FUCKING Crop Protection PDF

Summary

This document appears to be an educational resource, possibly notes for a course on insect physiology. It covers topics including the muscular system of insects, senses in insects, and related topics, but there is no specific exam board or year.

Full Transcript

MUSCULAR SYSTEM SENSES IN INSECTS

MUSCLE CONTRACTION – facilitated by nerve impulses at Locate food
nerve endings Find mates
MOVEMENT & APPENDAGES – produced by an intrinsic Avoid enemies
system of musculatures Make nests
Activities: Perform internal functions
Feeding BASIC SENSES
Walking 1. SIGHT
Jumping 2. SMELL (olfaction)
Flying 3. TASTE (gustation)
MUSCLES – made up contractile units called myosin filaments 4. TOUCH
STRIATED – light and dark bands made up of actin and myosin 5. HEARING
FIBERS – myofibrils situated in a matrix of multinucleated GROUPS OF ORGANS/RECEPTORS
cytoplasm 1. PHOTORECEPTORS – detect presence and quality of
MYOSIN FILAMENTS – protein, long coiled chains of incident light; when images are produced it is called sight
polypeptides ❖ COMPOUND EYES – perceive images, color,
PRINCIPAL TYPES OF INSECT MUSCLES movement; not found in primitively wingless insects
1. TYPICAL – fibrils (a small filament or fiber) only slightly OMMATIDIUM – facet is part of the individual
differentiated, enclosed in thick layer of superficial sensory units
plasma Number of Facets to a CE varies
2. MICROFIBRILLAR – fibrils closely packed, interspersed
20,000 in dragonflies
with columns of mitochondria
12,000 or more in Lepidoptera
SARCOLEMMA – plasma membrane
4,000 in Musca (housefly)
SARCOPLASMA – plasma
LIGHT-RECEPTOR APPARATUS (LRA) –
SARCOPLASM – cytoplasm
comprises 6 – 8 retinula cells
3. LAMELLAR or TUBULAR – direct flight muscles; nuclei
RHABDOM – central light sensor
found only along the central portion forming a column
❖ SIMPLE EYES/OCELLI – present in many immatures of
and surrounded by alternating rows of mitochondria and
Endopterygota; Also believed to perceive images
fibrils
although probably produce a less complete mosaic;
4. FIBRILLAR – found in indirect flight muscles of very
some appreciation of color; perceive movement of
efficient fliers (located along dorsum, thorax); in between
objects in their vicinity; responsible for orientation to light
fibrils are mitochondria and sarcoplasm
2 Classes
CATEGORIES OF MUSCLES OF INSECTS
DORSAL OCELLI – imagines and nymphs
1. VISCERAL MUSCLES – occur in circular, longitudinal
LATERAL OCELLI – endopterygote larvae
or oblique bands around the digestive tract = produce
2. CHEMORECEPTORS – detect the presence of chemical
peristaltic movements of the gut that moves food and
substances in the air thru the sense of smell (OLFACTION)
wastes along its length
OR on substrates thru the sense of taste (GUSTATION)
2. SEGMENTAL MUSCLES – series of bands that connect
FORMS OF CHEMORECEPTORS
body segments; Longitudinal bands connect the tergites
❖ TASTE RECEPTORS – sense molecules from liquids;
and sternites in the abdomen; Tergites to sternites of
have fine nerve endings exposed to the environment at
same segment are connected by oblique muscles on
hair tips
each side of the body
- Preferred to distilled H20 dilute acid/salt solution
3. APPENDAGE MUSCLES – movable appendages have
- Rejected esters, alcohols, amino acids
muscles either in them or attached to them
❖ SMELL RECEPTORS – perceived by olfactory sensilla
LOCOMOTION IN INSECTS
characterized by the presence of numerous pores
A. WALKING – basic mode of locomotion
- PHEROMONES – highly specific, volatile
TRIPOD MANNER – adult insects
substances perceived thru the olfactory sensilla
B. CRAWLING – basic mode of locomotion for worm-
after being secreted by other members of the same
shaped immatures
species
C. FLYING – only adults can accomplish flight
3. MECHANORECEPTORS – detect movements, vibrations,
D. UP-AND-DOWN BEAT CYCLE – mode of locomotion in
other mechanical disturbances
more primitive insects (dragonflies, roaches, beetles)
❖ TOUCH – monitored by hair sensilla, innervated by a
single neuron
 ❖ HEARING – perception of aerial vibrations by long, 2. SETAE or HAIRS or MACROTRICHIA or TRICHOID
slender, trichoid sensilla SENSILLA – multicellular with specialized cells
❖ TYMPANUM – perceived by chordotonal organs made - LARGE SETAE – bristles/chaetae
up of scolopidia - FLATTENED SETAE – scales on Lepidoptera
ST
- 1 ABDOMINAL SEGMENT – grasshopper
3 separate cells form each setae
- TIBIAE – crickets
- ABDOMEN AND METATHORAX – moths - TRICHOGEN CELL – hair formation
- JOHNSTON’S ORGAN – in the pedicel of adult - TORMOGEN CELL – socket formations
insects responds to movements of antennae; maybe - SENSORY CELL
involved in hearing 3. ACANTHAE – unicellular in origin
4. AUDITORY ORGANS 4. MICROTRICHIA – subcellular, from several to many
5. TEMPERATURE & HUMIDITY RECEPTORS extensions per cell
SENSILLA
PORE CANALS – passageways of secretions by the epidermis
COELONICA & CAMPANIFORMIA
from inside to outside
CHAETICA
TRICHOIDEA EXOSKELETON – support system

BASICONICA Functions of the Exoskeleton
INTEGUMENTARY SYSTEM
1. Provides a rigid foundation of the body
INTEGUMENT or BODY WALL – outer covering of the living
2. Serves as a point of attachment of muscles
tissues of insects; sclerotized for protection from abrasion as well
3. Serves as a covering to protect internal organs
as water proofing
4. Helps prevent desiccation
EPIDERMIS – single layer of cells
MOLTING – casting of old cuticle; triggered by hormones
CUTICLE – produced by the epidermis; covers e entire body released when an insect’s growth reaches physical limits of its
surface = restricts water loss exoskeleton

LAYERS OF THE CUTICLE ❖ APOLYSIS – separation of cuticle from the epidermis
❖ ECDYSIS – actual process of shedding off of the old skin
❖ EPICUTICLE – thin outer layer, 3mµ to 0.1 mµ thick;
1. Change in epidermal cells
permeable to chemicals and nutrients for growth but
2. Secretion of molting fluid
impermeable to enzymes that breakdown parts of the old
3. Secretion of cuticulin layer
cuticle before it is shed
4. Activation of molting fluid
Layers
5. Absorption of the digested remains of old cuticle and start
o HOMOGENOUS LAYER – innermost layer
of secretion of new procuticle
o LAYERS OF CUTICULIN (lipoprotein) – critical
6. Formation of wax and cement layer
in the growth process
7. Ecdysis and expansion of the new cuticle
o WAX – long hydrocarbon chain
8. SCLEROTIZATION/TANNING – processes by which the
o CEMENT – tanned protein with lipids serving as
new cuticle are made more resistant to degradation, stiffer,
a varnish-like covering of the wax or maybe in
less soluble; controlled by BURSICON
the form of an open meshwork providing a
- QUINONES – tanning substance for the cuticle coming
reservoir of lipids to replace lost surface lipids
from tyrosine or para-OH phenylalanine in the
❖ EXOCUTICLE – thicker layer; Forms the exuvium at
hemolymph
molting; Gives the cuticle its characteristic strength and
- B-SCLEROTIZATION – hardening without development
resilience; Formed of chitin (C18H13NO5)
of new color
- CHITIN – polymerized compound, a nitrogenous
- QUINONE SCLEROTIZATION – hardening with colors
polysaccharide linked to a protein
9. Start of wax secretion
❖ ENDOCUTICLE – still a thicker layer
❖ PHARATE CONDITION – insect actively constructing
❖ BASEMENT MEMBRANE – composed of
new exoskeleton takes days or weeks with very little
mucopolysaccharide secreted by hemocytes
evidence of change
CUTICULAR EXTENSIONS ❖ TENERAL CONDITION – newly molted insect, soft
unpigmented (white or ivory), until the tanning process
1. SPINES – multicellular with undifferentiated epidermal
is completed (a day or two)
cells
 PHYSIOLOGY OF MOLTING/DISTINCT SEQUENCE OF MALE’S REPRODUCTIVE SYSTEM
EVENTS
❖ SPERMATOGONIA – a group of germ cells at the distal end
1. Changes in epidermal cells of each follicle, dividing thru mitosis and increase in size to
2. Secretion of molting fluid form spermatocytes
3. Secretion of outer layer of cuticulin ❖ SPERMATOCYTES – migrate toward the end of the follicle,
4. Secretion of homogenous layer of cuticulin push along by continued cell division of spermatogonia;
5. Activation of molting fliid undergo meosis: 4 haploid spermatids
6. Absorption of the digested remains of old cuticle ❖ VASA EFFERENTIA – where mature sperm from the testes
7. Start of secretion of new procuticle pass out
(exo/endocuticle) ❖ SEMINAL VESICLE (STORAGE CHAMBER) – where
8. Ecdysis and expansion of the new cuticle mature sperms collect
9. Sclerotization ❖ VASA DEFERENTIA – join one another near midline to form
10. Start of wax secretion a single ejaculatory duct
❖ EJACULATORY DUCT – where sperm passes out of the
CONTROL OF MOLTING AND ASSOCIATED PROCESSES
males body thru a copulatory organ called aedeagus
1. ECDYSONE – play a vital role in controlling the events ❖ ACCESSORY GLANDS – 1 or more pairs of secretory
of molting; triggers the epidermal cells to change in glands; Connected to the system thru short ducts: some near
number and size (MOLTING HORMONE) the testes or seminal vesicles, others associated with the
2. BURSICON – controls sclerotization ejaculatory duct; in Periplaneta, form dense bunches of
3. A hormone released from the corpora allata-corpora tubules called the “MUSHROOM GLAND” of Huxley
cardiaca complex with ecdysone to control wax
FEMALE’S REPRODUCTIVE SYSTEM
secretion
4. A hormone with ecdysone controlling endocuticle ❖ PAIR OF OVARIES – swell with developing eggs when
production insect is actively reproducing, nearly filling the abdomen;
5. ECDEPTEROIDS – induce sclerotization in ligated subdivided into OVARIOLES
abdomen of blowfly larvae resulting to the induction of ❖ OOGONIA – 1st stage in the differentiation of an egg cell
de novo synthesis of enzyme dopa-decarboxylase in the ❖ OOCYTES – egg cell differentiated from the oogonium,
epidermal cells before maturation
❖ FEMALE ACCESSORY GLANDS – 1 or more pairs; usually
DIFFERENT TYPES OF CUTICLE
connected by small ducts to common oviduct or bursa
1. RIGID CUTICLE – produced as a result of tanning in the copulatrix; supply lubricants for the system; secrete protein-
outer part of the procuticle to form the exocuticle, but the rich egg shell (chorion) that surrounds the egg
extent of tanning, and hence the hardness of the cuticle
INSECT DEVELOPMENT – the growth and transformation of the
varies
insect from egg stage to the embryo, immature and adult stages
2. MEMBRANOUS CUTICLE – sclerites are joined by
flexible arthrodial membranes and in these the procuticle 2 Phases:
remains untanned but it also differs quantitatively from
1. EMBRYONIC DEVELOPMENT – development and
the cuticle of the sclerites in containing proteins with a
growth of the insect embryo inside the egg after the egg
different amino acid composition
of the female has been fertilized by the sperm of the
3. ELASTIC & EXTENSIBLE CUTICLE – some parts of
male insect
the cuticle contains a colorless, rubber-like protein called
2. POST-EMBRYONIC DEVELOPMENT – insect
resilin
development and growth after the egg has hatched.
REPRODUCTIVE SYSTEM During this period, the insect will undergo

Developing eggs move down the ovariole metamorphosis or change in form and size

Copulation (male deposits spermatophore in bursa ATYPICAL MODES OF REPRODUCTION
copulatrix)
❖ PARTHENOGENESIS – development from an unfertilized
Ovulation takes place
egg
Fertilization occurs as soon as sperm’s nucleus fuses
- THELYTOKOUS – female may produce only females
with egg cell’s nucleus
- ARRHENOTOKOUS – female produce only males
Oviposition or egg – laying follows closely
- AMPHITOKOUS or DEUTEROTOKOUS – female
Egg begins embryonic development
produce both sexes
❖ PAEDOGENESIS – reproduction in an immature stage
 - LARVAL PAEDOGENESIS – reproduction in an 2. PUPARIUM TANNING FACTING – regulates synthesis
immature stage of enzymes at the transcriptional level necessary for the
- PUPA PAEDOGENESIS – embryos are formed in the hydroxylation of tyrosine
haemocoele of paedogenetic mother-pupa (hemi-pupa)
HOW THE DIFFERENT HORMONES REGULATE
❖ NEOTENY – a non-terminal instar develops reproductive
DEVELOPMENT
features of an adult, including the ability to locate a mate,
copulate and deposit eggs (or larvae) in a conventional A stimulus from the environment is received by the insect’s
manner brain
- STREPSIPTERA – female development ceases at This is passed on to the nerves, then to the ganglia.
puparium stage Gland release hormone and is transported by the
❖ HERMAPRODITISM – having individuals that possess both haemolymph
testes and ovaries Hormone reaches target site
❖ POLYEMBRYONY – production of more than one embryo
TOXICOLOGY
from one egg by subdivision; restricted to parasitic insects
TOXICOLOGY – one of the oldest branches of pharmacology
Reproductive Strategies : “To Lay Eggs or Not To Lay Eggs”
The study of the harmful actions of chemicals on biologic
❖ OVIPARITY – egg laid shortly after fertilization
tissues
❖ OVOVIVIPARITY – eggs retained until embryogenesis
- metabolism and excretion of poisons,
complete
- action of poisons
❖ VIVIPARITY – eggs retained and embryo fed by mother
- treatment of poisoning
ENDOCRINE SYSTEM - systematic chemical and physical analyses and
diagnosis
HORMONES – internal secretions produced in or by one of the
endocrine glands
PESTICIDES – substances or mixture of substances intended to
TYPES OF ENDOCRINE ORGANS prevent, destroy, repel or mitigate any pest
1. NEUROSECRETORY CELLS OF THE BRAIN – groups
Insecticides
of modified nerve cells in the dorsal part of the
Miticides/Acaricides
protocerebrum that produce:
Nematicides
- Peptide hormone which activate the thoracic glands
Fungicides
- Prothoracicotrophic hormone (brain hormone)
Bactericides
- Bursicon
2. SPECIALIZED ENDOCRINE GLANDS Rodenticides

A. CORPORA CARDIACA – responsible for Molluscicides

discharging into the hemolymph neurosecretory INSECTICIDE TOXICOLOGY – study of a particular group of
materials produced by the brain toxic chemicals rather than on their effects in a particular group
B. CORPORA ALLATA – pair of small, ovoid cellular of animals
bodies of ectodermal origin associated with the
DEFINITION OF TERMS
stomodaeal ganglion behind the brain. Produce
juvenile hormone (JH) ABSORPTION – process by which a chemical crosses the
- JUVENILE HORMONE – controls various membrane barriers of a living organism and especially
metamorphosis and regulation of reproductive those processes by which a chemical is taken up from
development such as synthesis of yolk environmental media, including food and other ingested material
precursors or vitellogenins (regulates yolk
TOXICITY – refers to the ability of a poison (pesticide) to produce
deposition in eggs)
adverse effects ranging from slight symptoms as headaches to
C. THORACIC/PROTHORACIC GLANDS – a pair of
severe symptoms like coma, convulsions or death
diffused glands at the back of the head or in the
thorax TYPES OF TOXICITY
- ECDYSONE – molting hormone
❖ ACUTE TOXICITY – due to short-term exposure and
OTHER HORMONES adverse effects occurs within a relatively short period of time
of dosing or exposure
1. ANTERIOR SEGMENT REFRACTION FACTOR –
- ACUTE ORAL
cerebral neurosecretions released from the peripheral
- ACUTE DERMAL
nerve endings
- ACUTE INHALATION
 - LD50 (Lethal Dose 50) – single dose of a toxic R& D Process-HISTORY OF INSECTICIDE DEVELOPMENT
substance administered by any route, other than by
A. INORGANICS & BOTANICALS – 1st recorded use of
inhalation, that causes the death of 50% of an
insecticides: 2500 BC by Sumerians who believed that
animal population
rubbing the foul smelling sulfur on their bodies repel insects
- LD Lo (Lethal Dose Low) – lowest dose of a
and mites
substance reported to have caused death in humans
- Inorganic sulfur
or animals
- Arsenic
- LC50 (Lethal Concentration 50) – concentration of
- Lead arsenate, calcium arsenate, sodium arsenate,
a material in the air that kills 50% of a group of test
sodium fluorides, cryolite or sodium
animals when administered as a single exposure in
fluoroaluminate, sodium fluorosilicate and boric
a specific time period (usually 1hr)
acid
❖ CHRONIC TOXICITY – due to a repeated or long-term
- NATURAL PYRETHROIDS – 18-19th century
exposure and happens over a longer period of time than in
- ROTENOIDS – 19th century
acute toxicity
- Pyrethrum & derris – 1750 – 1880
DOSE – amount available for interaction with metabolic - DERRIS – a source of rotenone became popular to
processes or biologically significant receptors after crossing the control leaf- eating caterpillars; pyrethrum from
relevant biological boundary. This is the total amount of a chrysanthemum flowers was used as louse powder
substance administered to, taken up, or absorbed by an - NICOTINE – alkaloid compound was first used as
organism, tissue, or organ insecticide in 1763; isolated in pure form in 1828 by
Posselt and Reimmann and synthesized in 1904 by
PPM – parts per million
Pictet and Rotschy; Effective against aphids and other
PPB – parts per billion
soft-bodied insects; Highly toxic to mammals; easily
PPT – parts per trillion
absorbed in the skin
RESPONSE – the proportion of an exposed population with a - ROTENONE – was the 1st rotenoid to be identified; used
defined effect or the proportion of a group of individuals that as an insecticide before the advent of organosynthetic
demonstrates a defined effect in a given time at a given dose insecticides; was isolated by Geoffroy in 1892 and
rate named nicoulene
- NATURAL PYRETHROIDS – insecticides derived from
HALF-LIFE – time required for the concentration of a reactant in
flowering plants Chrysanthemum
a given reaction to reach a value that is the arithmetic mean of
- SYNTHETIC PYRETHROIDS – based from pyrethrum
its initial and final (equilibrium) values
compounds consisting of 6 esters
TOLERANCE – the ability of an organism to show less response B. MODERN INSECTICIDES (Synthetic Organics) –
to a specific dose of a chemical that it demonstrated on a prior Organochlorines – Organophosphates – Carbamates –
occasion; it refers to acquired resistance Pyrethroids – Neonicotinoids
- Highly effective insecticidal activity & low mammalian
INSECTICIDE USE PATTERN
toxicity: DDT as the most widely used pesticide in the
❖ INSECTICIDE USE PROFILE world until the 1960s
- Great transformation of Phil. agriculture in the last 50 – C. BIO-RATIONAL PESTICIDES – based on some type of
60 years where productivity started to increase in the naturally occurring products, e.g. biological insect
1960s is a consequence of improved agricultural hormones, developmental inhibitors, microbes, plant
infrastructure, massive increase in agricultural inputs extracts. These are synthesized to produce the new
(fertilizers & pesticides) and introduction of high yielding generation insecticides such as Bt, pyrethroids , spinosads
varieties. Pesticides = 18.2% in total agrochemical inputs and pheromones
expenditure
INSECTICIDE PRODUCTION
- The most commonly used are organophosphates,
carbamates and pyrethroids; mostly used on 1. SYNTHESIS
vegetables, bananas and rice - 1st synthesized in small scale by trained chemists in
- Endosulfan – an organophosphates that is most widely a well-equipped and sophisticated lab
used over the last 3 decades. Misused as a molluscicide - Involves modifying organic molecules on bioassay-
for golden snail control when organotin compounds assisted efficacy trials of a considerable number of
became scarce due to regulation test compounds or could even be a result of
❖ INSECTICIDE IMPORTATION – insecticides represent 56% serendipitous findings
of the total pesticide trade in the country in 1996
 - If compound proves viable in terms of activity and o Ensures that such products do not pose unintended or
cost-effectiveness, scale-up synthesis begins in the unreasonable risks to humans, animals and the
factory environment under the FIFRA and Food Quality
2. FORMULATION Protection Act( FQPA)
- Formulation of product in liquid or solid in the same o Conduct comprehensive review of pesticides that were
place or sent to a formulator first registered with the EPA prior to Nov. 1984 to
3. DILUTION consider the effect of older pesticides on human health
- Material is diluted to produce the amount of and the natural environment and to decide on the future
pesticide desired use of these pesticides (health and safety data)
- In most instances, the final product consists of 0.5 ❖ EUROPEAN FOOD SAFETY AUTHORITY (EU)
to 1 percent of the original a.i. in which it is now ❖ FERTILIZER & PESTICIDE AUTHORITY (PH)
ready to be applied
MATERIAL SAFETY DATA SHEET (MSDS)
DATA GENERATION AND THEIR VALUES SAFETY
A form with data regarding the properties of a particular
REGULATORY AGENCIES IN DATA GENERATION substance, copies of which are submitted to regulatory
FOR SAFETY VALUES. The crop protection industries agencies including local officials
are among the highly regulated in the world. Before a Data which is available on most pesticide products providing
new pesticide reaches the market, extensive laboratory relevant health and safety information on hazardous
and field tests are required by regulatory agencies chemicals
WHY REGULATE CHEMICAL PESTICIDES? To May include instructions for the safe use and potential
provide man and the environment with maximum hazard associated with a particular product (proper
possible protection from potential adverse effects and procedures for handling or working with a particular
facilitate international trade in food through the substance)
establishment of approved pesticide regulations Includes information on physical data (melting/boiling/flash
points), toxicity health effects, first aid, reactivity, storage,
REGULATORY AGENCIES
disposal, protective equipment to be used in handling and
Duties of chemical company: spill/leak procedures
- Identify uses of pesticide Specific to country and supplier since manufacturing and
- Test effectiveness of pesticide in the lab, formulation vary between manufacturers even within the
greenhouse, field under different environmental same country
conditions
ECONOMIC & LEGAL ASPECT OF INSECTICIDE USE
- Provide data on
o Chemical structure BENEFITS:
o Production
1. Higher yield, lower losses, higher quality products, more
o Formulation
uniform products and higher profit for the producers
o Fate persistence
2. Higher quality with less wastage, lower cost, uniform
o Environmental impact
product for ease of handling for the processors
- Submits a registration data package to regulatory
3. Lower risk of bio-contamination for the caterer
agency
4. More uniform products with fewer blemishes and increased
- Data includes:
sales for the retailer
o Studies on acute, chronic, reproductive and
5. Higher quality products, possibly lower costs for the
developmental toxicity to mammals, birds
consumer
and fish
6. Eradication of vectors by those concerned in public health
o Pesticide’s environmental fate, degradation
7. Best treatment for structural pests
and translocation to other sites
o Ecological studies on its harmful effects to, CONSEQUENCES:
an on non-target plants and animals
1. Inappropriate use caused problems of toxicity to non-target
❖ ENVIRONMENTAL PROTECTION AGENCY (USA) –
organism
grants registration of the product for certain uses, with
2. Residue on crops or environmental contamination
agreed label data and directions for use after being reviewed
3. Development of resistance
by govt. and other scientists
4. Need for frequent subsequent application
o Responsible for regulating pesticides with public health
5. As persistent organic pollutant – dangerous pesticide found
uses
in artesian wells around agricultural areas in Ilocos Norte,
 Laguna and Nueva Ecija, e.g. DDT, carbofuran, endosulfan, PROBIT ANALYSIS – statistical method in biological assay; it is
endrin, parathion residues of Ops, organochlorines, the most frequently used method in understanding dose-
pyrethroids found in soil and vegetables in Benguet response relationship
6. Pesticide misuse causes health impacts in farming
- A type of regression used to analyze binomial response
communities
variables ( a response variable with only 2 outcomes)
- increased mortality -dermal contamination
- It transforms the sigmoid dose-response curve to a
- depression in cholinesterase level
straight line that can be analyzed by regression either
- fetal abnormalities
thru least squares or maximum likelihood
- spontaneous abortion among pregnant women
- allergic reaction in eyes and skin, abdominal and chest PEST RESURGENCE – a situation in which a population, after
pain, dizziness, headache and nosebleed are common having been suppressed rebounds to numbers higher than
complaints of vegetable farmers in Benguet before suppression occurred. As a consequence of insecticide
resistance and destruction of natural enemies, a dramatic
TYPE OF BIOASSAY
increase in numbers of the targeted pest can occur, and if natural
BIOASSAY – a process of determining the biological activity of enemies recover much more slowly than the pest population, the
a substance and comparing its effect with those standard pest can exceed levels found prior to insecticide treatment
preparations on a test organism
SECONDARY PEST OUTBREAK – combination of suppression
❖ INJECTION METHOD – these method eliminates the of original target pest and effects of development of resistance
differences in surface activity, penetrability and other and destruction of natural enemies can lead to insects previously
properties of the body wall, digestive tract or the considered not pests being released control and become major
respiratory system of different insects pest
❖ TOPICAL METHOD – insecticide maybe applied
MECHANISM OF BIOLOGICAL ACTIVITY OF INSECTICIDES
topically to the outer surface of the insect using a
micropipettor or a special syringe directly to insects. This ❖ STOMACH INSECTICIDES – exert toxic action only after
is use to measure the relative toxicity of test compounds, being introduced into the alimentary canal through feeding
particularly contact poisons on treated substrates
❖ DIPPING or IMMERSION METHOD – also known as ❖ CONTACT INSECTICIDES – cause e toxicity when insects
“larval dip” method; another form of topical application come in contact with them and transported to site of action
using diluted solution of formulated insecticide via the circulatory system
developed for simple toxicological evaluation in field ❖ SYSTEMATIC INSECTICIDES – when applied to the plant,
conditions for extensions and field workers soil or used as a solution, preferably in the presence of
❖ RESIDUAL CONTACT TOXICITY TEST – involves significant water to aid uptake by plants, they are
coating a thin film of diluted solutions of formulated translocated to the untreated parts in concentrations that
insecticide onto a leaf, filter paper, glass or plastic make translocation sites toxic
surfaces and insects are released unto the treated
INSECTICIDE NOMENCLATURE – formal process
surface and thus exposed to the insecticide
❖ LEAF-DIP METHOD – insects are released on the INSECTICIDE TOXICITY – degree or intensity of virulence of a
treated leaf surface and allowed to feed poison
❖ ANTIFEEDANT TEST – dissolved compounds and the
MODES OF ACTION – involves ANATOMICAL, PHYSICAL, &
other half with methanol only and insects are introduced
BIOCHEMICAL RESPONSES
to the treated leaf and allowed to feed. Insects will not
feed on the portion laced with antifeedant substances MAJOR GROUPS BASED ON MODE OF ACTION

and feed only on the toxic free surface 1. NERVE POISON – affect the insect’s nervous system
❖ DIET INCORPORATION TEST – incorporates the e mostly as narcotics, axonic poisons and synaptic
toxicant in the artificial diet poisons
❖ IN PLANT ASSAY – use to assess the effects of o NARCOTICS – mostly physical
systemic insecticides on sucking insects. Plants are o AXONIC POISONS – act primarily by interrupting
allowed to take in first the toxin before the test insects /disrupting normal axonic transmission of the
are released nervous system
❖ HIGH-THROUGHPUT SCREENING – designed to - AXONIC TRANSMISSION – type of nerve
screen efficiently hundreds or thousands of chemicals in trans. conveying an impulse from an arrival
a short period of time with limited manpower point along the axon to another neuron, muscle,
or gland, or from a receptor cell
 o SYNAPTIC POISONS – act by interrupting synaptic 1b. Cationic – carry positive charge
transmission of the nervous system 1c. Non-ionic surfactants – have no residual
- SYNAPTIC TRANSMISSION – type of impulse charge and electrically neutral
trans. which is mainly chemical 2. STICKERS – materials that increase the
- Nicotine adhesion of solid particles to target surfaces
- Nicotine sulfate 3. EXTENDERS – function like stickers by
- Neonicotinoids – poison by mimicking retaining pesticides longer on the target area,
acetylcholine at the synapse; the receptors slow down evaporation and inhibit degradation
cannot distinguish between acetylcholine and by sunlight
nicotine 4. PLANT PENETRANTS – have molecular
- Spinosyns configuration that enhances penetration of some
- Formamidines – cause death by affecting pesticides into plants
enzymes involved with other chemical 5. DRIFT CONTROL ADHESIVE/DEPOSITION
transmitters at certain nerve synapses AIDS – improve on target placement of the
2. MUSCLE POISON – have a direct influence on muscle pesticide spray by increasing droplet size
tissue 6. DEFOAMING AGENTS – can reduce or
3. PHYSICAL TOXICANTS – block metabolic process by eliminate the foam or frothy “head” in sprayer
physical rather than chemical means tanks produced by the formulation
7. THICKENERS – used to control drift or slow
INSECTICIDE FORMULATIONS – involves manufacture of a
down evaporation after the deposition of spray
technical grade material
materials on target area
WHY ARE INSECTICIDES FORMULATED IN MANY FORMS? o Preservatives – antioxidants to slow down
decomposition of a.i
1. For storability
o Perfume – gives a pleasant odor to the pesticide
2. Ease and simplicity of application
o Coloring materials – added to differentiate them
3. Safety to applicator and environment
from non-toxic ones; may or may not be added
4. Improved biological efficacy
Synergists – chemicals that do not possess insecticidal
- A single insecticide is sold in different formulations. In
property but enhance the efficacy of the a.i.
choosing the right formulation, one has to consider the
following: TYPES OF INSECTICIDE FORMULATIONS
o Content of active ingredient
1. CONVENTIONAL or “TRADITIONAL”
o Ease in handling and mixing
FORMULATIONS
o Safety of the applicator
o Wettable powder
o Nature of pest to be controlled ( agri., forest,
o Dustable powder (DP)
urban, structure, etc.)
o Granules (GR)
o Efficacy against the pest
o Solution concentrate (SL)
o Habitat of pests
o Emulsifiable concentrate (ES)
COMPONENTS OF INSECTICIDE FORMULATIONS o Suspension concentrates
o Seed treatments
Active ingredient (a.i.)
o Fumigants
Inert materials/other ingredients
o Baits
o Solvents – a liquid that dissolves the a. i.. It
2. NEW-GENERATION FORMULATIONS
distributes the solute evenly throughout the solution
o Oil-in-emulsion (EW)
o Carriers or diluents – liquid or solids added to a
o Suspoemulsion (SE)
formulation to aid in the delivery of a.i.
o Controlled-release formulation
o Adjuvant – a chemical that does not possess
o Water-dispersable granules (WG)
pesticidal activity but improves its toxicity and
o Gelatinized fluids
effectiveness
o Ultra-low-volume (ULV) liquids
TYPES OF ADJUVANTS
o Microencapsulated product (ME)
1. SURFACTANTS – wetting agents that
o Water-soluble packets (WSP)
physically alter the surface tension of a spray
o Attractants
droplet
1a. Anionic Surfactants – carry a negative
charge, usually salts of certain organic acids
 CLASSIFICATION OF INSECTICIDES Egg-shell thinning
Degenerative lesions in the liver
Stage of development of arthropod intended to be
Abnormal reproduction
killed
Hypersensitivity
Route of entry – contact, stomach or fumigant
Class of compound – inorganic, organic PESTICIDE RESIDUES – any substance or mixture of
Origin of a.i. – natural-based or synthetic substances in food for humans and animals resulting from the
Mode of action – nerve poisons, muscle poisons, use of a pesticide and includes any specific derivatives, such as
physical toxicants degradation and conversion products, metabolites, reaction
Chemical structure – chlorinated hydrocarbons, products, and impurities which are considered to be of
organophosphorous, carbamates, pyrethroids, toxicological importance
neonicotinoids, developmental insecticides, microbials
MAXIMUM RESIDUE LIMIT – maximum concentration for a
MOVEMENT OF INSECTICIDES IN THE ENVIRONMENT pesticide residue resulting from the use of a pesticide

A. PENETRATION OF INSECTICIDE THRU THE GOOD AGRICULTURAL PRACTICE – the officially
INSECT’S CUTICLE recommended or authorized usage of pesticides under practical
B. RESIDUES OF INSECTICIDES (water, soil, air, conditions at any stage of products’ storage, transport,
animals, humans, commodities [food / feed]) distribution, and processing of food, agricultural commodities
C. ENVIRONMENTAL ALTERATION OF INSECTICIDE and animal feed, bearing in mind the variations in requirements
RESIDUES within and between regions, which take into account the
D. HAZARDS OF INSECTICIDES TO NON-TARGET minimum quantities necessary to achieve adequate control
ORGANISMS applied in a manner so as to leave a residue which is the smallest
amount practicable and which is toxicologically acceptable
RESIDUES – quantity of the original active ingredient or its
biologically -active transformation product which remains in or on ENVIRONMENTAL ALTERATION OF INSECTICIDAL
a substrate after weathering factors have taken effect RESIDUES

FACTORS AFFECTING RATE OF INSECTICIDE DEGRADATION to less toxic forms or in some instances
BREAKDOWN more toxic products
1. MICROBIAL DEGRADATION – yeasts, bacteria
Chemistry of the insecticide (water
and fungi known to breakdown carbaryl and
solubility/polarity/volatility/chem. reactivity-
chlorpyrifos
stability)
2. Degradation by sunlight and other physical
Chemical and physical property of spray additives
factors
Chemistry (pH, hardness) of the spray water
TRANSFER/TRANSLOCATION or BIOCONCENTRATION
Environmental factors (temperature, humidity,
into some ecosystems
rainfall)
IMMOBILIZATION
Plant factors (surface chemistry, waxiness, etc)
HAZARDS OF INSECTICIDES TO NON-TARGET
RESIDUE CHARACTERISTICS OF I IN SOILS
ORGANISMS
1. ORGANOCHLORINES – highly persistent in soil and
1. ACUTE TOXICITY (short-term toxicity) – measures
water
direct effect on organism but cannot totally represent
2. ORGANOPHOSPAHATES – breakdown in soil slow;
ecological hazard of compound
persistence increases in acidic soils
2. CHRONIC TOXICITY (long-term toxicity) – associated
3. CARBAMATES – have soil half-life of 7-28 days
with the build up or persistence of insecticides in the
4. BOTANICALS – short persistence on soil, water &
environment
plants
UNDESIRABLE EFFECTS OF INSECTICIDES
BIOLOGICAL MAGNIFICATION or BIOLOGICAL
CONCENTRATION – process by which biological organisms 1. DEVELOPMENT OF RESISTANCE
increase their pesticide content in relation to their position in the 2. DESTRUCTION OF NON-TARGET ORGANISMS,
food chain including pollinators and natural enemies of pests
and soil arthropods
EFFECTS OF ACCUMULATION OF PESTICIDES IN THE
3. PEST RESURGENCE
BODY OF BIOLOGICAL ORGANISMS

Death
 WAYS TO AVOIDANCE OF RESISTANCE

1. REDUCE PESTICIDE APPLICATION, thus reduce the
selection pressure, and the population is allowed to
recover
2. SPOT APPLICATION
3. USE NP INSECTICIDES
4. ENCOURAGE NATURAL ENEMIES
5. USE OF NEGATIVELY CORRELATED PESTICIDES
(affect different organ/enzyme systems)
6. SECONDARY PEST OUTBREAK
7. ADVERSE ENVIRONMENTAL EFFECTS resulting to
contamination of soils, water system and the produce
itself that accumulate biologically, especially in
vertebrates, as a result of biological magnification thru
food chains.
8. DANGERS TO HUMAN HEALTH EITHER DIRECTLY
OR INDIRECTLY