Lecture 01 week two lectures Ecotoxicology Notes-outline.doc

Lecture Notes, Dr. Shaukat Ali, Associate Professor, Emaail: dr.shaukat@kiu.edu.pk
Introduction to Environmental Toxicology
(Summarized and adapted from various locations on the www*)
Aims
The impact of toxic chemicals on wildlife and humans has been of great concern for the last fifty years.
Unfortunately this is a very large, complex subject area which can only be covered superficially within the time
available. However, this lecture is intended to give an introduction to fundamental aspects of how some pollutants
interact with living organisms to cause deleterious effects. The complexity will be explained and simplified where
possible. You should understand at least a little about the biology of key organisms and how pollutants cause
damage at a physiological level. You should be aware of how pollutants can induce change in organisms which
can be used as a ‘biomarker’ of the presence and action of the pollutants (although this will form the subject of a
later lecture in this course).
Thus as the main outcome of this lecture you should have an appreciation of the wide range of contemporary
issues that are caused by toxic chemicals in the environment and what regulatory authorities are doing to monitor
and control them. You should understand the main hazards that toxic chemicals pose and how risk to humans and
wildlife is controlled. You should be aware of the main groups of pollutants of contemporary concern.
The material covered will be useful for the consideration of two case studies on the impact of toxic chemicals in
the Great Lakes of North America and the Baltic Sea in later lectures.
Environmental Toxicology or Ecotoxicology?
Introduction
It was after World War II that increasing concern about the impact of toxic chemicals on the environment led
Toxicology to expand from the study of toxic impacts of chemicals on man to that of toxic impacts on the
environment. This subject became known as Environmental Toxicology.
Ecotoxicology is a relatively new discipline and was first defined by René Truhaut in 1969. It attempts to
combine two very different subjects: ecology ("the scientific study of interactions that determine the distribution
and abundance of organisms" Krebs 1985) and toxicology ("the study of injurious effects of substances on living
organisms", usually man). In toxicology the organisms sets the limit of the investigation whereas Ecotoxicology
aspires to assess the impact of chemicals not only on individuals but also on populations and whole ecosystems.
During the early years, the major tools of Environmental Toxicology were: detection of toxic residues in the
environment or in individual organisms and testing for the toxicity of chemicals on animals other than man. It was
however, a very big jump in understanding from an experimental animal to a complex, multivariate environment
and the subject of ECOTOXICOLOGY developed from the need to measure and predict the impact of pollutants
on populations, communities and whole ecosystems rather than on individuals. There is an on-going debate as to
the exact scope and definition of ecotoxicology.
The simplest definition found to date is that ecotoxicology is "the study of the harmful effects of chemicals upon
ecosystems" (Walker et al, 1996).
* Includes material adapted from : http://www.ipmrc.com/ compiled by Sue Dent
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A more complete definition of Ecotoxicology comes from Forbes & Forbes 1994 “the field of study which
integrates the ecological and toxicological effects of chemical pollutants on populations, communities and
ecosystems with the fate (Transport, transformation and breakdown) of such pollutants in the
environment”.
There are three main objectives in ecotoxicology (Forbes & Forbes 1994):
 obtaining data for risk assessment and environmental management.
 meeting the legal requirements for the development and release of new chemicals into the environment.
 developing empirical or theoretical principles to improve knowledge of the behaviour and effects of
chemicals in living systems.
(More information about the highlighted terms used below can be found in the Definitions section.)
In order to achieve these objectives, the main areas of study are:
The distribution of POLLUTANTS in the environment, their entry, movement, storage and transformation within
the environment.
The effects of pollutants on living organisms.
At an individual level, TOXICANTS may disrupt the biochemical, molecular and physiological structure and
function which will in turn have consequences for the structure and function of communities and ecosystems.
At the population level it may be possible to detect changes in the numbers of individuals, in gene frequency (as
in resistance of insects to insecticides) or changes in ecosystem function (e.g. soil nitrification) which are
attributable to pollution.
It may be possible to use BIOMARKERS to establish that a natural population has been exposed to pollution and
these can provide a valuable guide to whether or not a natural population is at risk or in need of further
investigation.
For the purposes of the Regulation and Registration of chemicals the toxicity of individual chemicals is
principally investigated via TOXICITY TESTING, the main tool of which is the Standard Toxicity Test (STT)
which usually tests the DOSE or CONCENTRATION of a particular chemical that is toxic to under controlled,
laboratory conditions. Toxicity tests are mainly carried out using individual animals although there has been a
move towards the use of more complex systems known as MESOCOSMS. In some situations, particularly in the
case of pesticides, it may be possible to carry out FIELD TRIALS to assess toxicity.
Toxicity data are used to make assessments of the HAZARD and the RISK posed by a particular chemical.
Significant Issues with Chemicals that have driven the development of
Ecotoxicology
1. DDT – around the world
2. Cadmium in Japan
3. Mercury in Japan
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4. PCBs in Japan and Taiwan
5. Dioxins – various
6. The contamination of pristine environments (eg Arctic) by atmospheric transport of organohalogens
Most workers in the field of ecotoxicology refer to the publication of Rachel Carson’s Silent Spring (1962) as a
landmark in the public’s awareness of potential damage to human and environmental health from man-made toxic
substances. According to Rodricks (1992), Carson’s book “almost single-handedly created modern society’s fears
about synthetic chemicals in the environment and, among other things, fostered renewed interest in the science of
toxicology”. Certainly the consolidation of academic and related pursuits into the study of toxic substances in the
environment dates from about the same time as the publication of Silent Spring. Prior to the 1960s, there were no
coordinated programmes in research, in education or in regulation that systematically addressed toxic substances
in the environment. Considerable progress has been made in all these areas during the past four decades.
Fate of chemicals in the environment and within organisms
As ecotoxicologists we are concerned with the movement and fate of toxic chemicals at both the organism level
and that of the whole ecosystem. The relevant issues are:
 the source,
 transport,
 modification and
 final fate of the pollutants.
At the organism level we need to be concerned with
 Uptake
 Excretion
 Sites of action, metabolism or storage
Toxicity testing and the regulation and release of toxic chemicals
As ecotoxicology largely arose from toxicology and the need to regulate the introduction of potentially toxic
chemicals into the environment, toxicity testing remains central to the subject today. Most toxicity testing for
pollutants is still based on tests on individual organisms in artificial test situations (see list of examples in next
section). These tests are cheap, reliable and easy to perform but there is much debate about the relevance of many
standard toxicity tests to 'real life'.
Initially in the early days of environmental toxicology the concept of the 'most sensitive species' was used to
relate the results of toxicity tests to the 'real world'. Certain species in a particular community were assessed as
being 'most sensitive' to pollutants. The logic was that if a pollutant was non-toxic to the 'most sensitive' species
then it would be safe for the rest of the community.
Essentially, this logic remains today - the results of tests on single species, in artificial situations are extrapolated
to predict the effects of pollutants on whole communities or ecosystems. It is assumed that if you have enough
information about the effects of a pollutant on the parts of an ecosystem, then you can assemble the effects on the
whole.
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There is however, some question about the usefulness of extrapolating from simple, highly artificial, single-
species toxicity tests to complex, multi-variate ecosystems. Forbes & Forbes (1994) argue that "understanding and
predicting the consequences of pollutant-induced effects on ecosystems requires that the effects be examined at
the level of interest" i.e. the population, community or ecosystem.
This debate has been the source of much division in ecotoxicology, between the Applied, often Industrial,
Ecotoxicologists concerned with the practicalities of chemical registration and testing and the Pure or Academic
Ecotoxicologists who regard many toxicity testing regimes as inappropriate or at worst useless. Unfortunately,
never the twain shall meet and the level of communication between the two camps has not been great. A fictional
exchange makes the point well (from Forbes & Forbes 1994):
"Academic Ecotoxicologist: Single species acute toxicity tests are too simplistic and have no connection with
what is really going on out in nature. These standard tests are not only irrelevant and a waste of time, they may in
fact do more harm than good if they lead us to believe that we can use them to adequately protect the environment
when in fact we cannot.
Industrial Ecotoxicologist: These tests may be oversimplified, but they are also cost-efficient, easy to perform, the
procedures have been worked out, and the fact is they are required by government. We have absolutely no
incentive to do more than is required by law, and, frankly, you have given us little hard evidence that current test
procedures do fail to protect the environment adequately.
Government Ecotoxicologist: Do you have any idea of the number of new chemicals that we have to assess each
year? We can't tell industry to stop producing new chemicals and we can't wait until we understand the whole
system before we try to protect it. If you think current procedures fail, then come up with some better tests -
which must of course be simple, cheap and fast.
Academic Ecotoxicologist: (Pause) ... Well, it's very complex, and of course I'll need much more data before I can
give you an answer. But those single-species acute tests are oversimplified and have no connection with what is
really going on out in the field ...
Government Ecotoxicologist: We need tests! Give us tests!"
The way forward for Ecotoxicology must be to integrate its two halves much more fully. Toxicity testing, using
single species, do provide useful information and will almost certainly remain central to the regulation and
registration of toxic chemicals but much can be done to expand the scope of toxicity testing, to add tests that
apply to higher levels of organisation and so increase their relevance to the communities and ecosystems that are
being protected.
Testing methodologies
An extensive range of ecotoxicological and biodegradation tests are required for the chemical, agrochemical and
pharmaceutical industries. The tests often used include:
 Bacterial toxicity tests
 Algal Growth tests with a variety of species
 Acute toxicity tests with Lemna minor
 Acute and Reproduction tests in Daphnia magna
 Acute toxicity tests with the marine copepod Acartia tonsa
 Oyster embryo larval toxicity test
 Acute toxicity test with the marine invertebrate Mysidopsis bahia
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 Earthworm toxicity tests
 Toxicity Tests with sediment dwelling organisms such as Chironomus or Lumbriculus
 Acute toxicity tests with freshwater and marine fish
 Bioaccumulation in fish
 Fish growth tests
 Early Life Cycle tests with fish
Definitions used in Ecotoxicology
Some of the terms used in ecotoxicology, such as LD50, have simple, widely accepted definitions and hence can
be defined here with some confidence. Others however vary quite widely in their interpretation from one text to
another. I have tried to indicate these below and can only suggest that the reader refer carefully to the introduction
of the text they are using. Where there is likely to be some contradiction I have listed the reference for the
definitions given.
ECOTOXICOLOGY
 is concerned with the toxic effects of chemical and physical agents on living organisms, especially on
populations and communities within defined ecosystems: it includes the transfer pathways of those agents
and their interactions with the environment. Butler, 1978.
 investigates the effects of substances on organisms. The hazard to animal and plant populations can be
determined by using survey data (retrospective) or by performing specific tests (prospective). Rudolph &
Boje, 1986.
 the science that seeks to predict the impacts of chemicals on ecosystems. Levin et al 1989.
 the study of harmful effects of chemicals upon ecosystems. Walker et al 1996.
POLLUTANT or CONTAMINANT, XENOBIOTIC or ENVIRONMENTAL CHEMICAL?
Variations of use of these terms are commonplace. “Environmental chemical” may be used to describe simply any
chemical that occurs in the environment (Walker et al 1996) or substances which enter the environment as a result
of human activity or occur in higher concentrations than they would in nature (Römbke & Moltmann 1995).
The terms contaminant and pollutant can be described separately but are often used as synonyms. Both words
are used to describe chemicals that are found at levels judged to be above those that would normally be expected.
“Pollutants” carries the connotation of the potential to cause harm, whereas contaminants are not by definition
harmful. This is however, not an easy distinction to make. Whether or not a contaminant is a pollutant may
depend on its level in the environment and the organism or system being considered, thus one particular substance
may be a contaminant relative to one species but pollutant relative to another. Finally, in practice it is often
difficult to demonstrate that harm is not being caused so that in effect pollutant and contaminant become
synonymous. (Walker et al 1996).
Xenobiotic is used to describe compounds that are 'foreign' to a particular organism, that is they do not play a part
in their normal biochemistry. A chemical that is normal to one organism may be foreign to another and so
xenobiotics may be naturally occurring as well as man-made compounds (Walker et al 1996). The term
Xenobiotic is sometimes also used in a more general sense to describe "foreign substances" in the environment
(Römbke & Moltmann 1995).
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HARM or DAMAGE?
Biological syste ms are resilient to harm caused by adverse factors in the environment since they are able to adapt
to some insults. There is a fundamental difference in viewpoint between these two words, one defines harm as an
effect regardless of any biological compensation that the population might make, the other defines damage as
occurring only if there is an effect subsequent to any compensation.
harm: biochemical or physical changes which adversely affect individual organisms' birth, growth or mortality
rates. Such changes would necessarily produce population declines were it not that other processes may
compensate. (Walker et al 1996).
damage: "the interaction between a substance and a biological system. The substance's potential to cause damage
is weighed against the protective potential inherent in the biological system (e.g. excretion or metabolic reactions,
adaptation or regeneration)" (Römbke & Moltmann 1995).
ENDPOINTS, DOSE and CONCENTRATION
There are many different ways in which toxicity can be measured but they are usually assessed relative to a
particular outcome or END POINT. Initially, most Toxicity Tests measured the number of organisms killed by a
particular DOSE or CONCENTRATION of the chemical being tested. With terrestrial animals the DOSE of
chemical (taken orally, applied to the skin or injected) administered is usually recorded. DOSE is usually used
where the dietary dose of a test chemical can be accurately determined. For aquatic organisms or where the test
chemical is dosed into the surrounding medium, the tests usually measure the CONCENTRATION of chemical
in the surrounding water/medium.
The following measures, known as a group as EDs or ECs (Effective Doses or Effective Concentrations) are
frequently used to describe data from toxicity tests:
LD50
Median lethal dose, that is the dose that kills 50% of the population
LC50
Median lethal concentration.
ED50/EC50
Median effect dose/concentration, that is the dose that produced a defined effect to 50% of the population.
NOED/NOEC
No Observed Effect Dose (or Concentration)
NOEL
No Observed Effect Level. Sometimes this more general term is used to describe either of the above. It can be
defined as the highest level (that is dose or concentration) of the test chemical that does not cause a statistically
significant difference from the control.
LOED/LOE
Lowest Observed Effect Dose (or Concentration)
There has been a move away from the use of lethal end points in toxicity testing towards the measurement of
EFFECTS rather than death. Examples of EFFECTS which can be used include changes in: reproduction (eg.
number of eggs laid or young hatched); growth (e.g. biomass or body length) and biochemical or physiological
effects (e.g. enzyme synthesis or respiration).
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HAZARD AND RISK
Toxicity data is used to make assessments of the HAZARD and the RISK posed by a particular chemical. Where:
HAZARD is the potential to cause harm
RISK is the probability that harm will be caused.
Defining HAZARD involves answering two questions, 'how much damage are we prepared to tolerate' and 'how
much proof is enough'. The first is a question for society, alleviating/avoiding/repairing damage involves costs,
how much are we prepared to pay? The second is largely a scientific problem of providing sufficient evidence that
damage is due to pollution. HAZARD is not necessarily directly related to toxicity, it is a product of exposure and
toxicity, a compound with moderate toxicity but very high exposure may cause more damage that a very toxic
chemical with very low exposure.
RISK is usually defined using the predicted environmental concentration (PEC) and the predicted environmental
no effect concentration (PNEC). Information on the movement and behaviour of pollutants in the environment are
used to calculate the PEC whereas data from Toxicity Testing must be extrapolated to calculate the PNEC. The
making of these calculations is not a precise art, apart from doubts about the extrapolation of Toxicity data from
the lab to the field it can be very difficult to estimate the degree of exposure, particularly for mobile taxa such as
birds and mammals.
BIOMARKERS
A Biomarker can be defined as a "biological response to a chemical or chemicals that gives a measure of
exposure and sometimes, also, of toxic effect" (Walker et al 1996), they can be divided into biomarkers of
exposure and of toxic effect. Examples of biomarkers range from the inhibition of AChE (acetylcholinesterase) in
the nervous system of animals to the thinning of eggshells in birds. Biomarkers can help to bridge the gap
between the laboratory and the field by giving direct evidence of whether or not a particular animal, plant or
ecosystem is being affected by pollution. They will often provide more reliable evidence of exposure than
measurements of the pollutants themselves in the environment, the latter are often short-lived and difficult to
detect, whereas their effects (detectable via biomarkers) may be much longer-term.
A QUESTION OF SCALE AND ACCURACY
The difficulty in extrapolating from simple, highly artificial, single-species toxicity tests to complex, multi-variate
ecosystems has led to attempts to develop more complex systems which can be used in toxicity tests. Such
systems are usually termed microcosms, mesocosms or macrocosms, that is small, medium or large multispecies
systems. It must be possible to control conditions in these systems to such an extent that they can provide
meaningful, reproducible (that is, the system could be accurately copied elsewhere), replicable (that is, two
replicates of the same experiment would produce the same results) data in toxicity tests. Simply because they are
more complex systems it is seldom possible to produce tests that are as precise and controlled as those carried out
in single species STTs. However, despite their limitations these larger-scale tests can provide important insights
into the effect of pollutants on whole systems rather than on single species.
MIXTURES OF CHEMICALS, ADDITION OR MULTIPLICATION?
In natural systems, organisms are often (usually) exposed to more than one pollutant at the same time. However,
regulatory authorities usually assume - unless there is evidence to the contrary - that the toxicity of combinations
of chemicals is roughly additive. Fortunately in many cases this is quite correct but in some cases, toxicity is more
than additive in that is there is POTENTIATION of toxicity. One particular type of potentiation called
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SYNERGISM occurs where the effect of two or more chemicals combine to have greater impact than expected
from their individual concentrations.
Ecotoxicology - What is a pesticide?
A literal definition of a pesticide would be "a killer of pests". In practice pesticides are no longer aimed
exclusively at killing the pests they are used to control and the term has acquired a rather wider meaning such as
"the chemical tools used to manage all kinds of pests" or in the US it's more official definition is "any substance
used for controlling, preventing destroying, repelling or mitigating any pest" (all definitions from Ware 1991).
Hence pesticides include not only those chemicals which kill the pest they are used against but also those such as
insect chemosterilants or plant and insect growth regulators which control pest populations without necessarily,
physically, killing the pests they come into contact with.
Pesticides have been divided into many different classes. Firstly, according to the target organism that they
control, so insect-icides kill (or control) insects, rodent-icides control rodents etc. The -icide suffix has been
widely used in the past, but relatively few of these terms are in common use today. Secondly, pesticides can be
classified according to their mode of action, that is the way in which they act on the pest population, e.g.
attractants, repellents, chemosterilants etc.
Finally, the definition of a pesticide has been widened once again to: "pesticides are used by man as intentional
additions to his environment in order to improve environmental quality for himself, his animals or his plants"
(Ware 1991). This definition allows the inclusion of 2 new classes of treatment. Firstly those such as plant growth
regulators, which are not only used as herbicides to control weeds, but also to control directly the growth of the
crop and hence improve its success. For instance, they are used to reduce the growth of cereals so that they do not
become too tall and prone to 'lodging' before harvest. Secondly, microbial pesticides which are not based on a
chemical but on bacteria, fungi, nematodes and viruses which attack the pest.
Each pesticide contains a chemical or 'active ingredient' (a.i.) which is responsible for its pesticidal effect, but
pesticides are rarely supplied as preparations of neat, concentrated or technical grade chemical. The active
ingredient must be FORMULATED with other non-pesticidal compounds before it is ready to use. Formulation
generally improves the properties of a chemical for: storage, handling, application, effectiveness and safety. The
FORMULATION of a pesticide is the form in which it is sold, not necessarily that in which it is used. The
formulation needs to be taken into account as it can alter the environmental behaviour of the chemical.
Ecotoxicology - Insecticides
While pesticides can be divided into many classes by target organism, mode of action etc for most purposes
chemical pesticides are divided into three major groups according to their target organism, that is: insecticides,
herbicides and fungicides. These groups are then subdivided into chemical groups such as organophosphates,
organochlorines, carbamates etc. This simplified classification effectively groups acaricides, nematicides and
molluscicides in with insecticides as many chemicals that have acaricidal, nematocidal or molluscicidal properties
are also insecticidal.
The current proliferation of chemical insecticides dates from World War II, until this time the insecticides
available were based on: arsenicals, petroleum oils, sulphur, hydrogen cyanide gas, cryolite and on extracts from
plants such as pyrethrum, nicotine and rotenone. Table 2: Classification of Insecticides gives a summary of the
main chemical classes of insecticide and the main chemicals in each class. The characteristics of the main classes
of insecticide: the organochlorines, organophosphates, carbamates and pyrethroids are summarised below.
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Organochlorines
Also called: chlorinated hydrocarbons
A large and varied group that has a particularly high public profile because of the environmental problems they
have caused. They were mostly discovered in 1942-56 and were very important in the early success of synthetic
insecticides. They are mostly Insecticides with a very wide range of actions, they can be divided into three main
groups:
DDT and related compounds including rhothane (DDD) and methoxychlor.
Widely used during World War II for control of disease vectors (such as mosquitoes) and subsequently much used
on agricultural pests such as ectoparasites of farm animals and insect disease vectors and also widely used
againstinsects in domestic and industrial premises.
chlorinated cyclodiene insecticides such as aldrin, dieldrin and heptachlor.
most widely used as seed dressings and soil insecticides.
hexachlorocyclohexanes (HCHs), such as lindane
used against pests and parasites of farm animals, also in insecticidal seed dressings.
Organochlorine insecticides are very stable solids with: limited vapour pressure, very low water solubility and
high lipophilicity. They may be very persistent in their original form or as stable metabolites. They tend to be
stored in body fats and are particularly hazardous because they are so stable and tend to accumulate in successive
organisms in the food chain. DDT and the HCHs a regarded as only moderately toxic to mammals while the
chlorinated cyclodienes are highly toxic.
Action: all organochlorine insecticides are nerve poisons but DDT has a different action to the chlorinated
cyclodienes and HCHs. DDT acts on the sodium channels in the nervous system so that the passage of an 'action
potential' along the nerve is disrupted. It causes uncontrolled repetitive spontaneous discharges along the nerve.
Uncoordinated muscle tremors and twitches are characteristic symptoms. The chlorinated cyclodienes and HCHs
act on the GABA receptors which function as a channel for Cl -
ions through the nerve membranes. They bind to
the GABA receptors and reduce the flow of Cl -
ions. Typical symptoms include convulsions.
Organophosphates
Also called: organic esters of phosphorus acid. Such as bromophos, chlorpyrifos, diazinon, dichlorvos,
fenitrothion, malathion, parathion and phorate.
The same basic constituents are combined with many additional chemicals to give a wide range of products with
very different properties. Organophosphates were developed during the second world war and have two main
uses: as insecticides and as nerve gases (chemical warfare agents).
They are mostly liquids, liphophilic, with some volatility and a few are solids. Generally, they are less stable and
more readily broken down than organochlorines and are relatively short-lived in the environment, hence most of
their hazard is associated with short-term (acute) toxicity. The water solubility of the various organophosphate
compounds is very variable and they are prepared in numerous formulations: as emulsifiable concentrates for
spraying and to control ectoparasites of farm animals (particularly sheep dips) and sometimes internal parasites
(such as ox warble fly); as seed dressings and as granular formulations particularly used for the most toxic
organophosphates (e.g. disyston and phorate) as the active ingredient is effectively 'locked up' in the granule and
is safer to handle and only slowly released into the environment. Organophosphates are also used to control
vertebrate pests such as Quelea in Africa.
Action: like organochlorines, organophosphates also act as a neurotoxin. They combine with the enzyme
acetylcholinesterase and prevent conduction of nerve impulses at junctions in the nervous system where
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acetylcholine is the natural transmitter. As a result, acetylcholine builds up in the nerve synapse and eventually
leads to synaptic block when the acetylcholine can no longer relay signals across the synapse. In neuro-muscle
junctions this leads to tetanus, the muscle is in a fixed state, unable to contract or relax in response to nerve
stimulation.
Carbamates
e.g. aldicarb, carbaryl, carbofuran, methiocarb, methomyl, pirimicarb and propoxur
Carbamates are a more recent development than organochlorines or organophosphates, they are all derivatives of
carbamic acid. The basic carbamate group is combined with different chemicals to produce insecticides with a
wide range of properties (in particular they vary greatly in their water solubility) and actions. Carbamates are not
only used as insecticides but also molluscicides and nematicides. Carbamates are also used as herbicides and
fungicides but these have a different mode of action and are described elsewhere.
Carbamates are mainly used to control insect pests in agriculture and horticulture, they have abroad spectrum of
activity and usually act by contact or stomach action although a few possess systemic activity (aldicarb,
carbofuran).
Action: basically the same as organophosphates, inhibiting the action of acetylcholine at the nerve synapses.
Doses of carbamates are not accumulative and carbamate poisoning is more easy to reverse than that caused by
organophosphates. They are generally regarded as representing a short-term hazard.
Pyrethroids
Such as cypermethrin, deltamethrin, permethrin, phenothrin, resmethrin.
Pyrethrin insecticides were developed from naturally occurring chemicals found in the flower heads of
Chrysanthenum sp. and these provided the model for the production of synthetic pyrethroid insecticides.
Pyrethroids are generally more stables than natural pyrethrins. The development of pyrethroids can be traced over
4 main phases (Ware 1991). The first generation allethrin was a synthetic duplicate of a natural pyrethrum, cinerin
I. The second generation included bioallethrin, phenothrin, resmethrin and bioresmethrin. These were marginally
more effective than natural pyrethrums but were neither effective enough nor photostable enough to be used
extensively in agriculture. However, they are still used in pest control formulations for the home. The third
generation of pyrethroids included fenvalerate and permethrin which were stable in sunlight and only slightly
volatile and could be used successfully in agriculture. Finally, the fourth and current generation of pyrethroids can
be used at much lower concentrations (one-fifth to one-tenth) that those in generation 3 and are all photostable.
Overall, most pyrethroids are not sufficiently soluble in water to be used a systemic insecticides. They are mainly
formulated as emulsifiable concentrates for spraying. They control a wide range of agricultural and horticultural
insect pests and are used extensively to control insect vectors of disease (e.g. tsetse fly in Africa)
Action: pyrethroids are generally solids with very low water solubility and they act as neruotoxins in a very
similar way to DDT. They are readily biodegradable but can bind to particles in soils and sediments and can be
persistent in these locations. They are particularly toxic to insects as opposed to mammals and birds and the main
environmental concerns are over their effects on fish and non-target invertebrates.
Ecotoxicology - Herbicides
It is really only in the last 50 years that use of chemical weedkillers or herbicides has become widespread. Prior to
this, the control of weeds in crops was carried out largely by manual weeding, crop rotation, ploughing and
various ways of stopping weed seeds being dispersed in crop seed. Today, the heavy use of herbicides is confined
to those countries that practice highly intensive, mechanised farming. In 1971 it was estimated that more energy
was expended on weeding crops than on any other single human task (Brain 1971 ). Herbicides are also used
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extensively in non-crop and amenity situations such as industrial sites, roadsides, ditch banks, recreational areas
etc.
Herbicides can be classified in a number of different ways. The main classification used is often according to
chemical class but they can also be classified according to their selectivity, the way that they affect the plant, the
timing of application and the area covered by an application. Herbicides are classed as selective if they kill some
plant species but not others, for instance they may kill the weeds but not the crop and as non-selective if they kill
all vegetation. Herbicides may be intrinsically selective in that they are active against some species of weed but
not others but they may also be used selectively, that is in such a way that they only come into contact with the
weeds and not the crop.
There are two main ways in which herbicides affect the plants they are applied to: contact herbicides kill parts of
the plant that they come into contact with. These are generally used against annual weeds and if they are to be
effective need complete coverage of the target weed with the chemical. Systemic or translocated herbicides are
absorbed either by the roots or foliage of the plant and then move within the plants system to areas remote from
the site of application. Translocated herbicides tend to be slower acting than contact ones and while they can be
used against annual weeds they are more commonly aimed at perennial weeds. With translocated herbicides a
uniform, although not necessarily complete, coverage of the target weeds is necessary.
Finally, herbicides can be classified according to the timing of application in relation to the crop they are being
used in. Pre-plant, or pre-sowing herbicides must be applied to an area before the crop is planted. Pre-emergence
herbicides are applied before the crop has emerged, this may allow an added level of selectivity as a herbicide can
be applied to growing weeds while the crop itself is still protected by the oil. Finally, post-emergence herbicides
are applied after the crop has emerged from the soil. Again, a level of selectivity may be introduced by applying a
germination inhibitor to prevent further germination of weed seeds - after the crop itself has germinated.
Phenoxy Herbicides
e.g. 2,4-D, MCPA, 2,4,5-T
All derivatives of phenoxyalkane carboxylic acids that act as plant growth regulator herbicides. Phenoxy
herbicides were the first safe, selective herbicides discovered and they are still used in huge quantities. They act
by simulating the action of natural hormones and produce uncoordinated plant growth. Their action is selective as
they are toxic to dicotyledonous but not monocotyledonous plants. Hence they can be used to control 'dicot' weeds
(broad leaved weeds) in 'monocot' crops (e.g. cereals, grass).
Their physical properties vary greatly according to formulation. For instance, as alkali salts they are highly water
soluble (can be formulated as aqueous solutions) whereas when as simple esters they have low water solubility
and are lipophilic (generally formulated as emulsifiable concentrates).
The main hazard they present is mainly posed by unwanted spray drift but they have also sometimes been
contaminated with the highly toxic compound TCDD (or dioxin).
Ecotoxicology - Fungicides
The control of fungal diseases of plants with chemicals has some inherent difficulties. Firstly, the pathogen and
the plant host are physiologically very similar and this makes phytotoxicity a major problem. Secondly, access to
the pathogen is not always easy as they spend most of their life-cycle within the tissues of the host plant. Finally,
it is often too late if the fungicide is applied when the first symptoms of the disease appear and so there is often a
need for prophylactic chemical control.
Table 4: Classification of Fungicides summarises the classification of the major fungicides currently in use.
Printed 13/05/2025

As with insecticides and herbicides the classification of fungicides is not straightforward. They can be classified
according to: chemical composition; application site; timing of application and mode of action or by product
behaviour. Of these the most commonly used divisions are according to chemical class (as in Table 4:
Classification of Fungicides) and timing of application, that is timing of application relative to the stage of
infection of the crop. Protectant fungicides are applied to the plant surface before infection occurs, they remain on
the surface and kill any fungal spores or bacterial cells that come into contact with them. Protectant fungicides
tend to be broad spectrum and be effective against a wide range of fungal diseases. To achieve a constant level of
protection it may be necessary to reapply them at regular intervals to replace deposits lost to rain run-off or
abrasion. Curative fungicides are applied after initial infection, usually quite early on in the progress of the
disease so that the infection might be destroyed before it produces visible symptoms. They are largely systemic
being absorbed by the roots, seeds or leaves of the plant and then translocated within it. They tend to be much
more specific than protectant fungicides and for this reason are more prone to the development of pathogen
resistance. Finally, eradicant fungicides are applied when an infection has already become visible and for
preventing further sporulation and spread of the disease.
References
Barlow, F (1985) Chemistry and formulation. In: Pesticide Application: Principles and Practice. Ed: P T Cairns, J
Jr & Niederlehner B R (1994) Ecological Toxicity Testing. CRC Press Inc: Boca Raton
Dent, D R (1995) Integrated Pest Management. Chapman & Hall: London, Glasgow, Weinheim, New York,
Tokyo, Melbourne, Madras.
Forbes, V E & Forbes T L (1994) Ecotoxicology in Theory and Practice. Chapman & Hall Ecotoxicology Series
2: London.
Haskell. Oxford Science Publications: Oxford. pp 1-34.
Rombke, J & J M Moltmann (1995) Applied Ecotoxicology. Lewis Publishers: Boca Raton, New York, London,
Tokyo.
Ware, G W (1991) Fundamentals of Pesticides. A self-instruction guide. Thomson Publications: Fresno USA.
Relevant Reading
Connell, D., P. Lam, et al. (1999). Introduction to Ecotoxicology, Blackwell Publishing.
Moriarty, F. (1988). Ecotoxicology: the study of pollutants in ecosystems. London, Academic Press.
Rasmussen, L. (1984). Ecotoxicology. Stockholm, Publishing House of the Swedish Research Councils.
Van Emden, H. and D. Peakall (1996). Beyond Silent Spring, Chapman & Hall.
Walker, C. H., S. P. Hopkin, et al. (2000). Principles of ecotoxicology. London; New York, Taylor & Francis.
Wright, D. A. and P. Welbourn (2002). Environmental Toxicology, Cambridge University Press.
NB Ecotoxicology - the Journal is available on-line via the Harold Cohen Library
Printed 13/05/2025

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