valerian الناردين نبات Herb Interactions Reported or Suspected Tang-kuei danggui warfarin (to cause bleeding) Salvia danshen المريمية, warfarin (to cause bleeding) نبات الناعمة Rhubarb dahuang راوند ↑cardiac glycosides and antiarrhythmic (by ↓K via laxative effect) Aloe luhui الصبار ↑cardiac glycosides and antiarrhythmic (by ↓K via laxative effect) Ma-huang MAO is (to cause hypertension); cardiac glycosides or halothane (to produce cardiac arrhythmia); caffeine (to ↑cardiovascular side effects) Astragalus huangqi قتاد cyclosporine, azathioprine, methotrexate (to impair intended immuno-suppressive effects). Bupleurum chaihu sedatives (potentiation) 16 17 Drug Herbal/Food Adverse Effects/Drug Interactions Reported Alprazolam Kavaفلفل كاوة Synergistic CNS activity of alprazolam Quinine Elevated serum drug levels of amantadine and risk of toxicity (ataxia, mental confusion) Khat Delayed or decreased absorption of amoxicillin and ampicillin Grapefruit (juice) Increased bioavailability of astemizole Quinine ↑serum drug levels of astemizole, and↑ risk of cardiotoxicity Buspirone Grapefruit(juice) Increased serum drug levels of buspirone Dihydrop. Ca. channel B. Grapefruit (juice) Increased serum drug levels: amlodipine 15%, felodipine >300%, nifedipine 35%, nisoldipine 400% Carbamazepine Grapefruit(juice) Increased serum drug levels by about 40% Quinine Elevated serum drug levels of carbamazepine by about 37% Grapefruit (juice) ↑ serum drug levels and increased usual ADRs of cyclosporine Quinine Elevated serum digoxin levels by about 75% Licorice Elevates serum digoxin levels 4-fold Amantadine Amoxicillin , ampicillin Astemizole Cyclosporine Digoxin Hawthorn الزعرور Increased cardiac toxicity البرى Estrogen Ginseng (Siberian) Elevates serum digoxin levels by about 75% St. John’s wort Decreases serum digoxin concentration by 25% Grapefruit (juice) Increased serum drug levels by 37% Herbal tea Increased serum drug levels by 28% Increased serum drug levels of lithium Lithium diuretic Herbs (broom الوزال, buchu, dandelion الهندباء ,juniper ) العرعر شجر Midazolam Grapefruit (juice) Increased serum drug levels of midazolam St. John’s wort Incoherent, confused, nausea, weakness, and fatigue; effects occurred 10 days after paroxetine was discontinued and first dose of St. John’s wort was initiated Ginseng (Siberian) Insomnia, tremulousness, tension headaches, irritability, and visual hallucinations Phenobarbital Quinine Elevated serum phenobarbital levels by about 35% Quinidine Grapefruit (juice) Reduced and delayed cardiac effects (QTc). Licorice Mineralocorticoid of licorice blocked; hypokalemia and muscle weakness Theophylline St. John’s wort Increases serum theophylline concentration by about 50% Triazolam Grapefruit (juice) Increased serum drug levels of triazolam Paroxetine and other SSRIs Phenelzine Spironolactone 17 18 Warfarin Dashen Increased anticoagulant activity or increased INR Ginkgo biloba الجنكه, garlic, feverfew الينسون, and cayenne Platelet aggregation inhibitor effects and increased risk of bleeding/bruising Ginseng(Siberian) Decreased anticoagulant activity or decreased INR Licorice Increased anticoagulant activity or increased INR Alfalfa فصة, البرسيم Decreased anticoagulant activity or decreased INR Vitamin E (doses of 200 IU/day) Increased anticoagulant activity and increased platelet aggregation inhibition, increased risk of bleeding Ginger زنجبيل ↑anticoagulant activity, increased INR, prolonged bleeding Quinine Increased anticoagulant activity or increased INR It may be possible to reduce or prevent ADRs by: Avoiding unnecessary drug use; if you don't prescribe drugs you will not get ADRs Consult the BNF and the BNF for Children which are useful sources of information on drug interactions. Read the Drug Safety Updates from the MHRA http://www.mhra.gov.uk/mhra/drugsafetyupdate Exercise caution when prescribing at extremes of age. These patients are at higher risk due to altered pharmacodynamics and pharmacokinetics Neonates (first 30 days of life) are at risk of toxicity due to inefficient renal filtration, relative enzyme deficiencies, differing target organ sensitivity, and inadequate detoxifying systems causing delayed excretion. Children; drugs are not extensively tested in this group, the drug may not be licensed at all or licensed but used 'off-label', for which the prescriber is legally responsible. Elderly; altered response to drugs (pharmacodynamics). reduced response at receptor level (beta-blockers), increased central nervous sensitivity (benzodiazepines) Reduced clotting factors (increased response to warfarin). Elderly; altered handling of drugs (pharmacokinetics) - see the BNF for specific dose reductions of individual drugs. Absorption- may be reduced (reduced levodopa and iron absorption may be clinically significant), Altered distribution; generally reduced weight in the elderly with decreased body water (need to reduce loading dose of digoxin) and increased body fat (benzodiazepines can accumulate) and decreased binding to albumin (phenytoin). Metabolism- reduced blood flow (propranolol), reduced liver mass (theophylline may become toxic). Excretion- decreased renal excretion (digoxin, lithium). Identify patients with co-existing disease which may affect drug elimination Reduce maintenance dose of digoxin in patients with renal impairment Reduce dose of oral propranolol in patients with hepatic disease Identify drugs which pose risk and monitor carefully Enzyme inducers and inhibitors- flag patient's notes to remind you and others. Drugs with major effect on a vital process such as warfarin Drugs with narrow therapeutic range such as digoxin, carbamazepine, theophylline, phenytoin Drugs where loss of effect may lead to disease breakthrough such as chronic obstructive pulmonary disease Patient dependent on prophylactic action such as transplant patients taking ciclosporin Counsel patients on drug action and possible side-effects, provide written information and encourage patients to report back progress and /or side-effects Gender – some ADRs are more prevalent in the female population. Examples of this are the increased susceptibility of females to the toxic effects of digoxin, heparin and captopril. 18 19 Information for Practitioners to Relay to Patients about Interactions with Drugs. Type of Interaction Examples Patient Information Drug absorption inhibited by binding, resulting in low drug levels. Tetracycline with minerals; alkaloids with tannins; pectins, resins, and fibers may bind several drugs. Take herbs at least one hour apart, preferably 1.5 hours apart from taking drugs. Drug absorption inhibited by rapid transit time, resulting in low drug levels. Diarrhea or frequent bowel movements due to colitis or laxative intake speeds transit of all materials through the intestinal tract. Treat diarrhea and avoid excessive use of laxatives. Induction of diarrhea is an intended treatment strategy in Chinese medicine for nephritis. Drug absorption and/or elimination modified. Saponins may improve absorption and elimination of drugs, altering the blood levels and rate of change of drug levels; strongly acid or alkaline herbs may alter absorption of drugs. Take herbs at least 1.5 hours apart from drugs; avoid herbal preparations that have high saponin content. Drugs metabolized too slowly resulting in elevated drug levels. Grapefruit juice and herbs that inhibit CYP enzyme system can result in much higher levels of drugs in the bloodstream, and longer persistence of the drugs. Take herbs at least 1.5 hours apart from drugs, preferably taking the drugs first (so that drug metabolism is already under way by the time the herbs can inhibit enzyme systems). Potassium decreased when using cardiac drugs, resulting in adverse cardiac conditions. Laxative and diuretic herbs may reduce potassium; these types of herbs are often given together for weight loss. Avoid any strong laxative or diuretic action while using cardiac drugs. To compensate for mild diuretic or laxative treatments, consume highpotassium foods. Drug action is intensified by similar effect of herbs. Blood vitalizing herbs and blood thinning drugs may prevent adequate clotting; hypoglycemic herbs and hypoglycemic drugs may lower blood sugar too far; caffeine or ephedrine containing herbs and CNS stimulants disturb nerve functions. When the drug therapy is already addressing a particular therapeutic goal, avoid adding an herbal therapy with the same goal. Intensify monitoring of blood conditions affected by the drugs. Drugs cause adverse reaction to occur when certain substances are ingested. MAO inhibitors can cause hypertension when an ordinary food component, tyramine, is ingested; some drugs can cause severe nausea when alcohol is ingested. Learn the known reactions and take reasonable steps to avoid problematic herbs. It may be unnecessary to have total abstinence from an herb that reacts with a drug. Miscellaneous: reported drug interactions. St. John’s wort decreases bioavailability of indinavir. Learn the known reactions and avoid using the combination. Desired drug effect is counteracted by herb effect. Immune-enhancing herbs may counteract intended immunosuppressive action of drugs in autoimmune disorders, including transplant rejection reactions. If herbs with known immuneenhancing actions are to be used, limit the dosage to avoid counteracting the drugs. 19 20 REFERENCE Tatro DS. Drug interactions with natural products. 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