This is a fully-resourced REVISION lesson which challenges the students on their knowledge of the content in TOPIC B5 (Health, disease and the development of medicines) of the Edexcel GCSE Combined Science specification. The lesson uses an engaging PowerPoint (79 slides) and accompanying worksheets to motivate students whilst they assess their understanding of this topic. The lesson has been designed in the way that the students have to work their way through a series of wards at the hospital which deals with communicable diseases caused by a range of pathogens and the non-communicable diseases ward such as the cardiac ward where CHD patients are assessed and treated. A range of exam questions, differentiated tasks and quiz competitions back up the engaging lesson and are used to test the following sub-topics: Bacterial, fungal and viral diseases in animals and plants Treatment of bacterial infections with antibiotics Preventing and reducing the spread of pathogens Vaccinations The physical and chemical defences of the human body The risk factors of CHD The range of surgical treatments for CHD Calculating the BMI Smoking and cardiovascular diseases The mathematical element of the course is also tested throughout the lesson and students are given helpful hints on exam techniques and how to structure answers. This resource is suitable for use at the end of topic B5 or in the lead up to mocks or the actual GCSE exams.

This lesson looks at the two stages of protein synthesis, transcription and translation, and focuses on the key details that students need to understand this potentially difficult topic. The lesson presentation has been deliberately written in a concise way to encourage the students to summarise the two stages and pick out the key points which will enable them to form longer answers when necessary. The lesson begins by introducing the students to RNA, and a quick check is done to see how much they can recall about the other nucleic acid, DNA. Moving forwards, students are challenged to study the structure of DNA and RNA in SPOT THE DIFFERENCE before being challenged to explain why RNA is necessary in this process. Time is taken to look at important sections such as complimentary base pairing and the identification of amino acids from the codon. A number of quick competitions have been written into the lesson to maintain engagement and the progress checks are regular so that students assess their understanding and any misconceptions can be quickly identified and addressed. This lesson has been written for GCSE students but should a teacher want to teach an introduction lesson on protein synthesis before going into more detail at a later date, then this would be suitable.

This lesson has been designed to guide GCSE students (14 - 16 year olds in the UK) through the steps involved in gas calculations. As you can see in the cover image, this lesson uses a step by step guide format to go through each of the critical stages. Hints and tips are given along the way and worked examples are used so that students can visualise how to set out their working. Important terminology such as room temperature and pressure (RTP) and limiting reactant are explained so that these do not cause issues. Students are given the opportunity to test their skills against some gas calculation questions which have detailed mark schemes and explanations to enable them to fully self-assess.

This detailed lesson describes the role of the mRNA, tRNA, rRNA and amino acids during the second stage of protein synthesis - translation. Both the PowerPoint and accompanying resources have been designed to cover the second part of point 2.1.3 (g) of the OCR A-level Biology A specification and continually links back to the previous lessons in this module on the structure of DNA and RNA and the genetic code Translation is a topic which is often poorly understood and so this lesson has been written to enable the students to understand how to answer the different types of questions by knowing and including the key details of the structures involved. The lesson begins by challenging the students to consider why it is so important that the amino acids are assembled in the correct order during the formation of the chain. Moving forwards, a quick quiz round called “LOST IN TRANSLATION” is used to check on their prior knowledge of the mRNA strand, the tRNA molecules, the genetic code and the ribosomes. The next task involves a very detailed description of translation that has been divided into 14 statements which the students have to put into the correct order. By giving them a passage that consists of this considerable detail, they can pick out the important parts to use in the next task where they have to answer shorter questions worth between 3 and 4 marks. These types of questions are common in the assessments and by building up through the lesson, their confidence to answer this type should increase. The final two tasks of the lesson involve another quiz, where the teams compete to transcribe and translate in the quickest time before using all that they have absorbed to answer some questions which involve the genetic code and the mRNA codon table

An engaging lesson presentation (34), accompanied by a summary worksheet, which together explore the factors which change the rate of transpiration and focuses on the explanation behind each factor. The lesson begins by introducing the term, transpiration, and linking this to the structure of a leaf to ensure that students know that water is lost as water vapour out of the stomata. Students are provided with an analogy of plants being like clothes on a washing line to challenge them to come up with some of the factors involved. Time is taken to look specifically at humidity as this is a factor which is commonly misunderstood. Moving forwards, students are challenged to draw sketch graphs to predict whether increasing each of these factors will increase the rate of transpiration or decrease it. A series of questions to lead to answers is used to show the students how to explain the effect of increasing the light intensity. The remainder of the lesson looks at a potometer and how it can be used to calculate the rate. The mathematical skills of the students are challenged during a range of tasks and then linked back to the Science so they can recognise which features of plants will help to reduce water loss. Progress checks are written into this lesson at regular intervals to allow students to assess their understanding and a number of quick competitions act to maintain engagement. This lesson has been written for GCSE students but is suitable for A-level students who are studying the plants topic

A fully-resourced lesson, designed for GCSE students which includes an engaging and informative lesson presentation (49 slides) and an image, actual and magnification question worksheet. This lesson looks at the key features of light and electron microscopes and guides students through calculating size and magnification. The lesson begins by challenging students to pick out two key terms about microscopes, magnification and resolution, from a group of Scientific words. The understanding of these two terms is critical if students will be able to compare the two types of microscopes so time is taken to go through the definitions and give examples. A number of quick quiz competitions have been written into the lesson to aid the engagement on a topic that some students may not initially consider to be that motivating. These competitions allow key terms such as micrometer and the two types of electron microscope to be introduced in an engaging way. As a result, students will know the numbers that explain why electron microscopes are more advanced than their light counterparts. The remainder of the lesson looks at the units of size which are used in calculation questions and a step by step guide is used to show the students to calculate the actual size of an object or the magnification. Progress checks have been written into this lesson at regular intervals so that students are constantly assessing their understanding.

A fast-paced lesson which includes an informative lesson presentation (20 slides) and a question worksheet. Together these resources guide GCSE students through the calculation questions that they can encounter on the topic of the conservation of momentum. The lesson begins by introducing the law of the conservation of momentum and reminding students of the equation which links momentum, mass and velocity that they are expected to recall for the GCSE exam. Time is taken to inform them of the two types of question which tend to arise on this topic - those where the masses lock together during the event and those where they remain as separate masses. Students are guided through both of these types of questions with worked examples to enable them to visualise how to begin and set out their workings. Key mathematical skills are involved such as rearranging the formula so this is also shown. Students are given the opportunity to apply these skills to a series of questions on the worksheet and the mark schemes are displayed so they can assess once completed.

This lesson uses the example of the genetic engineering of bacteria to produce insulin to walk students through the steps involved in this process. It has been written for GCSE students and therefore includes the detail required at this level, such as the involvement of restriction enzymes and the sticky ends that their cut produces. The lesson begins by challenging students to recognise that insulin is being described by a series of clues. Some further details of this hormone are recalled to test their previous knowledge of the endocrine system and also to lead into the genetic engineering of bacteria to make this protein. Moving forwards, time is taken to go through the details of plasmids and how they act as vectors as well as the enzymes, restriction and ligase. The main task of the lesson uses a series of descriptions to go through the steps involved in the process. Words or phrases are missing from each description so students have to use the terms they’ve encountered in this lesson as well as their prior knowledge to complete the step. Discussion-provoking questions are added to encourage the students to consider why certain parts of the process occur. The lesson concludes by the consideration of other organisms which have been genetically engineered as well as some of the risks of the process, which students are asked to complete for homework. As detailed above, this lesson has been designed for GCSE students but could be used with students taking A-level Biology, who are struggling to understand the detail found at this level and need to revisit the foundations.

A resourced lesson which looks at calculating acceleration using the (v-u)/t equation. This lesson includes an engaging lesson presentation (26 slides) and a worksheet of questions that can be used for homework or during the lesson. The lesson begins by looking at the actual meaning of acceleration, ensuring that students understand it is a rate and therefore recognise the units as a result. A number of engaging activities are included in the lesson, such as the ACCELERATION OLYMPICS, to maintain motivation. Students are shown how to rearrange the equation to make velocity or time the subject and then challenged to apply these in a series of questions. Deceleration is briefly mentioned at the end of the lesson. This lesson has been primarily designed for students studying GCSE (14 - 16 year olds in the UK) but it is suitable for students at KS3 too.

A fully-resourced lesson which uses a step-by-step guide to show students how to write fully balanced symbol equations. The lesson includes an engaging lesson presentation (38 slides) and associated worksheets containing questions which iaredifferentiated. The lesson begins by talking the students through the three steps involved in writing a chemical symbol equation. The first step involves writing in the formula for the elements. Students are introduced to the term, diatomic, and shown the 8 molecules that have to be written as a pair of atoms. Moving forwards, students are shown how to write chemical formulae for ionic compounds. They are reminded of how to use the group of the Periodic Table to work out the ion charge and how this is crucial when writing the formula. They are also shown how to write formulae which include brackets which is necessary when the charged molecules are involved. Finally, students are reminded of the rules of balancing symbol equations. There are progress checks at each stage so that students can assess their understanding and any misconceptions can be be addressed immediately. Time is taken to talk about state symbols, in case the exam question requires these to be included in the equation. The final section of the lesson involves students bringing their new-found skills together to write symbol equations for a range of reactions, including a neutralisation and reversible reaction. This task is differentiated so that students who need a little bit of assistance can still access the work. This lesson has been written for GCSE students (14-16 year olds in the UK)

A thought-provoking lesson presentation (34 slides) that looks at each of the stages in the development of drugs and considers the potential issues that arise at each of the stages. The lesson begins by ensuring that the students know the scientific definition of a drug and then they will be told how much is spent by the NHS alone each year on medicinal drugs so they can recognise the importance of this topic. Moving forwards, each stage in the development is considered in the appropriate detail. Students are challenged to consider some stages from both a scientific angle and a business angle so they can understand why certain animals are chosen for the testing. Key terms such as placebo and double blind trial are introduced and discussion time is written into the lesson so that insightful questions can be posed by all. There are regular progress checks throughout the lesson to allow the students to check on their understanding. This lesson has been written for GCSE students but could be used with KS3 students who might be carrying out research or a project on the topic of drugs.

A fully-resourced lesson which guides students through drawing, writing and recognising the electronic configurations of atoms and ions. The lesson includes an engaging lesson presentation (33 slides), an associated worksheet and a competition worksheet. The lesson begins by introducing the students to the number of electrons that can be held on the first three electron shells. They are then shown how to draw an electronic configuration and write this in brackets form. Students are given the opportunity to apply this knowledge by drawing the configuration of first 20 elements of the Periodic Table. Moving forwards, students are guided to enable them to discover how the electron configuration is linked to the position of an atom in the Periodic Table. The remainder of the lesson focuses on ions and how the configuration of these substances can be recognised. Some time is taken to explain how ions are formed from atoms and the lesson finishes with a competition which challenges students to identify atoms or ions from their configurations to form a word. There are regular progress checks throughout the lesson to allow the students to check on their understanding and a range of quiz competitions to maintain engagement. This lesson has been written for GCSE students but could be used with younger students, especially the initial part of the lesson on atoms and the link to the Periodic Table

A concise lesson presentation (21 slides) which uses a range of methods to allow students to discover how to draw dot and cross diagrams for covalent structures. The lesson begins by challenging the students to recall their knowledge of electronic structure to show the outer shell of two specified atoms. They will then see how it is possible for both of these atoms to get full outer shells by sharing as happens in this type of bonding. A few more examples are used to consolidate this understanding before quick competition is used to check the understanding so far. Moving forwards, a step by step guide shows students how to draw dot and cross diagrams using the same techniques as was utilised with the hulas. This lesson has been written for GCSE students but could be used with higher ability KS3 students.