Cadmium uptake from sediment by <i>Cylindrotheca closterium</i> and the effect of diatom presence on partitioning of cadmium between sediment and water: A laboratory study

Becker, Amani E ORCID: 0000-0001-9516-5120 and Copplestone, David (2019) Cadmium uptake from sediment by <i>Cylindrotheca closterium</i> and the effect of diatom presence on partitioning of cadmium between sediment and water: A laboratory study. LIMNOLOGY AND OCEANOGRAPHY, 64 (6). pp. 2550-2568.

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Abstract

<jats:title>Abstract</jats:title><jats:p>Although it is well established that microalgae take up metals and other contaminants from water and it has been suggested that algae may play a significant role in mobilizing sediment bound contaminants, there has been little research on the uptake of sediment‐associated contaminants by microalgae. This may be important for microphytobenthos, which is closely associated with sediments. We report on laboratory experiments investigating the uptake of cadmium (Cd) from sediment and water by <jats:italic>Cylindrotheca closterium</jats:italic> over 96 h. The role of microalgae in the partitioning of Cd between sediment and water was also investigated. While concentrations do not typically represent those in the natural environment, we showed <jats:italic>C. closterium</jats:italic> takes up Cd from sediment, and concentration in microalgae is affected by sediment organic matter content. <jats:italic>Cylindrotheca closterium</jats:italic> influenced Cd movement between sediment and water: transfer from water to sediment was slowed, while transfer from sediment to overlying water (all treatments) and interstitial water (unprocessed sediment treatments) was increased. This is the first article to describe Cd uptake by diatoms from intertidal sediment in relation to sediment properties and mobilization of Cd from sediment in the presence of diatoms. Microalgae may serve as a pathway for sediment‐associated metals to enter into aquatic food webs, and their presence appears to increase metal concentrations in water potentially making any mobilized metals available for uptake by other species. Given this and their importance as the basis of the food chain, there may be implications for environmental and human health and potential impacts for the biological stability of the sediment.</jats:p>

Item Type:	Article
Depositing User:	Symplectic Admin
Date Deposited:	10 Jun 2019 15:15
Last Modified:	05 Oct 2023 13:49
DOI:	10.1002/lno.11204
Open Access URL:	https://doi.org/10.1002/lno.11204
Related URLs:	Author Publisher
URI:	https://livrepository.liverpool.ac.uk/id/eprint/3045283