Iron toxicity: Difference between revisions

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| Stage 1||GI irritation: nausea and vomiting, abd pain, diarrhea||30-60 mins
| Stage 1||GI irritation: nausea and vomiting, abdominal pain, diarrhea||30-60 mins
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| Stage 2: latent||reduced GI symptoms||6-24 hours
| Stage 2: latent||reduced GI symptoms||6-24 hours

Revision as of 04:51, 15 July 2016

Background

  • Iron is the 4th most abundant atomic element in the earth's crust
  • biologically a component of hemoglobin, myoglobin, catalase, xanthine oxidase, etc
  • uptake highly regulated

Toxicity

  • Toxicity determined by mg/kg of elemental iron
  • Total amount of elemental iron ingested can calculated by multiplying the estimated number of tablets by the percentages of iron in the tablet preparation
  • Clinical severity is based approximated by elemental dose per kilograms:[1]
Severity Dose (mg/kg)
Mild 10-20
Moderate 20-60
Severe >60
  • Absence of GI symptoms within 6hr of ingestion excludes significant iron ingestion
  • Significant iron toxicity can result in a severe lactic acidosis from hypoperfusion due to volume loss, vasodilation and negative inotropin effects.

Elemental Iron Percentages

Elemental Iron Percentages

Iron Preparation % of Elemental Iron
Ferrous Fumarate 33%
Ferrous Sulfate 20%
Ferrous Gluconate 12%
Ferric pyrophosphate 30%
Ferroglycine sulfate 16%
Ferrous carbonate (anhydrous) 38%

Pathophysiology

  • Direct caustic injury to gastric mucosa[2]
  • occurs early, usually within several hours
    • Causing vomiting, diarrhea, abdominal pain, and GI bleeding
    • usually affects, the stomach, duodenum, colon rarely affected
    • can lead to formation of gastric strictures 2-8 weeks post-ingestion
  • Impaired cellular metabolism
    • Inhibiting the electron transport chain causes lactic acidosis
    • Direct hepatic, CNS, and cardiac toxicity (decreased CO and myocardial contractility)
    • Cell membrane injury from lipid peroxidation[3]
  • Increased capillary permeability
    • Hypotension
    • Venodilation
    • hypovolemic shock
  • Portal vein iron delivery to liver
    • overwhelm storage capatcity of Ferritin
    • Hepatotoxicity (cloudy swelling, periportal hepatic necrosis, elevated transaminases)
    • destroys hepatic mitochondria, disrupts oxidative phosphorylation --> worsening metabolic acidosis
  • Thrombin formation inhibition
    • Coagulopathy - direct effect on vitamin K clotting factors

Clinical Features

Iron Toxicity Stages
Staging Clinical Effect Time Frame
Stage 1 GI irritation: nausea and vomiting, abdominal pain, diarrhea 30-60 mins
Stage 2: latent reduced GI symptoms 6-24 hours
Stage 3: shock and metabolic acidosis metabolic acidosis, lactic acidosis, dehydration, coags, renal failure 6-72 hours
Stage 4: hepatotox hepatic failure 12-96 hours
Stage 5: bowel obstruction GI bowel scarring/healing 2-8 weeks
  • Stage I: GI toxicity: nausea, vomiting, diarrhea, GI bleeding from local corrosive effects of iron on the gastric and intestinal mucosa
  • Stage II: quiescent phase with resolution of GI symptoms and apparent clinical improvement
    • controversy between toxicologists whether this stage exists in significant poisonings
  • Stage III: systemic toxicity: shock and hypoperfusion
    • Primarily hypovolemic shock and acidosis, myocardial dysfunction also contributes
    • GI fluid losses, increase capillary permeability, decreased venous tone
    • severe anion gap acidosis
    • free radical damage to mitochondria disrupt oxidative phosphorylation which leads to lactic acidosis
    • hepatotoxicity from iron delivery via portal blood flow
  • Stage IV: clinical recovery, resolution of shock and acidosis usually by days 3-4
  • Stage V: late onset of gastric and pyloric strictures (2-8 week later) [4]

Differential Diagnosis

CAT MUDPILERS

Diagnosis

Work-Up

  • CBC
  • Chemistry - notice that this can appear like DKA
    • Anion gap metabolic acidosis
    • Hyperglycemia
  • Coags
  • LFTs
  • Iron levels
  • UA
    • Used to follow efficacy of Fe chelation
    • Urine changes from rusty colored vin rose to clear
  • Type and Screen
  • Xr KUB
    • In ambiguous cases consider abd xray as most Fe tabs are radioopaque
Vin rose.JPG


Serum Iron Concentration

Serum iron concentration can guide treatment but are not absolute in predicting or excluding toxicity

Peak serum iron level (usually around 4hrs post ingestion although very high doses may lead to delayed peak):

  • <300 mcg/dL: nontoxic or mild
  • 300-500 mcg/dL: Significant GI symptoms and potential for systemic toxicity
  • >500 mcg/dL: Moderate to severe systemic toxicity
  • >1000 mcg/dL: severe systemic toxicity and increased morbidity

If unable to obtain a serum iron level a glucose > 150 mg/dL and leukocyte count above 15000 is 100% specific and 50% sensitive in predicint=g levels > 300mcg/mL[5]

Management

Observation x 6 hrs

  • Patients with asymptomatic ingestion of <20mg/kg only require observation x 6hr
  • Volume resuscitation

Whole bowel irrigation

  • Consider only for large overdose with visible pills in the stomach on x-ray
  • Promotes increased gastric emptying and avoids large bezoar formation[6]

Deferoxamine

  • Systemic toxicity and iron level > 350 mcg/dL
  • Metabolic acidosis
  • Progressive symptoms
  • Serum iron level >500 mcg/dL
  • large #of pills on KUB
  • estimated dose > 60mg/kg Fe2+
  • Administered IV or IM because of poor oral absorption
  • one mole of Deferoxamine (100mg) bind one mole of iron (9mg) to form ferrioxamine
    • vin-rose urine (ferrioxamine is a reddish compound)
  • 15mg/kg/hr (determined empirically and never clinically tested)
    • can start slower at 8mg/kg/hr if concern for hypotension and uptitrate
  • can give 90mg/kg IM if unable to obtain IV however IVF is critical so IV access should be established ASAP
  • can cause hypotension
  • may cause flushing (anaphylactoid reaction)
  • rarely causes ARDS - associated with prolonged use
  • probably safe to use in pregnancy (give if obvious signs of shock/toxicity)

Hemodialysis

  • Not effective in removing iron due to large volumes of distribution
  • Dialysis can removes deferoxamine-iron complex in renal failure patients

Exchange Transfusion

  • Minimal evidence but has been described in larger overdoses[7]

Not Indicated

Orogastric lavage

  • Does not remove large numbers of pills and may have serious adverse events

Activated charcoal

  • Does not bind iron

Poison Control

1-800-222-1222 (California)

Disposition

  • Discharge after 6hr observation for asymptomatic (or only vomited 1-2x) AND ingestion <20mg/kg
  • Admit to ICU if deferoxamine required
  • Psychiatric evaluation if intentional ingestion

See Also

Toxidromes

References

  1. Robotham JL, Lietman PS: Acute iron poisoning. A review. Am J Dis Child 1980; 134:875-879.
  2. Robotham JL, Lietman PS. Acute iron poisoning. A review. Am J Dis Child 1980; 134:875-879.
  3. Aisen P et al. Iron toxicosis. Int Rev Exp Pathol 1990. 31:1-46.
  4. Fine, J. Iron Poisoning. Curr Probl Pediatr, Vol 30, Iss 3, p 71-90, March 2000
  5. Lacouture PG et al. Emergency assessment of severity in iron overdose by clinical and laboratory methods. J Pediatr 1981; 99:89-91.
  6. Position paper: Whole bowel irrigation. J Toxicol Clin Toxicol 2004; 42:843-854.
  7. Movassaghi N. et al. Comparison of exchange transfusion and deferoxamine in the treatment of acute iron poisoning. J Pediatr 1969; 75:604-608.