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S.P. Markey Laboratory of Neurotoxicology NIMH, NIH
Drug Metabolism S.P. Markey Laboratory of Neurotoxicology NIMH, NIH Nov. 14, 2002
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Evolution of Drug Metabolism As a Science Post WWII Pioneers
R.T. Williams – Great Britain 1942, worked on the metabolism on TNT with regard to toxicity in munitions workers; due to the war he assembled teams to work on metabolism of sulfonamides, benzene, aniline, acetanilide, phenacetin, and stilbesterol Developed concept of Phase 1 & Phase 2 Reactions. Biotransformation involves metabolic oxygenation, reduction, or hydrolysis; result in changes in biological activity (increased or decreased) Second phase, conjugation, in almost all cases resulted in detoxication.
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Evolution of Drug Metabolism As a Science Post WWII Pioneers
B.B. Brodie, U.S. NYU and Laboratory of Industrial Hygiene, NYC 1949 – Metabolic fate of acetanilide and phenacetin in man (with J. Axelrod) 1950s, NIH – pioneering studies on all aspects of drug metabolism; esp. reserpine, serotonin;hexobarbital tolerance 1952 – R.T. Williams spent 6 months at NIH; subsequently many students went between both labs (Dick Adamson, Jim Gillette, and Sidney Udenfriend) 1950s, Brodie lab developed the spectrophotofluorimeter (R. Bowman)
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Drug Metabolism Extrahepatic microsomal enzymes
(oxidation, conjugation) Hepatic microsomal enzymes (oxidation, conjugation) Hepatic non-microsomal enzymes (acetylation, sulfation,GSH, alcohol/aldehyde dehydrogenase, hydrolysis, ox/red)
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Liver Microsomal System
Oxidative Reactions: Cytochrome P450 mediated Examples Formation of an inactive polar metabolite Phenobarbital Formation of an active metabolite By Design: Purine & pyrimidine chemotherapy prodrugs Inadvertent: terfenadine – fexofenadine Formation of a toxic metabolite Acetaminophen – NAPQI
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Electron flow in microsomal drug oxidizing system
CYP R-Ase NADPH NADP+ CYP Fe+3 OH Drug e- Drug PC CYP Fe+3 OH Drug CYP-Fe+2 Drug CO CO hu CYP Fe+2 Drug e- O2 CYP Fe+2 Drug O2 2H+ H2O Electron flow in microsomal drug oxidizing system
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Cytochrome P450 Isoforms (CYPs) - An Overview
NADPH + H+ + O2 + Drug ® NADP+ + H2O + Oxidized Drug Carbon monoxide binds to the reduced Fe(II) heme and absorbs at 450 nm (origin of enzyme family name) CYP monooxygenase enzyme family is major catalyst of drug and endogenous compound oxidations in liver, kidney, G.I. tract, skin, lungs Oxidative reactions require the CYP heme protein, the reductase, NADPH, phosphatidylcholine and molecular oxygen CYPs are in smooth endoplasmic reticulum in close association with NADPH-CYP reductase in 10/1 ratio The reductase serves as the electron source for the oxidative reaction cycle
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CYP Families Twelve CYP gene families have been identified in humans, and the categories are based upon protein sequence homology Most of the drug metabolizing enzymes are in CYP 1, 2, & 3 families . CYPs have molecular weights of kDa. Frequently, two or more enzymes can catalyze the same type of oxidation, indicating redundant and broad substrate specificity. CYP3A4 is very common to the metabolism of many drugs; its presence in the GI tract is responsible for poor oral availabilty of many drugs
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CYP Nomenclature Families - CYP plus arabic numeral (>40% homology of amino acid sequence, eg. CYP1) Subfamily % homology of amino acid sequence; eg. CYP1A Subfamily - additional arabic numeral when more than 1 subfamily has been identified; eg. CYP1A2 Italics indicate gene (CYP1A2); regular font for enzyme
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CYP Tables Human CYPs - variability and importance in drug metabolism
Isoforms in metabolism of clinically important drugs Factors that influence CYP activity Drugs that inhibit CYPs Non-Nitrogenous CYP inhibitors Extrahepatic CYPs
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Human Liver Drug CYPs S. Rendic & F.J. DiCarlo, Drug Metab Rev 29:413-80, 1997
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Factors Influencing Activity and Level of CYP Enzymes
Red indicates enzymes important in drug metabolism S. Rendic & F. J. Di Carlo Drug Metab Rev 29: , 1997
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Participation of the CYP Enzymes in Metabolism of Some Clinically Important Drugs
S. Rendic & F.J. Di Carlo, Drug Metab Rev 29: , 1997
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Participation of the CYP Enzymes in Metabolism of Some Clinically Important Drugs (cont’d)
S. Rendic & F.J. Di Carlo, Drug Metab Rev 29: , 1997
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Drugs that Inhibit Drug Metabolism by Forming Complexes with CYPs
Modified from: A. Alvares and W.B. Pratt, Pathways of Drug Metabolism in Principles of Drug Metabolism (Eds. W.B. Pratt, P.Taylor) 3rd Edition, 1990
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Non-nitrogenous Substances that Effect Drug Metabolism by Forming Complexes with CYPs
Grapefruit juice - CYP 3A4 inhibitor; highly variable effects; unknown constituents D.G. Bailey, et al.; Br J Clin Pharmacol 1998, 46: Isosafrole, safrole - CYP1A1, CYP1A2 inhibitor; found in root beer, perfume Piperonyl butoxide & alcohol -CYP1A1, CYP1A2 inducer; insecticide constituent
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Overheard Conversation
At a B&B breakfast table, after grapefruit juice was served, someone remarked “A friend read the package insert with her prescription and the fine print warned against drinking grapefruit juice…is this true? Should it be avoided with all medications? How about grapefruit itself? How about orange juice?”
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Effect of Grapefruit Juice on Felodipine Plasma Concentration
5mg tablet with juice without Review- D.G. Bailey, et al.; Br J Clin Pharmacol 1998, 46:
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Grapefruit Juice Facts
GJ or G (not OJ) elevates plasma peak drug concentration, not elimination t1/2 GJ reduced metabolite/parent drug AUC ratio GJ caused 62% reduction in small bowel enterocyte 3A4 and 3A5 protein; liver not as markedly effected (i.v. pharmacokinetics unchanged) GJ effects last ~4 h, require new enzyme synthesis Effect cumulative (up to 5x Cmax) and highly variable among individuals depending upon 3A4 small bowel basal levels
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Human Drug Metabolizing CYPs Located in Extrahepatic Tissues
S. Rendic & F.J. DiCarlo, Drug Metab Rev 29:413-80, 1997
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Human Drug Metabolizing CYPs Located in Extrahepatic Tissues (cont’d)
S. Rendic & F.J. DiCarlo, Drug Metab Rev 29:413-80, 1997
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CYP Biotransformations
Chemically diverse small molecules are converted, generally to more polar compounds Reactions include: Aliphatic hydroxylation, aromatic hydroxylation Dealkylation (N-,O-, S-) N-oxidation, S-oxidation Deamination Dehalogenation
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Examples: ibuprofen, pentobarbital
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ibuprofen
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pentobarbital
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Aromatic Hydroxylation
Examples: acetanilide, phenytoin, propranolol Endogenous substrates: steroid hormones (not aromatic amino acids)
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phenytoin Arene epoxide intermediate produces multiple products
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propranolol
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N (or O, S)-Dealkylation
N-demethylation generates formaldehyde
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ethylmorphine N-demethylation favored over O-deakylation
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propranolol
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6-methylthiopurine
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Examples: chlorpheniramine, trimethylamine
Examples: chlorpromazine, cimetidine
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chlorpheniramine chlorpromazine
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Deamination Examples: amphetamine, diazepam
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amphetamine
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Example: carbon tetrachloride, others include
Example: carbon tetrachloride, others include. halothane, methoxyflurane
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Non-CYP Drug Biotransformations
Oxidations Hydrolyses Conjugation (Phase 2 Rxs) Major Conjugation Reactions Glucuronidation (high capacity) Sulfation (low capacity) Acetylation (variable capacity) Examples:Procainamide, Isoniazid Other Conjugation Reactions: O-Methylation, S-Methylation, Amino Acid Conjugation (glycine, taurine, glutathione) Many conjugation enzymes exhibit polymorphism
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Non-CYP drug oxidations
Monoamine Oxidase (MAO), Diamine Oxidase (DAO) - MAO (mitochondrial) oxidatively deaminates endogenous substrates including neurotransmitters (dopamine, serotonin, norepinephrine, epinephrine); drugs designed to inhibit MAO used to effect balance of CNS neurotransmitters (L-DOPA); MPTP converted to toxin MPP+ through MAO-B. DAO substrates include histamine and polyamines. Alcohol & Aldehyde Dehydrogenase - non-specific enzymes found in soluble fraction of liver; ethanol metabolism Xanthine Oxidase - converts hypoxanthine to xanthine, and then to uric acid. Drug substrates include theophylline, 6-mercaptopurine. Allopurinol is substrate and inhibitor of xanthine oxidase; delays metabolism of other substrates; effective for treatment of gout.
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Non-CYP drug oxidations
Flavin Monooxygenases Family of enzymes that catalyze oxygenation of nitrogen, phosphorus, sulfur – particularly facile formation of N-oxides Different FMO isoforms have been isolated from liver, lung (D. Ziegler, 1993, Ann Rev Pharmacol Toxicol 33: ) Complete structures defined (Review: J. Cashman, 1995, Chem Res Toxicol 8: ) Require molecular oxygen, NADPH, flavin adenosine dinucleotide (FAD) Single point (loose) enzyme-substrate contact with reactive hydroperoxyflavin monoxoygenating agent FMOs are heat labile and metal-free, unlike CYPs Factors affecting FMOs (diet, drugs, sex) not as highly studied as CYPs
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FMO Oxidations
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Hydrolysis Reactions Esters
Example: aspirin (others include procaine, clofibrate)
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Hydrolysis Reactions Amides
Example:lidocaine; others include peptide drugs
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Conjugation Reactions Glucuronidation
Liver has several soluble UDP-Gluc-transferases
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Glucuronic acid conjugation to phenols, 3°-amines, aromatic amines
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Conjugation Reactions Sulfation
+ (PAPS, 3’-phosphoadenosine- 5’-phosphosulfate) Examples: ethanol, p-hydroxyacetanilide, 3-hydroxycoumarin
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Sulfation may produce active metabolite
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Conjugation Reactions Acetylation
Examples: Procainamide, isoniazid, sulfanilimide, histamine NAT enzyme is found in many tissues, including liver
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Procainamide Unchanged in Urine, 59% 24% Fast 17% Slow 3% Unchanged 1%
NAPA 0.3%
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Procainamide trace metabolite non-enzymatic Lupus?
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Drug Conjugation Example: Isoniazid - N-acetyltransferase
First line drug in the treatment of TB; normally given at a does of 5 mg/kg, max. 300 mg/day for period of 9 months Rapid and slow acetylators first seen in TB patients; t1/2 for fast is 70 min; t1/2 for slow is 180 min N-acetyltransferase (NAT2 isoform) is in liver, gut Peripheral neuropathy (about 2% patients; higher doses produce effects in 10-20%) seen in slow acetylators (reversible with pyridoxine) Hepatotoxicity also seen, esp. in older patients
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NAT2 Isoniazid N-Acetylisoniazid minor
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N-Acetylation may trigger nitrenium ion formation
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Additional Effects on Drug Metabolism
Species Differences Major differences in different species have been recognized for many years (R.T. Williams). Phenylbutazone half-life is 3 h in rabbit, ~6 h in rat, guinea pig, and dog and 3 days in humans. Induction Two major categories of CYP inducers Phenobarbital is prototype of one group - enhances metabolism of wide variety of substrates by causing proliferation of SER and CYP in liver cells. Polycylic aromatic hydrocarbons are second type of inducer (ex: benzo[a]pyrene). Induction appears to be environmental adaptive response of organism Orphan Nuclear Receptors (PXR, CAR) are regulators of drug metabolizing gene expression
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PXR and CAR Protect Against Xenobiotics
target genes CAR xenobiotics xenoprotection RXR PXR cytoplasm nucleus S.A. Kliewer
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CYP3A Inducers Activate Human, Rabbit, and Rat PXR
rifampicin 1 3 5 7 9 11 13 15 17 19 PCN Cell-based reporter assay dexamethasone RU486 clotrimazole troglitazone tamoxifen Reporter activity (fold) S.A. Kliewer
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CYP3A Regulation ? Protect against xenobiotics
Expressed in liver and intestine Activated by xenobiotics Bind to Xenobiotic Response Elements CYP3A xenobiotics liver intestine XRE rifampicin PCN dexamethasone RU486 clotrimazole troglitazone tamoxifen ? xenobiotics (e.g., drugs) endobiotics (e.g., steroids) CYP3A HO-xenobiotics HO-endobiotics Protect against xenobiotics Cause drug-drug interactions S.A. Kliewer et al. Endo Rev 23:687, 2002
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Pregnane X Receptor (PXR)
human PXR Ligand DNA mouse PXR 77% 96% rat PXR 76% 82% 94% rabbit PXR PXR is one of Nuclear Receptor (NR) family of ligand-activated transcription factors. Named on basis of activation by natural and synthetic C21 steroids (pregnanes), including pregnenolone 16a-carbonitrile (PCN) Cloned due to homology with other nuclear receptors Highly active in liver and intestine Binds as heterodimer with retinoic acid receptor (RXR) S.A. Kliewer
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Constitutive Androstane Receptor (CAR)
PXR Highly expressed in liver and intestine Binds response elements as RXR heterodimer High basal transcriptional activity without ligand Sequestered in cytoplasm Activated by xenobiotics phenobarbital, TCPOBOP (1,4-bis[2-(3,5-dichloropyridyloxy)]benzene) S.A. Kliewer
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Plasticity in the PXR Binding Pocket
SR12813 hyperforin Volume: 1280 Å3 1544 Å3 S.A. Kliewer
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PXR Structure Large, elliptical hydrophobic cavity
The cavity changes shape to accommodate different ligands PXR is ideally suited to function as xeno-sensor xenobiotics PXR RXR xenobiotic metabolism S.A. Kliewer
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PXR and CAR Regulate Overlapping Genes
PCN (PXR) TCPOBOP (CAR) Phase I enzymes Cyp3a11 Cyp2b10 Aldh1a1 Aldh1a7 Phase II enzymes Ugt1a1 Gst-a1 Transporters Mrp2 Mrp3 Oatp2 (3.5x) (12x) (2.1x) (1.6x) (3.4x) (110x) (1.9x) Liver RNA (2.8x) (16x) (15x) (3.0x) (9.2x) (2.0x) (1.9x) S.A. Kliewer
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Acetaminophen Acetanilide – 1886 – accidentally discovered antipyretic; excessively toxic (methemoglobinemia); para-aminophenol and derivatives were tested. Phenacetin introduced in 1887, and extensively used in analgesic mixtures until implicated in analgesic abuse nephropathy; 1946, Lester reported conjugated para-aminophenol as major metabolite of acetanilide Brodie and Axelrod recognized acetaminophen as the major active metabolite in phenacetin CAR modulates acetaminophen toxicity [Science (Oct 11) 298:422, 2002]
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Acetaminophen and p-Aminophenols
Acetanilide, 1886 (accidental discovery of antipyretic activity; high toxicity) Phenacetin or acetophenetidin, 1887 (nephrotoxic, methemoglobinemia) 75-80% 70-90% Recognized as active metabolite of acetanilide and phenacetin in 1948 (Brodie &Axelrod); popular in US since 1955 Acetaminophen, 1893
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Acetominophen Metabolism
~60% ~35% CYP2E1* CYP1A2 CYP3A4 *induced by ethanol, isoniazid Protein adducts, Oxidative stress Toxicity NAPQI N-acetyl-p-benzoquinone imine
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Acetaminophen Toxicity
Acetaminophen overdose results in more calls to poison control centers in the United States than overdose with any other pharmacologic substance. The American Liver Foundation reports that 35% of cases of severe liver failure are caused by acetaminophen poisoning which may require organ transplantation. N-acetyl cysteine is an effective antidote, especially if administered within 10 h of ingestion [NEJM 319: , 1988] Addition of N-acetyl cysteine to acetaminophen tablets proposed to prevent liver toxicity. [British Medical Journal, Vol. 323, Sept. 15, 2001]
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Acetaminophen Protein Adducts
CYP2E HS-Protein H2N-Protein S.D. Nelson, Drug Metab. Rev. 27: (1995) J.L. Holtzman, Drug Metab. Rev. 27: (1995)
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NAPQI toxicity linked to CAR activation, GSH depletion
Glutathione S-Transferase (GST Pi) Phenobarb TCPOBOP CAR GST Pi toxicity androstanol oxidative stress mechanism ?
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but a CAR inhibitor protects against such damage (right).
Protective effect. Liver cells die (pale areas) when exposed to high doses of acetaminophen (left), but a CAR inhibitor protects against such damage (right). Jun Zhang,* Wendong Huang,* Steven S. Chua, Ping Wei, David D. Moore Science, October 11, 298:422, 2002
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Acetaminophen toxicity mechanism
Mice nulled for glutathione S-transferase are resistant to acetaminophen toxicity equal amounts of acetaminophen protein adducts formed in null and wild type suggesting protein adducts may not be toxic hepatic GSH lowered in wild type (but not in KO) after acetaminophen CAR nulled mice are also resistant to acetaminophen toxicity CAR-humanized mice demonstrate same toxicity response N-acetyl cysteine is an effective agent to block GSH depletion and rescue from liver damaging toxicity NAPQI-protein adduction or NAPQI-GSH depletion-oxidative stress....to be continued
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Terfenadine (Seldane©)
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Terfenadine in the News
DHHS/FDA: Terfenadine; Proposal to Withdraw Approval of Two New Drug Applications Federal Register 62, January 14, 1997 Hoechst Marion Roussel To Promote Switch From Seldane to Allegra Independent News Service, January 14, 1997 Citing Its Side Effects, F.D.A. Weighs Ban on Allergy Drug The New York Times, January 14, 1997 FDA Wants Drug Seldane Off Market The Washington Post, January 14, 1997 Hoechst’s First Quarter Results Below Forecasts Independent News Service, May 7, 1997
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Terfenadine Developed in 1980s as a 2nd generation H1-antihistamine; from introduction in 1985, prescriptions > 16 million in 1991 First generation antihistamines are lipophilic ethylamine derivatives that readily penetrate the CNS and placenta - objective of 2nd generation is minimal CNS effects (non-sedating), not crossing the blood brain barrier; longer acting Cardiac side-effects are serious - inhibition of potassium channels by unmetabolized parent drug causes prolongation of QT interval leading to life threatening arrythmia (torsades de pointes); first recognized at USUHS in 1989 (Monahan BP et al, JAMA 1990; 264: ) Drugs or substances inhibiting terfenadine metabolism (grapefruit juice, ketoconazole, itraconazole, antimicrobials) or liver dysfunction exacerbate the side effects
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Terfenadine Metabolism
(Seldane) CYP3A4 Fexofenadine (Allegra)
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Drug Metabolism - WWW Information Resources
Directory of P450 Containing Systems; comprehensive web site regarding all aspects of chemical structure (sequence and 3D) of P450 proteins from all species; steroid ligands; links to related sites including leading researchers on P450 Drug Metabolism Resource Guide - catalog with useful information and characteristics of natural and recombinant drug metabolizing enzymes; assay methods Site contains essay “The emerging role of ADME in optimizing drug discovery and design” RJ Guttendorf, Parke-Davis Site contains many useful documents regarding drug metabolism and FDA recommendations including "Drug Metabolism/Drug Interaction Studies in the Drug Development Process: Studies in Vitro", FDA Guidance for Industry.
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