ECOLOGY

Introduction to Ecology
Ecological Terms and Concepts

By the end of the lesson, the learner should be able to:
Define ecology and explain its importance. Distinguish between biotic and abiotic factors. State the significance of ecological studies.

Q/A: Review of organism-environment interactions. Discussion of ecology definition and importance. Teacher exposition of ecological studies for conservation and biodiversity.

Charts - Definition of ecology, Examples of ecological studies
Charts - Ecological terms definitions, Diagrams of biosphere layers

Certificate Biology Form 3, Pages 36-37

ECOLOGY

Ecosystems - Structure and Components
Abiotic Factors - Temperature and Water
Abiotic Factors - Light and Humidity

By the end of the lesson, the learner should be able to:
Define ecosystem and describe its components. Identify abiotic and biotic factors in ecosystems. Give examples of different ecosystem types.
Explain the importance of light intensity in ecosystems. Describe humidity effects on plant and animal distribution. Relate light to photosynthesis and productivity.

Discussion of ecosystem as natural self-sustaining unit. Exposition of abiotic factors (temperature, water, light) and biotic factors (producers, consumers). Examples of forest, grassland, aquatic ecosystems.
Discussion of light intensity and photosynthesis rates. Exposition of humidity effects on transpiration. Q/A: Adaptations to low light and dry conditions. Examples of shade plants and xerophytes.

Charts - Ecosystem components, Examples of different ecosystems
Charts - Temperature effects on organisms, Water cycle diagram
Charts - Light intensity effects, Humidity and transpiration

Certificate Biology Form 3, Pages 37-38
Certificate Biology Form 3, Pages 40-42

ECOLOGY

Abiotic Factors - Wind, Altitude, and Salinity
Biotic Factors - Producers

By the end of the lesson, the learner should be able to:
Explain effects of wind on plant growth. Describe altitude effects on organisms. Analyze salinity effects on plant distribution.

Discussion of wind effects on transpiration and plant shape. Exposition of altitude effects on atmospheric pressure and temperature. Q/A: Halophyte adaptations to saline conditions.

Charts - Wind effects on plants, Altitude zonation, Halophyte examples
Charts - Examples of producers, Photosynthesis equation

Certificate Biology Form 3, Pages 42-43

ECOLOGY

Biotic Factors - Consumers
Biotic Factors - Decomposers and Detrivores

By the end of the lesson, the learner should be able to:
Classify consumers into different types. Distinguish primary, secondary, and tertiary consumers. Give examples of herbivores and carnivores.

Detailed discussion of consumer types - primary (herbivores), secondary (carnivores), tertiary consumers. Examples: grazers, browsers, predators. Q/A: Omnivores as multiple-level consumers.

Charts - Consumer classification, Examples of different consumer types
Charts - Examples of decomposers, Nutrient cycling diagrams

Certificate Biology Form 3, Pages 44-45

ECOLOGY

Nitrogen Cycle

By the end of the lesson, the learner should be able to:
Describe the nitrogen cycle process. Explain the role of bacteria in nitrogen fixation. Identify stages of nitrification and denitrification.

Detailed study of nitrogen cycle using Fig 2.1. Discussion of nitrogen-fixing bacteria, nitrifying bacteria, and denitrifying bacteria. Q/A: Importance of nitrogen for protein synthesis.

Charts - Fig 2.1 nitrogen cycle, Table 2.1 bacterial roles

Certificate Biology Form 3, Pages 38-40

ECOLOGY

Trophic Levels and Energy Flow

By the end of the lesson, the learner should be able to:
Define trophic levels and identify different levels. Explain energy flow through ecosystems. Describe energy losses between trophic levels.

Teacher exposition of trophic levels - producers to tertiary consumers. Discussion of unidirectional energy flow and energy losses. Q/A: Reasons for energy loss at each level.

Charts - Trophic level diagrams, Energy flow patterns

Certificate Biology Form 3, Pages 43-45

ECOLOGY

Trophic Levels and Energy Flow
Food Chains

By the end of the lesson, the learner should be able to:
Define trophic levels and identify different levels. Explain energy flow through ecosystems. Describe energy losses between trophic levels.
Define food chains and construct examples. Identify energy flow direction in food chains. Give examples from terrestrial and aquatic habitats.

Teacher exposition of trophic levels - producers to tertiary consumers. Discussion of unidirectional energy flow and energy losses. Q/A: Reasons for energy loss at each level.
Study of food chain examples from textbook. Construction of terrestrial food chains (grass→impala→leopard). Aquatic food chains (plankton→fish→shark). Practice drawing food chains.

Charts - Trophic level diagrams, Energy flow patterns
Charts - Food chain examples, Arrows showing energy direction

Certificate Biology Form 3, Pages 43-45
Certificate Biology Form 3, Pages 46-47

ECOLOGY

Food Webs

By the end of the lesson, the learner should be able to:
Explain food webs as interconnected food chains. Construct food webs from given organisms. Analyze complex feeding relationships.

Study of Fig 2.4 simple food web. Construction of food webs showing multiple feeding relationships. Q/A: How food webs show ecosystem complexity.

Charts - Fig 2.4 food web, Complex food web examples

Certificate Biology Form 3, Pages 46-47

ECOLOGY

Ecological Pyramids - Introduction

By the end of the lesson, the learner should be able to:
Define ecological pyramids. Distinguish types of ecological pyramids. Explain pyramid of numbers concept.

Teacher exposition of ecological pyramids as graphical representations. Discussion of pyramid types - numbers, biomass, energy. Study of pyramid of numbers using Fig 2.6.

Charts - Fig 2.6 pyramid of numbers, Different pyramid types

Certificate Biology Form 3, Pages 47-49

ECOLOGY

Pyramid of Numbers and Biomass

By the end of the lesson, the learner should be able to:
Construct pyramids of numbers from data. Explain inverted pyramids. Define and construct pyramid of biomass.

Practice constructing normal and inverted pyramids of numbers. Discussion of when inverted pyramids occur (parasites, large trees). Study of biomass calculation and pyramid construction.

Data sets for pyramid construction, Calculators, Graph paper

Certificate Biology Form 3, Pages 47-50

ECOLOGY

Interspecific Relationships - Predation

By the end of the lesson, the learner should be able to:
Define predator-prey relationships. Describe predator and prey adaptations. Give examples of predation in different habitats.

Detailed discussion of predation as feeding relationship. Study of predator adaptations (speed, senses, hunting strategies). Q/A: Prey defense mechanisms (camouflage, mimicry, protective covering).

Charts - Predator-prey examples, Adaptation illustrations

Certificate Biology Form 3, Pages 50-52

ECOLOGY

Parasitism - Types and Adaptations

By the end of the lesson, the learner should be able to:
Define parasitism and distinguish parasite types. Explain endoparasites and ectoparasites. Describe parasitic adaptations.

Discussion of parasitism as harmful feeding relationship. Study of endoparasites (tapeworms, malaria parasites) vs ectoparasites (ticks, fleas). Detailed analysis of structural and physiological adaptations.

Charts - Parasite examples, Adaptation diagrams, Life cycle illustrations

Certificate Biology Form 3, Pages 52-57

ECOLOGY

Saprophytism and Economic Importance

By the end of the lesson, the learner should be able to:
Define saprophytism and role of decomposers. Explain economic importance of saprophytes. Describe harmful effects of saprophytes.

Discussion of saprophytes as decomposers. Economic benefits: recycling, soil fertility, antibiotics, fermentation. Harmful effects: food decay, food poisoning. Q/A: Useful vs harmful saprophytic activities.

Charts - Decomposition process, Examples of useful and harmful saprophytes

Certificate Biology Form 3, Pages 57-60

ECOLOGY

Mutualism and Symbiosis

By the end of the lesson, the learner should be able to:
Define mutualism and symbiosis. Give examples of mutually beneficial relationships. Explain lichens, mycorrhiza, and nitrogen-fixing bacteria.

Study of mutualistic relationships with examples: lichens (algae-fungi), mycorrhiza (fungi-tree roots), nitrogen-fixing bacteria (Rhizobium-legumes). Q/A: Benefits to both partners in each relationship.

Charts - Fig 2.8 lichens, Fig 2.9 root nodules, Symbiotic relationship examples

Certificate Biology Form 3, Pages 60-63

ECOLOGY

Commensalism

By the end of the lesson, the learner should be able to:
Define commensalism and give examples. Distinguish commensalism from other relationships. Analyze one-sided beneficial relationships.

Discussion of commensalism as one-sided benefit. Examples: ox-pecker birds and buffalo, cattle egrets and grazing animals, epiphytic plants on trees. Q/A: Why host doesn't benefit or suffer.

Charts - Commensalism examples, Epiphyte illustrations

Certificate Biology Form 3, Pages 63-64

ECOLOGY

Population Studies - Introduction

By the end of the lesson, the learner should be able to:
Define population and population density. Explain factors affecting population size. Describe carrying capacity concept.

Teacher exposition of population definitions. Discussion of biological factors: birth rate, death rate, sex ratio. Q/A: Environmental factors affecting population growth.

Charts - Population definitions, Factors affecting population

Certificate Biology Form 3, Pages 60-61

ECOLOGY

Population Estimation Methods - Direct Counting
Capture-Mark-Release-Recapture Method

By the end of the lesson, the learner should be able to:
Describe direct counting methods. Explain when direct counting is suitable. Practice population estimation calculations.
Explain the capture-recapture method. Apply the capture-recapture formula. Identify sources of error in the method.

Discussion of direct counting for small populations and large slow-moving animals. Examples: tree counting, aerial surveys. Practice with simple population counts and density calculations.
Detailed study of capture-recapture method for mobile animals. Practice using the formula: P = (M × R)/m. Discussion of assumptions and sources of error.

Calculators, Sample area measurements, Population data sets
Calculators, Sample data for calculations, Formula charts

Certificate Biology Form 3, Pages 61-62

ECOLOGY

Capture-Mark-Release-Recapture Method

By the end of the lesson, the learner should be able to:
Explain the capture-recapture method. Apply the capture-recapture formula. Identify sources of error in the method.

Detailed study of capture-recapture method for mobile animals. Practice using the formula: P = (M × R)/m. Discussion of assumptions and sources of error.

Calculators, Sample data for calculations, Formula charts

Certificate Biology Form 3, Pages 61-62

ECOLOGY

Quadrat and Transect Methods

By the end of the lesson, the learner should be able to:
Describe quadrat sampling method. Explain line and belt transect techniques. Practice population estimation using sampling.

Study of quadrat method for plants and small animals using Fig 2.12. Discussion of line transects for distribution patterns. Practice calculations using sampling formulas.

Quadrats (if available), Measuring tapes, Sample area data, Calculators

Certificate Biology Form 3, Pages 62-64

ECOLOGY

Plant Adaptations - Xerophytes

By the end of the lesson, the learner should be able to:
Define xerophytes and their habitat conditions. Describe structural adaptations for water conservation. Explain physiological adaptations of desert plants.

Study of xerophyte adaptations using Fig 2.14. Discussion of modified leaves, water storage, extensive roots, waxy cuticles. Q/A: Stomatal adaptations and reduced transpiration.

Charts - Fig 2.14 xerophyte examples, Cactus specimens (if available)

Certificate Biology Form 3, Pages 64-66

ECOLOGY

Plant Adaptations - Hydrophytes

By the end of the lesson, the learner should be able to:
Define hydrophytes and aquatic conditions. Describe adaptations to aquatic environments. Explain buoyancy and gaseous exchange adaptations.

Study of hydrophyte adaptations using Fig 2.15. Discussion of aerenchyma tissue, stomatal distribution, reduced xylem. Q/A: Adaptations to low light and oxygen levels in water.

Charts - Fig 2.15 aquatic plants, Water plant specimens (if available)

Certificate Biology Form 3, Pages 66-68

ECOLOGY

Plant Adaptations - Halophytes and Mesophytes
Environmental Pollution - Introduction

By the end of the lesson, the learner should be able to:
Define halophytes and saline habitat adaptations. Describe mesophyte characteristics. Compare different plant adaptation types.
Define pollution and identify major pollutants. Classify types of environmental pollution. Explain pollution effects on ecosystems.

Study of mangrove adaptations using Fig 2.16. Discussion of salt excretion, pneumatophores, viviparous seeds. Q/A: Mesophyte balance between water uptake and loss.
Teacher exposition of pollution definition and sources. Discussion of air, water, and soil pollution types. Q/A: Human activities causing pollution and ecosystem disruption.

Charts - Fig 2.16 mangroves, Comparison table of plant types
Charts - Pollution types and sources, Environmental damage photos

Certificate Biology Form 3, Pages 68-70
Certificate Biology Form 3, Pages 70-71

ECOLOGY

Air Pollution and Global Warming

By the end of the lesson, the learner should be able to:
Identify sources and effects of air pollution. Explain greenhouse effect and global warming. Describe ozone layer depletion.

Study of greenhouse effect using Fig 2.18. Discussion of greenhouse gases, acid rain, photochemical smog. Q/A: CFCs and ozone layer destruction, UV radiation effects.

Charts - Fig 2.18 greenhouse effect, Air pollution sources diagram

Certificate Biology Form 3, Pages 71-75

ECOLOGY

Air Pollution and Global Warming

By the end of the lesson, the learner should be able to:
Identify sources and effects of air pollution. Explain greenhouse effect and global warming. Describe ozone layer depletion.

Study of greenhouse effect using Fig 2.18. Discussion of greenhouse gases, acid rain, photochemical smog. Q/A: CFCs and ozone layer destruction, UV radiation effects.

Charts - Fig 2.18 greenhouse effect, Air pollution sources diagram

Certificate Biology Form 3, Pages 71-75

ECOLOGY

Water Pollution

By the end of the lesson, the learner should be able to:
Identify sources of water pollution. Explain effects on aquatic ecosystems. Describe eutrophication process.

Study of water pollution sources using Fig 2.20. Discussion of domestic waste, industrial effluents, pesticides, oil spills. Q/A: Eutrophication, algal blooms, and oxygen depletion.

Charts - Fig 2.20 water pollution sources, Eutrophication process diagram

Certificate Biology Form 3, Pages 75-78

ECOLOGY

Soil Pollution and Land Degradation

By the end of the lesson, the learner should be able to:
Identify causes of soil pollution. Explain land degradation processes. Describe soil conservation methods.

Discussion of soil pollution from non-biodegradable materials, pesticides, oil spills. Study of soil conservation using Fig 2.22. Q/A: Terracing, contour ploughing, agroforestry.

Charts - Fig 2.22 soil conservation methods, Soil erosion examples

Certificate Biology Form 3, Pages 78-82

ECOLOGY

Human Diseases and Ecology
Malaria and Parasitic Diseases

By the end of the lesson, the learner should be able to:
Relate environmental conditions to disease occurrence. Describe waterborne diseases. Explain disease transmission and prevention.
Describe malaria life cycle and transmission. Explain bilharzia and parasitic worm diseases. Analyze prevention and control measures.

Study of cholera, typhoid, amoebic dysentery transmission and prevention. Discussion of poor sanitation as disease cause. Q/A: Hygiene practices and disease control.
Detailed study of Plasmodium life cycle using Fig 2.24. Discussion of Anopheles mosquito control. Study of Schistosoma and Ascaris adaptations and prevention.

Charts - Disease transmission cycles, Prevention methods
Charts - Fig 2.24 malaria life cycle, Parasite life cycles, Prevention methods

Certificate Biology Form 3, Pages 82-84
Certificate Biology Form 3, Pages 84-88

ECOLOGY

Practical Activities and Field Studies

By the end of the lesson, the learner should be able to:
Apply ecological knowledge in practical investigations. Conduct population studies and food chain observations. Examine pollution in local environment.

Practical session: observing feeding relationships, estimating populations using quadrats, identifying pollution sources. Students conduct mini-ecosystem studies. Safety: Proper handling of specimens.

Quadrats, Sweep nets, Measuring tapes, Notebooks, Collection containers, Hand lenses

Certificate Biology Form 3, Pages 88-96

REPRODUCTION IN PLANTS AND ANIMALS

Introduction and Importance of Reproduction

By the end of the lesson, the learner should be able to:
Define reproduction and distinguish between asexual and sexual reproduction. Explain the importance of reproduction for species survival. State the role of cell division in reproduction.

Q/A: Review of basic reproduction concepts. Discussion of reproduction as biological process for producing new individuals. Teacher exposition of species survival importance. Q/A: Examples of organisms in danger due to poor reproduction (cheetah).

Charts - Types of reproduction, Examples of reproduction in different organisms

Certificate Biology Form 3, Page 99

REPRODUCTION IN PLANTS AND ANIMALS

Chromosomes and Genes
Mitosis - Introduction and Stages

By the end of the lesson, the learner should be able to:
Define chromosomes and genes. Explain diploid and haploid chromosome numbers. Describe the relationship between chromosomes, genes, and heredity. Give examples of chromosome numbers in different organisms.

Teacher exposition of chromosomes as DNA strands carrying genes. Discussion of diploid (2n) and haploid (n) numbers with examples: humans (46), fruit flies (8), onions (16). Q/A: Genes as functional units determining organism characteristics.

Charts - Chromosome structure, Examples of chromosome numbers in different species
Charts - Fig 3.1 mitosis stages, Models of cell division, Microscope slides of mitosis

Certificate Biology Form 3, Page 100

REPRODUCTION IN PLANTS AND ANIMALS

Mitosis - Differences in Plants and Animals
Meiosis - Introduction and Meiosis I

By the end of the lesson, the learner should be able to:
Compare mitosis in plant and animal cells. Explain cytokinesis differences. Describe the significance of mitosis. Examine mitosis in onion root tips practically.

Study of plant mitosis using Fig 3.2 - cell wall formation vs. invagination. Discussion of centriole presence in animals only. Practical examination of onion root tips to observe mitosis stages. Students draw and identify stages observed.

Charts - Fig 3.2 plant mitosis, Microscopes, Onion root tips, Acetocarmine stain, Glass slides, Cover slips
Charts - Fig 3.3A Meiosis I stages, Diagrams of homologous chromosomes, Crossing over illustrations

Certificate Biology Form 3, Pages 102-103, 108-109

REPRODUCTION IN PLANTS AND ANIMALS

Meiosis II and Comparison with Mitosis
Introduction to Reproduction
Cell Division - Mitosis

By the end of the lesson, the learner should be able to:
Describe the stages of Meiosis II. Compare and contrast mitosis and meiosis. Explain the significance of meiosis in genetic variation.
To distinguish between sexual and asexual reproduction. To state the importance of reproduction. To define genes and chromosomes. To describe the role of chromosomes in cell division.

Study of Meiosis II using Fig 3.3B: Prophase II, Metaphase II, Anaphase II, Telophase II. Detailed comparison using Table 3.1 - differences in purpose, number of divisions, chromosome behavior, genetic outcomes.
Q/A: Review classification concepts. Discussion: Definition of reproduction. Teacher exposition: Types of reproduction with examples. Tabulate differences between sexual and asexual reproduction. Q/A: Importance of reproduction in organisms.

Charts - Fig 3.3B Meiosis II stages, Table 3.1 comparison chart, Summary diagrams
Charts showing types of reproduction, Textbook, Wall charts
Charts showing mitosis stages, Microscope slides, Drawing materials

Certificate Biology Form 3, Pages 105-107
Certificate Biology Form 3, Pages 99-100

REPRODUCTION IN PLANTS AND ANIMALS

Mitosis in Young Root Tip
Meiosis Process

By the end of the lesson, the learner should be able to:
To observe mitosis in a young root tip. To identify different stages of mitosis under microscope. To draw cells showing stages of mitosis.

Practical work: Observing mitosis in onion root tip. Procedure: Preparation of slides, staining with iodine. Microscopic observation of different stages. Drawing and labeling observed cells. Recording observations.

Onion root tips, Microscope, 1M HCl, Cover slides, Iodine solution, Glass slides
Charts showing meiosis stages, Drawing materials, Textbook

Certificate Biology Form 3, Pages 102-103

REPRODUCTION IN PLANTS AND ANIMALS

Meiosis in Plant Cells
Asexual Reproduction - Binary Fission

By the end of the lesson, the learner should be able to:
To identify various stages of meiosis in plant cells. To observe meiosis in flower buds. To explain significance of meiosis.

Practical work: Observing meiosis in young flower buds. Preparation of slides from flower buds. Microscopic examination of meiotic stages. Drawing cells showing meiosis stages. Discussion: Significance of meiosis in gamete formation.

Flower buds, 1M HCl, Heat source, Glass slides, Filter paper, Microscope
Charts showing binary fission, Prepared slides of amoeba, Microscope, Drawing materials

Certificate Biology Form 3, Pages 105-108

REPRODUCTION IN PLANTS AND ANIMALS

Spore Formation and Budding

By the end of the lesson, the learner should be able to:
To describe spore formation in bread mould. To explain budding in yeast. To observe and draw various fungi.

Examination of bread/ugali mould under microscope. Identification of hyphae and sporangia. Observing yeast cells showing budding. Drawing and labeling fungal structures. Discussion: Conditions for spore formation and budding.

Bread/ugali mould, Microscope, Yeast culture, 10% sugar solution, Methylene blue, Hand lens

Certificate Biology Form 3, Pages 113-115

REPRODUCTION IN PLANTS AND ANIMALS

Sexual Reproduction in Plants - Flower Structure
Pollination - Insect Pollinated Flowers

By the end of the lesson, the learner should be able to:
To draw and label a flower. To identify parts of a flower. To explain flower terminologies. To count sepals, petals, stamens and carpels.

Practical work: Examining bean flowers, morning glory, and hibiscus. Dissection of flowers to identify parts. Counting floral parts and recording. Drawing longitudinal section of flower. Discussion: Functions of flower parts.

Bean flowers, Morning glory, Hibiscus, Hand lens, Scalpels, Drawing materials
Insect-pollinated flowers, Hand lens, Measuring rulers, Drawing materials

Certificate Biology Form 3, Pages 115-117

REPRODUCTION IN PLANTS AND ANIMALS

Wind-Pollinated Flowers and Adaptations
Self-Pollination Prevention and Fertilisation

By the end of the lesson, the learner should be able to:
To describe structure of wind-pollinated flowers. To identify adaptive features of wind-pollinated flowers. To compare insect and wind pollination.
To discuss mechanisms preventing self-pollination. To describe fertilisation process in flowering plants. To explain double fertilisation.

Practical examination: Structure of grass flowers, maize tassels. Identification of glumes, spikes, spikelets. Tabulate differences between insect and wind-pollinated flowers. Discussion: Adaptive features for wind pollination.
Discussion: Methods preventing self-pollination. Teacher exposition: Process of fertilisation. Drawing diagrams showing fertilisation stages. Q/A: Significance of double fertilisation. Discussion: Formation of zygote and endosperm.

Wind-pollinated flowers (grass, maize), Hand lens, Charts, Drawing materials
Charts showing fertilisation, Drawing materials, Textbook

Certificate Biology Form 3, Pages 120-121
Certificate Biology Form 3, Pages 121-123

REPRODUCTION IN PLANTS AND ANIMALS

Self-Pollination Prevention and Fertilisation

By the end of the lesson, the learner should be able to:
To discuss mechanisms preventing self-pollination. To describe fertilisation process in flowering plants. To explain double fertilisation.

Discussion: Methods preventing self-pollination. Teacher exposition: Process of fertilisation. Drawing diagrams showing fertilisation stages. Q/A: Significance of double fertilisation. Discussion: Formation of zygote and endosperm.

Charts showing fertilisation, Drawing materials, Textbook

Certificate Biology Form 3, Pages 121-123

REPRODUCTION IN PLANTS AND ANIMALS

Seed and Fruit Development

By the end of the lesson, the learner should be able to:
To explain seed formation. To describe fruit development. To classify fruits using specific criteria.

Discussion: Process of seed formation from ovule. Explanation of fruit development from ovary. Practical work: Examining variety of fruits. Classification of fruits into types. Recording observations and drawing fruits.

Variety of fruits, Petri dishes, Scalpels, Drawing materials, Charts

Certificate Biology Form 3, Pages 123-126

REPRODUCTION IN PLANTS AND ANIMALS

Placentation and Internal Fruit Structure

By the end of the lesson, the learner should be able to:
To define placentation. To identify types of placentation. To label internal structure of fruits. To examine ovaries of various fruits.

Teacher exposition: Types of placentation. Practical examination: Ovaries of beans, sunflower, pawpaw, orange. Drawing diagrams showing placentation types. Vertical sections of fruits showing internal structure.

Fruits (beans, sunflower, pawpaw, orange), Scalpels, Drawing materials

Certificate Biology Form 3, Pages 124-130

REPRODUCTION IN PLANTS AND ANIMALS

Fruit and Seed Dispersal

By the end of the lesson, the learner should be able to:
To explain adaptive features of fruits and seeds. To identify agents of dispersal. To classify fruits and seeds by dispersal method.

Practical examination: Various fruits and seeds. Grouping according to dispersal methods. Discussion: Adaptive features for wind, water, animal dispersal. Demonstration of seed dispersal mechanisms. Recording observations of external features.

Variety of fruits and seeds, Hand lens, Drawing materials, Collection containers

Certificate Biology Form 3, Pages 130-131

REPRODUCTION IN PLANTS AND ANIMALS

Review and Assessment
Introduction and Fertilisation Types
Reproduction in Amphibia and Mammalian Characteristics

By the end of the lesson, the learner should be able to:
To consolidate understanding of reproduction in plants. To apply knowledge in problem-solving. To prepare for examinations.
To distinguish between sexual and asexual reproduction in animals. To compare external and internal fertilisation. To give examples of animals using each method. To explain advantages of each fertilisation type.

Comprehensive review: Q/A session on all topics covered. Problem-solving exercises on reproduction processes. Drawing practice: Flower parts, fertilisation, fruit types. Written assessment covering unit objectives. Discussion of difficult concepts.
Q/A: Review plant reproduction concepts. Discussion: Types of reproduction in animals and hermaphrodites. Detailed comparison: External vs internal fertilisation with examples. Tabulate differences and advantages of each method.

Past examination papers, Drawing materials, Assessment sheets, Charts for reference
Charts showing reproduction types and fertilisation, Textbook, Wall charts
Frog eggs specimens, Charts showing amphibian and mammalian reproduction, Hand lens

Certificate Biology Form 3, Pages 113-143
Certificate Biology Form 3, Pages 147-148

REPRODUCTION IN PLANTS AND ANIMALS

Female Reproductive System Structure

By the end of the lesson, the learner should be able to:
To draw and label the human female reproductive system. To identify functions of ovaries, oviducts, uterus and vagina. To describe uterine structure and endometrium function. To explain placenta formation.

Drawing and labeling: Complete female reproductive system. Teacher demonstration using charts and models. Discussion: Functions of each organ and structure-function relationships. Detailed explanation: Endometrium role and placenta formation during pregnancy.

Charts of female reproductive system, Drawing materials, Models if available, Textbook

Certificate Biology Form 3, Pages 149-151

REPRODUCTION IN PLANTS AND ANIMALS

Stages of Reproduction and Oogenesis
Menstrual Cycle - Follicle Development and Ovulation

By the end of the lesson, the learner should be able to:
To list the stages of reproduction in mammals. To describe oogenesis from fetal development to puberty. To explain primordial follicle formation. To relate oogenesis to reproductive maturity.

Teacher exposition: Four main reproductive stages overview. Detailed discussion: Oogenesis process from fetal development. Q/A: Primordial follicle formation and puberty changes. Drawing diagrams showing follicle development stages.

Flow charts, Oogenesis diagrams, Drawing materials, Textbook
Menstrual cycle charts, Drawing materials, Textbook

Certificate Biology Form 3, Pages 151-152

REPRODUCTION IN PLANTS AND ANIMALS

Hormonal Control and Menstrual Phases
Ovum Structure and Fertilisation Process

By the end of the lesson, the learner should be able to:
To identify hormones controlling menstrual cycle. To explain FSH, LH, oestrogen and progesterone functions. To describe menstrual cycle phases and endometrium changes. To explain negative feedback mechanisms.

Detailed discussion: Four main hormones and their interactions. Graphical analysis: Hormone levels throughout cycle. Discussion: Endometrium thickening and breakdown phases. Q/A: Negative feedback control mechanisms and menstruation.

Hormone level graphs, Menstrual cycle phase charts, Textbook
Ovum structure charts, Fertilisation diagrams, Drawing materials, Textbook

Certificate Biology Form 3, Pages 154-156

REPRODUCTION IN PLANTS AND ANIMALS

Early Development and Twins Formation
Implantation and Pregnancy Indicators

By the end of the lesson, the learner should be able to:
To describe mitotic divisions after fertilisation. To explain morula and blastocyst formation. To distinguish between identical and fraternal twins. To describe mechanisms of multiple births.

Discussion: Zygote divisions and morula formation. Teacher exposition: Blastocyst development and trophoblast function. Detailed explanation: Types of twins and formation mechanisms. Q/A: Genetic basis of identical vs fraternal twins.

Developmental stages charts, Twin formation diagrams, Drawing materials, Textbook
Implantation charts, Pregnancy test demonstration materials, Textbook

Certificate Biology Form 3, Pages 157-158

REPRODUCTION IN PLANTS AND ANIMALS

Gestation and Embryonic Membranes

By the end of the lesson, the learner should be able to:
To define gestation period in humans. To identify extra-embryonic membranes. To describe amnion, chorion and allantois functions. To explain amniotic fluid importance.

Teacher exposition: 40-week gestation period comparison with other mammals. Detailed discussion: Formation and functions of amnion, chorion, allantois. Q/A: Amniotic fluid functions - protection, support, lubrication. Drawing embryonic membrane arrangement.

Gestation charts, Fetal development models, Drawing materials, Textbook

Certificate Biology Form 3, Pages 159-161

REPRODUCTION IN PLANTS AND ANIMALS

Placenta Structure and Functions

By the end of the lesson, the learner should be able to:
To describe placenta structure and formation. To explain maternal and fetal blood separation. To identify nutrient transfer and gas exchange functions. To discuss placental barrier limitations.

Detailed discussion: Placenta as temporary organ with dual tissue origin. Teacher exposition: Blood vessel arrangement and separation mechanisms. Discussion: Nutrient, oxygen transfer and harmful substance passage. Q/A: Placental protection and its limitations.

Placenta structure diagrams, Function charts, Drawing materials, Textbook

Certificate Biology Form 3, Pages 161-163

REPRODUCTION IN PLANTS AND ANIMALS

Pregnancy Hormones and Parturition

By the end of the lesson, the learner should be able to:
To identify hormones during pregnancy. To explain HCG, progesterone and oestrogen roles. To describe hormonal changes triggering birth. To explain the parturition process.

Discussion: Hormone secretion patterns during pregnancy. Teacher exposition: HCG, progesterone, oestrogen functions and interactions. Detailed explanation: Hormonal triggers for birth and oxytocin role. Q/A: Uterine contractions, cervix dilation and delivery stages.

Pregnancy hormone charts, Birth process diagrams, Hormone level graphs, Textbook

Certificate Biology Form 3, Pages 163-165

REPRODUCTION IN PLANTS AND ANIMALS

Male Reproductive System Structure and Functions

By the end of the lesson, the learner should be able to:
To draw and label male reproductive system. To identify testes, epididymis, vas deferens and accessory glands. To describe functions of each component. To explain scrotum function and temperature regulation.

Drawing and labeling: Complete male reproductive system. Teacher demonstration using charts and models. Discussion: Functions of testes, epididymis, vas deferens, accessory glands. Q/A: Scrotum location and temperature regulation for sperm production.

Male reproductive system charts, Drawing materials, Models if available, Textbook

Certificate Biology Form 3, Pages 164-166

REPRODUCTION IN PLANTS AND ANIMALS

Sperm Structure and Male Hormones

By the end of the lesson, the learner should be able to:
To draw and label spermatozoon structure. To explain head, middle piece and tail functions. To describe testosterone and FSH roles. To identify secondary sexual characteristics.

Drawing and labeling: Detailed sperm structure showing all components. Discussion: Sperm adaptations for fertilization and motility. Teacher exposition: Hormone control of sperm production and male development. Q/A: Testosterone effects and secondary sexual characteristics.

Sperm structure diagrams, Male hormone charts, Drawing materials, Textbook

Certificate Biology Form 3, Pages 166-167

REPRODUCTION IN PLANTS AND ANIMALS

HIV/AIDS - Causes and Transmission
AIDS Symptoms and Prevention

By the end of the lesson, the learner should be able to:
To describe HIV virus and immune system effects. To explain AIDS development and symptoms. To identify HIV transmission modes. To discuss high-risk behaviors.
To identify early and late AIDS symptoms. To describe opportunistic diseases. To explain AIDS prevention methods. To discuss social responsibility and behavior change.

Detailed discussion: HIV virus structure and immune system destruction. Teacher exposition: AIDS development and opportunistic diseases. Discussion: Transmission modes - sexual, blood, mother-to-child. Q/A: High-risk behaviors and transmission prevention.
Discussion: Early AIDS symptoms and progression to full syndrome. Teacher exposition: Opportunistic diseases and their effects. Detailed explanation: Prevention strategies and behavior modification. Group discussion: Social responsibility and community health.

AIDS awareness charts, HIV transmission diagrams, Educational materials, Textbook
AIDS symptom charts, Prevention posters, Case study materials, Textbook

Certificate Biology Form 3, Pages 167-170
Certificate Biology Form 3, Pages 170-171

REPRODUCTION IN PLANTS AND ANIMALS

AIDS Symptoms and Prevention

By the end of the lesson, the learner should be able to:
To identify early and late AIDS symptoms. To describe opportunistic diseases. To explain AIDS prevention methods. To discuss social responsibility and behavior change.

Discussion: Early AIDS symptoms and progression to full syndrome. Teacher exposition: Opportunistic diseases and their effects. Detailed explanation: Prevention strategies and behavior modification. Group discussion: Social responsibility and community health.

AIDS symptom charts, Prevention posters, Case study materials, Textbook

Certificate Biology Form 3, Pages 170-171

REPRODUCTION IN PLANTS AND ANIMALS

Bacterial STIs - Gonorrhea and Syphilis

By the end of the lesson, the learner should be able to:
To describe gonorrhea causes, symptoms and treatment. To explain syphilis stages and progression. To identify transmission modes for bacterial STIs. To discuss antibiotic treatment and prevention.

Detailed discussion: Gonorrhea bacterium and reproductive tract effects. Teacher exposition: Syphilis stages - primary, secondary, tertiary. Q/A: Transmission modes and treatment with antibiotics. Discussion: Prevention methods and partner responsibility.

STI information charts, Bacterial infection diagrams, Textbook

Certificate Biology Form 3, Pages 171-172

REPRODUCTION IN PLANTS AND ANIMALS

Viral STIs and Other Infections

By the end of the lesson, the learner should be able to:
To describe genital herpes causes and symptoms. To explain hepatitis B transmission and effects. To identify trichomoniasis and other STIs. To emphasize prevention strategies for all STIs.

Discussion: Viral STIs and their incurable nature. Teacher exposition: Herpes simplex virus effects and dormancy. Q/A: Hepatitis B liver effects and vaccination. Discussion: Comprehensive STI prevention and faithful relationships.

Viral STI charts, Prevention strategy posters, Textbook

Certificate Biology Form 3, Page 172