Oral Glycine and Sodium Thiosulfate for Lethal Cyanide Ingestion

Brenner, Matthew; Azer, Sarah; Oh, Kyung Jin; Han, Chang Hoon; Lee, Jangwoen; Mahon, Sari B.; Du, Xiaoyong; Mukai, David; Burney, Tanya; Saidian, Mayer; Chan, Agnes S.; Straker, Derek I; Bebarta, Vikhyat S.; Boss, Gerry R.

doi:10.4172/2161-0495.1000355

Cited by 4 publications

(5 citation statements)

References 33 publications

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“…[2][3][4]14,[24][25] Future studies should evaluate promising countermeasures in our swine model-similar to what has been done for intravenous KCN models-in experiments that reflect clinically relevant scenarios. 3,4,7,8 Our study has limitations. This study was a pilot study, and the sample size was small.…”

Section: Discussionmentioning

confidence: 94%

“…In particular, the authors used continuous-wave near-infrared tissue spectroscopy system to monitor for toxicity in real-time and found that a combination of oral glycine and sodium thiosulfate may be useful for treating high-dose acute cyanide ingestion. 7 The authors highlighted the difference between the metabolic rates of rabbits and humans as a limitation of using rabbits for these types of studies. Of the 2 species, rabbits have a higher metabolic rate, and this difference has implications regarding the toxicokinetics of oral poisonings, time window for antidote administration, and response to potential oral antidotes.…”

Section: Discussionmentioning

confidence: 99%

“…Rabbits and swine complement each other well in terms of drug development and assessment of physiologic and biochemical variables. [1][2][3][4]7 The FDA Animal Rule likely will require 2 animal models (including at least one large animal species) for testing the efficacy of oral cyanide countermeasures. 10 The selection of swine as a model of cyanide toxicity is appropriate for several reasons.…”

Section: Discussionmentioning

confidence: 99%

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Characterization of a Swine (Sus scrofa) Model of Oral Potassium Cyanide Intoxication

Hendry‐Hofer

Witeof

et al. 2018

comp med

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Cyanide is a readily available and potentially lethal substance. Oral exposure can result in larger doses, compared with other routes. Currently, there are no antidotes specific for use in the treatment of oral cyanide poisoning, and studies cannot be done in humans. We report on a new large animal model of oral cyanide toxicity to evaluate potential antidotes. Six female swine (; weight, 45 to 55 kg) were anesthetized, intubated, and instrumented. Animals received a KCN bolus of either 5 or 8 mg/kg delivered via orogastric tube. Time to apnea was recorded; parameters monitored included heart rate, respiratory rate, blood pressure, pulse oximetry, end-tidal CO2, arterial blood gasses, and lactate concentrations. The Welch test was used to calculate confidence intervals, mean, and standard deviation, and a Kaplan-Meier survival curve was used to compare survival between the 2 groups. At baseline, all animals in both groups were similar. Animals in the 5-mg/kg group had a more rapid time to apnea (5.1 ± 2.1 min), longer time to death (48.5 ± 38.1 min), and a greater rate of survival than the 8-mg/kg group (apnea, 10.6 ± 10.7 min; death, 26.1 ± 5.8 min). All animals displayed signs of toxicity (acidemia, hyperlactatemia, hypotension, apnea). We here report a large animal (swine) model of oral cyanide poisoning with dose-dependent effects in regard to time to death and survival rate. This model likely will be valuable for the development of medical countermeasures for oral cyanide poisoning.

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Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Characterization of a Swine (Sus scrofa) Model of Oral Potassium Cyanide Intoxication

Hendry‐Hofer

Witeof

et al. 2018

comp med

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“…However, our model does allow for invasive assessment of clinically relevant parameters. While most cases of cyanide toxicity result from ingestion or inhalation, we chose intravenous administration of potassium cyanide in an effort to induce reproducible, predictable, controlled, and rapid toxicity [2,3,12,17,18,20]. Intravenous administration minimizes the risk to research staff compared to the inhaled route.…”

Section: Limitationsmentioning

confidence: 99%

Intramuscular dimethyl trisulfide: efficacy in a large swine model of acute severe cyanide toxicity

Hendry‐Hofer

Witeof

Lippner³

et al. 2018

Clinical Toxicology

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Background-Cyanide is a deadly compound used as a terrorist agent. Current FDA approved antidotes require intravenous administration, limiting their utility in a mass casualty scenario. Dimethyl trisulfide (DMTS), a sulfur-based molecule, binds cyanide converting it to the less toxic by-product thiocyanate. Studies evaluating efficacy in rodents have been performed, but a large, clinically relevant animal model has not been reported. Objective-This study evaluates the efficacy of intramuscular DMTS on survival and clinical outcomes in a swine model of acute, severe cyanide toxicity. Methods-Anesthetized swine were instrumented for continuous monitoring of hemodynamics. Prior to potassium cyanide infusion animals were acclimated and breathing spontaneously. At 5minutes post apnea animals were treated with DMTS or saline. Vital signs, hemodynamics, and laboratory values were evaluated at various time points. Results-Baseline values and time to apnea were similar in both groups. Survival in the DMTS treated group was 83.3% and 0% in saline controls (p=0.005). The DMTS group returned to breathing at a mean time of 19.3+10 min after antidote, control animals did not return to breathing (CI difference 8.8, 29.8). At the end of the experiment or time of death, mean lactate was 9.41 mmol/L vs. 4.35 mmol/L (CI difference −10.94,0.82) in the saline and DMTS groups, respectively and pH was 7.20 vs. 7.37 (CI difference −0.04, 0.38). No adverse effects were observed at the injection site. Conclusion-Intramuscular administration of DMTS improves survival and clinical outcomes in our large animal swine model of acute cyanide toxicity.

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“…80 Robust research is under way to develop antidotes that have higher potency or that may be given intramuscularly or orally in the case of mass casualties (e.g., cobinamide, a hydroxocobalamin congener; sulfanegan, a sulfate donor; intramuscular nitrite and thiosulfate; and oral glycine or thiosulfate). 72,81,82 Hydrogen sulfide also binds to methemoglobin and cobalt compounds, and patients may benefit from the prompt administration of nitrite (without thiosulfate) or hydroxocobalamin. 58 In addition, cobinamide was shown to have antidotal efficacy on the toxic effects of hydrogen sulfide in a study in animals.…”

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confidence: 99%

Hazardous Chemical Emergencies and Poisonings

2019

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H azardous chemical emergencies and related poisonings result from various exposures, including inadvertent residential, industrial, occupational, or transportation mishaps; natural disasters; and hazardoussubstance releases that are intended to cause harm. 1-3 Up to 100,000 industrial chemicals are used each day in the United States, 4 and federal authorities estimate that more than 10,000 potentially consequential releases of hazardous substances occur annually. 4,5 In addition, numerous compounds have been developed primarily as military weapons, with exceedingly high toxicity. 6-8 Both toxic industrial chemicals and military chemical weapons are capable of causing mass casualties in a substantive release and may be deployed intentionally in the context of chemical terrorism, 8-10 targeted assassination attempts, 8,11,12 or wartime attacks on civilian populations, as tragically shown in the current Syrian war. 13,14 A toxidrome-based, emergency medical systems (EMS) approach to chemical weapons attacks was presented recently by Ciottone in the Journal. 8 (Toxidromes are constellations of clinical signs, particularly vital signs, mental status, and ocular, respiratory, neurologic, and skin findings, that are characteristic of general classes of poison.) A similar approach is useful for the myriad possible entities in nonintentional hazardous chemical incidents. We review the toxicology and hospital-based management of acute poisonings caused principally by dermal and inhalational exposure to several representative chemical-agent classes in incidents involving the release of hazardous substances or chemical attacks (Table 1). Cyanide and organophosphate poisonings are emphasized, since they can also affect individual patients in the more familiar contexts of occupational and residential exposures or ingestions with suicidal intent and since specific emergency antidotal therapy is crucial for good outcomes. Ov erv iew of Hospita l-Ba sed Emergenc y M a nagement Incidents involving the release of hazardous chemicals may result in widespread chaos and confusion, affecting the EMS response and emergency department (ED) care. 2,8 A rapid influx of multiple critically ill victims with unfamiliar illnesses, as well as numerous low-risk but understandably anxious patients, potentially far outnumbering the seriously ill, 1 poses significant challenges to hospital-based emergency care providers. Patients may bypass prehospital care and arrive at the hospital unaware of or misinformed regarding the cause of their symptoms, with the potential to chemically contaminate bystanders and staff. 2,15-17 Thus, prompt recognition of the chemical event is important so that ED staff and hospital emergency management personnel can secure hospital entrances and decontaminate contami

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Oral Glycine and Sodium Thiosulfate for Lethal Cyanide Ingestion

Cited by 4 publications

References 33 publications

Characterization of a Swine (Sus scrofa) Model of Oral Potassium Cyanide Intoxication

Characterization of a Swine (Sus scrofa) Model of Oral Potassium Cyanide Intoxication

Intramuscular dimethyl trisulfide: efficacy in a large swine model of acute severe cyanide toxicity

Hazardous Chemical Emergencies and Poisonings

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