🧭 Overview
🧠 One-sentence thesis
Toxicity testing provides systematic methods to assess the bioaccumulation potential and hazardous effects of chemicals on organisms through standardized protocols that measure concentration-response relationships and various endpoints, while increasingly incorporating alternative methods to reduce animal testing.
📌 Key points (3–5)
- Purpose of toxicity testing: Laboratory tests assess bioaccumulation potential and establish concentration-response relationships to derive toxicity parameters (LC₅₀, EC₅₀) for hazard assessment
- Two main endpoint categories: Whole-organism endpoints (survival, growth, reproduction, behavior) and molecular/biochemical endpoints (gene expression, enzyme activity, metabolic changes)
- Quality control requirements: Tests must meet validity criteria including minimum control survival, adequate replication, proper test design, and use of negative/positive controls to ensure reliable results
- Standardization importance: International bodies (OECD, ISO) develop standardized guidelines to reduce variation and enable regulatory acceptance through mutual acceptance of data (MAD)
- Common confusion - static vs. dynamic tests: Static bioaccumulation tests measure concentrations at one time point (may underestimate if equilibrium not reached), while dynamic tests measure uptake and elimination kinetics over time to calculate rate constants
🧪 Core testing approaches
🔬 Bioaccumulation testing methods
Bioaccumulation: The uptake of chemicals in organisms from the environment, quantified by bioconcentration factor (BCF) for water exposure or biota-to-soil/sediment accumulation factor (BSAF) for soil/sediment exposure.
Static exposure systems:
- Medium dosed once with test chemical
- Organisms and medium analyzed after exposure period
- BCF/BSAF calculated from measured concentrations
- Challenge: Exposure concentrations may decrease during test due to biodegradation, volatilization, sorption, or organism uptake
- Solution: Measure concentrations at multiple time points and use time-weighted-average (TWA) values
Dynamic (toxicokinetic) tests:
- Uptake phase: Organisms exposed in spiked medium, sampled at multiple time points
- Elimination phase: Organisms transferred to clean medium, sampled over time
- First-order one-compartment model fitted to data
- BCF/BSAF = uptake rate constant (k₁) / elimination rate constant (k₂)
- Advantage: Overcomes uncertainty about whether equilibrium was reached
- Sampling design: Typically 5-6 time points each for uptake and elimination, with 3-4 replicates per time point
Example: In a molybdenum uptake/elimination study with earthworms (Eisenia andrei), researchers calculated a BSAF of approximately 1.0 from the ratio of uptake and elimination rate constants, suggesting low bioaccumulation potential.
📊 Concentration-response relationships
Key paradigm: "The dose makes the poison" (Paracelsus) - any chemical can be toxic, but the dose determines the severity of effect.
Essential components:
- Organisms exposed to range of concentrations plus control group
- Response plotted against exposure concentration
- Concentration-response curves fitted to derive toxicity measures
Measures of toxicity:
- ECₓ/EDₓ: Effective concentration/dose causing x% effect (must specify endpoint)
- LCₓ/LDₓ: Lethal concentration/dose causing x% mortality
- EC₅₀/LC₅₀: Median effect/lethal concentration (most common estimate)
- NOEC: No-Observed Effect Concentration (highest concentration with no significant difference from control)
- LOEC: Lowest Observed Effect Concentration (lowest concentration significantly different from control)
Quantal vs. continuous data:
- Quantal: Yes/no responses (e.g., survival, avoidance) - population-level
- Continuous: Measurable parameters (e.g., growth rate, reproduction number) - can be individual-level
Curve parameters:
- Minimum response (often set to control level or zero)
- Maximum response (often 100% relative to control)
- Slope (steepness; determines distance between EC₅₀ and EC₁₀)
- Position (where curve sits on x-axis; may equal EC₅₀)
Don't confuse: Statistical significance vs. toxicological/biological significance - both must be evaluated separately.
🎯 Why ECₓ values are preferred over NOEC
Disadvantages of NOEC:
- Obtained by hypothesis testing rather than regression analysis
- Equals one of the test concentrations (doesn't use all data)
- Sensitive to number of replicates and variation between replicates
- Depends on statistical test chosen and variance
- No confidence intervals (cannot assess reliability)
- Difficult to compare between laboratories and species
- May sometimes equal or exceed EC₅₀ due to variation
Advantages of ECₓ (e.g., EC₁₀, EC₂₀):
- Uses all data from the test via curve fitting
- Has 95% confidence intervals indicating reliability
- Allows statistical comparison between studies
- More reproducible across laboratories
🦠 Test organisms and endpoints
🐛 Selection criteria for test organisms
Practical requirements:
- Easy to culture and maintain in laboratory
- Sensitive to different stressors
- Ecologically and/or economically relevant
- Available standardized test protocols
Common tension: Easy-to-culture species (often generalists) tend to be less sensitive, while sensitive species (often specialists) are harder to culture.
Representative test battery should include:
- Different life histories and functional groups
- Different taxonomic groups
- Different routes of exposure
- Organisms from relevant environmental compartments
Standard test organisms by compartment:
| Compartment | Example organisms |
|---|
| Water | Daphnia magna (crustacean), Danio rerio (fish), algae/cyanobacteria |
| Sediment | Chironomus riparius (midge), Lumbriculus variegatus (oligochaete) |
| Soil | Eisenia fetida/andrei (earthworm), Folsomia candida (collembolan), Enchytraeus species |
| Terrestrial | Apis mellifera (honeybee), various bird species, crop/non-crop plants |
Don't confuse: Standard vs. non-standard organisms - non-standard species may be more ecologically relevant for specific ecosystems (e.g., riverine insects for streams vs. Daphnia for stagnant water) but lack standardized protocols.
📈 Endpoints measured in toxicity tests
Whole-organism endpoints:
Mortality/survival:
- Assessed in both acute and chronic tests
- Can be scored at intervals throughout test
- Expressed as percentage of initial number or percentage of control
- Used to derive LC₅₀ values
Growth:
- Measured as increase in length or weight
- Best practice: Measure at start and end of exposure
- Express as percentage of initial measurement
- More distinctive than measuring final size alone
Reproduction:
- Day of first reproduction (ecologically relevant for population growth)
- Number of offspring (eggs, seeds, neonates, juveniles)
- Quality of offspring (physiological status, size, survival to adulthood)
- Integrated parameter incorporating many aspects
Behavioral endpoints (acute tests):
- Avoidance behavior (can be 100-1000× more sensitive than survival)
- Feeding inhibition
- Swimming behavior changes
- Ventilation behavior
- Advantage: Rapid response, sensitive, ecologically relevant (affects trophic interactions)
Example: Copper effects on caddisfly ventilation behavior occurred at ~150× lower concentrations than lethal effects on larvae.
Photosynthesis (plants/algae):
- Measured using pulse amplitude modulation (PAM) fluorometry
- Effective photosystem II efficiency (ΦPSII) in light-adapted cells
- Rapid, sensitive endpoint for herbicide effects
- Most herbicides directly or indirectly affect PSII
Sub-organismal endpoints:
- Enzyme activity (e.g., acetylcholinesterase inhibition)
- Biochemical markers (hormone levels, oxidative stress markers)
- Gene expression changes (transcriptomics)
- Metabolic changes (metabolomics)
- Epigenetic modifications
🌱 Primary producers in testing
Groups tested:
- Microalgae and cyanobacteria (unicellular)
- Macrophytes (multicellular aquatic plants)
- Terrestrial plants (dicots and monocots)
Exposure routes:
- Aquatic organisms: Water phase (all), sediment (rooting plants)
- Terrestrial plants: Air, soil, and water (soil moisture/rain)
- Emergent/floating plants: Multiple compartments
Key endpoints:
- Bioaccumulation (incorporation into tissues)
- Photosynthesis inhibition (acute effects)
- Growth inhibition (biomass, cell counts, size increase)
- Seedling emergence (germination and early development)
- Root morphology and metabolism
Challenge: Soil and sediment exposure introduces variability from redox conditions and organic matter content affecting chemical behavior.
🦠 Microorganisms in testing
Importance:
- Base of all ecosystems
- Vital for nutrient cycling (carbon, nitrogen)
- Perform essential ecosystem services
- Highly diverse metabolically
Protection goals:
- Biodiversity: Protecting species diversity
- Ecosystem services: Protecting functional processes (e.g., nitrogen transformation, water purification)
Test types:
Single species tests:
- Example: Ames test (Salmonella typhimurium for mutagenicity)
- Example: Freshwater algae/cyanobacteria growth inhibition (OECD 201)
- Advantage: Reproducible, standardized
- Limitation: Ecological relevance debatable; assumes similar sensitivity to relevant species
Community tests:
- Test whole communities exposed together
- Pollution-induced community tolerance (PICT) method
- Detects shift from sensitive to tolerant species
- Challenge: Difficult to attribute changes solely to toxic effects vs. species interactions
Process tests:
- Measure microbial processes (e.g., nitrogen transformation, carbon transformation)
- Example: OECD 216 - Soil nitrogen transformation test
- Clover meal → ammonia → nitrite → nitrate
- Key insight: Process may be maintained even if some species are intoxicated, due to growth of tolerant species
- Generally less sensitive than single species tests
Don't confuse: Short-term vs. long-term microbial tests - shorter tests often MORE sensitive because growth during longer tests allows resistant mutants to develop and take over.
🐦 Specialized testing: Birds
🦅 Why birds are important models
Physiological uniqueness:
- Oviparous (egg-laying with hard shells)
- Concentrated exposure to maternally transferred material in egg
- Embryos regulate own hormones early (no maternal physiological interference)
- High body temperature (40.6°C) and metabolic rate
- Rapid growth rate (especially altricial species)
Ecological importance:
- Diverse, abundant, widespread
- Inhabit human-altered habitats (agriculture)
- Essential ecosystem roles (seed dispersal, biological control, scavenger function)
- Often iconic species with public appeal
Exposure routes in agricultural settings:
- Feeding on treated crop
- Feeding on weeds or treated weed seeds
- Feeding on ground-dwelling or foliar invertebrates
- Feeding on earthworms in treated soil
- Drinking contaminated water
- Feeding on fish in contaminated streams
🧪 Avian toxicity tests
Acute oral toxicity:
- Gavage or capsule dosing at test start
- OECD 223: Sequential design, average 26 birds, can stop when accuracy sufficient
- USEPA: 60 birds (10 per dose × 5 doses + 10 controls)
- Derives LD₅₀ (mg/kg body weight/day)
- Species: Bobwhite quail, Japanese quail, mallard duck, zebra finch, budgerigar
Reproduction testing:
- One-generation tests in bobwhite quail and/or mallard
- Substance mixed into diet for 10 weeks before egg-laying
- Egg-laying period: at least 10 weeks
- Endpoints: Adult body weight, food consumption, reproductive parameters, 14-day old surviving chicks/ducklings
Avoidance testing:
- Assesses whether birds avoid contaminated food (especially seed treatments)
- Can reduce exposure risk but confounds dietary toxicity estimates
- Often conducted as pen (semi-field) studies
Endocrine disruptor testing:
- Two-generation test using Japanese quail
- Why Japanese quail: Precocial species (sexual differentiation occurs in egg), young mature and breed within 12 months
- Debate: Need for altricial species test (e.g., zebra finch) to capture different developmental patterns
Field studies:
- Test effects on multiple species simultaneously under actual exposure conditions
- Methods: Corpse searches, censusing, radiotracking
- Challenge: Defining relevant species for other locations
🧬 Alternative and molecular methods
🔬 In vitro toxicity testing
In vitro: Testing using tissues, cells, or proteins (literally "in glass"), now typically in plastic microtiter well-plates.
Advantages:
- Small test volumes
- Short test durations (15 minutes to 48 hours)
- Medium to high throughput
- Mechanism-specific responses
- Reduces animal use (3Rs: Reduce, Refine, Replace)
Protein-based assays:
Ligand binding assays:
- Purified protein incubated with test substance
- Determines if substance binds protein and inhibits natural ligand binding
- Uses radiolabeled or fluorescently labeled ligands
- Example: Estrogen receptor binding assay with radiolabeled estradiol
Enzyme inhibition assays:
- Measures decrease in substrate conversion rate
- Quantified by spectrophotometry or fluorescence
- Example: Acetylcholinesterase inhibition assay
🧫 Cell-based assays
Cell culture types:
| Type | Description | Advantages | Disadvantages |
|---|
| Primary culture | Cells directly isolated from donor | Closely resemble in vivo physiology | Slow division, specific conditions, finite, genetic variation between donors |
| Finite cell line | Subcultures from primary culture | Same as primary | Limited passages (20-60 divisions) before senescence |
| Continuous cell line | Immortalized cells (indefinite lifespan) | Quick proliferation, easy to culture/manipulate | Different genotype/phenotype than healthy cells, behave like cancer cells, lost some capacities |
Stem cell differentiation models:
Potency levels:
- Totipotent: Can differentiate into all cell types including extraembryonic (morula stage)
- Pluripotent: Can differentiate into all cell types except extraembryonic (inner cell mass)
- Multipotent: Can differentiate into restricted number of cell types (germ layers)
- Unipotent: Committed to single cell type
Embryonic stem cells (ESCs):
- Isolated from embryos at various stages
- Can divide indefinitely while undifferentiated
- Differentiated by manipulating culture conditions (growth factors, hormones, etc.)
- Ethical concern: Requires embryo destruction for human ESCs
Induced pluripotent stem cells (iPSCs):
- Differentiated cells reprogrammed to pluripotent state
- Exposed to reprogramming factors (transcription factors)
- Can then differentiate into any cell type
- Advantage: Avoids embryo destruction
- Alternative: Transdifferentiation (direct conversion between differentiated cell types without pluripotent stage)
Cell-based endpoints:
- Cell viability (mitochondrial function, membrane damage, metabolism)
- Cell growth
- Cell kinetics (absorption, elimination, biotransformation)
- Transcriptome, proteome, metabolome changes
- Cell-type specific functioning
- Effects on differentiation process
Reporter gene bioassays:
- Genetically modified cells/bacteria with reporter protein gene
- Expression triggered by receptor-toxicant interaction
- Measured as color, fluorescence, or luminescence change
- Used to screen for receptor activation/inactivation
🔮 Future developments
3D cell culturing:
- More realistic than 2D monolayers
- Includes cell-cell interactions, polarization, extracellular matrix, diffusion gradients
- Epithelial cells can be grown at air-liquid interface
Cell co-culturing:
- Different cell types cultured together
- Example: Differentiated cell + liver cell (for metabolism)
- Mimics organ-level interactions
Organ-on-a-chip:
- Different cell types in miniaturized channels
- Microfluidic system mimics blood flow
- Can expose to toxicants through "circulation"
Human body-on-a-chip:
- Multiple organ compartments interconnected
- Microfluidic circulatory system
- Reflects complex ADME processes
- Current status: In development, some impracticalities remain
Don't confuse: In vitro advantages for mechanism studies vs. limitations for in vivo extrapolation - cell cultures lack toxicokinetic processes (absorption, distribution, elimination), repair mechanisms, feedback loops, and tissue/organ interactions present in whole organisms.
🔍 Human toxicity testing
📋 General principles
Two main aims:
- Identify potential adverse effects on humans (hazard identification)
- Establish dose/concentration-response relationships for safe exposure levels
International harmonization:
- WHO and OECD develop testing guidelines
- OECD Mutual Acceptance of Data (MAD) system
- Built on OECD Test Guidelines and Good Laboratory Practice (GLP) principles
- Data generated in one member country accepted in all member countries
Alternative methods (3Rs):
- (Quantitative) Structure-Activity Relationships ((Q)SARs)
- In vitro tests (preferably human-origin cells/tissues)
- Read-across (using data from structurally related chemicals)
- Integrated Approaches to Testing and Assessment (IATA)
- Intelligent Testing Strategies (ITS)
Core test elements:
Test substance characterization:
- Chemical structure, composition, purity
- Impurities (nature and quantity)
- Stability
- Physicochemical properties (lipophilicity, density, vapor pressure)
Route of administration:
- Oral, dermal, or inhalation
- Based on physical-chemical properties and predominant human exposure route
Dose selection:
- Typically ≥3 dose levels (low, mid, high) plus control
- Increments between doses: factors of 2-10
- High dose: Produces toxicity without severe suffering or >10% mortality
- Mid dose: Produces slight toxicity
- Low dose: No toxicity
- Informed by toxicokinetic data and range-finding studies
Animal species:
- Usually small laboratory rodents (rats) of both sexes
- Economic and logistic reasons
- Sufficient numbers for statistical analysis
- Specialized tests may use guinea pigs, rabbits, dogs, non-human primates
Test duration:
- Acute: Single dose, effects within 14 days
- Subacute: 28 days (rats)
- Semi-chronic/sub-chronic: 90 days (rats)
- Chronic: 2 years lifetime (rats)
Parameters studied:
- Biochemical organ function
- Physiological measurements
- Metabolic and hematological information
- Extensive histopathological examination
- More parameters in longer, more expensive tests
Quality requirements:
- Good Laboratory Practice (GLP) compliance
- Qualified personnel at every level
- Detailed reporting for regulatory evaluation
- Statistical analysis (significance vs. biological relevance)
- Derive NOAEL, LOAEL, or benchmark doses (BMDs)
🧪 In vitro human toxicity tests
Cytotoxicity assays:
Trypan Blue Exclusion (TBE):
- Live cells exclude dye (clear cytoplasm)
- Dead cells take up dye (blue cytoplasm)
- Count viable/dead cells with hemacytometer
- Advantage: Simple, inexpensive, indicates membrane integrity
- Disadvantage: ~10% counting errors
Neutral Red Uptake (NRU):
- Viable cells incorporate neutral red into lysosomes
- After washing, dye released under acidified conditions
- Measured by spectrophotometry
- Based on universal cell functions (membrane integrity, energy, transport)
MTT assay:
- Mitochondrial enzymes reduce yellow MTT to purple formazan crystals
- Reflects number of viable cells
- Solubilize with DMSO, measure absorbance
- Advantage: Easy, safe, highly reproducible
- Disadvantage: Requires DMSO to solubilize insoluble product
Skin toxicity tests:
Skin corrosion/irritation:
- 3D human skin model (Episkin)
- Topical application of test substance
- Cell viability assessed by MTT
- Corrosive/irritant if viability decreases below threshold (LD₅₀)
- Replaces rabbit Draize test
Phototoxicity (3T3 NRU PT):
- Mouse fibroblast cell line (Balb/c 3T3)
- Compare cytotoxicity with/without simulated solar light
- Neutral red uptake measured 24h after treatment
- Light exposure may alter cell surface, reducing dye uptake
Skin sensitization:
- Tests address key biological events in sensitization process:
- Haptenation (chemical binding to skin proteins)
- Keratinocyte signaling (cytokine release, cytoprotective pathways)
- Dendritic cell maturation and mobilization
- T-cell proliferation in lymph nodes
Available non-animal methods:
- Direct Peptide Reactivity Assay (DPRA)
- KeratinoSens (ARE-Nrf2 luciferase test)
- h-CLAT (Human Cell Line Activation Test)
- U-SENS (U937 cell line activation)
- IL-8 Luc assay (Interleukin-8 reporter gene)
Carcinogenicity assays:
Genotoxic (GTX) carcinogens:
- Directly interact with DNA
- Cause DNA damage or chromosomal aberrations
- Tests: Ames test, E. coli reverse mutation, chromosome aberration assay, gene mutation test, micronucleus test
- Can use in vitro or in vivo approaches
Non-genotoxic (NGTX) carcinogens:
- Don't cause direct DNA damage
- Affect gene expression, signal transduction, cell structures, cell cycle
- Challenge: Large number of potential pathways makes identification difficult
- Tests: Two-year rodent assay, cell transformation assay
- Fewer in vitro alternatives available
📊 Epidemiology and molecular markers
📈 Environmental epidemiology basics
Epidemiology: The study of distribution and determinants of health-related states or events in specified populations, and application to prevention and control of health problems.
Key terms:
- Cohort: Group of people followed over time
- Determinant/risk factor: Factor (causally) related to health outcome
- Outcome: Disease (morbidity) or death (mortality)
- Target population: People of interest
- Study population/sample: Representative subset actually studied
Study designs:
Cross-sectional:
- Determinant and outcome measured at same time
- Quick and cheap
- Limitation: Cannot conclude causality (lacks temporality)
- Hypothesis-generating
Case-control:
- Sample selected based on outcome
- Determinant measured retrospectively
- Cases matched with controls (same disease risk)
- Advantages: Suitable for low incidence diseases, long latency periods
- Limitations: Recall bias, weak evidence for causality
- Calculates odds ratios (OR)
Cohort (prospective):
- Determinant measured at start
- Incidence measured after follow-up
- Starts with people at risk but not yet affected
- Advantages: Can conclude causal relationship (temporality), multiple outcomes
- Limitations: Not suitable for low incidence or long latency, attrition (loss to follow-up)
- Calculates relative risk (RR)
Nested case-control:
- Case-control study within cohort study
- Useful when few cases in cohort
Ecological:
- Uses aggregated data (not individual)
- Geographical or temporal comparisons
- Advantages: Uses published statistics, cheap, fast
- Limitations: Groups may differ in unmeasured ways, can't link individual exposure to individual outcome
- Hypothesis-generating
Experimental (RCT):
- Participants randomly assigned to intervention or control
- Variations: Cluster-randomized, crossover, waiting list designs
- Strongest evidence for causality
Confounding and effect modification:
- Confounder: Third factor influences both outcome and determinant
- Effect modifier: Association between exposure and outcome differs for certain groups
- Solution for both: Stratification (analyze groups separately)
🧬 Human biomonitoring
Human biomonitoring (HBM): Assessment of human exposure to chemicals by quantitative analysis of compounds, metabolites, or reaction products in human samples.
Sample types:
- Blood, urine, feces, saliva, breast milk, sweat
- Hair, nails, teeth
Purpose:
- Obtain insight into population exposure (internal dose)
- Integrate with health data for impact assessment
- Often focuses on specific age groups (neonates, children, adolescents, adults, elderly)
Major HBM programs:
- German Environment Survey (GerES)
- US National Health and Nutrition Examination Survey (NHANES)
- Canadian Health Measures Survey
- Flemish Environment and Health Study
- Japan Environment and Children's Study
Cohort studies:
- Cross-sectional: Exposure and health data at one time point
- Longitudinal: Follow-up at intervals to track changes and time trends
- Often 100,000+ participants for statistical power
- Collect exposure data, health measures, questionnaires (diet, lifestyle, socioeconomic status)
Ethics requirements:
- Medical Ethical Approval Committee approval mandatory
- Documentation needed:
- Study protocol
- Privacy safeguarding statement
- Information letter for volunteers (informed consent)
Chemical distribution in body:
- Depends on physicochemical properties (lipophilicity, persistence)
- Phase I and II metabolism
- Lipophilic compounds: Stored in fat tissue
- Hydrophilic compounds: Excreted after metabolism or unchanged
- Matrix choice based on compound properties (blood for lipophilic, urine for metabolites)
Analytical procedure:
- Sample pretreatment (remove particles)
- Extraction (concentrate compounds, remove interfering matrix)
- Chromatographic separation (LC or GC)
- Mass spectrometry detection (MS)
- Quantification
Analytical challenges:
- Very low concentrations (pg/L in cord blood)
- Small sample volumes
- Background contamination (e.g., phthalates in environment)
- Solution for contamination: Measure metabolites instead of parent compound
- Need for high accuracy, high throughput
- Long-term storage requirements (-20°C or -80°C)
Don't confuse: Parent compound vs. metabolite measurement - measuring metabolites (e.g., DEHP metabolites instead of DEHP itself) ensures the chemical passed through the body and underwent metabolism, avoiding false positives from environmental contamination.
🌍 The exposome concept
Exposome: Measure of all human life-long exposures and how these relate to health (Wild, 2005).
Three domains:
1. Internal exposome:
- Metabolism
- Endogenous hormones
- Body morphology
- Physical activity
- Gut microbiota
- Inflammation
- Aging
2. Specific external exposome:
- Radiation
- Infections
- Chemical contaminants and pollutants
- Diet
- Lifestyle factors (tobacco, alcohol)
- Medical interventions
3. General external exposome:
- Social capital
- Education
- Financial status
- Psychological stress
- Urban-rural environment
- Climate
Tools for exposome assessment:
- Wearables for monitoring
- Exposure modeling
- Internal biological measurements
- Statistical and data science frameworks
- Machine learning algorithms
🔬 Meet-in-the-middle model
Purpose: Identify causal relationships linking exposures to disease.
Three-step approach:
- Association between exposure and biomarkers of exposure
- Relationship between exposure and intermediate omics biomarkers (early effects)
- Relation between disease outcome and intermediate omics biomarkers
Principle: Causal association reinforced if found in all three steps.
Molecular markers studied:
Gene expression (transcriptomics):
- Changes at mRNA level
- Candidate approach (specific mRNAs) or genome-wide (microarray, NGS)
- Examples: Transcriptomic profiles for dioxin exposure, diesel exhaust, smoking, prenatal exposures
Epigenetics:
- Heritable changes not affecting DNA sequence
- DNA methylation: Most widely studied
- Methyl groups added to DNA
- Alters expression without changing sequence
- Can have transgenerational effects
- Example: Dutch Hunger Winter study - prenatal famine exposure affected IGF2 methylation 60 years later
- Histone modifications: Post-translational modifications, induced by oxidative stress
- microRNAs: Small noncoding RNAs regulating gene expression
Metabolomics:
- Study of all small molecule metabolic products
- Includes self-made metabolites, nutrients, pollutants, microbial products
- ~2900 known human metabolites (vs. ~30,000 genes)
- Strong statistical power due to lower number of features
- Can characterize biochemical changes from xenobiotic metabolism
Challenges:
- Difficult to obtain samples
- Need large study populations
- Complex statistical methods
- Tissue-specific effects (e.g., DNA methylation correlation varies by CpG site)
- Correlation between levels often poor (transcript ≠ protein ≠ metabolite)
⚙️ Quality control and standardization
✅ Validity criteria
Purpose: Control quality of toxicity test outcomes.
Typical criteria:
- Minimum % survival of control organisms
- Minimum growth rate or offspring production in controls
- Limited variation (<30%) in replicate control data
- If criteria not met: Results prone to doubt, may not be accepted
Control types:
Negative control:
- Non-exposed organisms
- Used to check validity criteria
- Monitor condition of test organisms
Solvent control:
- When test chemical added using solvent
- If response differs significantly from negative control: Use as control for analysis
- If no significant difference: Pool with negative control
Positive control:
- Chemical with known toxicity
- Tested frequently
- Checks if long-term culturing changes organism sensitivity
📏 Standardization importance
Organized by:
- Organization for Economic Co-operation and Development (OECD)
- International Standardization Organization (ISO)
- ASTM International
Aims:
- Reduce variation in test outcomes
- Carefully describe methods for:
- Culturing and handling organisms
- Test procedures
- Test media properties and composition
- Exposure conditions
- Data analysis
Process:
- Based on extensive round-robin testing (multiple laboratories)
- Regulatory bodies require standardized tests for chemical registration
- Example: REACH in Europe requires OECD guidelines
What is standardized:
- Test organism selection and care
- Exposure media
- Test conditions and duration
- Endpoints
- Environmental variables (caging, diet, temperature, humidity)
- Personnel requirements
- Animal welfare considerations
🔢 Replication and design
Biological replication:
- Determined by number of independent samples/isolations
- Not by technical replication later in procedure
- Sufficient replication needed to cope with biological variation
Test design considerations:
- Careful dose level selection and spacing
- Adequate to fulfill regulatory requirements
- Enable proper toxicity data estimates
- Minimize variation while maximizing information
Good Laboratory Practice (GLP):
- Quality control: Minimize errors, maximize accuracy and validity
- Quality assurance: Ensure procedures followed according to regulations
- Qualified personnel at every level
- Detailed documentation and reporting
- Electronic data processing systems for accuracy
Don't confuse: Number of dose levels vs. number of replicates - typically ≥3 dose levels plus control for dose-response, with multiple biological replicates at each level for statistical power.
This document provides a comprehensive overview of toxicity testing methods, from traditional whole-organism assays to cutting-edge molecular approaches, emphasizing the importance of standardization, quality control, and the ongoing shift toward alternative methods that reduce animal use while maintaining scientific rigor.