Abstract
From 1983 to 1991, iron caused over 30% of the deaths from accidental ingestion of drug products by children. An evidence-based expert consensus process was used to create this guideline. Relevant articles were abstracted by a trained physician researcher. The first draft of the guideline was created by the primary author. The entire panel discussed and refined the guideline before its distribution to secondary reviewers for comment. The panel then made changes in response to comments received. The objective of this guideline is to assist poison center personnel in the appropriate out-of-hospital triage and initial management of patients with suspected ingestions of iron by 1) describing the manner in which an ingestion of iron might be managed, 2) identifying the key decision elements in managing cases of iron ingestion, 3) providing clear and practical recommendations that reflect the current state of knowledge, and 4) identifying needs for research. This guideline applies to ingestion of iron alone and is based on an assessment of current scientific and clinical information. The expert consensus panel recognizes that specific patient care decisions may be at variance with this guideline and are the prerogative of the patient and the health professionals providing care, considering all of the circumstances involved. The panel's recommendations follow; the grade of recommendation is in parentheses. 1) Patients with stated or suspected self-harm or who are victims of malicious administration of an iron product should be referred to an acute care medical facility immediately. This activity should be guided by local poison center procedures. In general, this should occur regardless of the amount ingested (Grade D). 2) Pediatric or adult patients with a known ingestion of 40 mg/kg or greater of elemental iron in the form of adult ferrous salt formulations or who have severe or persistent symptoms related to iron ingestion should be referred to a healthcare facility for medical evaluation. Patients who have ingested less than 40 mg/kg of elemental iron and who are having mild symptoms can be observed at home. Mild symptoms such as vomiting and diarrhea occur frequently. These mild symptoms should not necessarily prompt referral to a healthcare facility. Patients with more serious symptoms, such as persistent vomiting and diarrhea, alterations in level of consciousness, hematemesis, and bloody diarrhea require referral. The same dose threshold should be used for pregnant women, however, when calculating the mg/kg dose ingested, the pre-pregnancy weight of the woman should be used (Grade C). 3) Patients with ingestions of children's chewable vitamins plus iron should be observed at home with appropriate follow-up. The presence of diarrhea should not be the sole indicator for referral as these products are often sweetened with sorbitol. Children may need referral for the management of dehydration if vomiting or diarrhea is severe or prolonged (Grade C). 4) Patients with unintentional ingestions of carbonyl iron or polysaccharide-iron complex formulations should be observed at home with appropriate follow-up (Grade C). 5) Ipecac syrup, activated charcoal, cathartics, or oral complexing agents, such as bicarbonate or phosphate solutions, should not be used in the out-of-hospital management of iron ingestions (Grade C). 6) Asymptomatic patients are unlikely to develop symptoms if the interval between ingestion and the call to the poison center is greater than 6 hours. These patients should not need referral or prolonged observation. Depending on the specific circumstances, follow-up calls might be indicated (Grade C).
Introduction
The ingestion of iron, either as tablets of iron salts or as constituents of vitamin and mineral supplements has, for the past few decades, been one of the major causes of poisoning mortality and morbidity in children. From 1983 through 2000, a review of the American Association of Poison Control Centers Toxic Substance Surveillance System showed that at least 43 children died from the ingestion of iron supplements Citation1,2. A review of poisoning deaths reported by US poison centers from 1983 to 1991 found that iron caused over 30% of the deaths from unintentional ingestion of drug products by children Citation1. The reasons for this high mortality are likely numerous and not entirely understood. Iron supplements might be considered by parents and caretakers to be innocuous dietary supplements, which could lead to careless storage and handling and delays in seeking medical care following ingestions. Ingestions of large numbers of tablets might occur because the bright colors of the tablets could be perceived by children to be candy. Once iron is absorbed from the gastrointestinal tract, the ability to remove it from the body is limited, thus allowing the iron to produce toxicity in spite of optimal treatment.
In January 1997, the US Food and Drug Administration (FDA) issued a final rule requiring that oral dosage forms containing more than 30 mg of elemental iron per dosage unit be packaged in unit-dose packaging with strong warning labels and in compliance with the Poison Prevention Packaging Act Citation3. Also at that time, many manufacturers voluntarily changed the coatings on tablets, eliminating the sugar coatings in favor of film coatings to further decrease the likelihood of children ingesting large numbers of tablets. These changes were associated with a reduction in the number of poisoning deaths in children from iron ingestions. Following implementation of the rule, from 1998 through 2002, one child was reported to have died from the ingestion of an iron-containing product Citation2. The National Health Alliance filed a lawsuit against the FDA charging that the agency did not have jurisdiction to enforce packaging of dietary supplements. In October 2003, a court agreed and the FDA removed the final rule requiring unit-dose packaging Citation4. Iron-containing products reverted to the Consumer Product Safety Commission regulations in effect prior to 1997, which include the use of child-resistant packaging.
Syndrome of Iron Poisoning
Poisoning with iron salts produces a multiphasic syndrome. The first phase, which occurs within a few hours after ingestion, results from the corrosive effects of iron on the gastrointestinal tract and is characterized by vomiting and diarrhea, both of which can become bloody and severe. Acidosis and shock can occur. The gastrointestinal symptoms might subside during the next phase, which can last for 24 hours or more. However, in severe cases, this resolution of symptoms might not be observed Citation5. During this time, free iron in the blood is depositing in soft tissues and disrupting cellular function. This leads to severe multisystem organ failure, which is the characteristic of the next phase that typically becomes apparent 48–96 hours after ingestion. In severe cases, coma, convulsions, liver and kidney failure, and respiratory distress syndrome are often encountered. Patients who survive severe iron poisoning may be left with scarring of the gastrointestinal tract Citation6,7. Postmortem examinations of fatal cases show corrosive injury to the gastrointestinal tract, hepatic necrosis, renal tubular necrosis, and deposition of iron in cardiac muscle and the brain Citation8,9.
Iron Products
Iron is sold as single-ingredient tablets, as prenatal vitamin supplements with iron, and as adult and pediatric vitamin products with iron. Several different iron salts are found in these products in a variety of dosages and dosage forms. The elemental iron content is the standard method of comparing iron salt products. Ferrous fumarate contains 33% elemental iron, ferrous sulfate contains 20% elemental iron, and ferrous gluconate is 12% elemental iron. Children's chewable vitamins with iron typically contain 18 mg of elemental iron or less per tablet.
Carbonyl iron is greater than 98% elemental iron but it cannot be compared directly with the iron salt products. Carbonyl iron is produced by the vaporization of iron pentacarbonyl, leading to the production of uncharged submicroscopic spheres of elemental iron crystals. In order to be absorbed from the gastrointestinal tract, carbonyl iron requires solubilization to ionized iron by stomach acid Citation10. This dissolution in stomach acid appears to be the rate- and quantity-limiting step in the absorption of the drug. In addition, carbonyl iron has not been reported to cause the corrosive injury to the gastrointestinal tract characteristically seen in iron salt poisoning.
Iron polysaccharide complex is another nonionic form of iron and contains 46% elemental iron by weight. It is produced by neutralization of a ferric chloride-carbohydrate solution. It is sold in products containing 18–150 mg of elemental iron per tablet. It is stated to have an oral LD50 in rats of greater than 5000 mg/kg Citation3. Limited human toxicity information is available but the product appears to have less toxicity than ferrous salts.
The amount of elemental iron present in typical products on the US market used for the same purpose is variable ().
Substances and Definitions
This guideline is intended to address exposures to iron only. The term “out-of-hospital” is defined as the period before a patient reaches a healthcare facility. An acute ingestion is defined as any number of ingestions that occur within a period of less than 8 hours. A child is defined as a person less than 6 years of age.
Intended Users of the Guideline
The intended users of this guideline are personnel in US poison centers. This guideline has been developed for the conditions prevalent in the US While the toxicity of iron is not expected to vary in a clinically significant manner in other nations, the out-of-hospital conditions could be much different. This guideline should not be extrapolated to other settings unless it has been determined that the conditions assumed in this guideline are present.
Objective of the Guideline
The objective of this guideline is to assist poison center personnel in the appropriate out-of-hospital triage and initial management of patients with suspected ingestions of iron by 1) describing the manner in which an ingestion of iron might be managed, 2) identifying the key decision elements in managing cases of iron ingestion, 3) providing clear and practical recommendations that reflect the current state of knowledge, and 4) identifying needs for research. This guideline applies to ingestion of iron alone. Coingestion of additional substances could require different referral and management recommendations depending on the combined toxicities of the substances.
This guideline is based on an assessment of current scientific and clinical information. The expert consensus panel recognizes that specific patient care decisions may be at variance with this guideline and are the prerogative of the patient and the health professionals providing care, considering all of the circumstances involved.
Methodology
The methodology used for the preparation of this guideline was developed after reviewing the list of key elements of guidelines described by Shaneyfelt et al. Citation13. An expert consensus panel was established to oversee the guideline development process (Appendix 1). The American Association of Poison Control Centers (AAPCC), the American Academy of Clinical Toxicology (AACT), and the American College of Medical Toxicology (ACMT) appointed members of their organizations to serve as panel members. To serve on the expert consensus panel, an individual had to have an exceptional track record in clinical care and scientific research in toxicology, board certification as a clinical or medical toxicologist, significant US poison center experience, and be an opinion leader with broad esteem. Two Specialists in Poison Information were included as full panel members to provide the viewpoint of the end users of the guideline.
Literature Search
The National Library of Medicine's PubMed database was searched (through November 2003) using iron (poisoning) or iron (toxicity) or ferrous compounds (poisoning) or ferrous compounds (toxicity) as MeSH terms, all limited to humans. The PubMed database was searched again (through November 2003) using iron or ferrous as textwords (title, abstract, MeSH term, CAS number) plus either poison* or overdos* or tox* or intox*, limited to humans. This same process was repeated in International Pharmaceutical Abstracts (1970–November 2003, excluding abstracts of meeting presentations), Science Citation Index (1977–November 2003), Database of Abstracts of Reviews of Effects (accessed November 2003), Cochrane Database of Systematic Reviews (accessed November 2003), and Cochrane Central Register of Controlled Trials (accessed November 2003). Reactions (1980–November 2003), the iron poisoning management in POISINDEX Citation14, and the bibliographies of recovered articles were reviewed to identify previously undiscovered articles. Furthermore, North American Congress of Clinical Toxicology abstracts published in the Journal of Toxicology-Clinical Toxicology (1995–2003) were reviewed for original human data. The iron chapter bibliographies in four major toxicology textbooks were reviewed for citations of additional articles with original human data Citation15-18. Finally, The Toxic Exposure Surveillance System (TESS) maintained by the American Association of Poison Control Centers was searched for deaths resulting from iron poisoning Citation2. These cases were abstracted for use by the panel.
Article Selection
The recovered citations were entered into an EndNote library and duplicate entries were eliminated. The abstracts of the remaining articles were reviewed, looking specifically for those that dealt with estimations of mg/kg or ingested doses with or without subsequent signs or symptoms, time of onset of symptoms, and management techniques that might be suitable for out-of-hospital use (e.g., gastrointestinal decontamination). Articles excluded were those that did not meet either of the preceding criteria, did not add new data (e.g., some reviews, editorials), or that exclusively described inpatient-only procedures (e.g., whole bowel irrigation). Specific animal studies were included only if they were relevant to panel recommendations.
Data Extraction
All articles that were retrieved from the search were reviewed by a single abstractor. Each article was assigned a level of evidence score from 1 to 6 using the rating scheme developed by the Centre for Evidence-Based Medicine at Oxford University (Appendix 2); the complete paper was then reviewed for original human data regarding the toxic effects of iron, or original human data directly relevant to the out-of-hospital management of patients with iron overdose. Relevant data (e.g., dose of iron, resultant effects, time of onset of effects, therapeutic interventions or decontamination measures given, efficacy or results of any interventions, and overall patient outcome) were compiled into a table and a brief summary description of each article was written. This full evidence table is available at http://www.aapcc.org/DiscGuidelines/IronEvidenceTable.pdf. The completed table of all abstracted articles was then forwarded to the panel members for review and consideration in developing the guideline. Every attempt was made to locate significant foreign language articles and have their crucial information extracted, translated, and tabulated. Copies of all of the articles were made available for reading by the panel members on a secure AAPCC website.
Guideline Writing and Review
A guideline draft was prepared by the primary author. The draft was submitted to the expert consensus panel for comment. Using a modified Delphi process, comments from the expert consensus panel members were collected, copied into a table of comments, and submitted to the primary author for response. The primary author responded to each comment in the table and, when appropriate, the guideline draft was modified to incorporate changes suggested by the panel. The revised guideline draft was again reviewed by the panel and, if there was no strong objection by any panelist to any of the changes made by the primary author, the draft was prepared for the external review process. External review of the second draft was conducted by distributing it electronically to AAPCC, AACT, and ACMT members and the secondary review panel. The secondary review panel consisted of representatives from the federal government, public health, emergency services, pediatrics, pharmacy practice, and consumer organizations (Appendix 3). Comments were submitted via a discussion thread on the AAPCC website or privately through e-mail communication to AAPCC staff. All submitted comments were stripped of any information that would identify their sources, copied into a table of comments, and reviewed by the expert consensus panel and the primary author. The primary author responded to each comment in the table and his responses and subsequent changes in the guideline were reviewed and accepted by the panel. Following a meeting of the expert consensus panel, the final revision of the guideline was prepared.
Evaluation of the Evidence on the Toxic Dose of Iron
The toxic dose for various iron products was difficult to evaluate from the literature for several reasons:
Histories of ingestion were often reported as unreliable.
Many different iron-containing products are or were on the market with varying elemental iron content.
Patients or their family members or the authors of the articles often failed to identify the exact product or list its elemental iron content.
The bioavailability of iron varies substantially between products.
Vomiting and diarrhea often occurred after ingestion and could have resulted in removal of some iron from the gastrointestinal tract.
In many patients, treatment procedures performed in a hospital might have influenced the outcome.
Many reports did not provide the doses in a per kilogram basis, making comparisons between reported patients difficult.
For the purposes of this guideline, the evidence on dose is divided into three general categories: acute iron exposures in children less than 6 years of age, acute exposures in patients 6 years of age or older, and acute exposures in pregnant women. Acute exposure was defined as a single exposure or multiple exposures occurring within a period of no more than 8 hours. This guideline does not deal with chronic oral exposures or parenteral iron exposures. The term out-of-hospital is defined as the period before a patient reaches a healthcare facility.
When the mg/kg dose or a child's weight was not included in an article, the mg/kg dose was estimated by the use of pediatric growth charts Citation19. The 95th percentile weight was used for a particular age and sex. When the sex of the child was not stated, the weight for boys was used. This approach errs on the side of estimating a lower mg/kg dose. Estimated mg/kg doses are italicized throughout the guideline whenever they are presented.
Acute Iron Ingestions in Children Less than 6 Years of Age
Adult Formulations of Ferrous Salts
No level 1–3 studies were found that specifically investigated the threshold dose for the development of toxicity in children less than 6 years of age with acute ingestions of adult formulations of ferrous sulfate, ferrous gluconate, or ferrous fumarate. Multiple level 4 articles contained some information on the relationship of dose and clinical effects but establishing a toxic threshold was usually not the primary goal of the articles. Specifically, there were 62 level 4 articles consisting of case reports and case series and two level 6 abstracts with dose and clinical effect information on ferrous sulfate ingestions in children Citation7Citation20-82, seven for ferrous gluconate Citation21-23Citation27Citation29Citation43Citation58, and three for ferrous fumarate Citation20Citation25Citation83. Unfortunately, one of the case series included children more than 6 years of age in the case pool, raising the possibility that intentional ingestions were included, making interpretation problematic Citation20. In another article, the age range included children up to 8 years of age Citation23. In three of the large case series either the precise products or the exact clinical effects were not specified Citation21-23.
Among the reported cases, the lowest ingested dose of ferrous sulfate associated with the development of significant nausea, vomiting, diarrhea, and stupor was four tablets in a 22-month-old child Citation24. Similarly, a 20-month-old was reported to be “drowsy and ill-appearing” after having ingested fewer than five tablets of ferrous sulfate Citation56. Both patients were hospitalized, treated with intravenous fluids and supportive care, and did well. In neither case was the amount of elemental iron in the tablets reported by the authors. Two pediatric iron ingestion case series reported that ingestions of fewer than 10 325-mg ferrous sulfate tablets resulted in severe toxicity Citation20,Citation22. Reynolds and Klein Citation22 reported the death of a 16-month-old child with the history of ingestion of “six ferrous sulfate tablets,” although the authors questioned the accuracy of the history based on a serum iron concentration of greater than 4500 µg/dL (greater than 800 mmol/L). The lowest dose of ferrous sulfate associated with a fatal outcome was a case of a 21-month-old child who, by history, had ingested five to 10 325-mg tablets along with 150–300 mg of phenobarbital and 75–150 mg of methamphetamine Citation25. The peak serum iron concentration was 2160 µg/dL (387 mmol/L). On autopsy, the child had a subdural hemorrhage, bilateral bronchopneumonia consistent with aspiration, renal tubular necrosis, and gastric erosions, indicating that the death might have been the result of a combination of effects of the ingested drugs.
The lowest ingested dose of ferrous gluconate associated with toxicity was 900 mg elemental iron (the exact dose of ferrous gluconate was not specified) that resulted in vomiting and drowsiness in a 15-month-old child Citation30. In another report, ingestion of 12–20 tablets of ferrous gluconate (exact dose and elemental iron content not specified) caused the death of an 18-month-old child. A serum iron concentration drawn at least 20 hours after the ingestion was 780 µg/dL (140 mmol/L) Citation27.
Greenblatt et al. Citation25 described a 35-month-old child who ingested 6000 mg of ferrous fumarate but they only reported that the child did not become “seriously ill.” In another case, a 17-month-old child ingested 43 ferrous fumarate tablets (294 mg/kg of elemental iron), underwent surgical removal of the tablets by gastrotomy, and developed no significant adverse effects Citation83.
There was one level 2b article and six level 4 articles in which the authors provided information on the dose of elemental iron ingested, but the exact iron preparations were not given or were not known. One article described a large, retrospective review of cases of acute iron ingestion reported to one poison center during a 2-year period Citation84. Three hundred thirty-nine cases were reported with an age range of 9 months to 33 years. The ingested doses were reported in 199 cases. In the group ingesting 20–40 mg/kg elemental iron, 22% developed abdominal pain, diarrhea, and vomiting while 42% and 33% for the 40–60 mg/kg and greater than 60 mg/kg groups, respectively, developed these symptoms. The higher dose groups had few patients and there was no statistically significant difference in the development of symptoms between the three groups. No deaths, shock, acidosis, or hepatotoxicity occurred.
Among the level 4 articles was a series of 29 patients in whom elevated serum iron concentrations were measured after ingestion of ferrous sulfate, ferrous gluconate, or unknown iron products, but clinical effects were not reported Citation21. Another level 4 paper was a retrospective review of 80 children less than 4 years of age with iron ingestions Citation22. The doses were known in only 23 patients and the authors stated that in four cases of severe toxicity the patients had ingested fewer than 10 tablets but the exact products were not specified. Among the four remaining case reports was a 7-week-old infant who was intentionally given “a few” tablets of an unknown iron product by the mother and developed lethargy, persistent acidosis, heme-positive stools, and dehydration. The serum iron concentration 36 hours after admission was 308 µg/dL (55 mmol/L) Citation85. There was a case of lethargy, vomiting, and watery black diarrhea after the ingestion of “fewer than 15 tablets” of an unknown iron product by a 21-month-old child. Although the time of ingestion was not provided, the serum iron concentration on admission was 463 µg/dL (83 mmol/L) Citation59. Death was reported following ingestion of 30 tablets of an unknown iron product by an 11-month-old infant Citation38.
There were no studies specifically looking at the time to onset of symptoms following the ingestion of ferrous salt formulations. In most case reports, the time of onset of symptoms is not reported. Instead, the authors report the time of presentation for medical care, which can be many hours after the initial onset of symptoms. In a few case reports and series there is evidence that the time to the onset of symptoms, such as drowsiness, abdominal pain, gastrointestinal upset, and vomiting, typically occurred within 1–4 hours of ingestion Citation7Citation22Citation26-29Citation31Citation33Citation36Citation43,44Citation47Citation49Citation55. In only one case report Citation37 did it appear that the time to onset of symptoms might have been delayed. This case involved a child who ingested 30 tablets of 325 mg ferrous sulfate and was then put down for a nap. The child awoke 10 hours later with vomiting and diarrhea and then soon developed lethargy.
provides reported or estimated mg/kg doses for the fatal cases reported in the literature and in TESS for those cases where a dose of iron was reported. As most of the authors failed to report the weight of the children, estimated weights, as previously described, were used to calculate the mg/kg dose ingested.
Multivitamins with Iron
Only one case report (level 4) was found with information on the relationship of dose and clinical effects. In this report, a 2-year-old child ingested 780 mg of elemental iron as a multivitamin with iron product. The iron salt in the product and the weight of the child were not reported. No clinical effects were described and the patient was reported to have done well following treatment with whole bowel irrigation Citation86.
Chewable Multivitamins with Iron
One case report (level 4) was found with information of the relationship of dose and clinical effects for chewable vitamins with iron Citation87. In this report, a 2-year-old child ingested 25–50 tablets of a chewable multivitamin with iron product (exact dose and elemental iron content not stated), developed a serum iron concentration of 370 µg/dL (66 mmol/L), and experienced no clinical effects. No case reports were found describing serious or fatal poisonings with these products.
Anderson et al. Citation88 performed a retrospective review of all pediatric ingestions of iron products reported to the TESS over a 15-year period (level 4). No severe or fatal poisonings were reported in 195,780 reported ingestions of pediatric chewable multivitamin with iron products.
In a swine model in which each animal was given either 60 mg/kg elemental iron as children's chewable iron tablets or ferrous sulfate tablets, Nordt et al. Citation89 demonstrated that the time to peak serum concentration of iron was shorter and the peak serum iron concentrations were greater in the children's chewable group than in the ferrous sulfate group, although none of the animals achieved a serum iron concentration greater than 500 µg/dL (90 mmol/L). At necropsy 10 hours after iron administration, all animals in the ferrous sulfate group showed extensive esophageal and gastric inflammation and hemorrhage while two animals in the children's chewable vitamin with iron group showed only minimal esophageal inflammation. The other animals in the children's chewable vitamin with iron group showed no gastrointestinal injury.
Liquid Ferrous Salt Products
No case reports of serious or fatal poisoning following ingestion of liquid ferrous salt products were identified. Rodgers et al. Citation26 reported a 35-month-old child who ingested 76 mg/kg of elemental iron in the form of drops containing 75 mg of ferrous sulfate (15 mg elemental iron) per 0.6 mL (level 4). The child developed vomiting and abdominal pain. The serum iron concentration 3.5 hours following ingestion was 359 µg/dL (64 mmol/L). The child received deferoxamine intravenously for 12 hours and was discharged on the second day following the ingestion.
Carbonyl Iron
One case series (level 4) article described a 2-year retrospective review of carbonyl iron exposures reported to five poison centers Citation90. Thirty-three cases (ages not specified) were identified but follow-up information was available for only 17 cases. Of these, the ingested dose ranged from 2.2 to 72 mg/kg of elemental iron. One child developed diarrhea and lethargy but these symptoms were attributed to the child's pre-existing viral infection. There were no published reports of serious or fatal poisoning from the ingestion of carbonyl iron products.
Polysaccharide Iron Complex
Klein-Schwartz analyzed TESS data from 1990–1998 for children who had ingested polysaccharide iron complex products (level 4). Six hundred twenty children were identified with none reported as having developed major effects or fatal poisoning Citation91.
Acute Iron Ingestions in Patients 6 Years of Age or Older
Adult Formulations of Ferrous Salts
No level 1–3 studies were found that specifically investigated the threshold dose for the development of toxicity in patients 6 years of age or older with acute ingestions of adult formulations of ferrous sulfate, gluconate, or fumarate. There were, however, articles that contained some information on the relationship of dose to clinical effects, but establishing a toxic threshold was usually not the primary goal of the studies.
The efficacy of sodium polystyrene sulfate for reducing iron absorption was evaluated in a prospective crossover study in which volunteers were given 10 mg/kg elemental iron as 325 mg ferrous sulfate tablets Citation92. The volunteers tolerated this dose with only nausea and vomiting as side effects. Another level 1b study gave healthy volunteers 10 mg/kg of elemental iron as ferrous sulfate to test magnesium hydroxide's effect on absorption and found that the subjects developed nausea, vomiting, abdominal pain, and diarrhea that could be related to either the iron ingested or the magnesium hydroxide that was administered Citation93. Wallace et al. Citation94 administered 5 mg/kg of elemental iron to volunteers as ferrous sulfate 325 mg tablets and nausea developed in a small number of the subjects (level 1b). Another study (level 2b) compared the effects of ferrous sulfate tablets to carbonyl iron in healthy volunteers. Ingestion of 100 mg of elemental iron as ferrous sulfate resulted in mild effects, primarily gastrointestinal, but also headache and weakness were reported Citation10. Burkhart et al. Citation95 administered 20 mg/kg of elemental iron as 200 mg ferrous fumarate tablets to six healthy volunteers to study the effect of an iron overload on total iron binding capacity. All six volunteers developed nausea, abdominal cramps, and diarrhea. One developed vomiting and four were given intravenous fluid replacement. All symptoms resolved within 6 to 12 hours.
There was one level 3b study, a 12-year retrospective review of 113 acute intentional iron ingestions at one institution, that pooled data from ferrous sulfate, fumarate, and gluconate ingestions and stratified the outcomes according to ingested dose in mg/kg of elemental iron. The patients were reported to have ingested a mean of 70 mg/kg of elemental iron with a range of 7 to 350 mg/kg. Twenty patients developed severe toxicity and seven died. The patients who died were said to have ingested between 35 and 110 mg/kg of elemental iron. However, no details of individual cases were provided. Ferrous sulfate was involved in 45 cases (90%), ferrous gluconate in three, and ferrous fumarate in two cases Citation96.
Fourteen cases of iron poisoning in 13 level 4 articles were identified Citation8Citation67Citation97-107. The lowest dose that resulted in adverse consequences was one tablet, which caused gastrointestinal perforation in three patients, two of whom died Citation97-99. The lowest dose resulting in systemic toxicity was a case in which the patient reportedly ingested 10 tablets of ferrous sulfate 325 mg and died Citation104. However, the patient's family noted that as many as 50 tablets were missing from the container and a serum iron measurement drawn 48 hours after the ingestion was 307 µg/dL (55 mmol/L). In another case in an adult, a dose of 3000–4500 mg ferrous sulfate (600–900 mg of elemental iron) ingested along with alcohol resulted in severe toxicity Citation106.
In a level 2b study assessing the effect of antacids on iron absorption, adult volunteers received 18 mg of elemental iron as ferrous fumarate and experienced no adverse effects Citation108. In another study, 6 mg/kg of elemental iron given as crushed ferrous fumarate tablets to six adult volunteers resulted in nausea, diarrhea, and dark stools in two subjects Citation109.
There were three case reports of ingestion of ferrous fumarate Citation104Citation110. The lowest ingested dose to cause mild systemic toxic effects from ferrous fumarate tablets was 1650 mg of elemental iron (37.5 mg/kg) that reportedly caused drowsiness and confusion Citation110.
The lowest ingested dose of ferrous succinate to cause toxicity was 60 tablets (42 mg/kg of elemental iron) that caused mild symptoms of toxicity such as drowsiness and epigastric pain Citation111.
There were five cases (level 4) reported in two articles in which the ferrous salt was unspecified. Tenenbein Citation86 reported four adult exposures with ingestions of 35 to 150 mg/kg of elemental iron who were treated with whole bowel irrigation and did well. The second article was a description of a patient who ingested 166 mg/kg of elemental iron and died as a result Citation112.
There were no studies found specifically examining the time to onset of symptoms in patients of this age group who had ingested ferrous salt formulations. As in the case of ferrous salt poisonings in children, case reports in this older age group also demonstrated that the typical time to onset of symptoms, such as abdominal pain, nausea, and vomiting, was 1 to 4 hours Citation8,Citation98Citation101,102Citation110Citation116-122. There was one case report found where the time of onset to symptoms might have been delayed, possibly as a result of the treatment the patient received. In this case, a 19-year-old male presented within 1 hour of ingestion of a large number of ferrous sulfate tablets. He was given ipecac syrup, and gastric lavage with sodium bicarbonate solutions was performed. Surgical removal of 60 tablets was performed at 16 hours after ingestion. The only sign or symptom mentioned is a mild metabolic acidosis that was reported at 8 hours following ingestion Citation125.
Liquid Ferrous Salt Products
Gomez et al. Citation113 gave 5 mg/kg of ferrous sulfate to healthy adult volunteers for the purpose of testing the efficacy of various decontamination measures (level 1b). The only adverse effect noted with this dose was mild nausea. Jackson et al. Citation114 gave 5 mg/kg of elemental iron as ferrous sulfate elixir to volunteers to test the efficacy of decontamination regimens. Some of the subjects developed nausea and lightheadedness. One death in an adult was identified (level 4). A young man “accidentally” ingested 1/4 pound of a ferrous sulfate suspension. He presented with hematemesis, shock, and cyanosis and died within 3 hours of ingestion Citation67. No reports were found that described serious or fatal poisonings in adults from the ingestion of pharmaceutical liquid iron preparations.
Chewable Multivitamins with Iron
No level 1–3 studies were found that specifically investigated the threshold dose for the development of toxicity in adults with acute multiple vitamin with iron exposures. There were, however, two level 2b articles that contained some information on dose and clinical effects but establishing a toxic threshold was not the primary goal of the studies. In the first, 6 mg/kg elemental iron was given as chewable multivitamins plus iron (in the form of ferrous fumarate) to adult volunteers resulting in nausea, diarrhea, and dark stools in two of six subjects Citation109. In the second study, doses of 5 and 10 mg/kg elemental iron (salt unspecified) were given as chewable multiple vitamins plus iron to adult volunteers, resulting in all five subjects experiencing some degree of nausea, diarrhea, and headaches at both dosages Citation115.
Polysaccharide Iron Complex
In an analysis of TESS data for 1990–1998, Klein-Schwartz Citation91 reported 183 adults who ingested polysaccharide-iron complex products (level 4). There were no major effects or fatalities reported. The report concluded that the majority of exposures to these products result in minimal or no toxicity.
Carbonyl Iron
No level 1–3 studies were found that specifically investigated the threshold dose for the development of toxicity in adults with acute carbonyl iron exposures. There was however, one level 2b article that contained some information on the relationship between dose and clinical effects, but establishing a toxic threshold was not the primary goal of the study. In this study, healthy adult volunteers were given oral carbonyl iron in doses ranging from 100 to 10,000 mg. Side effects increased in frequency with increasing dose but were mild and consisted primarily of diarrhea and unpleasant taste, although some experienced headaches and/or weakness Citation10.
There was also a 2-year retrospective review of all carbonyl iron exposures reported to five poison centers (level 4). Thirty-three cases (age not specified) were identified but follow-up was available for only 17. Three adults were referred to emergency departments. One ingested an unknown amount, one ingested 72 mg/kg, and one ingested 450 mg, but this patient's weight was not reported. All three remained asymptomatic and had serum iron concentrations that were within the reference range Citation90.
Acute Iron Ingestions in Pregnant Women
Adult Formulations of Ferrous Salts
No level 1–3 studies were found that specifically investigated a threshold dose for the development of toxicity in pregnant women with acute ingestions of adult formulations of ferrous sulfate, gluconate, or fumarate. There were, however, nine case reports (level 4) that contained information on the relationship of dose and clinical effects for adult formulations of ferrous sulfate Citation8Citation55Citation76Citation116-121 and one case report with an adult formulation of ferrous gluconate Citation122. The lowest ingested dose of ferrous sulfate to cause maternal effects was 30–50 mg/kg of elemental iron resulting in moderate abdominal distress Citation116. Six of the eight cases resulted in normal deliveries, one outcome was unreported, and one pregnancy terminated with a spontaneous abortion that occurred following a maternal ingestion of 29,000 mg ferrous sulfate at 16-weeks gestation, after which the mother died Citation120.
Tran et al. Citation122 described a patient who was in her 27th week of pregnancy when she ingested 16,200 mg ferrous gluconate (1850 mg or 24 mg/kg elemental iron). She developed vomiting and abdominal pain, a peak serum iron of 603 µg/dL (108 mmol/L), and later delivered a normal, healthy infant (level 4).
There was one level 4 article describing 68 cases of acute overdose of unspecified iron preparations in pregnant women. Follow-up information was available for 51 of the patients and the ingested doses could be estimated in 48 with a range of 470 mg to 10,000 mg elemental iron. The lowest dose associated with symptoms in a mother was 470 mg of elemental iron, which caused nausea. Only two patients developed systemic symptoms. There were 43 live births, three of which were premature, and another three had various abnormalities that the authors did not attribute to iron or deferoxamine therapy. There were two spontaneous abortions and four elective abortions Citation123.
Dose Requiring Referral to a Healthcare Facility
The only article found that specifically addressed out-of-hospital management of iron exposures was an article examining poison center “send-in guidelines” and threshold values for referral to healthcare facilities. The study was a level 2b retrospective analysis of 2921 cases reported to 56 poison centers. Cases were divided into three groups: less than 29 mg/kg, 30–50 mg/kg, and 51–60 mg/kg elemental iron ingested. The study found no difference in the proportion of patients referred to healthcare facilities, the proportion that developed symptoms, and the clinical outcome at poison centers with different send-in threshold doses for elemental iron Citation124.
Review of TESS Death Reports
All abstracts of iron-related deaths reported to TESS were examined for the years 1985 through 2002. Forty-two cases were found, three in adults and 39 in children. Nineteen cases involved ingestions of ferrous sulfate, 13 involved prenatal vitamins with iron, and 10 involved unspecified iron products. The death reports revealed that in most cases the amount ingested was unknown or very large. The dose was unknown for 23 children and in the range of 20–96 iron salt tablets in the others. In only one case did the history state that a child had ingested as few as four or five tablets. However, the case revealed that after removing a number of tablets from the mouth of the child, the father estimated that the child had ingested only four or five tablets. This was likely not an accurate estimate of the number that had been ingested. In the adult cases, the amount ingested was unknown in two cases and in one case was reported as 140 mg/kg of elemental iron Citation2. A summary of these cases is provided in .
Evaluation of Evidence Regarding Gastrointestinal Decontamination Procedures
Syrup of Ipecac
No level 1–3 studies were found concerning the effectiveness of ipecac syrup-induced emesis in the management of iron poisoning. There were five case reports (level 4) dealing with this topic. In three of the case reports, the patients required gastrotomies to remove concretions of iron tablets. In all three cases, the authors stated that the patients had previously received ipecac-induced emesis without effective removal of the concretions Citation125-127. The other article reported two cases Citation128. Case 1 was a 17-month-old child with a ferrous sulfate ingestion. An initial abdominal radiograph showed nine tablets in his stomach and one in his small intestine. He was given ipecac syrup, which resulted in three episodes of vomiting. A subsequent radiograph showed the same 10 tablets but in different positions. Case 2 was a 16-year-old girl who ingested 100 ferrous sulfate tablets. She was given ipecac syrup resulting in four episodes of vomiting, expelling 15 tablets over 1 hour. A radiograph after emesis showed more than 50 tablets remaining in the stomach.
Activated Charcoal
It has been generally felt that activated charcoal is ineffective in adsorption of iron because of the small molecular weight and ionic nature of iron Citation16Citation129. This was recently confirmed by an animal study and questioned by a human volunteer study. The animal study showed no effect of activated charcoal on the extent of iron absorption in rats when the 240-g animals were given 100 mg of elemental iron followed by activated charcoal in charcoal-to-iron ratios of 1:1, 2:1, and 4:1 Citation130. The human volunteer study (level 1b) demonstrated that oral administration of a premixed combination of one part deferoxamine and three parts activated charcoal given following a dose of liquid ferrous sulfate produced a reduction in serum iron concentration compared to the untreated control or activated charcoal arms of the study. The study used a small dose of liquid iron, and it is highly unlikely that deferoxamine would be available in an out-of-hospital situation. Therefore, this approach has no application in the out-of-hospital management of the typical iron poisoning Citation113.
Other Oral Binding or Complexing Agents
During the 1970s and 80s, oral administration of sodium bicarbonate was frequently advocated with the intention of decreasing oral absorption of iron. The in-vitro and in-vivo experimental evidence does not support this procedure. Czajka et al. Citation131 demonstrated in vitro that bicarbonate solutions complexed more iron than phosphate solutions. However, 83% of the iron remained in solution. In a rat model, Dean et al. Citation132 found no effect of sodium bicarbonate or sodium dihydrogen phosphate lavage solutions on the absorption of iron. Corby et al. Citation133 found decreased iron absorption in dogs following administration of magnesium hydroxide. However, increased serum concentrations of magnesium were noted. A human volunteer study (level 1b) demonstrated a 50% reduction in iron absorption with the administration of magnesium hydroxide Citation94. However, the volunteers were given 4.5 g of magnesium hydroxide for each gram of iron, a ratio unlikely to be tolerated by many patients with toxic iron ingestions. For example, a 10-kg child ingesting 60 mg/kg of elemental iron would require approximately 36 mL of milk of magnesia while a 70-kg adult ingesting 60 mg/kg would need 250 mL of milk of magnesia to achieve these ratios. In addition to these doses being large volumes that might be difficult to consume and tolerate, they could cause significant diarrhea. Another study (level 1b) did not find a significant difference in iron absorption following the administration of magnesium hydroxide to human volunteers given 10 mg/kg of ferrous sulfate Citation93. In clinical use, bicarbonate and phosphate solutions used for gastric lavage or as oral complexing agents have resulted in significant adverse events, morbidity, and mortality Citation28Citation134.
New oral iron chelating agents, such as deferiprone Citation135 and sodium HBED ligand Citation136, have been shown to improve survival and enhance iron excretion in iron-poisoned animals. In addition, modifications of deferoxamine, such as conjugation with dextran or hydroxyethyl starch, have shown the potential for enhanced efficacy and improved patient tolerability Citation137. Additional research must be conducted to determine the role for these agents.
Cathartics
No evidence was found supporting the use of cathartics in iron poisoning. As whole bowel irrigation is not an out-of-hospital procedure, it is not discussed in this guideline.
Conclusions
Key Decision Points for Triage
The expert consensus panel chose to emphasize the importance of information that would be needed in order to make a triage decision for a patient who has ingested an iron product. These variables include the patient's intent, the dose and formulation of the specific product ingested and other coingestants, the time of the ingestion, and the patient's symptoms or underlying medical conditions. The panel agreed that in each case the judgment of the specialist in poison information, with the assistance of their medical consultant or preapproved policies, might override any specific recommendation.
Patient Intent
The expert consensus panel concluded that all patients with a suicidal intent or in whom a malicious intent is suspected (e.g., child abuse or neglect) should be expeditiously transported to an emergency department. Patients without these characteristics are candidates for consideration of out-of-hospital management of their ingestion.
Dose and Formulation
The expert consensus panel concluded that the published evidence and the death reports did not provide solid evidence upon which to base a referral threshold dose for adult formulations of ferrous salts. The clinical judgment of the panel members supported the indications from the literature that a healthcare facility referral threshold of 40 mg/kg of elemental iron is safe for both adults and children. The available evidence does not support a different threshold value for pregnant women. As most iron ingestions in pregnant women are likely to be intentional in nature, most pregnant patients will be referred regardless of the amount ingested. However, the panel concluded that if a mg/kg calculation is to be performed for a pregnant woman, the calculation should be based upon the prepregnancy weight of the patient. The panel also acknowledged that there are isolated case reports of adverse events such as bowel perforations occurring following the ingestion of amounts of iron unlikely to cause systemic poisoning.
The panel noted that there are no published case reports of symptomatic systemic iron poisoning following ingestions of children's chewable vitamins with iron. In addition, a review of TESS data involving a large number of exposures to these products found no evidence of serious poisoning or death. The panel concluded that referral to a healthcare facility for ingestions of children's chewable vitamins plus iron is usually unnecessary. Referral might be needed for the treatment of dehydration if vomiting and diarrhea occur and are severe or prolonged.
The panel concluded that the limited evidence indicates that carbonyl iron and polysaccharide-iron complex formulations are less toxic than ferrous salt formulations. There are no reported deaths, no reports of serious toxicity, and animal and human evidence indicates that large doses (up to 140 mg/kg in adult volunteers) can be taken without toxicity. The panel concluded that referral to a healthcare facility for ingestions of these products is not necessary. However, the panel felt that until additional evidence is reported in the literature, these patients should receive follow-up calls from the poison center.
Time to Onset of Effects
The panel concluded that the case report evidence indicates that the onset of symptoms following ingestions of all types of ferrous salt formulations, in all age groups, is typically within 4 hours of ingestion and is unlikely to extend beyond 6 hours. The two cases where the onset of symptoms appears to have been delayed were considered to be the result of unusual circumstances.
Potential Out-of-Hospital Management
Gastrointestinal Decontamination
Although emesis, either spontaneous or induced, may remove some ingested iron, the expert consensus panel concluded that the published literature does not provide evidence that the out-of-hospital use of ipecac syrup in iron ingestions positively affects patient outcome. The panel also concluded that the evidence does not support the out-of-hospital use of activated charcoal in iron ingestions. It should be considered in cases where other agents have been coingested. There is no evidence supporting the use of cathartics.
Oral Alkalinizing or Complexing Agents
The expert consensus panel concluded that the evidence does not support the out-of-hospital use of oral alkalinizing or complexing agents such as bicarbonate or phosphate solutions. The use of these agents has resulted in substantial morbidity and mortality.
Recommendations
Patients with stated or suspected self-harm or who are victims of malicious administration of an iron product should be referred to an acute care medical facility immediately. This activity should be guided by local poison center procedures. In general, this should occur regardless of the amount ingested (Grade D).
Pediatric or adult patients with a known ingestion of 40 mg/kg or greater of elemental iron in the form of adult ferrous salt formulations or who have severe or persistent symptoms related to iron ingestion should be referred to a healthcare facility for medical evaluation. Patients who have ingested less than 40 mg/kg of elemental iron and who are having mild symptoms can be observed at home. Mild symptoms, such as vomiting and diarrhea, occur frequently. These mild symptoms should not necessarily prompt referral to a healthcare facility. Patients with more serious symptoms, such as persistent vomiting and diarrhea, alterations in level of consciousness, hematemesis, and bloody diarrhea, require referral. The same dose threshold should be used for pregnant women; however, when calculating the mg/kg dose ingested, the prepregnancy weight of the woman should be used (Grade C).
Patients with ingestions of children's chewable vitamins plus iron should be observed at home with appropriate follow-up. The presence of diarrhea should not be the sole indicator for referral as these products are often sweetened with sorbitol. Children may need referral for the management of dehydration if vomiting or diarrhea is severe or prolonged (Grade C).
Patients with unintentional ingestions of carbonyl iron or polysaccharide-iron complex formulations should be observed at home with appropriate follow-up (Grade C).
Ipecac syrup, activated charcoal, cathartics, or oral complexing agents, such as bicarbonate or phosphate solutions, should not be used in the out-of-hospital management of iron ingestions (Grade C).
Asymptomatic patients are unlikely to develop symptoms if the interval between ingestion and the call to the poison center is greater than 6 hours. These patients should not need referral or prolonged observation. Depending on the specific circumstances, follow-up calls might be indicated (Grade C).
These recommendations are summarized in Appendix 4.
Implications for Research
The expert consensus panel identified the following topics where additional research is needed or analysis of existing databases might be useful.
The use of oral chelating agents should be examined. Human studies to verify efficacy are required as well as studies examining the potential out-of-hospital use for these agents.
Although the published information suggests that carbonyl and polysaccharide-iron complex appear to have less toxicity than ferrous salts, the panel felt that this requires additional confirmatory studies.
Additional research should be conducted to determine if the threshold value for referral to a healthcare facility of 40 mg/kg of elemental iron in the form of adult iron formulations can be safely increased.
Additional research should be conducted to determine the risk of toxicity following ingestion of liquid iron products and to determine if a different referral threshold value should be established for these formulations.
Disclosures
There are no potential conflicts of interest reported by the expert consensus panel or project staff regarding this guideline.
Guidelines for the Management of Poisoning. Supported in full by Cooperative Agreement 8 U4BHS00084 between the American Association of Poison Control Centers and the Maternal and Child Health Bureau, Health Resources and Services Administration, Department of Human Services. Copyright © 2005 American Association of Poison Control Centers.
References
- Litovitz T, Manoguerra A. Comparison of pediatric poisoning hazards: an analysis of 3.8 million exposure incidents. A report from the American Association of Poison Control Centers.Pediatrics 1992; 89:999–1006., [PUBMED], [INFOTRIEVE], [CSA]
- AAPCC TESS fatality abstracts 1985–2002., [CSA]
- Iron-containing supplements and drugs: label warning statements and unit-dose packaging requirements.Fed Regist 1997; 62:2217–2250., [CSA]
- Iron-containing supplements and drugs; label warning statements and unit-dose packaging requirements; removal of regulations for unit-dose packaging requirements for dietary supplements and drugs. Final rule; removal of regulatory provisions in response to court order.Fed Regist 2003; 68:59714–59715., [CSA]
- Fine J S. Iron poisoning.Curr Probl Pediatr 2000; 30:71–90., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Mills K C, Curry S C. Acute iron poisoning.Emerg Med Clin North Am 1994; 12:397–413., [PUBMED], [INFOTRIEVE], [CSA]
- Filpi R G, Majd M, LoPresti J M. Reversible gastric stricture following iron ingestion.South Med J 1973; 66:845–846., [PUBMED], [INFOTRIEVE], [CSA]
- Manoguerra A S. Iron poisoning: report of a fatal case in an adult.Am J Hosp Pharm 1976; 33:1088–1090., [PUBMED], [INFOTRIEVE], [CSA]
- Abraham S C, Yardley J H, Wu T T. Erosive injury to the upper gastrointestinal tract in patients receiving iron medication: an underrecognized entity.Am J Surg Pathol 1999; 23:1241–1247., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Gordeuk V R, Brittenham G M, McLaren C E, Hughes M A, Keating L J. Carbonyl iron therapy for iron deficiency anemia.Blood 1986; 67:745–752., [PUBMED], [INFOTRIEVE], [CSA]
- Clinical Pharmacology™, Electronic Drug Information and Medication Management Resource. Tampa, FL: Gold Standard Multimedia, 2004.
- eFACTS®. Drug Facts and Comparisons. Chicago: Wolters Kluwer Health, 2004:10.
- Shaneyfelt T M, Mayo-Smith M F, Rothwangl J. Are guidelines following guidelines? The methodological quality of clinical practice guidelines in the peer-reviewed medical literature.JAMA 1999; 281:1900–1905., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Klasco R K, ed. Poisindex System. Greenwood Village, CO: Thomson Micromedex, , edition expires March 2004.
- In: Ellenhorn M J, ed. Ellenhorn's Medical Toxicology: Diagnosis and Treatment of Human Poisoning. 2nd ed. Baltimore: Williams & Wilkins, 1997.
- In: Goldfrank L R, Flomenbaum N E, Lewin N A, Howland M A, Hoffman R S, Nelson L S, eds. Goldfrank's Toxicologic Emergencies. 7th ed. New York: McGraw-Hill, 2002.
- In: Haddad L M, Shannon M W, Winchester J F, eds. Clinical Management of Poisoning and Drug Overdose. 3rd ed. Philadelphia: WB Saunders, 1998.
- Ford M D, Delaney K A, Ling J, Erickson T. Clinical Toxicology. Philadelphia: WB Saunders, 2000.
- Kuczmarski R J, Ogden C L, Grummer-Strawn L M, Flegal K M, Guo S S, Wei R, Mei Z, Curtin L R, Roche A F, Johnson C L. CDC Growth Charts: United States. Advance Data from Vital and Health Statistics; No. 314. Hyattsville, MD: National Center for Health Statistics, 2000.
- James J A. Acute iron poisoning: assessment of severity and prognosis.J Pediatr 1970; 77:117–119., [PUBMED], [INFOTRIEVE], [CSA]
- Green V A. Iron ingestions—the Children's Mercy Hospital.Clin Toxicol 1971; 4:245–252., [PUBMED], [INFOTRIEVE], [CSA]
- Reynolds L G, Klein M. Iron poisoning—a preventable hazard of childhood.S Afr Med J 1985; 67:680–683., [PUBMED], [INFOTRIEVE], [CSA]
- Westlin W F. Deferoxamine in the treatment of acute iron poisoning. Clinical experiences with 172 children.Clin Pediatr (Phila) 1966; 5:531–535., [CSA]
- Jacobinzer H, Raybin H. Accidental chemical poisonings: iron intoxication.NY J Med 1962; 62:85–87., [CSA]
- Greenblatt D J, Allen M D, Koch-Weser J. Accidental iron poisoning in childhood. Six cases including one fatality.Clin Pediatr (Phila) 1976; 15:835–838., [CSA]
- Rodgers G P, Koline D E, Finger D. Unusual case of iron intoxication.J Toxicol Clin Toxicol 1987; 25:251–253., [PUBMED], [INFOTRIEVE], [CSA]
- Barker G A, Brown T C, Hosking C S. Acute iron poisoning—clinical features and management.Anaesth Intensive Care 1974; 2:345–350., [PUBMED], [INFOTRIEVE], [CSA]
- Bachrach L, Correa A, Levin R, Grossman M. Iron poisoning: complications of hypertonic phosphate lavage therapy.J Pediatr 1979; 94:147–149., [PUBMED], [INFOTRIEVE], [CSA]
- Roberts R J, Nayfield S, Soper R, Kent T H. Acute iron intoxication with intestinal infraction managed in part by small bowel resection.Clin Toxicol 1975; 8:3–12., [PUBMED], [INFOTRIEVE], [CSA]
- Whitten C F, Gibson G W, Good M H, Goodwin J F, Brough A J. Studies in acute iron poisoning. I. Desferrioxamine in the treatment of acute iron poisoning: clinical observations, experimental studies, and theoretical considerations.Pediatrics 1965; 36:322–335., [PUBMED], [INFOTRIEVE], [CSA]
- Wasserman G S, Martens D O, Green V A. Early aggressive treatment of iron poisoning.Am Fam Phys 1977; 15:125–127., [CSA]
- Peterson C D, Fifield G C. Emergency gastrotomy for acute iron poisoning.Ann Emerg Med 1980; 9:262–264., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Barr D G, Fraser D K. Acute iron poisoning in children: role of chelating agents.Br Med J 1968; 1:737–741., [PUBMED], [INFOTRIEVE], [CSA]
- Vuthibhagdee A, Harris N F. Antral stricture as a delayed complication of iron intoxication.Radiology 1972; 103:163–164., [PUBMED], [INFOTRIEVE], [CSA]
- Judkins D. Iron overdose in a fifteen-month-old child.J Emerg Nurs 1984; 10:31–33., [PUBMED], [INFOTRIEVE], [CSA]
- Everson G W, Bertaccini E J, O'Leary J. Use of whole bowel irrigation in an infant following iron overdose.Am J Emerg Med 1991; 9:366–369., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Durbin D R, Wood B P. Radiological case of the month. Acute iron poisoning and gastrointestinal decontamination procedure.Am J Dis Child 1992; 146:765–766., [PUBMED], [INFOTRIEVE], [CSA]
- Anonymous. Toddler deaths resulting from ingestion of iron supplements—Los Angeles, 1992–1993.MMWR, Morbid Mortal Wkly Rep 1993; 42:111–113., [CSA]
- Ioannides A S, Panisello J M. Acute respiratory distress syndrome in children with acute iron poisoning: the role of intravenous desferrioxamine.Eur J Pediatr 2000; 159:158–159., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Pestaner J P, Ishak K G, Mullick F G, Centeno J A. Ferrous sulfate toxicity: a review of autopsy findings.Biol Trace Elem Res 1999; 69:191–198., [PUBMED], [INFOTRIEVE], [CSA]
- Kaczorowski J M, Wax P M. Five days of whole-bowel irrigation in a case of pediatric iron ingestion.Ann Emerg Med 1996; 27:258–263., [PUBMED], [INFOTRIEVE], [CSA]
- Smith W L, Franken E A Jr, Grosfeld J L, Ballantine T V. Pneumatosis of the bowel secondary to acute iron poisoning. Radiological quiz.Radiology 1977; 122, , pp. 192, 246. [CSA]
- Fischer D S, Parkman R, Finch S C. Acute iron poisoning in children: the problem of appropriate therapy.JAMA 1971; 218:1179–1184., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Cheney K, Gumbiner C, Benson B, Tenenbein M. Survival after a severe iron poisoning treated with intermittent infusions of deferoxamine.J Toxicol Clin Toxicol 1995; 33:61–66., [PUBMED], [INFOTRIEVE], [CSA]
- Gezernik W, Schmaman A, Chappell J S. Corrosive gastritis as a result of ferrous sulphate ingestion.S Afr Med J 1980; 57:151–154., [PUBMED], [INFOTRIEVE], [CSA]
- Gleason W A, deMello D E, deCastro F J, Connors J J. Acute hepatic failure in severe iron poisoning.J Pediatr 1979; 95:138–140., [PUBMED], [INFOTRIEVE], [CSA]
- deCastro F J, Jaeger R W, Gleason W A. Liver damage and hypoglycemia in acute iron poisoning.Clin Toxicol 1977; 10:287–289., [PUBMED], [INFOTRIEVE], [CSA]
- Cantanna R, Morini M. RDS in uncaso di intossicazione da solfato ferroso.Minerva Anestesiol 1988; 54:381–386., [PUBMED], [INFOTRIEVE], [CSA]
- Henretig F M, Karl S R, Weintraub W H. Severe iron poisoning treated with enteral and intravenous deferoxamine.Ann Emerg Med 1983; 12:306–309., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Knott L H, Miller R C. Acute iron intoxication with intestinal infarction.J Pediatr Surg 1978; 13:720–721., [PUBMED], [INFOTRIEVE], [CSA]
- Ng R C, Perry K, Martin D J. Iron poisoning: assessment of radiography in diagnosis and management.Clin Pediatr (Phila) 1979; 18:614–616., [CSA]
- Freeman D, Manoguerra A. Absence of urinary color-change in a severely iron poisoned child treated with deferoxamine [abstract].Vet Hum Toxicol 1981; 23:351., [CSA]
- Thomson J. Ferrous sulphate poisoning. Its incidence, symptomotology, treatment and prevention.Br Med J 1950; 1:645–646., [CSA]
- Gandhi R, Robarts F. Hourglass stricture of the stomach and pyloric stenosis due to ferrous sulfate poisoning.Br J Surg 1962; 49:613–617., [PUBMED], [INFOTRIEVE], [CSA]
- Schauben J L, Augenstein W L, Cox J, Sato R. Iron poisoning: report of three cases and a review of therapeutic intervention.J Emerg Med 1990; 8:309–319., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Spencer I O. Ferrous sulphate poisoning in children.Br Med J 1951; 2:1112–1117., [CSA]
- Brown R J, Gray J D. The mechanism of acute ferrous sulphate poisoning.Can Med Assoc J 1955; 73:192–197., [PUBMED], [INFOTRIEVE], [CSA]
- Mann K V, Picciotti M A, Spevack T A, Durbin D R. Management of acute iron overdose.Clin Pharm 1989; 8:428–440., [PUBMED], [INFOTRIEVE], [CSA]
- Covey T J. Ferrous sulfate poisoning: a review, case summaries, and therapeutic regimen.J Pediatr 1964; 64:218–226., [PUBMED], [INFOTRIEVE], [CSA]
- Roxburgh R C. Fersolate poisoning.Proc R Soc Med 1949; 42:85–86., [CSA]
- Ross F G. Pyloric stenosis and fibrous stricture of the stomach due to ferrous sulphate poisoning.Br Med J 1953; 2:1200–1202., [CSA]
- Santos A S, Pisciotta A V. Acute iron intoxication. Treatment with desferrioxamine (BA-29837).Am J Dis Child 1964; 107:424–427., [PUBMED], [INFOTRIEVE], [CSA]
- Clark W M Jr, Jurow S S, Walford R L, Warthen R O. Ferrous sulfate poisoning.Am J Dis Child 1954; 88:220–226., [CSA]
- Branch L K. Ferrous sulfate poisoning: report of a fatal case.Pediatrics 1952; 10:677–680., [PUBMED], [INFOTRIEVE], [CSA]
- Crosskey P H. Pyloric stenosis after ferrous sulphate poisoning.Br Med J 1952; 2:285., [CSA]
- Birk R E, Stallard S K. Acute ferrous sulfate poisoning: report of a nonfatal case.J Pediatr 1954; 45:164–168., [PUBMED], [INFOTRIEVE], [CSA]
- Foucar F, Gordon B, Kaye S. Death following ingestion of ferrous sulfate.Am J Clin Pathol 1948; 18:971–973., [CSA]
- Schafir M. The management of acute poisoning by ferrous sulfate.Pediatrics 1961; 27:83–94., [PUBMED], [INFOTRIEVE], [CSA]
- Amerman E E, Brescia M A, Aftahi F. Ferrous sulfate poisoning: report of a case successfully treated by exchange transfusion.J Pediatr 1958; 53:476–478., [PUBMED], [INFOTRIEVE], [CSA]
- Duffy T L, Diehl A M. Ferrous sulfate poisoning: report of three cases.J Pediatr 1952; 40:1–5., [PUBMED], [INFOTRIEVE], [CSA]
- Shoss J. Ferrous sulfate poisoning: a case treated with BAL.J Pediatr 1954; 44:77–78., [PUBMED], [INFOTRIEVE], [CSA]
- Smith J P. The pathology of ferrous sulphate poisoning.J Pathol Bacteriol 1952; 64:467–472., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Wilmers M J, Heriot A J. Pyloric stenosis complicating acute poisoning by ferrous sulphate.Lancet 1954; 267:68–69., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Forbes G. Poisoning with a preparation of iron, copper, and manganese (2 deaths due to ferrous sulfate).Br Med J 1947; 1:367–370., [CSA]
- Davis D W, Gibbs G E. Iron poisoning.Am Pract Dig Treat 1956; 7:1092–1094., [PUBMED], [INFOTRIEVE], [CSA]
- Dugdale A E, Powell L W. Acute iron poisoning: its effects and treatment.Med J Aust 1964; 11:990–992., [PUBMED], [INFOTRIEVE], [CSA]
- Simpson K, Blunt A. Acute ferrous sulfate poisoning treated with edathamil calcium-disodium.Lancet 1960; 2:1120–1122., [CSA], [CROSSREF]
- Shepherd J A. Ferrous sulphate poisoning with gross stricture of the stomach.Br Med J 1955; 2:418–419., [CSA]
- Murphy J W, Neustein C, Hoffman A C, Winters H V, Gaskins A L. Acute iron poisoning. Report of a sase and review of the literature.Arch Pediatr 1951; 68:303–308., [PUBMED], [INFOTRIEVE], [CSA]
- Cann H M, Verhulst H L. Accidental poisoning in young children—the hazards of iron medication.Am J Dis Child 1960; 99:688–691., [PUBMED], [INFOTRIEVE], [CSA]
- Charney E. A fatal case of ferrous sulfate poisoning.JAMA 1961; 178:326–327., [PUBMED], [INFOTRIEVE], [CSA]
- Shapiro N, Barbezat G O. A case of acute iron poisoning treated with desferrioxamine B.S Afr Med J 1964; 38:461–463., [PUBMED], [INFOTRIEVE], [CSA]
- Venturelli J, Kwee Y, Morris N, Cameron G. Gastrotomy in the management of acute iron poisoning.J Pediatr 1982; 100:768–769., [PUBMED], [INFOTRIEVE], [CSA]
- Klein-Schwartz W, Oderda G M, Gorman R L, Favin F, Rose S R. Assessment of management guidelines. Acute iron ingestion.Clin Pediatr (Phila) 1990; 29:316–321., [CSA]
- Black J, Zenel J. Child abuse by intentional iron poisoning presenting as shock and persistent acidosis.Pediatrics 2003; 111:197–199., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Tenenbein M. Whole bowel irrigation in iron poisoning.J Pediatr 1987; 111:142–145., [PUBMED], [INFOTRIEVE], [CSA]
- Deason J G. Acute iron ingestion in a 2-year-old child.J Emerg Nurs 1995; 21:9–11., [PUBMED], [INFOTRIEVE], [CSA]
- Anderson B, Turchen S, Manoguerra A, Clark R. Retrospective analysis of ingestions of iron containing products in the United States: are there differences between chewable vitamins and adult preparations?. J Emerg Med 2000; 19:255–258., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Nordt S, Williams S, Behling C, Richter P, Manoguerra A, Clark R. Comparison of the toxicities of two iron formulations in a swine model.Acad Emerg Med 1999; 6:1104–1108., [PUBMED], [INFOTRIEVE], [CSA]
- Spiller H A, Wahlen H S, Stephens T L, Krenzelok K P, Benson B, Peterson J, Dellinger J A. Multi-center retrospective evaluation of carbonyl iron ingestions.Vet Hum Toxicol 2002; 44:28–29., [PUBMED], [INFOTRIEVE], [CSA]
- Klein-Schwartz W. Toxicity of polysaccharide-iron complex exposures reported to poison control centers.Ann Pharmacother 2000; 34:165–169., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Shepherd G, Klein-Schwartz W, Burstein A H. Efficacy of the cation exchange resin, sodium polystyrene sulfonate, to decrease iron absorption.J Toxicol Clin Toxicol 2000; 38:389–394., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Snyder B K, Clark R F. Effect of magnesium hydroxide administration on iron absorption after a supratherapeutic dose of ferrous sulfate in human volunteers: a randomized controlled trial.Ann Emerg Med 1999; 33:400–405., [PUBMED], [INFOTRIEVE], [CSA]
- Wallace K L, Curry S C, LoVecchio F, Raschke R A. Effect of magnesium hydroxide on iron absorption following simulated mild iron overdose in human subjects.Acad Emerg Med 1998; 5:961–965., [PUBMED], [INFOTRIEVE], [CSA]
- Burkhart K K, Kulig K W, Hammond K B, Pearson J R, Ambruso D, Rumack B. The rise in the total iron-binding capacity after iron overdose.Ann Emerg Med 1991; 20:532–535., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Kroeker S, Minuk G Y. Intentional iron overdose: an institutional review.Can Med Assoc J 1994; 150:45–48., [CSA]
- Abbarah T R, Fredell J E, Ellenz G B. Ulceration by oral ferrous sulfate.JAMA 1976; 236:2320., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Evensen S A, Forde R, Opedal I, Stormorken H. Acute iron intoxication with abruptly reduced levels of vitamin K-dependent coagulation factors.Scand J Haematol 1982; 29:25–30., [PUBMED], [INFOTRIEVE], [CSA]
- Evrard C, Coffin O, Kaladji C, Brun J, Benard Y, Doumert J. Hémoptysie massive dix jours après extraction bronchique d'un comprimé de sulfate ferreux inhalé accidentellement.Ann Chir 1991; 45:726–728., [PUBMED], [INFOTRIEVE], [CSA]
- Henriksson P, Nilsson L, Nilsson I M, Stenberg P. Fatal iron intoxication with multiple coagulation defects and degradation of factor VIII and factor XIII.Scand J Haematol 1979; 22:235–240., [PUBMED], [INFOTRIEVE], [CSA]
- Lavender S, Bell J A. Iron intoxication in an adult.Br Med J 1970; 2:406., [PUBMED], [INFOTRIEVE], [CSA]
- Peck M G, Rogers J F, Rivenbark J F. Use of high doses of deferoxamine (Desferal) in an adult patient with acute iron overdosage.J Toxicol Clin Toxicol 1982; 19:865–869., [PUBMED], [INFOTRIEVE], [CSA]
- Tenenbein M. Whole bowel irrigation for toxic ingestions.J Toxicol Clin Toxicol 1985; 23:177–184., [PUBMED], [INFOTRIEVE], [CSA]
- Tenenbein M, Kopelow M L, deSa D J. Myocardial failure and shock in iron poisoning.Human Toxicol 1988; 7:281–284., [CSA]
- Tenenbein M, Littman C, Stimpson R E. Gastrointestinal pathology in adult iron overdose.J Toxicol Clin Toxicol 1990; 28:311–320., [PUBMED], [INFOTRIEVE], [CSA]
- Wallack M K, Winkelstein A. Acute iron intoxication in an adult.JAMA 1974; 229:1333–1334., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Inglodby C J.H. Perforated jejunal diverticulum due to local iron toxicity.Br Med J 1977; 1:949–950., [CSA]
- O'Neil-Cutting M A, Crosby W H. The effect of antacids on the absorption of simultaneously ingested iron.JAMA 1986; 255:1468–1470., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Linakis J G, Lacouture P G, Woolf A. Iron absorption from chewable vitamins with iron versus iron tablets: implications for toxicity.Pediatr Emerg Care 1992; 8:321–324., [PUBMED], [INFOTRIEVE], [CSA]
- Ben Mokhtar H, Thabet H, Brahmi N, Zaghdoudi A, Hamouda C, Amamou M. Acute iron poisoning.Vet Hum Toxicol 2002; 44:219–220., [PUBMED], [INFOTRIEVE], [CSA]
- Eriksson F, Johansson S V, Mellstedt H, Stranberg O, Wester P O. Iron intoxication in two adult patients.Acta Med Scand 1974; 196:231–236., [PUBMED], [INFOTRIEVE], [CSA]
- Cernelc M, Kusar V, Jeretin S. Fatal peroral iron poisoning in a young woman.Acta Haematol 1968; 40:90–94., [PUBMED], [INFOTRIEVE], [CSA]
- Gomez H F, McClafferty H H, Flory D, Brent J, Dart R C. Prevention of gastrointestinal iron absorption by chelation from an orally administered premixed deferoxamine/charcoal slurry.Ann Emerg Med 1997; 30:587–592., [PUBMED], [INFOTRIEVE], [CSA]
- Jackson T W, Ling L J, Washington V. The effect of oral deferoxamine on iron absorption in humans.J Toxicol Clin Toxicol 1995; 33:325–329., [PUBMED], [INFOTRIEVE], [CSA]
- Ling L J, Hornfeldt C S, Winter J P. Absorption of iron after experimental overdose of chewable vitamins.Am J Emerg Med 1991; 9:24–26., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Blanc P, Hryhorczuk D, Danel I. Deferoxamine treatment of acute iron intoxication in pregnancy.Obstet Gynecol 1984; 64:12S–14S., [PUBMED], [INFOTRIEVE], [CSA]
- Olenmark M, Biber B, Dottori O, Rybo G. Fatal iron intoxication in late pregnancy.J Toxicol Clin Toxicol 1987; 25:347–359., [PUBMED], [INFOTRIEVE], [CSA]
- Lacoste H, Goyert G L, Goldman L S, Wright D J, Schwartz D B. Acute iron intoxication in pregnancy: case report and review of the literature.Obstet Gynecol 1992; 80:500–501., [PUBMED], [INFOTRIEVE], [CSA]
- Richards R, Brooks S E. Ferrous sulphate poisoning in pregnancy (with afibrinogenaemia as a complication).West Indian Med J 1966; 15:134–140., [PUBMED], [INFOTRIEVE], [CSA]
- Strom R L, Schiller P, Seeds A E, Bensel R T. Fatal iron poisoning in a pregnant female.Minn Med 1976; 59:483–489., [PUBMED], [INFOTRIEVE], [CSA]
- Turk J, Aks S, Ampuero F, Hryhorczuk D O. Successful therapy of iron intoxication in pregnancy with intravenous deferoxamine and whole bowel irrigation.Vet Hum Toxicol 1993; 35:441–444., [PUBMED], [INFOTRIEVE], [CSA]
- Tran T, Wax J R, Steinfeld J D, Ingardia C J. Acute intentional iron overdose in pregnancy.Obstet Gynecol 1998; 92:678–680., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- McElhatton P R, Roberts J C, Sullivan F M. The consequences of iron overdose and its treatment with desferrioxamine in pregnancy.Human Exp Toxicol 1991; 10:251–259., [CSA]
- Benson B E, Cheshire S, McKinney P E, Litovitz T L, Tandberg D, Foster H. Do poison center guidelines adversely affect patient outcomes as triage referral values increase?. J Toxicol Clin Toxicol 2003; 41:585–590., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Foxford R. Gastrotomy. A surgical approach to iron overdose.Ann Emerg Med 1985; 14:1223–1226., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Landsman I, Bricker J T, Reid B S, Bloss R S. Emergency gastrotomy: treatment of choice for iron bezoar.J Pediatr Surg 1987; 22:184–185., [PUBMED], [INFOTRIEVE], [CSA]
- Peterson C D, Fifield G C. Emergency gastrotomy for acute iron poisoning.Ann Emerg Med 1980; 9:262–264., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Tenenbein M. Inefficacy of gastric emptying procedures.J Emerg Med 1985; 3:133–136., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Decker W J, Combs H F, Corby D G. Adsorption of drugs and poisons by activated charcoal.Toxicol Appl Pharmacol 1968; 13:454–460., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Gades N, Chyka P, Butler A, Virgous C, Mandrell T. Activated charcoal and the absorption of ferrous sulfate in rats.Vet Hum Toxicol 2003; 45:183–187., [PUBMED], [INFOTRIEVE], [CSA]
- Czajka P, Konrad J, Duffy J. Iron poisoning—an in vitro comparison of bicarbonate and phosphate lavage solutions.J Pediatr 1981; 98:491–494., [PUBMED], [INFOTRIEVE], [CSA]
- Dean B, Krenzelok E. Invivo effectiveness of oral complexation agents in the management of iron poisoning.J Toxicol Clin Toxicol 1987; 25:221–230., [PUBMED], [INFOTRIEVE], [CSA]
- Corby D G, McCullen A H, Chadwick E W, Decker W J. Effect of orally administered magnesium hydroxide in experimental iron intoxication.J Toxicol Clin Toxicol 1985; 23:489–499., [PUBMED], [INFOTRIEVE], [CSA]
- Geffner M E, Opas L M. Phosphate poisoning complicating treatment for iron ingestion.Am J Dis Child 1980; 134:509–510., [PUBMED], [INFOTRIEVE], [CSA]
- Berkovitch M, Livne A, Lushkov G, Segal M, Talmor C, Bentur Y, Klein J, Koren G. The efficacy of oral deferiprone in acute iron poisoning.Am J Emerg Med 2000; 18:36–40., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Bergeron R, Wiegand J, Brittenham G. HBED ligand: preclinical studies of a potential alternative to deferoxamine for treatment of chronic iron overload and acute iron poisoning.Blood 2002; 99:3019–3026., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
- Dragsten P R, Hallaway P E, Hanson G J, Berger A E, Bernard B, Hedlund B E. First human studies with a high-molecular-weight iron chelator.J Lab Clin Med 2000; 135:57–65., [PUBMED], [INFOTRIEVE], [CSA], [CROSSREF]
Appendix 1
Expert Consensus Panel Members
Lisa L. Booze, PharmD
Certified Specialist in Poison Information
Maryland Poison Center
University of Maryland School of Pharmacy
Baltimore, Maryland
E. Martin Caravati, MD, MPH, FACMT, FACEP
Professor of Surgery (Emergency Medicine)
University of Utah
Medical Director
Utah Poison Center
Salt Lake City, Utah
Gwenn Christianson, RN, MSN
Certified Specialist in Poison Information
Indiana Poison Center
Indianapolis, Indiana
Peter A. Chyka, PharmD, FAACT, DABAT
Professor, Department of Pharmacy
University of Tennessee Health Science Center
Memphis, Tennessee
Daniel C. Keyes, MD, MPH, FACEP, FACMT
Medical Director
Pine Bluff Chemical Demilitarization Facility
Associate Professor, Southwestern Toxicology Training Program
Dallas, Texas
Anthony S. Manoguerra, PharmD, DABAT, FAACT
Professor of Clinical Pharmacy and Associate Dean
School of Pharmacy and Pharmaceutical Sciences
University of California San Diego
Former Director, California Poison Control System, San Diego Division
San Diego, California
Kent R. Olson, MD, FACEP, FAACT, FACMT
Medical Director
California Poison Control System, San Francisco Division
Clinical Professor of Medicine and Pharmacy
University of California, San Francisco
San Francisco, California
Elizabeth J. Scharman, PharmD, DABAT, BCPS, FAACT
Director, West Virginia Poison Center
Professor, West Virginia University School of Pharmacy
Department of Clinical Pharmacy
Charleston, West Virginia
Paul M. Wax, MD, FACMT
Managing Director
Banner Poison Center
Professor of Clinical Emergency Medicine
University of Arizona School of Medicine
Phoenix, Arizona
Alan D. Woolf, MD, MPH, FACMT
Director, Program in Environmental Medicine
Children's Hospital, Boston
Associate Professor of Pediatrics
Harvard Medical School
Boston, Massachusetts
Appendix 2
Appendix 3
Secondary Review Panel Organizations
Ambulatory Pediatric Association
American Academy of Breastfeeding Medicine
American Academy of Emergency Medicine
American Academy of Pediatrics
American Association for Health Education
American College of Clinical Pharmacy
American College of Emergency Physicians
American College of Occupational and Environmental Medicine
American Public Health Association
American Society of Health System Pharmacists
Association of Maternal and Child Health Programs
Association of Occupational and Environmental Clinics
Association of State and Territorial Health Officials
Canadian Association of Poison Control Centres
Centers for Disease Control and Prevention—National Center for Injury Prevention and Control
Consumer Federation of America
Consumer Product Safety Commission
Department of Transportation
Emergency Medical Services for Children
Emergency Nurses Association
Environmental Protection Agency
European Association of Poisons Control Centers and Clinical Toxicologists
Food and Drug Administration
National Association of Children's Hospitals and Related Institutions
National Association of Emergency Medical Services Physicians
National Association of Emergency Medical Technicians
National Association of School Nurses
National Association of State Emergency Medical Services Directors
National Safe Kids Campaign
Teratology Society
World Health Organization International Programme on Chemical Safety