The toxicokinetics of cyanide and mandelonitrile in the horse and their relevance to the mare reproductive loss syndrome.
Abstract: The epidemiological association between black cherry trees and mare reproductive loss syndrome has focused attention on cyanide and environmental cyanogens. This article describes the toxicokinetics of cyanide in horses and the relationships between blood cyanide concentrations and potentially adverse responses to cyanide. To identify safe and humane blood concentration limits for cyanide experiments, mares were infused with increasing doses (1-12 mg/min) of sodium cyanide for 1 h. Infusion at 12 mg/min produced clinical signs of cyanide toxicity at 38 min; these signs included increased heart rate, weakness, lack of coordination, loss of muscle tone, and respiratory and behavioral distress. Peak blood cyanide concentrations were about 2500 ng/mL; the clinical and biochemical signs of distress reversed when infusion stopped. Four horses were infused with 1 mg/min of sodium cyanide for 1 h to evaluate the distribution and elimination kinetics of cyanide. Blood cyanide concentrations peaked at 1160 ng/mL and then declined rapidly, suggesting a two-compartment, open model. The distribution (alpha) phase half-life was 0.74 h, the terminal (beta phase) half-life was 16.16 h. The mean residence time was 12.4 h, the steady-state volume of distribution was 2.21 L/kg, and the mean systemic clearance was 0.182 L/h/kg. Partitioning studies showed that blood cyanide was about 98.5% associated with the red cell fraction. No clinical signs of cyanide intoxication or distress were observed during these infusion experiments. Mandelonitrile was next administered orally at 3 mg/kg to four horses. Cyanide was rapidly available from the orally administered mandelonitrile and the C max blood concentration of 1857 ng/mL was observed at 3 min after dosing; thereafter, blood cyanide again declined rapidly, reaching 100 ng/mL by 4 h postadministration. The mean oral bioavailability of cyanide from mandelonitrile was 57% +/- 6.5 (SEM), and its apparent terminal half-life was 13 h +/- 3 (SEM). No clinical signs of cyanide intoxication or distress were observed during these experiments. These data show that during acute exposure to higher doses of cyanide (~600 mg/horse; 2500 ng/mL of cyanide in blood), redistribution of cyanide rapidly terminated the acute toxic responses. Similarly, mandelonitrile rapidly delivered its cyanide content, and acute cyanide intoxications following mandelonitrile administration can also be terminated by redistribution. Rapid termination of cyanide intoxication by redistribution is consistent with and explains many of the clinical and biochemical characteristics of acute, high-dose cyanide toxicity. On the other hand, at lower concentrations (<100 ng/mL in blood), metabolic transformation of cyanide is likely the dominant mechanism of termination of action. This process is slow, with terminal half-lives ranging from 12-16 hours. The large volume of distribution and the long terminal-phase-elimination half-life of cyanide suggest different mechanisms for toxicities and termination of toxicities associated with low-level exposure to cyanide. If environmental exposure to cyanide is a factor in the cause of MRLS, then it is likely in the more subtle effects of low concentrations of cyanide on specific metabolic processes that the associations will be found.
Publication Date: 2003-01-01 PubMed ID: 20021160DOI: 10.1080/15376510309832Google Scholar: Lookup
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Summary
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This research article explains the process of how cyanide, particularly from black cherry trees, affects the reproductive system of mares causing mare reproductive loss syndrome (MRLS). Researchers conducted various experiments to investigate the toxicokinetics of cyanide and mandelonitrile absorption, distribution,and elimination in horses.
Methodology of Research
- The study first looked at the toxic effects of cyanide on horses, specifically mares, by infusing them with increasing doses of sodium cyanide. The maximum tolerable dose observed was 12 mg per minute, after which horses started showing clinical signs of cyanide toxicity at 38 minutes.
- The experiment continued by injecting the horses with 1mg/min of sodium cyanide for 1 hour to study the distribution and elimination kinetics of the compound. The decay of cyanide concentration in the horses’ bloodstream revealed a two-phase model, i.e., the distribution phase with half-life of about 0.74 hours and the terminal phase with half-life of around 16.16 hours. The systemic clearance was also calculated to be about 0.182 L/h/kg.
- Researchers also conducted a test to see how much of the cyanide was associated with the red blood cells of the host, and it was found that around 98.5% of cyanide is linked to red blood cells.
- To investigate the effects of mandelonitrile (a cyanogenic glycoside found in black cherry tree), horses were orally administered a dose of 3mg/kg. According to the results, mandelonitrile rapidly released cyanide into the bloodstream, reaching maximum concentration 3 minutes post administration.
Key Findings & Interpretations
- The study found that acute exposure to higher doses of cyanide caused clinical signs of toxicity that could be rapidly reversed once infusion of cyanide was halted. This suggested that redistribution of cyanide in the horse system quickly negated the toxicity.
- Similar to cyanide, mandelonitrile also delivered its cyanide content rapidly into the bloodstream which could be terminated immediately after redistribution.
- On the contrary, the toxicity of lower cyanide concentrations is eliminated through a slower metabolic transformation process, with terminal half-lives ranging from 12-16 hours.
- The investigation found larger volumes of cyanide distribution and longer half-life in terminal phase elimination in horses, thus leaving the possibility for different mechanisms in cyanide toxicity at low level exposure.
- The concluding note of the research suggested that if environmental exposure to cyanide does contribute to MRLS, the associations might be found in low concentrations of cyanide’s subtle effects on specific metabolic processes.
Cite This Article
APA
Dirikolu L, Hughes C, Harkins D, Boyles J, Bosken J, Lehner F, Troppmann A, McDowell K, Tobin T, Sebastian MM, Harrison L, Crutchfield J, Baskin SI, Fitzgerald TD.
(2003).
The toxicokinetics of cyanide and mandelonitrile in the horse and their relevance to the mare reproductive loss syndrome.
Toxicol Mech Methods, 13(3), 199-211.
https://doi.org/10.1080/15376510309832 Publication
Researcher Affiliations
- Maxwell H. Gluck Equine Research Center, University of Kentucky, Lexington, Kentucky, USA.
Citations
This article has been cited 3 times.- Nourani MR, Kalantari Hesari A, Shahrooz R, Asadi MR. Effect of Sodium Cyanide-induced Tissue Hypoxia on Reproductive Capability of Male Mice and the Protective Effect of Ethyl Pyruvate. Arch Razi Inst 2021 Jul;76(2):323-333.
- Lachowicz JI, Alexander J, Aaseth JO. Cyanide and Cyanogenic Compounds-Toxicity, Molecular Targets, and Therapeutic Agents. Biomolecules 2024 Nov 7;14(11).
- Khan HMA, Yusof NA, Ahmad SAA, Yu CY, Raston NHA, Rahman SFA. Electrochemical aptasensor for 2-amino-2-thiazoline-4-carboxylic acid (ATCA), a metabolite for cyanide poisoning. Sci Rep 2024 Oct 11;14(1):23859.
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