On the half-life of thiocyanate in the plasma of the marine fish Amphiprion ocellaris: implications for cyanide detection.

Nancy E Breen,Sara Hunt,Julia Grossman,J Alexander Bonanno,Andrew L Rhyne,Jordan Brown,Hannah Nolte

doi:10.7717/peerj.6644

Abstract

The illegal practice of using cyanide (CN) as a stunning agent to collect fish for both the marine aquarium and live fish food trades has been used throughout the Indo-Pacific for over 50 years. CN fishing is destructive to all life forms within the coral reef ecosystems where it is used and is certainly one of many anthropogenic activities that have led to 95% of the reefs in the Indo-Pacific being labeled at risk for degradation and loss. A field-deployable test for detecting fish caught using CN would assist in combating the use of this destructive practice, however, no reliable and robust test exists. Further, there is little toxicokinetic data available on marine fish to support the development of such a test, yet such data is critical to establishing the concentration range and time scale over which such a test would be viable. This study presents the first direct measurement of the half-life of the metabolite thiocyanate (SCN) after pulsed exposure to CN in a marine fish. SCN was measured in the plasma of Amphiprion ocellaris after exposure to 50 ppm CN for three exposure times (20, 45, and 60 s) using HPLC-UV and a C30 column pre-treated with polyethylene glycol. Plasma SCN levels observed are dose-dependent, reflecting a longer time for conversion of CN to SCN as the dose of CN increases. SCN plasma levels reached a maximum concentration (1.2–2.3 ppm) 12–20 h after exposure to CN. The half-life for the elimination of SCN was 1.01 ± 0.26 days for 45 s exposure and 0.44 ± 0.15 days for 20 s exposure. Fish were also directly exposed to SCN (100 ppm for 11 days) and the observed half-life for SCN elimination was 0.35 ± 0.07 days. Plasma SCN levels did not return to control levels, even after 41 days when exposed to CN but did return to control levels after 48 days when exposed to SCN. The similar half-lives observed for CN and SCN exposure suggests that SCN exposure can be used as a proxy for measuring the rate of SCN elimination following CN exposure. In order for plasma SCN to be used as a marker for CN exposure, these results must be extended to other species and endogenous levels of SCN in wild caught fish must be established.

Highlights

Despite being illegal in most countries, cyanide (CN) fishing continues to be used throughout the Indo-Pacific region to capture reef fish for the marine aquarium trade (MAT) and live fish food trade (LFFT) industries (Calado et al, 2014; Davis, Murray & Katsiadaki, 2017; Losada & Bersuder, 2017)
Thiocyanate in the plasma of the marine fish A. ocellaris is quantified using HPLC-UV and C30 column pre-treated with PEG
SCN can be observed in the plasma of A. ocellaris following exposure to CN or SCN

Summary

Introduction

Despite being illegal in most countries, cyanide (CN) fishing continues to be used throughout the Indo-Pacific region to capture reef fish for the marine aquarium trade (MAT) and live fish food trade (LFFT) industries (Calado et al, 2014; Davis, Murray & Katsiadaki, 2017; Losada & Bersuder, 2017). This constant and prolonged exposure to such a poison is certainly one of many anthropogenic activities that has led to 95% of the reefs in the Indo-Pacific to be labeled at risk for degradation and loss (Burke et al, 2011) To combat this threat, governments, environmental groups, and NGOs have often cited the need for the development of a simple, reliable test to detect whether or not a fish has been captured using CN (Bruckner & Roberts, 2008; Davis, Murray & Katsiadaki, 2017). Such a test would allow for the screening of captured fish and potentially the enforcement of existing laws banning this practice

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