- •CONTENTS
- •Preface
- •Contributors
- •1 Introduction to Toxicology
- •1.1 Definition and Scope, Relationship to Other Sciences, and History
- •1.1.2 Relationship to Other Sciences
- •1.1.3 A Brief History of Toxicology
- •1.3 Sources of Toxic Compounds
- •1.3.1 Exposure Classes
- •1.3.2 Use Classes
- •1.4 Movement of Toxicants in the Environment
- •Suggested Reading
- •2.1 Introduction
- •2.2 Cell Culture Techniques
- •2.2.1 Suspension Cell Culture
- •2.2.2 Monolayer Cell Culture
- •2.2.3 Indicators of Toxicity in Cultured Cells
- •2.3 Molecular Techniques
- •2.3.1 Molecular Cloning
- •2.3.2 cDNA and Genomic Libraries
- •2.3.3 Northern and Southern Blot Analyses
- •2.3.4 Polymerase Chain Reaction (PCR)
- •2.3.5 Evaluation of Gene Expression, Regulation, and Function
- •2.4 Immunochemical Techniques
- •Suggested Reading
- •3.1 Introduction
- •3.2 General Policies Related to Analytical Laboratories
- •3.2.1 Standard Operating Procedures (SOPs)
- •3.2.2 QA/QC Manuals
- •3.2.3 Procedural Manuals
- •3.2.4 Analytical Methods Files
- •3.2.5 Laboratory Information Management System (LIMS)
- •3.3 Analytical Measurement System
- •3.3.1 Analytical Instrument Calibration
- •3.3.2 Quantitation Approaches and Techniques
- •3.4 Quality Assurance (QA) Procedures
- •3.5 Quality Control (QC) Procedures
- •3.6 Summary
- •Suggested Reading
- •4 Exposure Classes, Toxicants in Air, Water, Soil, Domestic and Occupational Settings
- •4.1 Air Pollutants
- •4.1.1 History
- •4.1.2 Types of Air Pollutants
- •4.1.3 Sources of Air Pollutants
- •4.1.4 Examples of Air Pollutants
- •4.1.5 Environmental Effects
- •4.2 Water and Soil Pollutants
- •4.2.1 Sources of Water and Soil Pollutants
- •4.2.2 Examples of Pollutants
- •4.3 Occupational Toxicants
- •4.3.1 Regulation of Exposure Levels
- •4.3.2 Routes of Exposure
- •4.3.3 Examples of Industrial Toxicants
- •Suggested Reading
- •5 Classes of Toxicants: Use Classes
- •5.1 Introduction
- •5.2 Metals
- •5.2.1 History
- •5.2.2 Common Toxic Mechanisms and Sites of Action
- •5.2.3 Lead
- •5.2.4 Mercury
- •5.2.5 Cadmium
- •5.2.6 Chromium
- •5.2.7 Arsenic
- •5.2.8 Treatment of Metal Poisoning
- •5.3 Agricultural Chemicals (Pesticides)
- •5.3.1 Introduction
- •5.3.3 Organochlorine Insecticides
- •5.3.4 Organophosphorus Insecticides
- •5.3.5 Carbamate Insecticides
- •5.3.6 Botanical Insecticides
- •5.3.7 Pyrethroid Insecticides
- •5.3.8 New Insecticide Classes
- •5.3.9 Herbicides
- •5.3.10 Fungicides
- •5.3.11 Rodenticides
- •5.3.12 Fumigants
- •5.3.13 Conclusions
- •5.4 Food Additives and Contaminants
- •5.5 Toxins
- •5.5.1 History
- •5.5.2 Microbial Toxins
- •5.5.3 Mycotoxins
- •5.5.4 Algal Toxins
- •5.5.5 Plant Toxins
- •5.5.6 Animal Toxins
- •5.6 Solvents
- •5.7 Therapeutic Drugs
- •5.8 Drugs of Abuse
- •5.9 Combustion Products
- •5.10 Cosmetics
- •Suggested Reading
- •6 Absorption and Distribution of Toxicants
- •6.1 Introduction
- •6.2 Cell Membranes
- •6.3 Mechanisms of Transport
- •6.3.1 Passive Diffusion
- •6.4 Physicochemical Properties Relevant to Diffusion
- •6.4.1 Ionization
- •6.5 Routes of Absorption
- •6.5.1 Extent of Absorption
- •6.5.2 Gastrointestinal Absorption
- •6.5.3 Dermal Absorption
- •6.5.4 Respiratory Penetration
- •6.6 Toxicant Distribution
- •6.6.1 Physicochemical Properties and Protein Binding
- •6.7 Toxicokinetics
- •Suggested Reading
- •7 Metabolism of Toxicants
- •7.1 Introduction
- •7.2 Phase I Reactions
- •7.2.4 Nonmicrosomal Oxidations
- •7.2.5 Cooxidation by Cyclooxygenases
- •7.2.6 Reduction Reactions
- •7.2.7 Hydrolysis
- •7.2.8 Epoxide Hydration
- •7.2.9 DDT Dehydrochlorinase
- •7.3 Phase II Reactions
- •7.3.1 Glucuronide Conjugation
- •7.3.2 Glucoside Conjugation
- •7.3.3 Sulfate Conjugation
- •7.3.4 Methyltransferases
- •7.3.7 Acylation
- •7.3.8 Phosphate Conjugation
- •Suggested Reading
- •8 Reactive Metabolites
- •8.1 Introduction
- •8.2 Activation Enzymes
- •8.3 Nature and Stability of Reactive Metabolites
- •8.4 Fate of Reactive Metabolites
- •8.4.1 Binding to Cellular Macromolecules
- •8.4.2 Lipid Peroxidation
- •8.4.3 Trapping and Removal: Role of Glutathione
- •8.5 Factors Affecting Toxicity of Reactive Metabolites
- •8.5.1 Levels of Activating Enzymes
- •8.5.2 Levels of Conjugating Enzymes
- •8.5.3 Levels of Cofactors or Conjugating Chemicals
- •8.6 Examples of Activating Reactions
- •8.6.1 Parathion
- •8.6.2 Vinyl Chloride
- •8.6.3 Methanol
- •8.6.5 Carbon Tetrachloride
- •8.6.8 Acetaminophen
- •8.6.9 Cycasin
- •8.7 Future Developments
- •Suggested Reading
- •9.1 Introduction
- •9.2 Nutritional Effects
- •9.2.1 Protein
- •9.2.2 Carbohydrates
- •9.2.3 Lipids
- •9.2.4 Micronutrients
- •9.2.5 Starvation and Dehydration
- •9.2.6 Nutritional Requirements in Xenobiotic Metabolism
- •9.3 Physiological Effects
- •9.3.1 Development
- •9.3.2 Gender Differences
- •9.3.3 Hormones
- •9.3.4 Pregnancy
- •9.3.5 Disease
- •9.3.6 Diurnal Rhythms
- •9.4 Comparative and Genetic Effects
- •9.4.1 Variations Among Taxonomic Groups
- •9.4.2 Selectivity
- •9.4.3 Genetic Differences
- •9.5 Chemical Effects
- •9.5.1 Inhibition
- •9.5.2 Induction
- •9.5.3 Biphasic Effects: Inhibition and Induction
- •9.6 Environmental Effects
- •9.7 General Summary and Conclusions
- •Suggested Reading
- •10 Elimination of Toxicants
- •10.1 Introduction
- •10.2 Transport
- •10.3 Renal Elimination
- •10.4 Hepatic Elimination
- •10.4.2 Active Transporters of the Bile Canaliculus
- •10.5 Respiratory Elimination
- •10.6 Conclusion
- •Suggested Reading
- •11 Acute Toxicity
- •11.1 Introduction
- •11.2 Acute Exposure and Effect
- •11.3 Dose-response Relationships
- •11.4 Nonconventional Dose-response Relationships
- •11.5 Mechanisms of Acute Toxicity
- •11.5.1 Narcosis
- •11.5.2 Acetylcholinesterase Inhibition
- •11.5.3 Ion Channel Modulators
- •11.5.4 Inhibitors of Cellular Respiration
- •Suggested Reading
- •12 Chemical Carcinogenesis
- •12.1 General Aspects of Cancer
- •12.2 Human Cancer
- •12.2.1 Causes, Incidence, and Mortality Rates of Human Cancer
- •12.2.2 Known Human Carcinogens
- •12.3 Classes of Agents Associated with Carcinogenesis
- •12.3.2 Epigenetic Agents
- •12.4 General Aspects of Chemical Carcinogenesis
- •12.5 Initiation-Promotion Model for Chemical Carcinogenesis
- •12.6 Metabolic Activation of Chemical Carcinogens and DNA Adduct Formation
- •12.7 Oncogenes
- •12.8 Tumor Suppressor Genes
- •12.8.1 Inactivation of Tumor Suppressor Genes
- •12.8.2 p53 Tumor Suppressor Gene
- •12.9 General Aspects of Mutagenicity
- •12.10 Usefulness and Limitations of Mutagenicity Assays for the Identification of Carcinogens
- •Suggested Reading
- •13 Teratogenesis
- •13.1 Introduction
- •13.2 Principles of Teratology
- •13.3 Mammalian Embryology Overview
- •13.4 Critical Periods
- •13.5 Historical Teratogens
- •13.5.1 Thalidomide
- •13.5.2 Accutane (Isotetrinoin)
- •13.5.3 Diethylstilbestrol (DES)
- •13.5.4 Alcohol
- •13.6 Testing Protocols
- •13.6.1 FDA Guidelines for Reproduction Studies for Safety Evaluation of Drugs for Human Use
- •13.6.3 Alternative Test Methods
- •13.7 Conclusions
- •Suggested Reading
- •14 Hepatotoxicity
- •14.1 Introduction
- •14.1.1 Liver Structure
- •14.1.2 Liver Function
- •14.2 Susceptibility of the Liver
- •14.3 Types of Liver Injury
- •14.3.1 Fatty Liver
- •14.3.2 Necrosis
- •14.3.3 Apoptosis
- •14.3.4 Cholestasis
- •14.3.5 Cirrhosis
- •14.3.6 Hepatitis
- •14.3.7 Oxidative Stress
- •14.3.8 Carcinogenesis
- •14.4 Mechanisms of Hepatotoxicity
- •14.5 Examples of Hepatotoxicants
- •14.5.1 Carbon Tetrachloride
- •14.5.2 Ethanol
- •14.5.3 Bromobenzene
- •14.5.4 Acetaminophen
- •14.6 Metabolic Activation of Hepatotoxicants
- •Suggested Reading
- •15 Nephrotoxicity
- •15.1 Introduction
- •15.1.1 Structure of the Renal System
- •15.1.2 Function of the Renal System
- •15.2 Susceptibility of the Renal System
- •15.3 Examples of Nephrotoxicants
- •15.3.1 Metals
- •15.3.2 Aminoglycosides
- •15.3.3 Amphotericin B
- •15.3.4 Chloroform
- •15.3.5 Hexachlorobutadiene
- •Suggested Reading
- •16 Toxicology of the Nervous System
- •16.1 Introduction
- •16.2 The Nervous system
- •16.2.1 The Neuron
- •16.2.2 Neurotransmitters and their Receptors
- •16.2.3 Glial Cells
- •16.3 Toxicant Effects on the Nervous System
- •16.3.1 Structural Effects of Toxicants on Neurons
- •16.3.2 Effects of Toxicants on Other Cells
- •16.4 Neurotoxicity Testing
- •16.4.1 In vivo Tests of Human Exposure
- •16.4.2 In vivo Tests of Animal Exposure
- •16.4.3 In vitro Neurochemical and Histopathological End Points
- •16.5 Summary
- •Suggested Reading
- •17 Endocrine System
- •17.1 Introduction
- •17.2 Endocrine System
- •17.2.1 Nuclear Receptors
- •17.3 Endocrine Disruption
- •17.3.1 Hormone Receptor Agonists
- •17.3.2 Hormone Receptor Antagonists
- •17.3.3 Organizational versus Activational Effects of Endocrine Toxicants
- •17.3.4 Inhibitors of Hormone Synthesis
- •17.3.5 Inducers of Hormone Clearance
- •17.3.6 Hormone Displacement from Binding Proteins
- •17.4 Incidents of Endocrine Toxicity
- •17.4.1 Organizational Toxicity
- •17.4.2 Activational Toxicity
- •17.4.3 Hypothyroidism
- •17.5 Conclusion
- •Suggested Reading
- •18 Respiratory Toxicity
- •18.1 Introduction
- •18.1.1 Anatomy
- •18.1.2 Cell Types
- •18.1.3 Function
- •18.2 Susceptibility of the Respiratory System
- •18.2.1 Nasal
- •18.2.2 Lung
- •18.3 Types of Toxic Response
- •18.3.1 Irritation
- •18.3.2 Cell Necrosis
- •18.3.3 Fibrosis
- •18.3.4 Emphysema
- •18.3.5 Allergic Responses
- •18.3.6 Cancer
- •18.3.7 Mediators of Toxic Responses
- •18.4 Examples of Lung Toxicants Requiring Activation
- •18.4.1 Introduction
- •18.4.2 Monocrotaline
- •18.4.3 Ipomeanol
- •18.4.4 Paraquat
- •18.5 Defense Mechanisms
- •Suggested Reading
- •19 Immunotoxicity
- •19.1 Introduction
- •19.2 The Immune System
- •19.3 Immune Suppression
- •19.4 Classification of Immune-Mediated Injury (Hypersensitivity)
- •19.5 Effects of Chemicals on Allergic Disease
- •19.5.1 Allergic Contact Dermatitis
- •19.5.2 Respiratory Allergens
- •19.5.3 Adjuvants
- •19.6 Emerging Issues: Food Allergies, Autoimmunity, and the Developing Immune System
- •Suggested Reading
- •20 Reproductive System
- •20.1 Introduction
- •20.2 Male Reproductive Physiology
- •20.3 Mechanisms and Targets of Male Reproductive Toxicants
- •20.3.1 General Mechanisms
- •20.3.2 Effects on Germ Cells
- •20.3.3 Effects on Spermatogenesis and Sperm Quality
- •20.3.4 Effects on Sexual Behavior
- •20.3.5 Effects on Endocrine Function
- •20.4 Female Reproductive Physiology
- •20.5 Mechanisms and Targets of Female Reproductive Toxicants
- •20.5.1 Tranquilizers, Narcotics, and Social Drugs
- •20.5.2 Endocrine Disruptors (EDs)
- •20.5.3 Effects on Germ Cells
- •20.5.4 Effects on the Ovaries and Uterus
- •20.5.5 Effects on Sexual Behavior
- •Suggested Reading
- •21 Toxicity Testing
- •21.1 Introduction
- •21.2 Experimental Administration of Toxicants
- •21.2.1 Introduction
- •21.2.2 Routes of Administration
- •21.3 Chemical and Physical Properties
- •21.4 Exposure and Environmental Fate
- •21.5 In vivo Tests
- •21.5.1 Acute and Subchronic Toxicity Tests
- •21.5.2 Chronic Tests
- •21.5.3 Reproductive Toxicity and Teratogenicity
- •21.5.4 Special Tests
- •21.6 In vitro and Other Short-Term Tests
- •21.6.1 Introduction
- •21.6.2 Prokaryote Mutagenicity
- •21.6.3 Eukaryote Mutagenicity
- •21.6.4 DNA Damage and Repair
- •21.6.5 Chromosome Aberrations
- •21.6.6 Mammalian Cell Transformation
- •21.6.7 General Considerations and Testing Sequences
- •21.7 Ecological Effects
- •21.7.1 Laboratory Tests
- •21.7.2 Simulated Field Tests
- •21.7.3 Field Tests
- •21.8 Risk Analysis
- •21.9 The Future of Toxicity Testing
- •Suggested Reading
- •22 Forensic and Clinical Toxicology
- •22.1 Introduction
- •22.2 Foundations of Forensic Toxicology
- •22.3 Courtroom Testimony
- •22.4.1 Documentation Practices
- •22.4.2 Considerations for Forensic Toxicological Analysis
- •22.4.3 Drug Concentrations and Distribution
- •22.5 Laboratory Analyses
- •22.5.1 Colorimetric Screening Tests
- •22.5.2 Thermal Desorption
- •22.5.6 Enzymatic Immunoassay
- •22.6 Analytical Schemes for Toxicant Detection
- •22.7 Clinical Toxicology
- •22.7.1 History Taking
- •22.7.2 Basic Operating Rules in the Treatment of Toxicosis
- •22.7.3 Approaches to Selected Toxicoses
- •Suggested Reading
- •23 Prevention of Toxicity
- •23.1 Introduction
- •23.2 Legislation and Regulation
- •23.2.1 Federal Government
- •23.2.2 State Governments
- •23.2.3 Legislation and Regulation in Other Countries
- •23.3 Prevention in Different Environments
- •23.3.1 Home
- •23.3.2 Workplace
- •23.3.3 Pollution of Air, Water, and Land
- •23.4 Education
- •Suggested Reading
- •24 Human Health Risk Assessment
- •24.1 Introduction
- •24.2 Risk Assessment Methods
- •24.2.2 Exposure Assessment
- •24.2.3 Dose Response and Risk Characterization
- •24.3 Noncancer Risk Assessment
- •24.3.1 Default Uncertainty and Modifying Factors
- •24.3.2 Derivation of Developmental Toxicant RfD
- •24.3.3 Determination of RfD and RfC of Naphthalene with the NOAEL Approach
- •24.3.4 Benchmark Dose Approach
- •24.3.5 Determination of BMD and BMDL for ETU
- •24.3.6 Quantifying Risk for Noncarcinogenic Effects: Hazard Quotient
- •24.3.7 Chemical Mixtures
- •24.4 Cancer Risk Assessment
- •24.5 PBPK Modeling
- •Suggested Reading
- •25 Analytical Methods in Toxicology
- •25.1 Introduction
- •25.2 Chemical and Physical Methods
- •25.2.1 Sampling
- •25.2.2 Experimental Studies
- •25.2.3 Forensic Studies
- •25.2.4 Sample Preparation
- •25.2.6 Spectroscopy
- •25.2.7 Other Analytical Methods
- •Suggested Reading
- •26 Basics of Environmental Toxicology
- •26.1 Introduction
- •26.2 Environmental Persistence
- •26.2.1 Abiotic Degradation
- •26.2.2 Biotic Degradation
- •26.2.3 Nondegradative Elimination Processes
- •26.3 Bioaccumulation
- •26.4 Toxicity
- •26.4.1 Acute Toxicity
- •26.4.2 Mechanisms of Acute Toxicity
- •26.4.3 Chronic Toxicity
- •26.4.5 Abiotic and Biotic Interactions
- •26.5 Conclusion
- •Suggested Reading
- •27.1 Introduction
- •27.2 Sources of Toxicants to the Environment
- •27.3 Transport Processes
- •27.3.1 Advection
- •27.3.2 Diffusion
- •27.4 Equilibrium Partitioning
- •27.5 Transformation Processes
- •27.5.1 Reversible Reactions
- •27.5.2 Irreversible Reactions
- •27.6 Environmental Fate Models
- •Suggested Reading
- •28 Environmental Risk Assessment
- •28.1 Introduction
- •28.2 Formulating the Problem
- •28.2.1 Selecting Assessment End Points
- •28.2.2 Developing Conceptual Models
- •28.2.3 Selecting Measures
- •28.3 Analyzing Exposure and Effects Information
- •28.3.1 Characterizing Exposure
- •28.3.2 Characterizing Ecological Effects
- •28.4 Characterizing Risk
- •28.4.1 Estimating Risk
- •28.4.2 Describing Risk
- •28.5 Managing Risk
- •Suggested Reading
- •29 Future Considerations for Environmental and Human Health
- •29.1 Introduction
- •29.2 Risk Management
- •29.3 Risk Assessment
- •29.4 Hazard and Exposure Assessment
- •29.5 In vivo Toxicity
- •29.6 In vitro Toxicity
- •29.7 Biochemical and Molecular Toxicology
- •29.8 Development of Selective Toxicants
- •Glossary
- •Index
CHAPTER 1
Introduction to Toxicology
ERNEST HODGSON
1.1 DEFINITION AND SCOPE, RELATIONSHIP TO OTHER SCIENCES, AND HISTORY
1.1.1Definition and Scope
Toxicology can be defined as that branch of science that deals with poisons, and a poison can be defined as any substance that causes a harmful effect when administered, either by accident or design, to a living organism. By convention, toxicology also includes the study of harmful effects caused by physical phenomena, such as radiation of various kinds and noise. In practice, however, many complications exist beyond these simple definitions, both in bringing more precise meaning to what constitutes a poison and to the measurement of toxic effects. Broader definitions of toxicology, such as “the study of the detection, occurrence, properties, effects, and regulation of toxic substances,” although more descriptive, do not resolve the difficulties. Toxicity itself can rarely, if ever, be defined as a single molecular event but is, rather, a cascade of events starting with exposure, proceeding through distribution and metabolism, and ending with interaction with cellular macromolecules (usually DNA or protein) and the expression of a toxic end point. This sequence may be mitigated by excretion and repair. It is to the complications, and to the science behind them and their resolution, that this textbook is dedicated, particularly to the how and why certain substances cause disruptions in biologic systems that result in toxic effects. Taken together, these difficulties and their resolution circumscribe the perimeter of the science of toxicology.
The study of toxicology serves society in many ways, not only to protect humans and the environment from the deleterious effects of toxicants but also to facilitate the development of more selective toxicants such as anticancer and other clinical drugs and pesticides.
Poison is a quantitative concept, almost any substance being harmful at some doses but, at the same time, being without harmful effect at some lower dose. Between these two limits there is a range of possible effects, from subtle long-term chronic toxicity to immediate lethality. Vinyl chloride may be taken as an example. It is a potent hepatotoxicant at high doses, a carcinogen with a long latent period at lower
A Textbook of Modern Toxicology, Third Edition, edited by Ernest Hodgson
ISBN 0-471-26508-X Copyright 2004 John Wiley & Sons, Inc.
3
4 INTRODUCTION TO TOXICOLOGY
doses, and apparently without effect at very low doses. Clinical drugs are even more poignant examples because, although therapeutic and highly beneficial at some doses, they are not without deleterious side effects and may be lethal at higher doses. Aspirin (acetylsalicylic acid), for example, is a relatively safe drug at recommended doses and is taken by millions of people worldwide. At the same time, chronic use can cause deleterious effects on the gastric mucosa, and it is fatal at a dose of about 0.2 to 0.5 g/kg. Approximately 15% of reported accidental deaths from poisoning in children result from ingestion of salicylates, particularly aspirin.
The importance of dose is well illustrated by metals that are essential in the diet but are toxic at higher doses. Thus iron, copper, magnesium, cobalt, manganese, and zinc can be present in the diet at too low a level (deficiency), at an appropriate level (maintenance), or at too high a level (toxic). The question of dose-response relationships is fundamental to toxicology (see Section 1.2).
The definition of a poison, or toxicant, also involves a qualitative biological aspect because a compound, toxic to one species or genetic strain, may be relatively harmless to another. For example, carbon tetrachloride, a potent hepatotoxicant in many species, is relatively harmless to the chicken. Certain strains of rabbit can eat Belladonna with impunity while others cannot. Compounds may be toxic under some circumstances but not others or, perhaps, toxic in combination with another compound but nontoxic alone. The methylenedioxyphenyl insecticide synergists, such as piperonyl butoxide, are of low toxicity to both insects and mammals when administered alone but are, by virtue of their ability to inhibit xenobiotic-metabolizing enzymes, capable of causing dramatic increases in the toxicity of other compounds.
The measurement of toxicity is also complex. Toxicity may be acute or chronic, and may vary from one organ to another as well as with age, genetics, gender, diet, physiological condition, or the health status of the organism. As opposed to experimental animals, which are highly inbred, genetic variation is a most important factor in human toxicity since the human population is highly outbred and shows extensive genetic variation. Even the simplest measure of toxicity, the LD50 (the dose required to kill 50% of a population under stated conditions) is highly dependent on the extent to which the above variables are controlled. LD50 values, as a result, vary markedly from one laboratory to another.
Exposure of humans and other organisms to toxicants may result from many activities: intentional ingestion, occupational exposure, environmental exposure, as well as accidental and intentional (suicidal or homicidal) poisoning. The toxicity of a particular compound may vary with the portal of entry into the body, whether through the alimentary canal, the lungs, or the skin. Experimental methods of administration such as injection may also give highly variable results; thus the toxicity from intravenous (IV), intraperitoneal (IP), intramuscular (IM), or subcutaneous (SC) injection of a given compound may be quite different. Toxicity may vary as much as tenfold with the route of administration. Following exposure there are multiple possible routes of metabolism, both detoxifying and activating, and multiple possible toxic endpoints (Figure 1.1).
Attempts to define the scope of toxicology, including that which follows, must take into account that the various subdisciplines are not mutually exclusive and are frequently interdependent. Due to overlapping of mechanisms as well as use and chemical classes of toxicants, clear division into subjects of equal extent or importance is not possible.
DEFINITION AND SCOPE, RELATIONSHIP TO OTHER SCIENCES, AND HISTORY |
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Toxicant Exposure
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Figure 1.1 Fate and effect of toxicants in the body.
Many specialized terms are used in the various subdisciplines of toxicology as illustrated in the Dictionary of Toxicology, 2nd edition (Hodgson et al., 1998). However, some terms are of particular importance to toxicology in general; they are defined in the glossary to be found at the end of this volume.
A.Modes of Toxic Action. This includes the consideration, at the fundamental level of organ, cell and molecular function, of all events leading to toxicity in vivo: uptake, distribution, metabolism, mode of action, and excretion. The term mechanism of toxic action is now more generally used to describe an important molecular event in the cascade of events leading from exposure to toxicity, such as the inhibition of acetylcholinesterase in the toxicity of organophosphorus and carbamate insecticides. Important aspects include the following:
1.Biochemical and molecular toxicology consider events at the biochemical and molecular levels, including enzymes that metabolize xenobiotics, generation of reactive intermediates, interaction of xenobiotics or their metabolites with macromolecules, gene expression in metabolism and modes of action, and signaling pathways in toxic action.
2.Behavioral toxicology deals with the effects of toxicants on animal and human behavior, which is the final integrated expression of nervous function in the intact animal. This involves both the peripheral and central nervous systems, as well as effects mediated by other organ systems, such as the endocrine glands.
3.Nutritional toxicology deals with the effects of diet on the expression of toxicity and with the mechanisms of these effects.
6INTRODUCTION TO TOXICOLOGY
4.Carcinogenesis includes the chemical, biochemical, and molecular events that lead to the large number of effects on cell growth collectively known as cancer.
5.Teratogenesis includes the chemical, biochemical, and molecular events that lead to deleterious effects on development.
6.Mutagenesis is concerned with toxic effects on the genetic material and the inheritance of these effects.
7.Organ toxicity considers effects at the level of organ function (neurotoxicity, hepatotoxicity, nephrotoxicity, etc.).
B.Measurement of Toxicants and Toxicity. These important aspects deal primarily with analytical chemistry, bioassay, and applied mathematics; they are designed to provide the methodology to answer certain critically important questions. Is the substance likely to be toxic? What is its chemical identify? How much of it is present? How can we assay its toxic effect, and what is the minimum level at which this toxic effect can be detected? A number of important fields are included:
1.Analytical toxicology is a branch of analytical chemistry concerned with the identification and assay of toxic chemicals and their metabolites in biological and environmental materials.
2.Toxicity testing involves the use of living systems to estimate toxic effects. It covers the gamut from short-term tests for genotoxicity such as the Ames test and cell culture techniques to the use of intact animals for a variety of tests from acute toxicity to lifetime chronic toxicity. Although the term “bioassay” is used properly only to describe the use of a living organism to quantitate the amount of a particular toxicant present, it is frequently used to describe any in vivo toxicity test.
3.Toxicologic pathology is the branch of pathology that deals with the effects of toxic agents manifested as changes in subcellular, cellular, tissue, or organ morphology.
4.Structure-activity studies are concerned with the relationship between the chemical and physical properties of a chemical and toxicity and, particularly, the use of such relationships as predictors of toxicity.
5.Biomathematics and statistics relate to many areas of toxicology. They deal with data analysis, the determination of significance, and the formulation of risk estimates and predictive models.
6.Epidemiology as it applies to toxicology, is of great importance as it deals with the relationship between chemical exposure and human disease in actual populations rather than in experimental settings.
C.Applied Toxicology. This includes the various aspects of toxicology as they apply in the field or the development of new methodology or new selective toxicants for early application in the field setting.
1.Clinical toxicology is the diagnosis and treatment of human poisoning.
2.Veterinary toxicology is the diagnosis and treatment of poisoning in animals other than humans, particularly livestock and companion animals, but not excluding feral species. Other important concerns of veterinary toxicology are the possible
DEFINITION AND SCOPE, RELATIONSHIP TO OTHER SCIENCES, AND HISTORY |
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transmission of toxins to the human population in meat, fish, milk, and other foodstuffs and the care and ethical treatment of experimental animals.
3.Forensic toxicology concerns the medicolegal aspects, including detection of poisons in clinical and other samples.
4.Environmental toxicology is concerned with the movement of toxicants and their metabolites and degradation products in the environment and in food chains and with the effect of such contaminants on individuals and, especially, populations. Because of the large number of industrial chemicals and possibilities for exposure, as well as the mosaic of overlapping laws that govern such exposure, this area of applied toxicology is well developed.
5.Industrial toxicology is a specific area of environmental toxicology that deals with the work environment and constitutes a significant part of industrial hygiene.
D.Chemical Use Classes. This includes the toxicology aspects of the development of new chemicals for commercial use. In some of these use classes, toxicity, at least to some organisms, is a desirable trait; in others, it is an undesirable side effect. Use classes are not composed entirely of synthetic chemicals; many natural products are isolated and used for commercial and other purposes and must be subjected to the same toxicity testing as that required for synthetic chemicals. Examples of such natural products include the insecticide, pyrethrin, the clinical drug, digitalis, and the drug of abuse, cocaine.
1.Agricultural chemicals include many compounds, such as insecticides, herbi-
cides, fungicides, and rodenticides, in which toxicity to the target organism is a desired quality whereas toxicity to “nontarget species” is to be avoided. Development of such selectively toxic chemicals is one of the applied roles of comparative toxicology.
2.Clinical drugs are properly the province of pharmaceutical chemistry and pharmacology. However, toxic side effects and testing for them clearly fall within the science of toxicology.
3.Drugs of abuse are chemicals taken for psychological or other effects and may cause dependence and toxicity. Many of these are illegal, but some are of clinical significance when used correctly.
4.Food additives are of concern to toxicologists only when they are toxic or being tested for possible toxicity.
5.Industrial chemicals are so numerous that testing them for toxicity or controlling exposure to those known to be toxic is a large area of toxicological activity.
6.Naturally occurring substances include many phytotoxins, mycotoxins, and minerals, all occurring in the environment. The recently expanded and now extensive use of herbal remedies and dietary supplements has become a cause of concern for toxicologists and regulators. Not only is their efficacy frequently dubious, but their potential toxicity is largely unknown.
7.Combustion products are not properly a use class but are a large and important class of toxicants, generated primarily from fuels and other industrial chemicals.
E.Regulatory Toxicology These aspects, concerned with the formulation of laws, and regulations authorized by laws, are intended to minimize the effect of toxic chemicals on human health and the environment.
- #15.08.20134.04 Mб14Hastie T., Tibshirani R., Friedman J. - The Elements of Statistical Learning Data Mining, Inference and Prediction (2002)(en).djvu
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- #15.08.201315.44 Mб23Hudlicky M, Pavlath A.E. (eds.) - Chemistry of Organic Fluorine Compounds 2[c] A critical Review (1995)(en).djvu
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