GENETICS

Introduction to Genetics and Variation

By the end of the lesson, the learner should be able to:
Define genetics, heredity and variation. Explain the importance of studying genetics. Identify examples of variation in organisms.

Q/A on prior knowledge of inheritance. Brainstorming on observable differences in humans. Discussion on the meaning of genetics and heredity.

Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 1-2

GENETICS

Observable Variations in Human Beings
Discontinuous and Continuous Variation

By the end of the lesson, the learner should be able to:
Observe and record variations in tongue rolling, fingerprints and height. Distinguish between different types of variations. Create data tables.

Practical activity on tongue rolling. Fingerprint examination using ink pads. Height measurement and data recording.

Ink pad, plain paper, metre rule, exercise books
Graph paper, rulers, height data from previous lesson, textbook

KLB Secondary Biology Form 4, Pages 2-3

GENETICS

Causes of Variation
Chromosome Structure
Chromosome Behaviour During Mitosis
Chromosome Behaviour During Meiosis
DNA Structure and Replication

By the end of the lesson, the learner should be able to:
Explain genetic and environmental causes of variation. Describe role of meiosis, fertilization and mutations in creating variation.
Describe chromosome behaviour during meiosis. Explain crossing over and reduction division. Compare mitosis and meiosis.

Exposition on sources of variation. Discussion on independent assortment during meiosis. Examples of environmental effects on phenotypes.
Continuation of chromosome modeling using threads. Demonstration of reduction division. Discussion on gamete formation.

Textbook, chalkboard, chalk
Textbook, chalkboard, chalk, exercise books, pencils
Colored threads (6cm and 3cm), scissors, manila paper, string for tying knots
Colored threads, manila paper, textbook
Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 4-5
KLB Secondary Biology Form 4, Pages 8-9

GENETICS

DNA and Protein Synthesis
Mendel's Experiments and First Law

By the end of the lesson, the learner should be able to:
Explain role of DNA in protein synthesis. Describe mRNA formation and function. Understand genetic code concept.

Exposition on transcription and translation. Discussion on messenger RNA. Examples of genetic codes using chalkboard diagrams.

Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 12-13

GENETICS

Monohybrid Inheritance Concepts

By the end of the lesson, the learner should be able to:
Define monohybrid inheritance, genotype, phenotype. Distinguish between dominant and recessive genes. Explain homozygous and heterozygous conditions.

Exposition on genetic terminology. Practice using genetic symbols on chalkboard. Discussion on gene expression patterns.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 15-17

GENETICS

Genetic Crosses and Punnet Squares

By the end of the lesson, the learner should be able to:
Draw genetic cross diagrams. Use punnet squares to show genetic crosses. Predict offspring genotypes and phenotypes.

Step-by-step construction of genetic crosses on chalkboard. Practice with punnet squares. Student exercises on genetic problems.

Textbook, chalkboard, chalk, exercise books, pencils

KLB Secondary Biology Form 4, Pages 17-18

GENETICS

Probability in Inheritance
Modeling Random Gamete Fusion
Complete Dominance Problems

By the end of the lesson, the learner should be able to:
Explain probability in genetic inheritance. Calculate phenotypic and genotypic ratios. Demonstrate random events using coin tossing.
Demonstrate random fusion of gametes. Use simple materials to model inheritance. Analyze experimental vs expected results.

Mathematical analysis of genetic ratios. Coin tossing experiment to demonstrate probability. Statistical interpretation of results.
Practical activity using different colored beans to represent gametes. Data collection and analysis. Discussion on sample size effects.

Coins, exercise books for recording, calculators (if available), textbook
Different colored beans (or maize grains), small containers, exercise books
Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 18-19
KLB Secondary Biology Form 4, Pages 19-20

GENETICS

Incomplete Dominance

By the end of the lesson, the learner should be able to:
Define incomplete dominance. Analyze inheritance in four o'clock plants. Compare with complete dominance patterns. Draw genetic crosses showing blending.

Exposition on incomplete dominance using chalkboard diagrams. Genetic crosses showing blending inheritance. Practice problems with flower colors.

Textbook, chalkboard, chalk, colored chalk (if available)

KLB Secondary Biology Form 4, Pages 22-24

GENETICS

ABO Blood Group System

By the end of the lesson, the learner should be able to:
Explain multiple alleles concept. Describe ABO blood group inheritance. Understand co-dominance in blood groups. Solve blood group problems.

Detailed explanation of blood group genetics on chalkboard. Genetic crosses involving blood group inheritance. Practice problems and paternity cases.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 24-25

GENETICS

Rhesus Factor and Unknown Genotypes

By the end of the lesson, the learner should be able to:
Describe Rhesus factor genetics. Explain test cross and back cross methods. Use selfing to determine genotypes.

Exposition on Rh factor inheritance using chalkboard. Demonstration of test cross technique. Practice problems on genotype determination.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 25-26

GENETICS

Sex Determination
Gene Linkage
Sex-linked Inheritance - Color Blindness

By the end of the lesson, the learner should be able to:
Describe sex determination in humans and other animals. Explain XX/XY sex determination systems. Calculate probability of male/female offspring.
Describe sex-linked inheritance patterns. Explain color blindness inheritance. Construct and analyze pedigree charts.

Exposition on sex chromosomes using chalkboard diagrams. Genetic crosses for sex determination. Comparison with other animals.
Detailed exposition on X-linked inheritance using chalkboard. Genetic crosses for color blindness. Drawing simple pedigree charts.

Textbook, chalkboard, chalk
Textbook, chalkboard, chalk, exercise books, rulers

KLB Secondary Biology Form 4, Pages 26-27
KLB Secondary Biology Form 4, Pages 28-30

GENETICS

Sex-linked Inheritance - Haemophilia

By the end of the lesson, the learner should be able to:
Explain haemophilia inheritance. Understand carrier females and affected males. Analyze inheritance through generations.

Exposition on haemophilia genetics. Drawing inheritance patterns on chalkboard. Practice with pedigree construction and analysis.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 30-31

GENETICS

Crossing Over and Recombination

By the end of the lesson, the learner should be able to:
Explain crossing over during meiosis. Understand how crossing over affects linkage. Describe formation of new gene combinations.

Detailed explanation of crossing over using simple diagrams. Examples of recombinant offspring drawn on chalkboard. Discussion on genetic variation.

Textbook, chalkboard, chalk, colored chalk

KLB Secondary Biology Form 4, Page 31

GENETICS

Chromosomal Mutations - Non-disjunction
Chromosomal Mutations - Polyploidy

By the end of the lesson, the learner should be able to:
Define chromosomal mutations. Explain non-disjunction during meiosis. Describe Down's syndrome and other chromosome disorders.

Exposition on non-disjunction using chalkboard diagrams. Drawing normal vs abnormal chromosome sets. Discussion on genetic disorders.

Textbook, chalkboard, chalk, exercise books
Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 32-35

GENETICS

Gene Mutations
Genetic Disorders - Albinism

By the end of the lesson, the learner should be able to:
Define gene mutations. Describe insertion, deletion, substitution and inversion. Explain effects on protein synthesis using analogies.
Describe albinism inheritance. Explain enzyme deficiency in albinism. Calculate inheritance probabilities. Draw genetic crosses.

Detailed exposition on point mutations using simple examples. Use SMS text analogies for mutations. Discussion on protein changes.
Case study of albinism using chalkboard diagrams. Genetic crosses for albinism inheritance. Discussion on carrier parents and affected children.

Textbook, chalkboard, chalk, simple text examples
Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 36-38
KLB Secondary Biology Form 4, Pages 38-40

GENETICS

Genetic Disorders - Sickle Cell Anaemia

By the end of the lesson, the learner should be able to:
Describe sickle cell anaemia inheritance. Explain hemoglobin differences. Understand sickle cell trait vs disease.

Exposition on sickle cell genetics using diagrams. Comparison of normal and sickle cell hemoglobin. Genetic crosses and probabilities.

Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 40-42

GENETICS

Environmental Effects on Gene Expression
Applications of Genetics

By the end of the lesson, the learner should be able to:
Explain gene-environment interactions. Describe phenotypic plasticity. Understand limitations of genetic determinism.

Discussion on environmental influences using local examples. Plant growth under different conditions. Twin studies and environmental factors.

Textbook, local plant examples, chalkboard
Textbook, local breeding examples, chalkboard

KLB Secondary Biology Form 4, Pages 42-43

SUPPORT AND MOVEMENT

Importance of Support and Movement; Plant Support Strategies

By the end of the lesson, the learner should be able to:
Explain the necessity for support in plants and animals. Describe importance of movement in organisms. Identify different support mechanisms in plants. Explain role of turgor pressure and alternative support methods.

Brainstorming on why organisms need support. Discussion on consequences of lack of support. Observation of local plants showing different support strategies. Practical experiment on wilting in herbaceous vs woody plants. Analysis of climbing plants and their support adaptations.

Textbook, chalkboard, chalk, local plant specimens, herbaceous and woody plants for wilting experiment

KLB Secondary Biology Form 4, Pages 120-121, 125-126

SUPPORT AND MOVEMENT

Tissue Arrangement in Monocot and Dicot Stems
Supporting Tissues in Plants and Their Functions

By the end of the lesson, the learner should be able to:
Describe arrangement of tissues in monocotyledonous and dicotyledonous stems. Compare tissue arrangements between monocots and dicots. Identify supporting tissues and their distribution.
Identify types of supporting tissues: collenchyma, sclerenchyma, xylem vessels, tracheids. Explain functions of each supporting tissue. Describe how these tissues provide mechanical strength. Compare tissue properties and locations.

Examination of fresh monocot and dicot stem cross-sections. Drawing and labeling tissue arrangements on chalkboard. Practical observation of vascular bundle patterns. Comparison of scattered vs ring arrangements. Discussion on supporting tissue distribution.
Detailed exposition on supporting tissue types using diagrams. Discussion on tissue characteristics and functions. Examination of tissue examples in stem sections. Comparison of tissue properties and mechanical strength. Drawing tissue structures and arrangements.

Textbook, chalkboard, chalk, fresh monocot stems (maize, sugarcane), fresh dicot stems (bean plants), razor blades, hand lenses
Textbook, chalkboard, chalk, microscope slides (if available), fresh stem sections, exercise books

KLB Secondary Biology Form 4, Pages 121-125

SUPPORT AND MOVEMENT

Types of Animal Skeletons
Fish Locomotion - Structure and Mechanism

By the end of the lesson, the learner should be able to:
Identify three types of animal skeletons: hydrostatic, exoskeleton, endoskeleton. Compare structure, composition, and functions of each skeleton type. Explain advantages and disadvantages of different skeleton types.

Exposition on skeleton types using examples. Examination of arthropod specimens showing exoskeleton. Discussion on bone and cartilage as endoskeleton materials. Comparison table of skeleton characteristics. Analysis of evolutionary adaptations and growth limitations.

Textbook, chalkboard, chalk, arthropod specimens (grasshoppers, crabs), bone specimens, comparison charts
Textbook, fresh fish specimen, chalkboard, chalk, forceps, measuring tools, calculator, exercise books

KLB Secondary Biology Form 4, Pages 126-127

SUPPORT AND MOVEMENT

Human Axial Skeleton - Skull and Rib Cage

By the end of the lesson, the learner should be able to:
Describe structure and functions of human skull. Explain structure and function of rib cage. Understand protection and support roles. Identify bone features and adaptations.

Examination of skull and rib cage specimens or models. Drawing skull and rib cage structures. Discussion on brain and organ protection. Analysis of breathing movements and rib articulation. Identification of skull sutures and rib cage components.

Textbook, chalkboard, chalk, skull and rib cage specimens, exercise books

KLB Secondary Biology Form 4, Pages 130-131

SUPPORT AND MOVEMENT

Vertebral Column - Cervical and Thoracic Vertebrae

By the end of the lesson, the learner should be able to:
Describe general structure of vertebrae. Identify features of cervical vertebrae including atlas and axis. Explain features and adaptations of thoracic vertebrae. Compare regional vertebrae differences.

Examination of cervical and thoracic vertebrae specimens. Drawing and labeling atlas, axis, and typical cervical vertebrae. Study of thoracic vertebrae and rib articulation points. Discussion on regional adaptations for function. Comparison of vertebrae features.

Textbook, chalkboard, chalk, cervical and thoracic vertebrae specimens, exercise books

KLB Secondary Biology Form 4, Pages 131-134

SUPPORT AND MOVEMENT

Vertebral Column - Lumbar, Sacral and Caudal Vertebrae
Pectoral Girdle and Forelimb Bones
Pelvic Girdle and Hindlimb Bones

By the end of the lesson, the learner should be able to:
Identify features of lumbar vertebrae and their weight-bearing adaptations. Describe structure of sacral vertebrae and sacrum formation. Explain structure of caudal vertebrae. Compare all vertebrae types.
Describe structure of pectoral girdle components: scapula and clavicle. Identify forelimb bones: humerus, radius, ulna, carpals, metacarpals, phalanges. Explain joint formations and articulations.

Examination of lumbar, sacral, and caudal vertebrae specimens. Drawing large centrum and processes of lumbar vertebrae. Study of sacrum formation and fusion. Discussion on weight support and regional specializations. Complete vertebral column analysis.
Examination of pectoral girdle and forelimb bones. Drawing and labeling complete forelimb structure. Discussion on shoulder and elbow joint formation. Analysis of bone features and muscle attachment points. Study of pentadactyl limb pattern.

Textbook, chalkboard, chalk, lumbar, sacral, and caudal vertebrae specimens, complete vertebral column
Textbook, chalkboard, chalk, pectoral girdle and forelimb bone specimens, exercise books
Textbook, chalkboard, chalk, pelvic girdle and hindlimb bone specimens, exercise books

KLB Secondary Biology Form 4, Pages 134-136
KLB Secondary Biology Form 4, Pages 136-138

SUPPORT AND MOVEMENT

Types of Joints and Their Structure

By the end of the lesson, the learner should be able to:
Identify types of joints: immovable, gliding, and movable (synovial). Describe structure of synovial joints including cartilage, synovial fluid, and ligaments. Explain joint components and their functions.

Examination of different joint types and synovial joint structure. Drawing synovial joint components. Discussion on cartilage function and synovial fluid properties. Analysis of joint mobility and stability. Practical observation of joint movements.

Textbook, chalkboard, chalk, joint specimens or models, exercise books

KLB Secondary Biology Form 4, Pages 140-141

SUPPORT AND MOVEMENT

Ball and Socket vs Hinge Joints; Movement Mechanisms

By the end of the lesson, the learner should be able to:
Compare ball and socket joints with hinge joints. Describe movement capabilities and examples of each joint type. Explain how muscles work in antagonistic pairs at joints. Understand lever systems in movement.

Examination of hip/shoulder and elbow/knee joints. Demonstration of movement ranges and planes. Drawing joint structures and movement mechanisms. Practical demonstration of biceps and triceps action. Analysis of flexor and extensor muscle function.

Textbook, chalkboard, chalk, joint specimens, practical movement demonstrations, exercise books

KLB Secondary Biology Form 4, Pages 141-143

SUPPORT AND MOVEMENT

Types of Muscle Tissue and Their Functions

By the end of the lesson, the learner should be able to:
Identify three types of muscle tissue: skeletal (striated), smooth (visceral), and cardiac. Compare structure and functions of each muscle type. Explain voluntary vs involuntary muscle control. Describe muscle fiber characteristics.

Drawing structures of different muscle types on chalkboard. Detailed comparison of muscle fiber characteristics. Discussion on muscle control mechanisms and locations. Analysis of muscle contraction properties and endurance. Examples of each muscle type in body systems.

Textbook, chalkboard, chalk, exercise books, muscle tissue comparison charts

KLB Secondary Biology Form 4, Pages 142-144

SUPPORT AND MOVEMENT
REPRODUCTION IN PLANTS AND ANIMALS

Skeletal Muscle Structure and Contraction Mechanism
Smooth and Cardiac Muscle Specializations
Introduction and Importance of Reproduction
Chromosomes and Genes

By the end of the lesson, the learner should be able to:
Describe detailed structure of skeletal muscle fibers including myofibrils, actin, and myosin. Explain muscle contraction mechanism and sliding filament theory. Understand energy requirements and muscle fatigue.
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.

Detailed exposition on muscle fiber structure using diagrams. Discussion on sliding filament theory and molecular basis of contraction. Explanation of ATP requirements and calcium ion role. Analysis of muscle fatigue and recovery. Practical muscle function demonstrations.
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).

Textbook, chalkboard, chalk, exercise books, detailed muscle structure diagrams
Textbook, chalkboard, chalk, exercise books, comprehensive muscle comparison tables
Charts - Types of reproduction, Examples of reproduction in different organisms
Charts - Chromosome structure, Examples of chromosome numbers in different species

KLB Secondary Biology Form 4, Pages 142-143
Certificate Biology Form 3, Page 99

REPRODUCTION IN PLANTS AND ANIMALS

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

By the end of the lesson, the learner should be able to:
Define mitosis and explain its significance. Describe the stages of mitosis in detail. Identify sites where mitosis occurs in plants and animals.

Detailed study of mitosis stages using Fig 3.1: Prophase (early and late), Metaphase, Anaphase, Telophase, Interphase. Discussion of chromosome behavior, spindle formation, cytokinesis. Q/A: Sites of mitosis - growth areas, tissue repair.

Charts - Fig 3.1 mitosis stages, Models of cell division, Microscope slides of mitosis
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 100-102

REPRODUCTION IN PLANTS AND ANIMALS

Meiosis II and Comparison with Mitosis
Introduction to Reproduction

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.

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.

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

Certificate Biology Form 3, Pages 105-107

REPRODUCTION IN PLANTS AND ANIMALS

Cell Division - Mitosis
Mitosis in Young Root Tip
Meiosis Process

By the end of the lesson, the learner should be able to:
To describe the process of mitosis. To identify the stages of mitosis. To explain the significance of mitosis.

Teacher exposition: Stages of mitosis with diagrams. Drawing and labeling stages of mitosis. Discussion: Importance of mitosis in growth and repair. Q/A: Comparison of daughter cells with parent cell.

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

Certificate Biology Form 3, Pages 100-102

REPRODUCTION IN PLANTS AND ANIMALS

Meiosis in Plant Cells
Asexual Reproduction - Binary Fission
Spore Formation and Budding
Sexual Reproduction in Plants - Flower Structure
Pollination - Insect Pollinated Flowers

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.
To describe spore formation in bread mould. To explain budding in yeast. To observe and draw various fungi.

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.
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.

Flower buds, 1M HCl, Heat source, Glass slides, Filter paper, Microscope
Charts showing binary fission, Prepared slides of amoeba, Microscope, Drawing materials
Bread/ugali mould, Microscope, Yeast culture, 10% sugar solution, Methylene blue, Hand lens
Bean flowers, Morning glory, Hibiscus, Hand lens, Scalpels, Drawing materials
Insect-pollinated flowers, Hand lens, Measuring rulers, Drawing materials

Certificate Biology Form 3, Pages 105-108
Certificate Biology Form 3, Pages 113-115

REPRODUCTION IN PLANTS AND ANIMALS

Wind-Pollinated Flowers and Adaptations

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.

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.

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

Certificate Biology Form 3, Pages 120-121

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
Fruit and Seed Dispersal
Review and Assessment

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.
To consolidate understanding of reproduction in plants. To apply knowledge in problem-solving. To prepare for examinations.

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.
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.

Fruits (beans, sunflower, pawpaw, orange), Scalpels, Drawing materials
Variety of fruits and seeds, Hand lens, Drawing materials, Collection containers
Past examination papers, Drawing materials, Assessment sheets, Charts for reference

Certificate Biology Form 3, Pages 124-130
Certificate Biology Form 3, Pages 113-143

REPRODUCTION IN PLANTS AND ANIMALS

Introduction and Fertilisation Types
Reproduction in Amphibia and Mammalian Characteristics
Female Reproductive System Structure

By the end of the lesson, the learner should be able to:
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.

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.

Charts showing reproduction types and fertilisation, Textbook, Wall charts
Frog eggs specimens, Charts showing amphibian and mammalian reproduction, Hand lens
Charts of female reproductive system, Drawing materials, Models if available, Textbook

Certificate Biology Form 3, Pages 147-148

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
Early Development and Twins Formation

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
Developmental stages charts, Twin formation diagrams, Drawing materials, Textbook

Certificate Biology Form 3, Pages 154-156

REPRODUCTION IN PLANTS AND ANIMALS

Implantation and Pregnancy Indicators
Gestation and Embryonic Membranes
Placenta Structure and Functions

By the end of the lesson, the learner should be able to:
To define implantation and describe the process. To explain chorionic villi formation and anchoring. To identify early signs of pregnancy. To explain HCG hormone function and detection.
To define gestation period in humans. To identify extra-embryonic membranes. To describe amnion, chorion and allantois functions. To explain amniotic fluid importance.

Detailed discussion: Implantation timing and chorionic villi development. Teacher exposition: Blastocyst embedding in endometrium. Discussion: Early pregnancy symptoms and HCG hormone. Q/A: Laboratory confirmation methods and pregnancy tests.
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.

Implantation charts, Pregnancy test demonstration materials, Textbook
Gestation charts, Fetal development models, Drawing materials, Textbook
Placenta structure diagrams, Function charts, Drawing materials, Textbook

Certificate Biology Form 3, Pages 158-159
Certificate Biology Form 3, Pages 159-161

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
Bacterial STIs - Gonorrhea and Syphilis
Viral STIs and Other Infections

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 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: 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.
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.

AIDS awareness charts, HIV transmission diagrams, Educational materials, Textbook
AIDS symptom charts, Prevention posters, Case study materials, Textbook
STI information charts, Bacterial infection diagrams, Textbook
Viral STI charts, Prevention strategy posters, Textbook

Certificate Biology Form 3, Pages 167-170
Certificate Biology Form 3, Pages 171-172