L09 Ecotoxicology 2024 PDF

Summary

These lecture notes provide an overview of ecotoxicology, defining it as the study of the effects of toxic chemicals on biological organisms. The notes explore the concepts of ecotoxicology from various perspectives, including population, community, ecosystem and biosphere levels. They cover differences between ecotoxicology and environmental toxicology and describe the methods used in eco-toxicity testing.

Full Transcript

6/7/2024

L09 Ecotoxicology

Timo Hamers

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Ecotoxicology

 Ecotoxicology is the study of the effects of toxic chemicals
on biological organisms, especially at the population,
community, ecosystem, and biosphere levels. Ecotoxicology
is a multidisciplinary field, which integrates biology,
chemistry, toxicology and ecology

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Focus on effects populations, communities, ecosystem

general community
endpoints
population

individual

organ
tissue
cellular
molecular
specific
endpoints
mechanistic ecological
understanding relevance

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Ecotoxicology vs Environmental Toxicology

Environmental chemistry Environmental toxicology
Environmental Uptake + direct
Emission Exposure
distribution effects on organisms

Ecology

Indirect effects on
organisms

Effects on structure and
functioning of ecosystem

Ecotoxicology
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Ecotoxicology is an integrated science
 The study of harmful effects of chemicals on ecosystems,
including effect on individuals, and consequent effects at the
level of population and above
 Ecotoxicology integrates different disciplines

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Two approaches in ecotoxicity testing

 To make a PROGNOSIS
What is a safe environmental concentration for the ecosystem?

 To make a DIAGNOSIS
Is this field site polluted or clean?
1. Prognosis: Start in the lab,
extrapolate to the field

2. Diagnosis: Assess
the field directly

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Prognostic testing

 Predictive: start in the lab, extrapolate to field
 Indicator species cultured in the laboratory
 Follows principles of human toxicity testing
 Determine dose-response curve for single species and
single chemical
 Endpoints: survival, growth, reproduction, behaviour,
biochemical parameters (biomarkers)
 Test protocol development, harmonization of methods
 Models for dose-response analysis
 Use derived parameters for risk assessment
 Applicable to new (and existing) chemicals
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Test selection

 The most sensitive species does not exist!
 Depends on
Species traits
Life cycle
Endpoint studied
Position in the food chain
Chemical behavior
Mode of action
Route of exposure
Etc..
 Therefore: you need a battery of test species!
Various trophic levels
Various endpoints
Various taxonomic groups
Various contributions to ecosystem functioning
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Same generic principles as in human toxicity testing

 Routes of exposure
 Phases in toxic response
 Classification of toxic response

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Animal exposure routes

 Oral via GI track (all animals)
via food and water
 Contact (topical) influentialpoints.com

via skin (dermal): vertebrates
CC BY 3.0

via cuticle: arthropods
via body wall (slugs, worms)
 Respiratory https://lite.lstmed.ac.uk/

via lung or gills (vertebrates)
via trachea (invertebrates)
 Special routes, e.g.
via injection
via suppository
Jun Chen; https://gochordates.weebly.com/lung-lung-derivatives.html

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Phases in toxic response

 Exposure:
 how does an organism get into contact with compound?
Routes of exposure (previous slide)
 to what extend does an organism get into contact with compound?
External (concentration in air, (drinking) water, soil, food)
Dose (quantity per bodyweight per day)
Internal (concentration in body or body compartment)

 Toxicokinetics: what does the body do to the compound?
Absorption, Distribution, Metabolism, Excretion
Qualitatively and quantitatively

 Toxicodynamics: what does the compound do to the body? Hazard!
Qualitatively: what type of effect?
Quantitatively: dose-response relationship

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Classification in toxic response

 Possibility for repair
Reversible (can be repaired)
vs
Irreversible (permanent)
 Rate
Acute (shortly after single exposure)
vs
Chronic (after prolonged and repeated exposure)
 Site of action
Local (at site of first contact)
vs
Systemic (at site distant from first contact)
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Acute vs chronic

 Acute
Effects upon short-term exposure (hours – days)
Usually focus on mortality à LC50
Sometimes also sublethal endpoints

 Chronic
Effects upon long-term exposure (weeks – months)
Duration depends on species and life cycle
Effects due to cumulation of damage
Focus on sublethal endpoints (growth, reproduction)
EC50, EC10, NOEC
Mortality also included

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Toxicity tests – what endpoints?

 Specific endpoints
Gene expression
Enzyme activity
Neurotransmission
Histological tissue examination
Etc…

 Generic endpoints,
important for population
Survival
Growth / Metabolism
Reproduction
Behaviour

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Aquatic ecotoxicity test – what species?

 Model for the aquatic ecosystem
Algae (e.g. Scenedesmus sp.)
Invertebrate (e.g. water flea Daphnia sp.)
Fish (e.g. rainbow trout, zebrafish, medaka,
fathead minnow)

 Definition of acute and chronic depends on
species and life cycle:
Species Acute Chronic
Daphnia magna 48 h 21 d
Ceriodaphnia dubia 48 h 7d
Fish (adult) 96 h 28 d
Fish (ELS)* 96 h
* Early life stage test

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Sediment ecotoxicity testing – what species?

 Chironomid larvae (Insects) (OECD)
 Hyalella azteca (Amphipods)
 Lumbriculus variegatus (Oligochaetes)

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Terrestrial ecotoxicity test – what species?

 Model for the terrestrial ecosystem
> Invertebrates
– Earthworms (Eisenia)
– Enchytraeids
– Springtails (Collembola)
– Plants
> Soil microorganisms
– Nitrification
– Respiration

Definition of acute and chronic
depends on species and life cycle:
Species Acute Chronic
Eisenia foetida 7/14 d 28/56 d
Folsomia sp 4d 21/28 d

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Alternative test species (examples)

 Terrestrial species
Predatory mites Molluscs Insect Oribatid mites Isopods Carabid beetles Nematodes
larvae

 Aquatic species
Bacteria Macrophyte
(e.g. Aliivibrio fisheri) (e.g. Lemna minor)

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Ecotoxicity testing in practice

 Negative control (C0) and positive control (Cp)
 Series of increasing test concentrations (C1 – Cn) or doses,
in replicates
 Animals from standardized culture (same age, size, health)
 Standardized test medium
 Climate room (temperature, light-dark regime, etc)

C0 C1 C2 C… Cn Cp
C0 C1 C2 C… Cn Cp
C0 C1 C2 C… Cn Cp

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Diagnostic testing

 Assess the impact of toxic compounds on the ecosystem
directly in the field
 Ecology and environmental chemistry become crucial

chemistry
Sediment, plant and animal
concentrations TRIAD approach:
integrated assessment
of contaminated soils
and sediments along
risk three lines of evidence
toxicity ecology
Bioassays Field observations
biomarkers & experimentation

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Diagnostic testing – in situ

 Assess the impact of toxic compounds on the ecosystem
directly in the field
 Collect organisms from the field
 Determine
Species abundance/diversity
Health condition
Pathology
Behavior
Biomarkers (see L16)

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Diagnostic testing in situ: field observations
Structural and functional endpoints

 Ecotoxicology studies not only effects on individuals but also
on populations and communities:
Structural Functional
Structural effects endpoints endpoints
Pattern description Abundance of Decomposition
species
Functional effects
Species diversity Soil respiration
Process characterization Biomass Nitrification
Spatial distribution Nitrogen fixation
Adult/juvenile ratio Primary production

Sex ratio Humification
Etc Etc

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Diagnostic testing in situ - Functional parameters

Litter decomposition

Feeding activity of the soil fauna

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Structural and functional endpoints
 Ecotoxicology studies not only effects on individuals but also
on populations and communities:
Structural Functional
Structural effects endpoints endpoints
Pattern description Abundance of Decomposition
species
Functional effects
Species diversity Soil respiration
Process characterization Biomass Nitrification
Spatial distribution Nitrogen fixation
Adult/juvenile ratio Primary production

Most sensitive? Sex ratio Humification
Most ecological relevant? Etc Etc
Overlap among species in function: functional redundancy
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Diagnostic testing – ex situ

 Bring a field sample to the lab
soil, sediment, water, passive sampler

 Perform toxicity test (bioassay) on field sample or its extract
In the laboratory under controlled conditions
Endpoints: survival, behaviour, growth, reproduction, etc.

 Compare response on test sample with
“non-polluted” reference sample, or
least contaminated sample from gradient, or
dilution required to obtain no effect

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Why bioassays in addition to chemical analysis?

 Chemical analysis
Often restricted to a limited set of targeted compounds
Does not account for transformation products
Does not account for bioavailability
Threshold values (environmental quality standards) only derived
for single chemicals

 In practice exposure is usually to a mixture of (many)
pollutants with unknown composition → toxicity hard to
predict
 Bioassays may provide additional insight into actual
ecological risk by integrating effects of bioavailable
concentrations of different chemicals

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Diagnostic testing ex situ - examples of bioassays

 Bacterial tests
enzyme inhibition
Bioluminescence inhibition (Aliivibrio fischeri)
Mutagenicity (Ames test)

 Cell-based assays
Reporter gene assays (based on modes of action, e.g. Calux)

 In vivo tests
Laboratory-cultured test organisms (daphnids, earthworms, etc)
Endpoints: survival, behaviour, growth, reproduction, biomarkers

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Effect-directed analysis (see L18)

 Identify compounds responsible for the observed bioassay
response
High-throughput bioassays combined with
Advanced chemical analytical methods

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Learning goals: after this lecture you can…

 Explain the difference between prognostic and diagnostic
testing
 Explain why a battery of ecotoxicity tests is needed
 Mention typical test species for aquatic and terrestrial
ecotoxicity testing
 Name quality control criteria for ecotoxicity testing
 Distinguish between structural and functional endpoints
 Explain the value of effect-based bioassay testing in addition
to chemical analysis

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Right or wrong?
 In diagnostic toxicity testing the impact of chemicals is determined
directly in the field or in field samples
 Fish is the most sensitive species for ecotoxicity testing
 The duration of a chronic toxicity test depends on the life cycle of
the test species
 The TRIAD approach is based on three pillars: exposure,
toxicokinetics, and toxicodynamics
 A negative control shows a decrease in response and a positive
control shows an increase in response
 A changes in sex ratio is an example of a functional endpoint
 Bioassay testing accounts for bioavailability, and chemical
analysis not

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