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Toxicokinetics

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Understand differences between PK and TK. Be familiar with general management of ODs ... bezoar formation. not all drugs are 'rapid and completely absorbed' ... – PowerPoint PPT presentation

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Title: Toxicokinetics


1
Toxicokinetics
  • Harold J. Manley, Pharm.D., BCPS
  • Assistant Professor

2
Objectives
  • Definition
  • Understand differences between PK and TK
  • Be familiar with general management of ODs
  • Be familiar with management of specific ODs
  • Understand the role of Pharmacist in ODs

3
Toxicokinetics (TK)
  • Definition
  • the absorption, distribution, metabolism, and
    excretion of drugs at doses associated with
    clinical toxicity

4
Absorption
  • most important TK parameter
  • (gt70 poisonings are PO)
  • still occurring in patients when they present
  • After initial assessment/stabilization, 1st
    therapeutic attempt is to prevent further
    absorption

5
Absorption (continued)
  • In general, Absorption is slowed
  • decreased rate of tablet dissolution
  • decreased gastric emptying time
  • anticholinergic effects
  • sustained released formulations
  • bezoar formation
  • not all drugs are rapid and completely absorbed
  • PHT 6-39 hrs, maprotaline up to 24 hrs

6
Distribution
  • VD and PPB
  • Saturation of PPB sites allowing for more free
    drug
  • More free drug allowing for other tissues to take
    up, thereby increasing VD
  • Example
  • ASA VD increases up to 50 in ODs
  • reason for CNS effects

7
Metabolism
  • Rate important because
  • determines duration of intoxication
  • formation of less (more) toxic metabolites to
    more water soluble substances
  • Enzymes
  • may become saturated
  • remember we only have so much
  • saturation or excessive utilization may prolong
    elimination/toxicity
  • Example
  • APAP

8
Elimination
  • Generally slower
  • secondary to decreased metabolism
  • secondary to toxic substance
  • Example ASA
  • decreases pH of urine due to metabolic acidosis
  • low urine pH inhibits excretion of ASA
  • Toxic effects on Kidney or Liver secondary to OD
  • Approach to patient
  • try to determine rate of elimination
  • try to increase rate of elimination (HD, PD,
    Hemoperfusion, alkalinize urine, GI
    decontamination)

9
Comparison of PK and TK
10
Pathophysiologic Effects
  • Gastrointestinal Motility
  • a decrease will allow for greater dissolution and
    more absorption
  • Cardiovascular/Pulmonary
  • low cardiac output may decrease distribution,
    higher blood conc.
  • Acid/Base Disturbances
  • acidosis increases VD of salicylates, base admin.
    may aid in TCA overdoses

11
Pathophysiologic Effects
  • Renal Function
  • May be compromised due to direct or indirect
    toxicity
  • Hepatic function
  • liver damage alters metabolism
  • Inhibition/Stimulation of enzymes
  • Decreases in blood flow
  • Hypothermia
  • may alter disposition of toxins

12
General Management
  • ABCs
  • airway
  • breathing
  • circulation
  • Apply TK principles to
  • History of Exposure (ingestion)
  • Clinical presentation
  • Laboratory Data

13
General Management (continued)
  • Gastrointestinal decontamination
  • activated charcoal
  • syrup of ipecac
  • gastric lavage
  • whole bowel irrigation
  • Extracorporeal elimination
  • Hemodialysis
  • Hemoperfusion
  • Combined HD and HP
  • Peritoneal dialysis
  • Urinary Alkalinization

14
Criteria for HD or HP
  • Toxin causes severe M M
  • Quantity of drug will cause severe M M
  • Patients ability to remove toxins is impaired
  • Available for treatment within window of
    opportunity
  • No immed. irreversible damage
  • Drug removed efficiently by HD or HP

15
Salicylate overdose
  • Absorption
  • delayed gastric emptying and dissolution
  • Distribution
  • increases with acidosis, protein binding sites
    become saturated
  • Elimination
  • varies with dose and urine pH
  • urine pH 5 yields 2-3 elimination
  • urine pH 8 yield up to 80 elimination
  • half-life increases with dose

16
Salicylate overdose (continued)
  • ASA
  • weak acid, pKa 3.5
  • hydrolyzed in stomach
  • metabolized in liver
  • Peak absorption 30-120 minutes
  • half-life in therapeutic doses up to 19 hrs
  • VD 0.12-0.17 L/kg therapeutic doses
  • Levy and Yaffe found that VD increases up to 0.35
    L/kg in children
  • VD increased because of low plasma pH, resulting
    in increased amount of nonionized salicylate
    available to cross membranes
  • PPB 80-90 (decreases in overdose)

17
Salicylate overdose (continued)
  • Must differentiate between acute or chronic
    ingestion
  • Done nomogram more closely correlates signs of
    toxicity with serum levels with acute toxicity
  • Clinical presentation and serum levels must both
    be taken into consideration when determining
    therapy
  • respiratory alkalosis (due to direct stimulation
    of resp center and subsequent hyperventilation)
  • metabolic acidosis
  • tinnitus
  • pulmonary edema
  • seizures, coma

18
Salicylate effects
  • PG inhibition
  • PLT dysfunction, Renal failure, Gastric erosion
  • CNS respiratory stimulation
  • Hyperventilation, Resp. Alkalosis, Incr.
    insensible loss
  • Smooth muscle stimulation
  • Incr. O2 demands
  • Fever, Metabolic acidosis, Respiratory alkalosis,
    Alterate cellular organ function
  • Stimulate insulin secretion
  • hypoglycemia
  • Krebs cycle inhib.
  • Metab.Acid. Imp. glucose metab. ketone production
  • Hypoprothrombinemia
  • Incr. PT
  • Capillary leak
  • Pulmonary edema
  • Impaired CNS glucose uptake
  • Encephalopathy

19
Salicylate overdose Management
  • Hydration
  • 0.25-0.5 N saline titrate to urine output of
    100-200 mL/h
  • Activated Charcoal
  • 50-60 grams will decrease absorption by 25-50
  • Alkalinization of urine
  • urine pH goal gt 7.5
  • 1 mEq/kg sodium bicarb (mild)
  • 50-100 mEq sodium bicarb bolus therapy in
    addition of above (moderate to severe cases)
  • HD or HP may increase elimination
  • reserved for severe patients (seizures)

20
APAP overdose
  • Absorption
  • may be delayed with increasing dose
  • F may increase as first-pass metabolism is
    saturated
  • 500mg F 63
  • 2000mg F 87
  • Distribution
  • dose-dependant
  • Elimination
  • conjugate stores deplete and increases amount
    metabolized to toxic metabolite (occurs once
    glutathione stores are lt30 of normal)
  • toxic metabolite N-acetly-p-benzoquinonimine
    NAPBQ

21
APAP Stages of Poisoning
  • Stage I
  • 6-14 hrs post ingestion
  • anorexia, N/V, diaphoresis
  • may be asymptomatic
  • Stage II
  • above symptoms improve
  • LFTs and PT may be elevated
  • Stage III
  • 3-5 days post ingestion
  • acute liver failure with increased bilirubin,
    uremia, metabolic acidosis
  • Stage IV
  • recovery 7-8 days

22
APAP overdose management
  • Rumack - Matthew Nomogram
  • N-acetylcysteine
  • acts as a substrate for toxic metabolite
  • maximum protection against hepatotoxicity if
    administered 8-10 hrs post ingestion (up to 16
    hrs)
  • PO 140mg/kg load then 70 mg/kg q 4 hrs x 17
    doses
  • IV investigational in US
  • 20 hr regimen 150mg/kg in 200 ml 5 dex over 15
    min50mg/kg in 500 ml 5 dextrose over 4 hrs 100
    mg/kg in 1L 5 dextrose over 16 hrs
  • 48 hr regimen 140mg/kg in 5 dextrose over 1
    hr followed 4 hr after initiation of treatment
    by 12 maintenance doses (70 mg/kg) over 1 hr in
    5 dextrose each commencing 4 hr post initiation
    of preceding dose

23
APAP overdose management (continued)
  • Vit K (PT gt 1.5 x normal) or FFP (PT gt 3.0 x
    normal) if needed
  • maintain normal hydration and electrolyte balance
  • Problems with IV NAC
  • not sterile
  • must be prepared by pharmacy
  • patient adverse reactions (presumed due to
    histamine release)

24
Extended Release APAP
  • 1994 introduced by McNeil
  • Contains 325 mg APAP immediate release and 325mg
    APAP delayed release
  • Overdoses produce a dilemma due to the altered
    absorption
  • Interpretation of Rumack - Matthew Nomogram
    difficult

25
Alcohols Methanol
  • Absorption
  • absorbed rapidly, small amount can be lethal
    peak in 30-60 min.
  • Distribution
  • small VD
  • Metabolism/Elimination
  • metabolized to toxic metabolites
  • toxins resp for metabolic acidosis
  • Half-life varies from 12-20 hours
  • EtOH competes for Al.Dehydrog
  • fomepizole alcohol dehydrogenase inhibitor

26
Alcohol ethylene glycol
  • colorless, odorless liquid which has a sweet
    taste and an inebriating effect
  • accumulation of toxic metabolites assoc. M M
  • Half-life of ethylene glycol approx. 3 hours
  • Toxic metabolites include formaldehyde, formic
    acid, glycolic acid, oxalic acid

27
Alcohol ethylene glycol
  • Stage 1
  • neurologic (0.5-30 hrs) inebriation, nausea and
    vomiting, hyporeflexia, seizures, coma, opth.
    manifest.
  • Stage 2
  • cardiopulm. (12-24hrs) tachycardia, htn, pulm.
    edema
  • Stage 3
  • renal (gt24 hrs) flank pain, oliguria to anuria,
    renal failure

28
Alcohol ethylene glycol
  • Absorption
  • rapidly and completely absorbed peak within 1-4
    hours
  • Distribution
  • similar to MeOH, small VD
  • Metabolism/Elimination
  • metabolized to toxic metabolites
  • half-life approx 3 hours
  • EtOH competes for metabolism
  • fomepizole alcohol dehydrogenase inhibitor

29
Role of a Pharmacist
  • Apply TK fundamentals to OD situations
  • Suggest specific antidotes for certain overdoses
  • Determine duration of treatment of OD by
    monitoring serum/plasma toxin levels
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