Human health risk from consumption of aquatic species in arsenic-contaminated shallow urban lakes

Arsenic (As) causes cancer and non-cancer health effects in humans. Previous research revealed As concentrations over 200 mu g g(-1) in lake sediments in the south-central Puget Sound region affected by the former ASARCO copper smelter in Ruston, WA, and significant bioaccumulation of As in plankton in shallow lakes. Enhanced uptake occurs during summertime stratification and near-bottom anoxia when As is mobilized from sediments. Periodic mixing events in shallow lakes allow dissolved As to mix into oxygenated waters and littoral zones where biota reside. We quantify As concentrations and associated health risks in human-consumed tissues of sunfish [pumpkinseed (Lepomis gibbosus) and bluegill (Lepomis macrochirus)], crayfish [signal (Pacifastacus leniusculus) and red swamp (Procambarus clarkii)], and snails [Chinese mystery (Bellamya chinensis)] from lakes representing a gradient of As contamination and differing mixing regimes. In three shallow lakes with a range of arsenic in profundal sediments (20 to 206 mu g As g-(1)), mean arsenic concentrations ranged from 2.9 to 46.4 mu g g(-1) in snails, 2.6 to 13.9 mu g g(-1) in crayfish, and 0.07 to 0.61 mu g g(-1) in sunfish. Comparatively, organisms in the deep, contaminated lake (208 mu g g(-1), in profundal sediments) averaged 11.8 mu g g(-1) in snails and 0.06 mu g g(-1) in sunfish. Using inorganic As concentrations, we calculated that consuming aquatic species from the most As-contaminated shallow lake resulted in 4-10 times greater health risks compared to the deep lake with the same arsenic concentrations in profundal sediments. We show that dynamics in shallow, polymictic lakes can result in greater As bioavailability compared to deeper, seasonally stratified lakes. Arsenic in oxygenated waters and littoral sediments was more indicative of exposure to aquatic species than profundal sediments, and therefore we recommend that sampling methods focus on these shallow zones to better indicate the potential for uptake into organisms and human health risk. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The research found elevated arsenic concentrations in Puget Sound region lakes, with significant bioaccumulation in plankton. Factors such as seasonal mixing and near-bottom anoxia influence arsenic uptake. Monitoring and risk assessment of arsenic contamination should focus on shallow zones in lakes.