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

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.

Exposition on sources of variation. Discussion on independent assortment during meiosis. Examples of environmental effects on phenotypes.

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

KLB Secondary Biology Form 4, Pages 4-5

GENETICS

Chromosome Behaviour During Mitosis
Chromosome Behaviour During Meiosis
DNA Structure and Replication
DNA and Protein Synthesis

By the end of the lesson, the learner should be able to:
Demonstrate chromosome behaviour during mitosis. Identify stages of mitosis. Explain importance of mitosis.
Describe the structure of DNA. Explain DNA replication process. Understand the role of DNA in heredity.

Practical activity using colored threads to model mitosis stages. Creating paper models of mitotic stages. Group discussions.
Drawing DNA double helix on chalkboard. Step-by-step explanation of replication. Discussion on base pairing rules.

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

KLB Secondary Biology Form 4, Pages 6-8
KLB Secondary Biology Form 4, Pages 10-12

GENETICS

Mendel's Experiments and First Law

By the end of the lesson, the learner should be able to:
Describe Mendel's experiments with garden peas. State Mendel's first law of inheritance. Explain reasons for Mendel's success.

Q/A on Mendel's work. Detailed discussion of pea plant experiments using chalkboard diagrams. Analysis of F1 and F2 results.

Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 13-15

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

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

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

GENETICS

Complete Dominance Problems

By the end of the lesson, the learner should be able to:
Solve genetic problems involving complete dominance. Analyze inheritance patterns in garden peas. Practice genetic calculations.

Worked examples of genetic problems on chalkboard. Practice sessions with various characteristics. Group problem-solving.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 20-21

GENETICS

Incomplete Dominance
ABO Blood Group System

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)
Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 22-24

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

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.
Define gene linkage and linkage groups. Explain inheritance of linked genes. Understand why some genes are inherited together.

Exposition on sex chromosomes using chalkboard diagrams. Genetic crosses for sex determination. Comparison with other animals.
Exposition on linked genes using simple diagrams. Examples from fruit fly genetics drawn on chalkboard. Discussion on chromosome maps.

Textbook, chalkboard, chalk

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

GENETICS

Sex-linked Inheritance - Color Blindness

By the end of the lesson, the learner should be able to:
Describe sex-linked inheritance patterns. Explain color blindness inheritance. Construct and analyze pedigree charts.

Detailed exposition on X-linked inheritance using chalkboard. Genetic crosses for color blindness. Drawing simple pedigree charts.

Textbook, chalkboard, chalk, exercise books, rulers

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.
Describe structural chromosome changes. Explain polyploidy in plants. Understand chromosome number variations.

Exposition on non-disjunction using chalkboard diagrams. Drawing normal vs abnormal chromosome sets. Discussion on genetic disorders.
Exposition on chromosome number changes. Examples of polyploidy in agriculture using chalkboard. Discussion on plant breeding applications.

Textbook, chalkboard, chalk, exercise books

KLB Secondary Biology Form 4, Pages 32-35
KLB Secondary Biology Form 4, Pages 35-36

GENETICS

Gene Mutations

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.

Detailed exposition on point mutations using simple examples. Use SMS text analogies for mutations. Discussion on protein changes.

Textbook, chalkboard, chalk, simple text examples

KLB Secondary Biology Form 4, Pages 36-38

GENETICS

Genetic Disorders - Albinism

By the end of the lesson, the learner should be able to:
Describe albinism inheritance. Explain enzyme deficiency in albinism. Calculate inheritance probabilities. Draw genetic crosses.

Case study of albinism using chalkboard diagrams. Genetic crosses for albinism inheritance. Discussion on carrier parents and affected children.

Textbook, chalkboard, chalk, exercise books

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
EVOLUTION

Environmental Effects on Gene Expression
Applications of Genetics
Meaning of Evolution and Origin of Life Theories

By the end of the lesson, the learner should be able to:
Explain gene-environment interactions. Describe phenotypic plasticity. Understand limitations of genetic determinism.
Define evolution and organic evolution. Distinguish between special creation and chemical evolution theories. Explain the scientific approach to understanding life's origin.

Discussion on environmental influences using local examples. Plant growth under different conditions. Twin studies and environmental factors.
Brainstorming on how life began. Discussion on religious vs scientific explanations. Exposition on chemical evolution theory. Comparison of different viewpoints.

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

KLB Secondary Biology Form 4, Pages 42-43
KLB Secondary Biology Form 4, Pages 53-55

EVOLUTION

Chemical Evolution and Miller's Experiment

By the end of the lesson, the learner should be able to:
Describe Miller's spark discharge experiment. Explain formation of organic compounds from simple molecules. Understand primitive earth conditions.

Detailed exposition on Miller's experimental setup using chalkboard diagrams. Discussion on primitive atmosphere composition. Analysis of experimental results and significance.

Textbook, chalkboard, chalk, simple laboratory glassware for demonstration

KLB Secondary Biology Form 4, Pages 53-55

EVOLUTION

Evidence for Evolution - Fossil Records

By the end of the lesson, the learner should be able to:
Define fossils and explain fossil formation. Describe types of fossils. Analyze fossil evidence for evolution. Understand geological time scale.

Exposition on fossil formation processes. Examination of any available fossil specimens or pictures. Discussion on fossil records of humans and other organisms. Timeline construction on chalkboard.

Textbook, any available fossil specimens, pictures from textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 55-62

EVOLUTION

Geographical Distribution and Comparative Embryology

By the end of the lesson, the learner should be able to:
Explain biogeographical evidence for evolution. Describe continental drift effects on species distribution. Compare embryological development in vertebrates.

Discussion on animal and plant distribution patterns. Examination of world map showing species distribution. Drawing embryological stages on chalkboard. Comparison of vertebrate embryos.

Textbook, world map, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 60-63

EVOLUTION

Comparative Anatomy - Homologous Structures
Comparative Anatomy - Analogous and Vestigial Structures

By the end of the lesson, the learner should be able to:
Define homologous structures. Examine pentadactyl limb in different vertebrates. Explain divergent evolution. Identify adaptive modifications.
Define analogous and vestigial structures. Compare bird and insect wings. Give examples of vestigial organs. Explain convergent evolution.

Practical examination of bone specimens or pictures. Drawing and labeling pentadactyl limbs of different animals. Discussion on common ancestry evidence. Comparison of limb modifications.
Examination of bird and insect wing specimens. Drawing wing structures on chalkboard. Discussion on vestigial organs in humans and other animals. Examples of convergent evolution.

Textbook, bone specimens (if available), pictures of animal limbs, chalkboard, chalk, exercise books
Textbook, wing specimens (bird feathers, insect specimens), chalkboard, chalk

KLB Secondary Biology Form 4, Pages 63-67
KLB Secondary Biology Form 4, Pages 67-70

EVOLUTION

Cell Biology and Comparative Serology Evidence

By the end of the lesson, the learner should be able to:
Describe cellular evidence for evolution. Explain biochemical similarities in organisms. Understand serological tests for evolutionary relationships.

Discussion on universal cellular features. Exposition on ATP, DNA similarities across species. Explanation of blood protein comparisons. Simple demonstration of precipitation reactions.

Textbook, chalkboard, chalk, simple solutions for demonstration (if available)

KLB Secondary Biology Form 4, Pages 69-70

EVOLUTION

Lamarck's Theory vs Darwin's Theory

By the end of the lesson, the learner should be able to:
Explain Lamarck's theory of acquired characteristics. Describe Darwin's theory of natural selection. Compare and contrast both theories. Understand scientific acceptance criteria.

Exposition on Lamarck's giraffe example using chalkboard drawings. Detailed explanation of Darwin's natural selection theory. Comparison table construction. Discussion on scientific evidence.

Textbook, chalkboard, chalk

KLB Secondary Biology Form 4, Pages 71-73

EVOLUTION

Natural Selection in Action

By the end of the lesson, the learner should be able to:
Explain struggle for existence and survival of the fittest. Describe peppered moth example. Model cryptic coloration effects. Understand environmental selection pressures.

Practical activity modeling cryptic coloration using paper cutouts. Discussion on peppered moth case study. Examples of predator-prey relationships. Analysis of selection pressures.

White and black paper, scissors, textbook, chalkboard

KLB Secondary Biology Form 4, Pages 73-75

EVOLUTION

Modern Examples of Evolution and Resistance

By the end of the lesson, the learner should be able to:
Describe antibiotic and pesticide resistance. Explain sickle cell trait advantage in malaria areas. Understand ongoing evolutionary processes. Apply evolutionary principles to current issues.

Discussion on drug-resistant bacteria and insects. Case study of malaria and sickle cell trait. Examples of rapid evolutionary changes. Q/A session and topic review.

Textbook, local examples of pesticide resistance, chalkboard

KLB Secondary Biology Form 4, Pages 75-77

RECEPTION, RESPONSE AND CO-ORDINATION

Meaning of Stimulus, Response and Irritability; Types of Responses
Tropisms in Plants - Types and Survival Value
Nastic Responses and Role of Auxins

By the end of the lesson, the learner should be able to:
Define stimulus, response and irritability. Explain the need for sensitivity and response. Define taxis and different types of tactic responses. Explain survival value of responses.
Define nastic responses. Describe types of nastic movements. Explain what auxins are and their functions. Describe how auxins control tropic responses.

Brainstorming on environmental changes. Discussion on stimulus-response concept using daily examples. Exposition on irritability and tactic responses. Practical observation of simple responses in termites/insects using local materials.
Exposition on nastic responses using diagrams. Discussion on Mimosa pudica responses. Detailed exposition on auxin mechanism using chalkboard diagrams. Simple demonstrations of auxin effects on plant growth.

Textbook, chalkboard, chalk, bread crumbs, termites or other insects, dry sand
Textbook, chalkboard, chalk, seedlings, cardboard boxes for light experiments, local plant examples
Textbook, chalkboard, chalk, Mimosa plant (if available), simple seedlings for auxin demonstration

KLB Secondary Biology Form 4, Pages 78-81
KLB Secondary Biology Form 4, Pages 84-89

RECEPTION, RESPONSE AND CO-ORDINATION

Introduction to Nervous System and Neurone Structure

By the end of the lesson, the learner should be able to:
Describe the need for co-ordination in animals. Compare nervous and endocrine systems. Describe structure of nerve cells. Distinguish between sensory, motor, and relay neurones.

Exposition on animal co-ordination systems. Discussion on rapid vs slow responses. Drawing neurone structures on chalkboard. Detailed exposition on neurone types and functions. Student drawing exercises.

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

KLB Secondary Biology Form 4, Pages 89-92

RECEPTION, RESPONSE AND CO-ORDINATION

Brain Structure and Functions

By the end of the lesson, the learner should be able to:
Describe structure of the human brain. Identify major parts: cerebrum, cerebellum, medulla oblongata. Explain functions of each brain part. Describe protective features.

Drawing brain structure on chalkboard. Exposition on brain anatomy and protection. Detailed discussion on brain part functions. Q&A on voluntary vs involuntary activities. Case studies of brain injuries.

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

KLB Secondary Biology Form 4, Pages 92-95

RECEPTION, RESPONSE AND CO-ORDINATION

Spinal Cord and Reflex Actions

By the end of the lesson, the learner should be able to:
Describe structure and functions of spinal cord. Define reflex action. Distinguish between simple and conditioned reflexes. Describe reflex arc components.

Drawing spinal cord cross-section on chalkboard. Exposition on spinal cord functions. Practical demonstration of knee-jerk reflex. Drawing reflex arc diagrams. Discussion on reflex vs voluntary actions.

Textbook, chalkboard, chalk, exercise books, simple tools for reflex testing

KLB Secondary Biology Form 4, Pages 95-98

RECEPTION, RESPONSE AND CO-ORDINATION

Nerve Impulse Transmission and Synapses
Endocrine System and Hormone Functions

By the end of the lesson, the learner should be able to:
Explain resting potential and action potential. Describe nerve impulse transmission. Describe structure and function of synapses. Explain role of neurotransmitters.
Define hormones and endocrine glands. Compare endocrine and nervous systems. Identify major endocrine glands. Explain negative feedback mechanism.

Detailed exposition on nerve impulse transmission using diagrams. Discussion on ionic movements and electrical changes. Drawing synapse structure. Exposition on chemical transmission at synapses.
Exposition on endocrine system concept. Drawing endocrine gland locations on chalkboard. Detailed comparison between nervous and endocrine control. Discussion on hormone transport and target organs.

Textbook, chalkboard, chalk, exercise books, simple analogies using local examples

KLB Secondary Biology Form 4, Pages 98-100
KLB Secondary Biology Form 4, Pages 100-101

RECEPTION, RESPONSE AND CO-ORDINATION

Thyroxine and Adrenaline Functions

By the end of the lesson, the learner should be able to:
Describe functions of thyroid and adrenal glands. Explain effects of thyroxine on metabolism. Explain effects of adrenaline on body systems. Understand related disorders.

Detailed exposition on thyroxine functions and disorders. Discussion on hypothyroidism and hyperthyroidism. Exposition on adrenaline effects during emergencies. Case studies of hormone-related conditions.

Textbook, chalkboard, chalk, local health examples

KLB Secondary Biology Form 4, Pages 101-103

RECEPTION, RESPONSE AND CO-ORDINATION

Drug Abuse Effects on Coordination

By the end of the lesson, the learner should be able to:
Identify commonly abused drugs. Explain effects of drug abuse on nervous system. Describe health consequences of drug abuse. Understand prevention strategies.

Discussion on local drug abuse problems. Exposition on drug effects on coordination and health. Health education on drug abuse prevention. Case studies from local community. Group discussions on prevention strategies.

Textbook, chalkboard, chalk, local health examples, community case studies

KLB Secondary Biology Form 4, Pages 103-104

RECEPTION, RESPONSE AND CO-ORDINATION

Structure of the Human Eye

By the end of the lesson, the learner should be able to:
Describe external and internal structure of the eye. Identify major parts and their functions. Explain protective features of the eye. Understand image formation basics.

Drawing detailed eye structure on chalkboard. Exposition on eye anatomy and part functions. Discussion on eye protection mechanisms. Introduction to light path through eye. Student labeling exercises.

Textbook, chalkboard, chalk, exercise books, rulers

KLB Secondary Biology Form 4, Pages 104-109

RECEPTION, RESPONSE AND CO-ORDINATION

Vision, Rods, Cones and Image Formation
Accommodation and Pupil Control
Eye Defects and Their Correction

By the end of the lesson, the learner should be able to:
Explain functions of rods and cones. Describe image formation in the eye. Understand color vision and visual acuity. Explain binocular and stereoscopic vision.
Explain accommodation mechanism for near and distant objects. Describe pupil size control. Understand role of ciliary muscles and iris.

Exposition on photoreceptor functions and differences. Discussion on color vision mechanism. Explanation of image formation process. Practical activities on visual perception and blind spot demonstration.
Detailed exposition on accommodation using diagrams. Discussion on lens shape changes and muscle action. Explanation of pupil control in different light conditions. Practical observations of pupil responses.

Textbook, chalkboard, chalk, white paper, pencils for blind spot experiment
Textbook, chalkboard, chalk, simple lenses (if available), torch or bright light
Textbook, chalkboard, chalk, examples of different spectacles, exercise books

KLB Secondary Biology Form 4, Pages 105-109
KLB Secondary Biology Form 4, Pages 109-110

RECEPTION, RESPONSE AND CO-ORDINATION

Structure of the Human Ear

By the end of the lesson, the learner should be able to:
Describe structure of outer, middle, and inner ear. Identify major parts and their functions. Explain ear protection mechanisms.

Drawing detailed ear structure on chalkboard. Exposition on ear anatomy of all three parts. Discussion on ear part functions. Explanation of ear protection and wax function. Student labeling exercises.

Textbook, chalkboard, chalk, exercise books, rulers

KLB Secondary Biology Form 4, Pages 112-113

RECEPTION, RESPONSE AND CO-ORDINATION

Hearing Mechanism

By the end of the lesson, the learner should be able to:
Explain mechanism of hearing from sound waves to brain interpretation. Describe role of ear ossicles, cochlea, and auditory nerve. Understand sound discrimination.

Step-by-step exposition on hearing process using detailed diagrams. Discussion on sound wave transmission through ear parts. Explanation of sound interpretation in brain. Simple sound experiments if possible.

Textbook, chalkboard, chalk, simple sound sources for demonstration

KLB Secondary Biology Form 4, Pages 113-114

RECEPTION, RESPONSE AND CO-ORDINATION

Balance and Posture Control

By the end of the lesson, the learner should be able to:
Explain how ear maintains balance and posture. Describe role of semicircular canals and vestibule. Understand body balance mechanisms.

Exposition on balance control mechanisms using diagrams. Discussion on semicircular canals and their orientation. Explanation of otoliths and gravity detection. Simple balance experiments and demonstrations.

Textbook, chalkboard, chalk, simple materials for balance demonstration

KLB Secondary Biology Form 4, Pages 114-115

RECEPTION, RESPONSE AND CO-ORDINATION

Ear Defects and Hearing Problems
Integration and Coordination Systems Review
Practical Applications and Assessment

By the end of the lesson, the learner should be able to:
Identify ear defects and hearing problems. Explain causes of deafness and hearing loss. Describe prevention and treatment methods.
Compare plant and animal coordination systems. Integrate nervous, endocrine, and sensory systems. Apply knowledge to solve coordination problems.

Discussion on types of deafness and their causes. Exposition on ear infections and prevention. Examples of hearing problems from local community. Health education on ear care and protection.
Comprehensive review of all coordination systems. Comparison charts of different response types. Problem-solving exercises on coordination scenarios. Q&A sessions covering all topics. Preparation for assessments.

Textbook, chalkboard, chalk, local examples of hearing problems
Textbook, chalkboard, chalk, exercise books, review materials
Textbook, assessment materials, local case studies, exercise books

KLB Secondary Biology Form 4, Pages 115-116
KLB Secondary Biology Form 4, Pages 78-116