E5080 General Ecotoxicology

Faculty of Science
Autumn 2022
Extent and Intensity
2/0/0. 2 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).
Taught in person.
Teacher(s)
prof. RNDr. Luděk Bláha, Ph.D. (lecturer)
prof. RNDr. Jakub Hofman, Ph.D. (lecturer)
Guaranteed by
prof. RNDr. Luděk Bláha, Ph.D.
RECETOX – Faculty of Science
Contact Person: prof. RNDr. Luděk Bláha, Ph.D.
Supplier department: RECETOX – Faculty of Science
Timetable
Wed 9:00–10:50 D29/252-RCX1
Prerequisites
NOW ( E5081 General Ecotoxicology - Pr )
This is an introductory course to science and applications of Ecotoxicology. The only prerequisite is knowledge of general biology and chemistry (secondary school level). The course is lectured in English for both Czech and international students, including visiting students. Basic understanding to spoken English is required, the speed of lecturing is slower and adjusted to students´ needs. This allows for good understanding and practicing of scientific English through listening, speaking (group discussions, case studies) and writing (periodic small tests, final written and oral exam).
Course Enrolment Limitations
The course is also offered to the students of the fields other than those the course is directly associated with.
fields of study / plans the course is directly associated with
Course objectives
The aims of this introductory course to Ecotoxicology are (1) to introduce Ecotoxicology as highly important and relevant science discipline with numerous practical and regulatory applications, (2) to provide an overview of scientific problems, concepts and methodologies as well as ecotoxicological data and their analyses and interpretations, (3) to learn and practice the knowledge through case studies in aquatic and terrestrial environments.
Learning outcomes
After the course:
Student will understand Ecotoxicology as interdisciplinary science combining principles and concepts of exposure assessment to stressors (namely hazardous chemicals) with the assessment of their hazards (i.e. adverse effects that stressors cause to living systems).
Student will be be able to explain principles and discuss examples of prototypical stressors and their effects – from molecules and cells to individuals, populations and ecosystems; from microorganisms and plants to animals including humans.
Student will be able to describe essential ecotoxicological methods, i.e. biological assays in aquatic and terrerstrial systems, and interprete simple ecotoxicological data with respect to potential environmental risks.
Student will be able to address and discuss the use of ecotoxicological knowledge in solving practical environmental problems, including the regulation and management of chemicals.
Syllabus
  • 1 – Ecotoxicology – brief history, motivation and needs for ecotoxicology science. Essential terms – Exposure, Hazards, Risks, dose-response. Framework of Adverse Outcome Pathways (AOPs) in eco/toxicology as an approach used during the course. [Example and case stories - DDT, Mercury-Hg].
  • 2 & 3 – Exposures and stressors – pollution sources and main groups of toxic compounds in the environment. Environmental fate (transport, distribution, transformations) and driving properties of chemical compounds (lipophilicity - Kow, reactivity/stability). Bioconcentration, bioaccumulation, biomagnification. Bioavailability – principles and examples. Overview of major groups of hazardous chemicals - examples, properties. [Case studies – environmental fate of chemicals in different environments].
  • 4 – Living systems & Ecotoxicology. Structure and functions of living organisms as targets of toxicants. Ecophysiological roles - Producers, Consumers, Decomposers. Theory of stress and stress responses. Energy – homeostasis, distribution and disturbances in response to stressors (DEB – Dynamic Energy Budget concept). Adaptation to stress – physiological and evolutionary adaptation mechanisms. Principles determining sensitivity of organisms to chemical toxicity. [Case studies – adaptation and biological sensitivity]
  • 5 – Toxicokinetics – concept of exposures (dose, concentration) and response and the role of toxicokinetics. ADME (Absorption, Distribution, Metabolism, Excretion) processes in different organisms. [Case studies – evaluation of exposure and toxicokinetics in different environments].
  • 6 – Toxicodynamics – Molecular initiating events as drivers of AOPs. Principles of toxicodynamic interactions with biomolecules in living systems. Modes of action – nonspecific (non-reactives/reactive) vs specific (key-lock). Phospholipids (membranes), nucleic acids and proteins as targets of toxic compounds. Complex toxicity mechanisms (oxidative stress, nuclear receptors - AhR, ER, AR) & corresponding adverse outcomes at individual level. [Case studies – toxicity and ecotoxicity of model chemicals]
  • 7 – Ecotoxicological effects at the level of individuals. Key apical endpoints - lethality, growth and development, reproduction. Examples of the effects at producers, consumers and decomposers & corresponding adverse outcomes at the levels of populations and ecosystems. [Case studies – fish ecotoxicity - from embryo to populations]
  • 8 - (Chemical) stress in populations, communities and ecosystems. Populations and their responses to stress; structural and functional parameters, evolutionary adaptations. Communities and toxic stress – floristic and faunistic records, community indices, key species, bioindicators. [Case study - river contamination case study]
  • 9 - Experimental ecotoxicology - bioassays, types, design, results - (eco)toxicological data and concentration-response curve, LCx, ECx, NOEC, LOEC. Examples of the most important bioassays. [Case studies – selection of bioassays for given problem, concrete results of bioassay]
  • 10 - Ecotoxicological applications. Prospective and retrospective risk assessment - principles and examples, derivation of safe values (PNEC) and environmental limits, PEC vs PNEC, RQ/HQ. Use of bioassays in regulatory frameworks [Case studies – REACH, pesticides]
  • 11 - Ecotoxicological methodology for field studies - real problems in real ecosystems and how to address ecotoxicity, causality, TRIAD approach and weight of evidence, sampling, bioindication, biomonitoring [Case studies – contaminated site study ...]
  • 12 – Advanced Environmental toxikology, current research directions - ecotoxicology in the 21st century (in vitro, in silico), 3R, AOPs, exposome and omics technologies, nanomaterials, microplastics.
Literature
    recommended literature
  • VAN GESTEL, Kees. Environmental Toxicology, an open online textbook. 2021. URL info
  • BLÁHA, Luděk and Jakub HOFMAN. Ecotoxicology of Environmental Pollutants. Online. In Jan Filip;Tomáš Cajthaml; Petra Najmanová; Miroslav Černík; Radek Zbořil. Advanced Nano-Bio Technologies for Water and Soil Treatment. Cham: Springer, 2020, p. 549-572. ISBN 978-3-030-29839-5. Available from: https://dx.doi.org/10.1007/978-3-030-29840-1_27. URL info
  • ANDĚL, Petr. Ekotoxikologie, bioindikace a biomonitoring. Vyd. 1. Liberec: Evernia, 2011, 243, [22]. ISBN 9788090378797. info
  • KOPP, Radovan, Klára HILSCHEROVÁ and Eva POŠTULKOVÁ. Základy vodní ekotoxikologie. Vydání první. Brno: Mendelova univerzita v Brně, 2015, 151 stran. ISBN 9788075093349. info
    not specified
  • NEWMAN, Michael C. Fundamentals of ecotoxicology : the science of pollution. Fifth edition. Boca Raton: CRC Press, Taylor & Francis Group, 2020, xxv, 681. ISBN 9780815354024. info
  • CAMPBELL, P. G. C., Peter V. HODSON, Pamela WELBOURN, David A. WRIGHT, Valérie S. LANGLOIS, Christopher J. MARTYNIUK, Christopher D. METCALFE and Louise M. WINN. Ecotoxicology. First published. Cambridge: Cambridge University Press, 2022, xviii, 576. ISBN 9781108819732. info
  • WALKER, C. H. Principles of ecotoxicology. 4th ed. Boca Raton, Fla.: CRC Press, 2012, xxv, 360. ISBN 9781439862667. info
Teaching methods
Weekly classes (each week in the semester). Lectures are combined with group discussions (problem solving, case studies), and weekly mini-tests in IS MUNI (ROPOTS).
Assessment methods
Systematic weekly activity is required during the semester: this is checked by weekly ROPOTS (Odpovědníky) in IS MUNI. Students are required to ask all ROPOTs, each with 80% success. Final exam consists of (i) a written test (60% weight), (ii) oral exam - 2 broader discussion questions (30%), (iii) activity and performance during semester (10%).
Language of instruction
English
Further Comments
Study Materials
The course is taught annually.
The course is also listed under the following terms Autumn 2019, Autumn 2020, autumn 2021, Autumn 2023, Autumn 2024.
  • Enrolment Statistics (Autumn 2022, recent)
  • Permalink: https://is.muni.cz/course/sci/autumn2022/E5080