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| WK | LSN | TOPIC | SUB-TOPIC | OBJECTIVES | T/L ACTIVITIES | T/L AIDS | REFERENCE | REMARKS |
|---|---|---|---|---|---|---|---|---|
| 2 | 1 |
GENETICS
|
Introduction to Genetics and Variation
Observable Variations in Human Beings |
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
Ink pad, plain paper, metre rule, exercise books |
KLB Secondary Biology Form 4, Pages 1-2
|
|
| 2 | 2-3 |
GENETICS
|
Discontinuous and Continuous Variation
Causes of Variation Chromosome Structure |
By the end of the
lesson, the learner
should be able to:
Define discontinuous and continuous variation. Give examples of each type. Plot frequency distribution graphs for continuous variation. Explain genetic and environmental causes of variation. Describe role of meiosis, fertilization and mutations in creating variation. |
Analysis of tongue rolling and height data. Plotting frequency-height graphs on chalkboard. Discussion on differences between variation types.
Exposition on sources of variation. Discussion on independent assortment during meiosis. Examples of environmental effects on phenotypes. |
Graph paper, rulers, height data from previous lesson, textbook
Textbook, chalkboard, chalk Textbook, chalkboard, chalk, exercise books, pencils |
KLB Secondary Biology Form 4, Pages 3-4
KLB Secondary Biology Form 4, Pages 4-5 |
|
| 2 | 4 |
GENETICS
|
Chromosome Behaviour During Mitosis
|
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. |
Practical activity using colored threads to model mitosis stages. Creating paper models of mitotic stages. Group discussions.
|
Colored threads (6cm and 3cm), scissors, manila paper, string for tying knots
|
KLB Secondary Biology Form 4, Pages 6-8
|
|
| 2 | 5 |
GENETICS
|
Chromosome Behaviour During Meiosis
DNA Structure and Replication |
By the end of the
lesson, the learner
should be able to:
Describe chromosome behaviour during meiosis. Explain crossing over and reduction division. Compare mitosis and meiosis. |
Continuation of chromosome modeling using threads. Demonstration of reduction division. Discussion on gamete formation.
|
Colored threads, manila paper, textbook
Textbook, chalkboard, chalk, exercise books |
KLB Secondary Biology Form 4, Pages 8-9
|
|
| 3 | 1 |
GENETICS
|
DNA and Protein Synthesis
|
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
|
|
| 3 | 2-3 |
GENETICS
|
Mendel's Experiments and First Law
Monohybrid Inheritance Concepts |
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. Define monohybrid inheritance, genotype, phenotype. Distinguish between dominant and recessive genes. Explain homozygous and heterozygous conditions. |
Q/A on Mendel's work. Detailed discussion of pea plant experiments using chalkboard diagrams. Analysis of F1 and F2 results.
Exposition on genetic terminology. Practice using genetic symbols on chalkboard. Discussion on gene expression patterns. |
Textbook, chalkboard, chalk
Textbook, chalkboard, chalk, exercise books |
KLB Secondary Biology Form 4, Pages 13-15
KLB Secondary Biology Form 4, Pages 15-17 |
|
| 3 | 4 |
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
|
|
| 3 | 5 |
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
|
|
| 4 | 1 |
GENETICS
|
Probability in Inheritance
|
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. |
Mathematical analysis of genetic ratios. Coin tossing experiment to demonstrate probability. Statistical interpretation of results.
|
Coins, exercise books for recording, calculators (if available), textbook
|
KLB Secondary Biology Form 4, Pages 18-19
|
|
| 4 | 2-3 |
GENETICS
|
Modeling Random Gamete Fusion
Complete Dominance Problems |
By the end of the
lesson, the learner
should be able to:
Demonstrate random fusion of gametes. Use simple materials to model inheritance. Analyze experimental vs expected results. Solve genetic problems involving complete dominance. Analyze inheritance patterns in garden peas. Practice genetic calculations. |
Practical activity using different colored beans to represent gametes. Data collection and analysis. Discussion on sample size effects.
Worked examples of genetic problems on chalkboard. Practice sessions with various characteristics. Group problem-solving. |
Different colored beans (or maize grains), small containers, exercise books
Textbook, chalkboard, chalk, exercise books |
KLB Secondary Biology Form 4, Pages 19-20
KLB Secondary Biology Form 4, Pages 20-21 |
|
| 4 | 4 |
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
|
|
| 4 | 5 |
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
|
|
| 5 | 1 |
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
|
|
| 5 | 2-3 |
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
|
|
| 5 | 4 |
GENETICS
|
Sex Determination
|
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. |
Exposition on sex chromosomes using chalkboard diagrams. Genetic crosses for sex determination. Comparison with other animals.
|
Textbook, chalkboard, chalk
|
KLB Secondary Biology Form 4, Pages 26-27
|
|
| 5 | 5 |
GENETICS
|
Gene Linkage
|
By the end of the
lesson, the learner
should be able to:
Define gene linkage and linkage groups. Explain inheritance of linked genes. Understand why some genes are inherited together. |
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 27-28
|
|
| 6 | 1 |
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
|
|
| 6 | 2-3 |
GENETICS
|
Sex-linked Inheritance - Color Blindness
Sex-linked Inheritance - Haemophilia |
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. Explain haemophilia inheritance. Understand carrier females and affected males. Analyze inheritance through generations. |
Detailed exposition on X-linked inheritance using chalkboard. Genetic crosses for color blindness. Drawing simple pedigree charts.
Exposition on haemophilia genetics. Drawing inheritance patterns on chalkboard. Practice with pedigree construction and analysis. |
Textbook, chalkboard, chalk, exercise books, rulers
|
KLB Secondary Biology Form 4, Pages 28-30
KLB Secondary Biology Form 4, Pages 30-31 |
|
| 6 | 4 |
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
|
|
| 6 | 5 |
GENETICS
|
Chromosomal Mutations - Non-disjunction
|
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
|
KLB Secondary Biology Form 4, Pages 32-35
|
|
| 7 | 1 |
GENETICS
|
Chromosomal Mutations - Polyploidy
|
By the end of the
lesson, the learner
should be able to:
Describe structural chromosome changes. Explain polyploidy in plants. Understand chromosome number variations. |
Exposition on chromosome number changes. Examples of polyploidy in agriculture using chalkboard. Discussion on plant breeding applications.
|
Textbook, chalkboard, chalk
|
KLB Secondary Biology Form 4, Pages 35-36
|
|
| 7 | 2-3 |
GENETICS
|
Chromosomal Mutations - Polyploidy
Gene Mutations |
By the end of the
lesson, the learner
should be able to:
Describe structural chromosome changes. Explain polyploidy in plants. Understand chromosome number variations. Define gene mutations. Describe insertion, deletion, substitution and inversion. Explain effects on protein synthesis using analogies. |
Exposition on chromosome number changes. Examples of polyploidy in agriculture using chalkboard. Discussion on plant breeding applications.
Detailed exposition on point mutations using simple examples. Use SMS text analogies for mutations. Discussion on protein changes. |
Textbook, chalkboard, chalk
Textbook, chalkboard, chalk, simple text examples |
KLB Secondary Biology Form 4, Pages 35-36
KLB Secondary Biology Form 4, Pages 36-38 |
|
| 7 | 4 |
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
|
|
| 7 | 5 |
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
|
|
| 8 | 1 |
GENETICS
|
Environmental Effects on Gene Expression
|
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
|
KLB Secondary Biology Form 4, Pages 42-43
|
|
| 8 | 2-3 |
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. Identify applications in plant and animal breeding. Explain genetic counselling. Understand blood transfusion genetics. Introduce genetic engineering basics. |
Discussion on environmental influences using local examples. Plant growth under different conditions. Twin studies and environmental factors.
Exposition on practical genetics applications. Local examples of plant breeding. Discussion on genetic counselling process and medical applications. |
Textbook, local plant examples, chalkboard
Textbook, local breeding examples, chalkboard |
KLB Secondary Biology Form 4, Pages 42-43
KLB Secondary Biology Form 4, Pages 43-49 |
|
| 8 | 4 |
GROWTH AND DEVELOPMENT
|
Introduction and Definitions
|
By the end of the
lesson, the learner
should be able to:
To distinguish between growth and development. To define growth as permanent increase in size and weight. To explain development as structural changes and differentiation. To relate growth to cell division and tissue formation. |
Q/A: Review reproduction concepts. Discussion: Definition of growth vs development. Teacher exposition: Cell division, differentiation and tissue formation. Q/A: Examples of growth and development in organisms. Discussion: Growth as characteristic of living organisms.
|
Charts showing growth and development, Textbook, Wall charts
|
Certificate Biology Form 3, Pages 178-179
|
|
| 8 | 5 |
GROWTH AND DEVELOPMENT
|
Measurement of Growth
Patterns and Rate of Growth |
By the end of the
lesson, the learner
should be able to:
To identify different methods of measuring growth. To explain linear dimensions, mass and dry weight measurements. To describe advantages and limitations of each method. To calculate growth rates. |
Discussion: Methods of measuring growth in plants and animals. Teacher exposition: Linear measurements, mass, dry weight procedures. Practical demonstration: Measuring techniques. Q/A: Why dry weight is more accurate for plants. Calculate growth rate examples.
|
Measuring instruments, Scales, Rulers, Calculators, Sample plants
Growth curve charts, Graph paper, Calculators, Sample data sets |
Certificate Biology Form 3, Pages 178-179
|
|
| 9 | 1 |
GROWTH AND DEVELOPMENT
|
Factors Controlling Plant Growth
|
By the end of the
lesson, the learner
should be able to:
To identify external factors affecting plant growth. To explain how oxygen, temperature, water, light and space influence growth. To describe internal factors including hormones. To relate factors to plant survival and adaptation. |
Detailed discussion: External factors - oxygen, temperature, water, light, space. Teacher exposition: How each factor affects biochemical processes. Q/A: Competition effects and resource limitation. Introduction to internal factors and plant hormones.
|
Environmental factor charts, Temperature scales, Light meters if available, Textbook
|
Certificate Biology Form 3, Pages 180-181
|
|
| 9 | 2-3 |
GROWTH AND DEVELOPMENT
|
Stages of Growth and Life Cycle
Seed Structure - Monocots and Dicots Conditions for Germination |
By the end of the
lesson, the learner
should be able to:
To describe stages from seed to maturity. To distinguish between annuals and perennials. To identify vegetative and reproductive phases. To explain germination, primary and secondary growth. To identify conditions necessary for seed germination. To explain roles of water, oxygen and temperature in germination. To describe enzyme activation and food mobilization. To investigate scarification effects. |
Discussion: Plant life cycle from seed to maturity. Teacher exposition: Vegetative vs reproductive growth phases. Q/A: Differences between annuals and perennials with examples. Overview of germination, primary and secondary growth stages.
Detailed discussion: Water absorption, enzyme activation, hydrolysis reactions. Teacher exposition: Oxygen requirements for respiration and ATP production. Q/A: Temperature effects on enzyme activity. Discussion: Scarification and testa permeability. Demonstration of vernalization concept. |
Plant life cycle charts, Examples of annual and perennial plants, Textbook
Soaked bean and maize seeds, Hand lens, Scalpels, Drawing materials, Iodine solution Germination apparatus, Seeds at different stages, Temperature monitoring equipment, Textbook |
Certificate Biology Form 3, Pages 181-182
Certificate Biology Form 3, Pages 183-184 |
|
| 9 | 4 |
GROWTH AND DEVELOPMENT
|
Types of Germination
Germination Practical Investigation |
By the end of the
lesson, the learner
should be able to:
To distinguish between epigeal and hypogeal germination. To describe hypocotyl and epicotyl elongation. To explain cotyledon behavior in each type. To give examples of plants showing each germination type. |
Practical observation: Germinating bean and maize seeds at different stages. Teacher exposition: Epigeal germination - hypocotyl elongation, cotyledon emergence. Discussion: Hypogeal germination - epicotyl elongation, cotyledons remain underground. Drawing comparative diagrams of both types.
|
Germinating seeds at various stages, Drawing materials, Observation trays, Hand lens
Seeds, Petri dishes, Cotton wool, Measuring rulers, Data recording sheets, Clay pots |
Certificate Biology Form 3, Pages 184-186
|
|
| 9 | 5 |
GROWTH AND DEVELOPMENT
|
Primary Growth and Meristems
|
By the end of the
lesson, the learner
should be able to:
To describe primary growth in plants. To identify apical meristems and their functions. To explain tissue development from meristems. To relate meristem activity to plant growth. |
Discussion: Primary growth in seedlings and herbaceous plants. Teacher exposition: Apical meristem structure and cell characteristics. Q/A: Meristem cell division and differentiation processes. Drawing diagrams showing meristem distribution in plants.
|
Meristem distribution charts, Drawing materials, Microscope slides of meristems, Textbook
|
Certificate Biology Form 3, Pages 186-187
|
|
| 10 | 1 |
GROWTH AND DEVELOPMENT
|
Secondary Growth and Cambium Activity
|
By the end of the
lesson, the learner
should be able to:
To describe secondary growth in dicots. To explain vascular cambium and cork cambium functions. To identify secondary xylem and phloem formation. To relate secondary growth to plant strength and support. |
Detailed discussion: Secondary thickening in woody plants. Teacher exposition: Vascular cambium tangential divisions. Q/A: Secondary xylem and phloem development. Discussion: Cork cambium, lenticels and bark formation. Drawing cross-sections showing secondary tissues.
|
Secondary growth diagrams, Tree trunk sections, Drawing materials, Hand lens
|
Certificate Biology Form 3, Pages 186-188
|
|
| 10 | 2-3 |
GROWTH AND DEVELOPMENT
|
Secondary Growth and Cambium Activity
Annual Rings and Plant Dormancy |
By the end of the
lesson, the learner
should be able to:
To describe secondary growth in dicots. To explain vascular cambium and cork cambium functions. To identify secondary xylem and phloem formation. To relate secondary growth to plant strength and support. To explain annual ring formation in temperate trees. To describe factors causing plant dormancy. To identify dormancy in buds, seeds and organs. To explain dormancy advantages for plant survival. |
Detailed discussion: Secondary thickening in woody plants. Teacher exposition: Vascular cambium tangential divisions. Q/A: Secondary xylem and phloem development. Discussion: Cork cambium, lenticels and bark formation. Drawing cross-sections showing secondary tissues.
Discussion: Annual growth seasons and ring formation. Teacher exposition: Environmental factors triggering dormancy. Q/A: Metabolic changes during dormancy periods. Discussion: Dormancy in bulbs, corms, rhizomes. Examples of seasonal dormancy in tropical plants. |
Secondary growth diagrams, Tree trunk sections, Drawing materials, Hand lens
Tree trunk cross-sections, Dormant plant organs, Charts, Textbook |
Certificate Biology Form 3, Pages 186-188
Certificate Biology Form 3, Page 188 |
|
| 10 | 4 |
GROWTH AND DEVELOPMENT
|
Seed Dormancy and Breaking Mechanisms
|
By the end of the
lesson, the learner
should be able to:
To describe seed dormancy characteristics. To explain factors that break seed dormancy. To identify vernalization, moisture, light and chemical effects. To discuss advantages of seed dormancy. |
Detailed discussion: Dormant seed characteristics and low metabolic activity. Teacher exposition: Vernalization, moisture, light requirements. Q/A: Chemical inhibitors and gibberellic acid effects. Discussion: Dormancy advantages - dispersal time, favorable conditions.
|
Dormant seeds, Germination comparison setups, Chemical solutions, Textbook
|
Certificate Biology Form 3, Pages 188-189
|
|
| 10 | 5 |
GROWTH AND DEVELOPMENT
|
Seed Dormancy and Breaking Mechanisms
|
By the end of the
lesson, the learner
should be able to:
To describe seed dormancy characteristics. To explain factors that break seed dormancy. To identify vernalization, moisture, light and chemical effects. To discuss advantages of seed dormancy. |
Detailed discussion: Dormant seed characteristics and low metabolic activity. Teacher exposition: Vernalization, moisture, light requirements. Q/A: Chemical inhibitors and gibberellic acid effects. Discussion: Dormancy advantages - dispersal time, favorable conditions.
|
Dormant seeds, Germination comparison setups, Chemical solutions, Textbook
|
Certificate Biology Form 3, Pages 188-189
|
|
| 11 | 1 |
GROWTH AND DEVELOPMENT
|
Plant Growth Substances - Auxins
|
By the end of the
lesson, the learner
should be able to:
To describe discovery of plant hormones by Fritz Went. To explain auxin functions in stems, leaves, roots and fruits. To identify IAA structure and translocation. To discuss practical applications of auxins. |
Teacher exposition: Went's experiments with oat coleoptiles and auxin discovery. Discussion: Auxin effects in different plant organs. Q/A: Apical dominance and parthenocarpy. Practical applications: rooting powders, herbicides, fruit development.
|
Auxin experiment diagrams, Plant cuttings, Rooting powder demonstration, Textbook
|
Certificate Biology Form 3, Pages 189-192
|
|
| 11 | 2-3 |
GROWTH AND DEVELOPMENT
|
Gibberellins, Cytokinins and Other Hormones
Practical Applications of Plant Hormones |
By the end of the
lesson, the learner
should be able to:
To describe gibberellin functions and effects. To explain cytokinin roles in cell division and growth. To identify abscissic acid as growth inhibitor. To describe ethene and florigen effects. To explain commercial uses of plant hormones. To describe hormone applications in agriculture and horticulture. To identify hormone uses in crop production. To discuss economic benefits of hormone applications. |
Discussion: Gibberellin effects on stem elongation and seed germination. Teacher exposition: Cytokinin functions in meristematic tissues. Q/A: Abscissic acid antagonistic effects. Discussion: Ethene in fruit ripening and florigen in flowering.
Discussion: Commercial applications of auxins in propagation. Teacher exposition: Gibberellins in brewing and dwarf plant treatment. Q/A: Hormone use in fruit production and weed control. Case studies: Economic benefits in agriculture and horticulture. |
Plant hormone effect charts, Ripening fruits, Textbook
Hormone application examples, Agricultural product samples, Case study materials |
Certificate Biology Form 3, Pages 192-194
Certificate Biology Form 3, Pages 191-194 |
|
| 11 | 4 |
GROWTH AND DEVELOPMENT
|
Animal Growth Patterns and Life Cycles
|
By the end of the
lesson, the learner
should be able to:
To distinguish continuous from discontinuous growth in animals. To describe sigmoid growth curve phases. To explain lag, exponential, decelerating and plateau phases. To compare growth patterns in different animal groups. |
Analysis of sigmoid growth curves showing four phases. Teacher exposition: Continuous growth in mammals, birds, fish. Discussion: Discontinuous growth in insects and amphibians. Q/A: Factors affecting each growth phase.
|
Growth curve charts, Animal development examples, Graph paper, Textbook
|
Certificate Biology Form 3, Pages 193-194
|
|
| 11 | 5 |
GROWTH AND DEVELOPMENT
|
Animal Growth Patterns and Life Cycles
|
By the end of the
lesson, the learner
should be able to:
To distinguish continuous from discontinuous growth in animals. To describe sigmoid growth curve phases. To explain lag, exponential, decelerating and plateau phases. To compare growth patterns in different animal groups. |
Analysis of sigmoid growth curves showing four phases. Teacher exposition: Continuous growth in mammals, birds, fish. Discussion: Discontinuous growth in insects and amphibians. Q/A: Factors affecting each growth phase.
|
Growth curve charts, Animal development examples, Graph paper, Textbook
|
Certificate Biology Form 3, Pages 193-194
|
|
| 12 | 1 |
GROWTH AND DEVELOPMENT
|
Complete Metamorphosis
|
By the end of the
lesson, the learner
should be able to:
To describe complete metamorphosis stages. To explain life cycle of housefly and butterfly. To identify egg, larva, pupa and adult stages. To discuss economic importance of insects with complete metamorphosis. |
Detailed study: Housefly life cycle - egg, maggot, pupa, imago. Teacher exposition: Butterfly development - caterpillar, chrysalis, adult. Q/A: Structural and behavioral differences between stages. Discussion: Economic importance - pests, silk production.
|
Insect life cycle charts, Preserved specimens if available, Drawings, Textbook
|
Certificate Biology Form 3, Pages 195-198
|
|
| 12 | 2-3 |
GROWTH AND DEVELOPMENT
|
Incomplete Metamorphosis
Hormonal Control of Growth in Animals |
By the end of the
lesson, the learner
should be able to:
To describe incomplete metamorphosis characteristics. To explain life cycles of cockroach and locust. To identify nymphal stages and molting process. To compare complete and incomplete metamorphosis. To identify growth hormones in different animals. To explain human growth hormone from pituitary gland. To describe insect molting hormones - ecdysone and juvenile hormone. To explain thyroxine role in frog metamorphosis. |
Discussion: Egg to adult development through nymphal stages. Teacher exposition: Cockroach and locust life cycles. Q/A: Molting/ecdysis process and wing development. Comparison table: Complete vs incomplete metamorphosis.
Discussion: Growth hormone control in mammals. Teacher exposition: Pituitary gland and human growth regulation. Q/A: Insect hormone balance - ecdysone and neotonin effects. Discussion: Thyroxine control of amphibian metamorphosis. |
Incomplete metamorphosis charts, Grasshopper specimens, Comparison tables, Textbook
Hormone control charts, Animal development diagrams, Textbook |
Certificate Biology Form 3, Pages 198-199
Certificate Biology Form 3, Page 199 |
|
| 12 | 4 |
GROWTH AND DEVELOPMENT
|
Hormonal Control of Growth in Animals
|
By the end of the
lesson, the learner
should be able to:
To identify growth hormones in different animals. To explain human growth hormone from pituitary gland. To describe insect molting hormones - ecdysone and juvenile hormone. To explain thyroxine role in frog metamorphosis. |
Discussion: Growth hormone control in mammals. Teacher exposition: Pituitary gland and human growth regulation. Q/A: Insect hormone balance - ecdysone and neotonin effects. Discussion: Thyroxine control of amphibian metamorphosis.
|
Hormone control charts, Animal development diagrams, Textbook
|
Certificate Biology Form 3, Page 199
|
|
| 12 | 5 |
GROWTH AND DEVELOPMENT
|
Growth Measurement Practical
|
By the end of the
lesson, the learner
should be able to:
To measure plant growth over time. To record linear measurements and calculate growth rates. To plot growth curves from collected data. To analyze factors affecting growth differences. |
Practical work: Long-term measurement of plant growth (height, leaf length). Data recording: Daily/weekly measurements over extended period. Mathematical analysis: Growth rate calculations. Graph plotting: Growth curves and growth rate curves.
|
Growing plants, Measuring rulers, Data recording sheets, Graph paper, Calculators
|
Certificate Biology Form 3, Pages 201-202
|
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