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Title: Tricyclic Antidepressants


1
Extracorporeal Techniques in the Treatment of
Poisoned Patients
2
Techniques commonly used for extracorporeal drug
removal
  • 1. Haemodialyis
  • 2. Haemoperfusion
  • 3. Continuous haemofiltration
  • 4. Continuous haemodiafiltration

3
Other techniques that are available
  • 1. Peritoneal Dialysis - much poorer drug
    clearance than haemodialysis so very rarely
    used (Blye E 1984, Shannon M 1990)
  • 2. Plasmapheresis
  • available in a very limited number of centres
  • high rate of complications
  • 3 published case reports thyroxine
    theophylline OD (Binemilis J 1987, Jones JS
    1986, Laussen P 1991)
  • 3. Exchange transfusion
  • rebound increase in drug concentration
  • case reports e.g. chloral hydrate, iron,
    theophylline, quinine, methaemoglobinaemia
    (Mowry JB 1983, Burrows A 1972, Berlin G
    1985, Shannon MW 1992)

4
When should extracorporeal techniques be
considered?
  • Severe clinical features or markers of severe
    toxicity and failure to respond to full
    supportive care
  • or Significantly raised blood concentration for
    a toxin with good correlation between blood
    concentration and clinical effect
  • Impairment of the normal route of elimination
    of the compound

Poisoning with a drug that is removed by one of
the techniques AND
5
Two main factors influence drug removal by
extracorporeal techniques
1. Kinetics of the drug - need to consider
toxicokinetics and not just pharmacokinetics -
the ideal drug kinetics differ for each
technique
  • 2. Mechanism of removal for each technique
  • Intervention is only worthwhile if total body
    clearance is increased by at least 30
  • (Cherskov M 1982)

6
Drug Kinetics and Extracorporeal Techniques (1)
1. Molecular size - not just molecular
mass, also steric hindrance polarity
  • 2. Volume of distribution - the larger the
    Vd the less drug is available in the blood
    compartment for presentation to
    the extracorporeal device
  • 3. Protein binding - generally only free
    drug is cleared, this is particularly important
    for haemodialysis

7
Drug Kinetics and Extracorporeal Techniques (2)
4. Rate of endogenous clearance - the
contribution of extracorporeal removal is greater
for drugs with low endogenous clearance - if
endogenous clearance is high (gt 4ml/kg/min), it
is unlikely that further techniques to increase
elimination will alter outcome (Pond SM 1991)
5. Rate of redistribution often difficult to
predict - if slow redistribution from a
secondary compartment, after stopping the
technique there is likely to be a rebound in
concentration of the drug
8
Limited Data on drug clearance by the techniques
in the literature
  • Data largely based on isolated case reports
  • It is not possible to extrapolate from one
    extracorporeal system to the other
  • Have to rely on
  • knowledge of the principles of the methods and
    kinetics of the drug involved
  • data from previous reports in which the removal
    kinetics have been studied before, during and
    after elimination

9
Haemoperfusion(HPF)
  • First reported use in poisoning was for
    barbiturates (Yatzidis 1964)
  • Blood is pumped through a column containing an
    adsorbent, usually activated charcoal
  • - other adsorbents have been used in the past
    e.g. resin, amberlite and haemacol
  • - the adsorbent is coated with a biocompatible,
    ultrathin membrane
  • A standard haemofiltration pump present on most
    ICUs can be used to operate the system, the only
    special equipment required is the perfusion column

10
Haemoperfusion 2
  • Performed for 4-6hrs at flow rates of
    150-250ml/min
  • Resistance of 25-30mmHg within filter (Webb DJ
    1993)
  • Can be difficult or impossible in hypotensive
    patients low flow rates and/or clotting of the
    lines will force abandonment of the procedure
  • Anticoagulation with heparin (PTT 2.0-2.5) or
    prostacyclin is required, to reduce risk of
    clotting of the circuit
  • The adsorptive capacity decreases over time
    because of deposition of cellular debris and
    proteins (Ehlers SM 1978)
  • HPF does not correct electrolyte disturbances,
    metabolic acidosis or uraemia

11
Complications of Haemoperfusion
1. Complications common to all extracorporeal
techniques - e.g. hypotension,
bleeding/thrombosis at the access site, systemic
bleeding due to anticoagulation, nosocomial
infection
  • 2. Complications specific to HPF
  • i) Thrombocytopenia
  • - 30-50 with uncoated adsorbents (Hampel 1978)
  • - 10-30 with ultrathin coated adsorbents
    (Chang 1977)
  • ii) Leucopenia - minimal with ultrathin coated
    adsorbents
  • iii) Hypocalcaemia - rarely clinically
    significant (Pond SM 1979)
  • iv) Charcoal embolisation - filter in the venous
    line prevents charcoal emboli

12
Indications for Haemoperfusion 1
  • Characteristics of compounds that make them
    amenable to removal by HPF
  • - Adsorbed by charcoal
  • - Low volume of distribution (lt 1 L/kg)
  • - Single compartment kinetics
  • - Low endogenous clearance (lt 4mL/kg/min)
  • Protein binding, water solubility molecular
    size are not such limiting factors because the
    drug is in direct contact with the adsorbent

13
Indications for Haemoperfusion 2
  • Carbamazepine
  • Phenobarbitone
  • Theophylline
  • (Meprobomate)
  • (Phenytoin Kawasaki 2000)
  • (Na Valproate)
  • (Salicylates)

Drugs for which haemoperfusion may be used in
clinical toxicology practice
14
Haemoperfusion for carbamazepine poisoning
  • Significant morbidity (arrhythmias, coma,
    convulsions) and mortality with large
    ingestions (Jones AL 1998, Weaver DF 1988)
  • T1/2 in overdose 19-32 hrs (8-13hrs
    therapeutically) and so causes prolonged toxicity
    (Hundt HKL 1983, Luke DR 1985)
  • Low Vd (1.4 L/kg) endogenous clearance (1.3
    ml/kg/min), binds activated charcoal
  • Protein binding 74 and not water soluble
  • therefore no significant HDx clearance (Cutler
    RE 1987)
  • recent report of the use of high-efficiency
    dialysis for carbamazepine, however no data on
    clearance given (Schuerer DJE 2000)

15
Half-life clearance of carbamazepine in
overdose
  • 1. Controls T1/2 19-32 hrs Clearance 59-90
    ml/min (Hundt HKL 1983, Vreeth 1986,
    Cutler RE 1984)
  • 2. MDAC T1/2 8.6-9.5 hrs Clearance 105-113
    ml/min
  • (Wason S 1992, Boldy DAR 1987,
    Monty-Cabrera 1996)
  • 3. HPF T1/2 8.6-10.7 hrs Clearance 80-129
    ml/min
  • (Leslie PJ 1983, De Groot G 1984, Nilsson
    1984)
  • MDAC and HPF increase carbamazepine clearance to
    a similar extent
  • HPF should be reserved for
  • - life-threatening toxicity (e.g. cardiotoxicity,
    status epilepticus)
  • - particularly cases with poor gut motility or
    renal impairment

16
Haemoperfusion for phenobarbitone poisoning
  • Barbiturate poisoning is now rare in the UK, but
    large ingestions can cause significant
  • morbidity (coma and cardiorespiratory depression)
  • mortality 1-10 with ingestion of gt 6g
    (Goldfrank LR 1986)
  • T1/2 in overdose 80-120 hrs (10-16 hrs
    therapeutically) so causes prolonged toxicity
    (Vale JA 1987)
  • Phenobarbitone low Vd (0.6-1.2 L/kg)
    endogenous clearance (0.06 ml/kg/min), binds
    activated charcoal, protein binding 25-51, not
    water soluble

17
Half-life and clearance of phenobarbitone in
overdose
  • 1. Controls T1/2 80-120 hrs Clearance 4-27
    ml/min (Hardman JG 1996, Vale JA 1987)
  • 2. MDAC T1/2 12-36 hrs Clearance 84 ml/min
  • (Boldy DAR 1986, Pond SM 1984)
  • 3. HDx T1/2 no data Clearance 22-49 ml/min
  • (Verbooten GA 1980, Cutler RE 1987)
  • 4. HPF T1/2 7.2-11 hrs Clearance 77-140
    ml/min
  • (Cutler RE 1987, Jacobsen D 1984)

18
Haemoperfusion for phenobarbitone poisoning
  • Both MDAC and HPF increase phenobarbitone
    clearance, HPF to a greater extent
  • Most cases respond to full supportive care
    together with use of MDAC (Jacobsen D
    1984,Goldfrank LR 1986)
  • HPF should be reserved for (Jacobsen D 1984, De
    Groot G 1982)
  • life-threatening toxicity deterioration despite
    full supportive care (coma cardiorespiratory
    depression)
  • particularly patients with poor gut motility or
    renal impairment

19
Haemodialysis (HDx)
  • Most widely used for renal replacement in
    patients with ESRD
  • Only available in a limited number of centres in
    the UK and so often patients need to be
    transferred for haemodialysis
  • First reported use in poisoning was for
    barbiturates (Setter 1966)

20
Haemodialysis 2
  • Blood is pumped (150-300ml/min) across a
    semi-permeable membrane (MW 500D)
  • performed for 4-8hrs at a time (intermittent)
  • Dialysis fluid infused countercurrent on the
    other side of the membrane establishing a
    concentration gradient
  • Solutes diffuse across the membrane into the
    dialysate
  • corrects uraemia and electrolyte / acid-base
    disturbances
  • Anticoagulation is required (either systemic or
    of the circuit)

21
Problems with haemodialysis in poisoned patients
  • Results in rapid fluid shifts causing significant
    haemodynamic effects (hypoxia and hypotension)
  • may not be tolerated in patients with severe
    poisoning
  • Rebound in drug concentrations can occur after
    HDx because it is intermittent only clears free
    drug in plasma

Only available in a limited number of centres
  • May increase elimination of drugs given
    therapeutically (e.g. ethanol in methanol
    poisoning)
  • Complications as for all extracorporeal
    techniques
  • bleeding/thrombosis at the site of access or
    systemic bleeding due to anticoagulation, air
    embolism, nosocomial infection

22
Indications for Haemodialysis 1
  • Characteristics of compounds that make them
    amenable to removal by HDx
  • - Molecular weight lt 500D
  • - Water soluble
  • - Poorly bound to plasma protein
  • - Low volume of distribution (lt 1 L/kg)
  • - Single compartment kinetics
  • - Low endogenous clearance (lt 4mL/kg/min)

23
Indications for Haemodialysis 2
  • Substances for which haemodialysis may be used in
    clinical toxicology practice
  • Salicylates (Aspirin)
  • Lithium
  • Alcohols
  • ethylene glycol, methanol, ethanol, isopropanol
  • Theophylline
  • Metformin (Althoff PH 1978)
  • (Bromide)

24
Salicylate poisoning HDx or HPF?
  • Salicylate poisoning can cause significant
  • morbidity metabolic acidosis, coma, convulsions,
    ARF, pulmonary oedema
  • mortality up to 5 in patients with severe
    clinical features or metabolic
    acidosis (Chapman BJ 1989)
  • Aspirin pharmacokinetics
  • Vd 0.17 - 0.21 L/kg (increased by acidaemia)
  • low endogenous clearance 0.88 ml/kg/min
  • protein binding 73 - 94 (saturates in overdose)
  • molecular weight 138 D
  • water soluble
  • binds activated charcoal
  • T1/2 2-4.5hrs therapeutically, up to 18-36hrs in
    overdose

25
Salicylate poisoning HDx or HPF?
  • 1. Controls T1/2 19 - 36 hrs Clearance 23 - 40
    ml/min (Levy G 1965, Pond SM 1984)
  • 2. UA T1/2 2.5 - 6.3 hrs Clearance 48
    ml/min
  • (Vree TB 1994, Prescott LF 1982)
  • 3. HDx T1/2 1.9 hrs Clearance 80 - 86 ml/min
  • (Pond SM 1984, Jacobsen D 1988)
  • 4. HPF T1/2 2.4 - 6.2 hrs Clearance 57-116
    ml/min
  • (Pond SM 1984, Jacobsen D 1988)
  • MDAC Probably has little impact on increasing
    elimination but continue MDAC until peak in
    salicylate level to prevent delayed
    absorption (Hillman RJ 1985, Proudfoot 1979)

UA Urinary Alkalinisation to pH 8.5
26
Salicylate poisoning HDx or HPF?
  • HPF achieves marginally better clearance but
    cant correct the acid-base, electrolyte and
    fluid balance problems that are common in
    patients with severe salicylate poisoning
  • Haemodialysis is therefore the extracorporeal
    method of choice for patients with severe
    salicylate poisoning

27
Salicylate poisoning Indications for
haemodialysis
  • Severe clinical features
  • coma, convulsions, pulmonary oedema
  • acute renal failure (impairs elimination)
  • Metabolic acidosis resistant to correction
  • particularly if pH lt 7.2 (increased CNS transit
    of salicylate)
  • Salicylate concentration gt 700-800mg/l
    (50-58mmol/l)
  • no data as to whether HDx in this group alters
    outcome, but salicylate level gt 900mg/l
    associated with 5 mortality
    (Chapman BJ 1989)
  • children (lt12yr) elderly (gt65yr) more
    susceptible to CNS toxicity, therefore lower
    threshold for HDx (Krause DS 1992) Low
    er thresholds in chronic salicylate poisoning

28
Haemofiltration
  • Continuous technique
  • - dissolved solute is removed by convection
    with plasma water when pressure is
    applied to one side of the membrane, cellular
    components and particles greater than the pore
    size are then passed back in to the circulation
  • - the filtrate produced contains non-protein
    bound solutes up to the cut-off limit of the
    membrane
  • - fluid removed in the filtrate is replaced
    with an appropriate (buffered) replacement fluid
    (given pre- or post- filter)
  • Blood flow rates of 125 - 300 ml/min generate
    filtrate flow rates of 25 - 70 ml/min (1500-4200
    ml/hr)
  • Synthetic membranes have a cut-off limit of up to
    10 - 40,000 D

29
Haemofiltration haemodiafiltration(CVVHF) (CV
VHDF)
  • Haemodiafiltration can be achieved by infusing
    dialysis fluid countercurrent to the membrane
    allowing diffusive solute removal by dialysis in
    addition to the convective removal by filtration

CVVHDF
CVVHF
  • HDF allows greater removal of smaller molecules
    (lt500D) and also better control of hyperkalaemia
    and other metabolic disturbances
  • (CUPID combination of CVVHF and intermittent
    HDx)

30
Haemofiltration
Characteristics of drugs that make them amenable
to HF molecular size - mass lt 10-40,000 D,
steric hindrance and charge are also important
(most membranes negatively charged) single
compartment kinetics low endogenous clearance
(4ml/kg/min) low volume of distribution less
important than for HDx low protein binding
less important than for HDx
  • Clearance (ml/min) is less appropriate for a
    continuous technique
  • Sieving coefficient is the best expression of
    solute removal SC of 1 indicates free passage
    SC 2UF / (AV)

31
Haemofiltration
  • There is little data on the sieving coefficients
    of drugs
  • this data is membrane-specific
  • the limited data available is largely for
    therapeutic drug concentrations e.g. phenytoin
    0.14, digoxin 0.35, cefuroxime 0.87, gentamicin
    0.8, theophylline 0.5 - 0.8
  • however, toxicokinetics is different to
    pharmacokinetics
  • For a drug with a sieving coefficient of 1, the
    concentration of drug in the filtrate will equal
    that in the remaining plasma (although some
    dilution will occur when replacement fluid is
    given)
  • - therefore large volumes need to be exchanged
    over a prolonged period of time for a significant
    fall in concentration to occur

32
Haemofiltration vs. Conventional Haemodialysis
  • Advantages
  • - Availability
  • - Less haemodynamic effects and so better
    tolerated by seriously poisoned patients
  • - greater removal of high molecular weight
    substances e.g. aminoglycosides, iron-DFO
    complex
  • - continuous technique so rebound in drug
    concentration is less likely
  • Disadvantage
  • - poorer/slower clearance of low molecular weight
    substances (lt 500D) ... this includes most drugs

33
Substances for which CVVHF / CVVHDF may be
considered in poisoning
  • Case reports for
  • - Lithium (Ayuso Gatell A 1989, Bellomo R 1991,
    Leblanc M 1996, Hazouard E 1999)
  • - Ethylene glycol (Christiansson LK 1995,
    Walder AD 1994)
  • - Theophylline (Henderson 2001)
  • - Vancomycin (Walczyk M 1988, Goebel J 1999,
    Bunchman T 1999)
  • - N-acetylprocainamide (Domoto DT 1987)
  • - Iron-DFO compex (Baner W 1988)
  • Other possible indications
  • - CVVHF/DF may be necessary for correction of
    electrolyte disturbances or lactic acidosis and
    for renal support
  • - Further (in-vitro) work is required before
    CVVHF can be recommended for removal of other
    substances

34
Theophylline poisoning HDx, HPF or CVVHF?
  • Theophylline poisoning can cause significant
    morbidity and mortality
  • Theophylline pharmacokinetics
  • molecular weight 180D, water soluble
  • Vd 0.5L/kg
  • low endogenous clearance (0.7ml/kg/min)
  • 40 - 56 protein bound
  • binds activated charcoal
  • hepatic metabolism to inactive metabolites (lt15
    excreted unchanged)
  • T1/2 19-34hrs in overdose (8hrs therapeutically)

35
Theophylline poisoning HDx, HPF or CVVHF?
  • 1. Controls T1/2 19 - 34 hrs Clearance 40
    ml/min (Cutler RE 1987)
  • 2. MDAC T1/2 2.2 - 8.0 hrs Clearance 140
    ml/min
  • (Davis R 1985, Shannon M
    1993)
  • 3. HDx T1/2 2.4 - 6.2 hrs Clearance 33 - 144
    ml/min
  • (Levy G 1977, Lee CS 1979,
    Hootkins R 1980)
  • 4. HPF T1/2 1.4 - 2.0hrs Clearance 96 - 276
    ml/min
  • (Woo OF 1985, Hootkins R 1980)
  • 5. CVVHF T1/2 5.9hrs Clearance unable to
    calculate
  • (Henderson JH 2001, single
    case report, no AC given initially)
  • MDAC and HDx increase clearance to a similar
    extent, but marginally greater increase in
    clearance with HPF and HPF is the treatment of
    choice in severe poisoning

36
Theophylline poisoning Indications for
haemoperfusion
  • Grade III or IV poisoning (seizures, VT,
    hypotension) (Sessler CN 1990, Shannon MW 1993)
  • ? Prophylactically in a patient with a serum
    theophylline
  • gt 100 mg/l (600 mmol/l) in acute poisoning
  • - risk of seizures ? 50 to 35, but
    uncontrolled data (Shannon MW 1987 1993,
    Olson KR 1985)
  • gt 60 mg/l (330 mmol/l) in symptomatic chronic
    poisoning
  • (Sessler CN 1990, Shannon MW 1992)
  • Lower threshold in patients with severe
    co-morbidity e.g. chronic liver disease, CCF,
    COPD

MOST patients require MDAC supportive care only
37
Extracorporeal treatment for lithium poisoning
  • Lithium poisoning can result in significant
    morbidity, particularly acute on chronic overdose
    (Gadaleah 1988, Ferron 1995)
  • Vd 0.8-1.2 L/kg, molecular wt 6.9D, non-protein
    bound
  • T1/2 is 14-30hrs and so clinical effects can be
    prolonged in overdose

38
Indications for extracorporeal treatment in
lithium poisoning
  • Severe clinical effects
  • coma, convulsions, respiratory failure, ARF
  • Consider if lithium level greater than
  • (Hansen HE 1978, Ellenhorn MJ 1997, Jaegar A
    1993)
  • ? 6 - 8 mmol/l in acute overdose
  • ? 4 mmol/l in acute overdose in a patient on
    lithium
  • ? 2.5mmol/l in symptomatic chronic accumulation
  • Kinetic criteria have also been proposed (Jaegar
    A 1993)
  • e.g. amount of lithium removed by HDx in 6 hrs
    expected to be greater than 24 hour renal
    elimination
  • Other than the clinical indications, none of
    these criteria have been validated

39
Haemodialysis or CVVHF/CVVHDF for severe lithium
poisoning?
  • 1. Haemodialysis (Jaegar A 1993, Okussa MD
    1994, Scharman EJ 1997)
  • Controls T1/2 14-30 hrs Clearance 10 - 40
    ml/min
  • HDx T1/2 3.6 - 5.7 hrs Clearance 70 - 170
    ml/min
  • BUT rebound often occurs (Jaegar A 1985,
    1993)
  • Lithium levels should be repeated 6-12hrs after
    HDx
  • 2. CAVHDF/CVVHDF 3 case series (9cases),
    12-44hrs HF (Bellomo 1991, Leblanc 1996,
    Hazouard 1999)
  • Clinical improvement fall in lithium
    concentrations
  • Clearance of 20.5-61.9ml/min
  • No significant rebound

40
Haemodialysis or CVVHF/CVVHDF for severe lithium
poisoning?
  • Haemodialysis remains the extracorporeal method
    of choice in patients with severe lithium
    poisoning
  • must be aware that a rebound in lithium levels
    can occur after haemodialysis
  • If haemodialysis is not available CVVHDF may be a
    suitable alternative, but it will need to be
    performed for at least 12-18hrs

41
Conclusions 1
  • For most severely poisoned patients supportive
    care is all that is necessary and extracorporeal
    techniques are indicated in only a limited number
    of poisonings
  • Haemoperfusion
  • - Carbamazepine, theophylline, phenobarbitone
  • Haemodialysis
  • - Salicylates, alcohols, (theophylline), lithium
  • Haemofiltration
  • - ?Lithium, alcohols
  • - Correction of electrolyte disturbances or
    lactic acidosis and for renal support
  • - Aminoglycosides, removal of iron-DFO in
    patients with ARF

42
Conclusions 2
  • Haemofiltration may be used, in the future, for
    the treatment of selected cases of severe
    poisoning
  • However, presently, there is limited data
    available to guide its use in clinical practice
  • If CVVHF is being used for renal support or
    treatment of lactic acidosis in poisoned patients
    please collect blood/filtrate samples ...
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