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Chapter 13. Drug Metabolism

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Title: Chapter 13. Drug Metabolism


1
Chapter 13. Drug Metabolism
  • Introduction the process of drugs in the body
    includes absorption, distribution, metabolism and
    elimination. Drug metabolism is also named drug
    biotransformation

2
  • Important Terms
  • Biotransformation Processes of drugs or toxins
    in the body, which may change the physical,
    chemical or biological properties of the drugs or
    toxins.
  • Bioavailability F, the fraction of the dose
    that reaches the systemic circulation. F1 for IV
    administration.
  • Distribution Movement of drug from the central
    compartment (tissues) to peripheral compartments
    (tissues) where the drug is present.

3
  • Elimination The processes that encompass the
    effective "removal" of drug from "the body"
    through excretion or metabolism.
  • Half-Life the length of time necessary to
    eliminate 50 of the remaining amount of drug
    present in the body.

4
Routes of Administration
  • Oral
  • Injection Intravenous, Subcutaneous,
    Intramuscular, Intraperitoneal
  • Transdermal (patch)
  • Mucous membranes of mouth or nose (includes
  • nasal sprays)
  • Inhalation
  • Rectal or vaginal

5
1. Biotransformation and the enzymes
  • The major site for drug biotransformation is the
    liver. The extrahepatic sites include the lung,
    kidney, intestine, brain, skin, etc.
  • The major organelles for drug biotransformation
    is microsome, and others include cytosol and
    mitochondria.
  • The major enzymes for drug biotransformation are
    microsomal enzymes.

6
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)
7
Reactions in biotransformation
  • Include Phase 1 Phase 2 Reactions.
  • Phase 1 involves metabolic oxygenation,
    reduction, or hydrolysis result in changes in
    biological activity (increased or decreased)
  • Phase 2 conjugationbound by polar molecules or
    modified by functional groups, in almost all
    cases results in detoxication.

8
1) The first phase reactions
  • Metabolic oxygenation
  • Microsomal enzymes catalyze hydroxylation,
    dealkylation, deamination, S-oxidation,
    N-oxidation and hydroxylation, dehalogenation,
    etc.

9
a) Hydroxylation Hydroxylations include
aliphatic and aromatic hydroxylation
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b) Dealkylation
  • Dealkylations include N-, O- and S-dealkylation.
  • R-X-CH2-R
  • R-X-CH(OH)-R
  • R-XH OCH-R

O
X O, N, S
15
N-dealkylation
  • Dealkylation of secondary or tertiary amines will
    produce primary amines and aldehydes.

16
O-dealkylation
  • Dealkylation of ethers or esters will produce
    phenols and aldehydes.

Codeine
Morphine
17
S-dealkylation
  • S-dealkylation usually produces sulfhydryl group
    and aldehyde.
  • R-S-CH3 R-S-CH2OH R-SH
    HCHO

O
6-methylthiopurine 6-thiopurine
18
c) Deamination
  • Deamination may produce ketone and ammonia.

For example, deamination of amphetamine
19
d) S-oxidation
For example, S-oxidation of chlorpromazine
20
e) N-oxidation
For example, N-oxidation of chlorpheniramine
21
  • B. Microsomal oxidases and their action
    mechanisms
  • The enzymes that catalyze the above oxygenation
    of drugs are called mixed- function oxidase or
    monooxygenase. In the reactions, one oxygen is
    reduced into water and the other is integrated
    into the substrate molecule.
  • RH O2 NADPH H ROH NADP H2O

22
  • Mixed-function oxidase contains cytochrome P450
    (CYP) and NADPH as electron carrier and hydrogen
    provider.
  • The CYP family Human CYPs have several types
    and subtypes, named CYP1, 2, 3 CYP1a, 1b, and
    so on. They are important in drug metabolism.

23
Human Liver CYPs
S. Rendic F.J. DiCarlo, Drug Metab Rev
29413-80, 1997
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  • C. Other oxidases
  • Monoamine oxidase
  • These enzymes exist in mitochondria.
  • They catalyze oxidation of amines into aldehyde
    and ammonia. For example, degradation of
    5-hydroxytryptamine.
  • RCH2-NH2 RCHNH RCHO NH3

O
H2O
26
  • Alcohol and aldehyde oxidases
  • R-CHOH R-CHO R-COOH

Alcohol dehydrogenase
Aldehyde dehydrogenase
27
D. Reductions
  • Aldehyde and ketone reductases these enzymes
    catalyze reduction of ketones or aldehydes to
    alcohols.
  • For example
  • CCl3CHO CCl3CH2OH
  • The coenzyme may be NADH or NADPH.

2H
Trichloroacetaldehyde
Trichloroethanol
28
  • Reductases for Azo or nitro compounds
  • These reductases mainly exist in hepatic
    mitochondria with NADH or NADPH as coenzyme.

Azo
Aniline
Nitrobenzene
29
E. Hydrolysis
  • Esters and amides may be hydrolyzed to produce
    acids and alcohol or amine.

Para-aminobenzoic acid
Ester(Procain)
Amide(Procainamide)
30
2) The second phase reactions
  • The second phase reactions of drugs are also
    named Conjugation Reactions . These reactions
    include glucuronidation, sulfation, acetylation,
    methylation and amino acid binding.

31
Glucuronidation
32
SulfationPAPS is the phosphate donor.
(PAPS, 3-phosphoadenosine- 5-phosphosulfate)
33
Acetylation
Acetylation may reduce the water solubility of
the compounds.
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Methylation
  • Methylation of phenols, amines and biologically
    active molecules may change their activity or
    toxicity. Generally, methylation reduces the
    hydrophilicity of the compound.
  • S-adenosylmethionine (SAM) is the donor of
    methyl group.
  • Methylation includes N- or O-methylation.

36
  • Methylation
  • RH R-CH3

SAM
37
2. Factors that affect drug metabolism
  • Inducers
  • Inducers are those that promote drug metabolism
    in the body. Most inducers are lipophilic
    compounds and have no specificity in actions.
  • Examples barbital, ether, amidopyrine, miltown
    (meprobamate), glucocorticoids, vit. C, etc.
    Repeated administration of these drugs may result
    in drug-resistance.

38
  • The mechanism by which inducers enhance drug
    metabolism in the body is believed to be the
    induction of the enzymes involved in the drug
    metabolism.
  • For example, phenobarbital stimulates
    proliferation of SER and increases production of
    some enzymes in the metabolisn of drugs, such as
    liver CYPs and UDP-glucuronate transferase, both
    of which enhance metabolism of many drugs in the
    liver (oxygenation and conjugation).

39
  • Inhibitors
  • Inhibitors are those that inhibit drug metabolism
    in the body. Include competitive and
    non-competitive inhibitors.
  • a) A drug inhibits the metabolism of other drugs
    such as chloramphenicol and isoniazid. They
    inhibit hepatic microsomal enzymes. Combined
    administration of these drugs and others such as
    barbitals may increase the toxicity of the
    latter.

40
  • b) Non-drug compounds inhibit the metabolism of
    drugs such as pyrogallol (????). This compound
    inhibits o-methylation of epinephrine and thus
    enhances the activity of the hormone in body (it
    competes with epinephrine for methyltransferase).

41
  • Other factors
  • Species difference.
  • Sex, age, nutrition conditions have effects on
    drug metabolism.
  • Hepatic functions.

42
3. Significance of drug biotransformation
  1. Effective removal of drug from the body through
    excretion or metabolism. For example, sulfation
    and glucuronidation increase secretion of the
    drug in urine.
  2. Change of the biological activity or toxicity of
    drugs in the body. For example,
    trichloroacetaldehyde is first reduced into
    trichloroethanol and then conjugated by
    glucuronate to become a non-toxic compound.

43
  1. Inactivation of bioactive molecules in the body.
    For example, some hormones are inactivated
    through biotransformation in the liver
    (epinephrine, steroid hormones).
  2. Exploration of new drugs. Based on the mechanisms
    of biotransformation, it is possible to design
    new drugs with longer half-lives and fewer
    side-effects.
  3. Explanation for the carcinogenic property of some
    drugs. For example, after biotransformation some
    non-toxic drugs may become toxic or
    carcinogenic.

44
N-acetylation may form nitrenium ion which is a
potent carcinogenic agent
45
  • The mechanisms of biotransformation may be used
    to improve the efficacy of drugs. For example,
    those that are mainly metabolized in the liver
    may have less efficacy through oral
    administration than IV route.
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