hrvatski jezikClear Cookie - decide language by browser settings

Dynamic energy budget approach to modeling mechanisms of CdSe quantum dot toxicity

Klanjšček, Tin; Nisbet, R.M.; Priester, J.H.; Holden, P.A. (2013) Dynamic energy budget approach to modeling mechanisms of CdSe quantum dot toxicity. Ecotoxicology, 22 (2). pp. 319-330. ISSN 0963-9292

| Request a personal copy from author

Abstract

A mechanistic model of bacterial growth based on dynamic energy budget (DEB) theory is utilized to investigate mechanisms of toxicity of CdSe quantum dots (QDs). The model of QD toxicity is developed by extending a previously published DEB model of cadmium ion toxicity to include a separate model of QD toxic action. The extension allows for testing whether toxicity from QD exposure can be explained fully by dissolved cadmium exposure only, or if the separate effects of QDs need to be taken into account as well. Two major classes of QD toxicity mechanisms are considered: acclimation expressed through initial retardation of growth, and three separate metabolic effects that can be a result of QDs either reversibly or irreversibly associating with the cell. The model is consistent with the data, and is able to distinguish toxic effects due to QD nano-particles from the effects due to cadmium ions. Results suggest that, in contrast to ionic exposure where required acclimation remains constant as exposure increases, increase of the energy required for acclimation with exposure is the primary toxic effect of QDs. Reactive oxygen species measurements help conclude that increase in energetic cost of maintenance processes such as cellular repair and maintenance of cross-membrane gradients is the most important of the three metabolic effects of QD toxicity.

Item Type: Article
Uncontrolled Keywords: dynamic energy budget (DEB); dadmium nano-particle toxicity; mechanistic model; toxicity mechanisms; Pseudomonas aeruginosa bacteria; reactive oxygen species (ROS)
Subjects: NATURAL SCIENCES > Biology > Ecology
NATURAL SCIENCES > Biology > General Biology
NATURAL SCIENCES > Interdisciplinary Natural Sciences > Environmental Science
BIOTECHNICAL SCIENCES > Biotechnology > Waste Management
Divisions: Division for Marine and Enviromental Research
Projects:
Project titleProject leaderProject codeProject type
Ecological modelling for sustainable management of resources (Ekološko modeliranje za održivo upravljanje resursima)-Tarzan Legović098-0982934-2719MZOS
Depositing User: Tin Klanjšček
Date Deposited: 05 Nov 2015 13:12
URI: http://fulir.irb.hr/id/eprint/2216
DOI: 10.1007/s10646-012-1028-7

Actions (login required)

View Item View Item

Downloads

Downloads per month over past year

Contrast
Increase Font
Decrease Font
Dyslexic Font
Accessibility