This lesson describes how the structure of arteries, arterioles, capillaries, venules and veins in the mammalian circulatory system relate to their functions. The PowerPoint and accompanying resources are part of the second lesson in a series of 2 lessons which have been designed to cover specification point (b) of topic 3 in AS unit 2 of the WJEC A-level Biology A specification. The first lesson in this series covers the structure and function of the human heart and its associated blood vessels This lesson has been written to build on any prior knowledge from GCSE or earlier in this topic to enable students to fully understand why a particular type of blood vessel has particular features. Students will be able to make the connection between the narrow lumen and elastic tissue in the walls of arteries and the need to maintain the high pressure of the blood. A quick version of the GUESS WHO game is used to introduce smooth muscle and collagen in the tunica media and externa and again the reason for their presence is explored and explained. Moving forwards, it is quite likely that some students will not be aware of the transition vessels that are the arterioles. This section begins with an understanding of the need for these vessels because the structural and functional differences between arteries and capillaries is too significant. The action of the smooth muscle in the walls of these vessels is discussed and students will be challenged to describe a number of situations that would require blood to be redistributed. The middle part of the lesson looks at the role of the capillaries in exchange and links are made to diffusion to ensure that students can explain how the red blood cells pressing against the endothelium results in a short diffusion distance. The remainder of the lesson considers the structure of the veins and students are challenged to explain how the differences to those observed in arteries is due to the lower blood pressure found in these vessels.

This lesson describes the structure and function of the human heart and names the blood vessels associated with this organ . The PowerPoint and accompanying resources are part of the first lesson in a series of 2 lessons that have been designed to cover point (b) in topic 3 of AS unit 2 of the WJEC A-level Biology specification As this topic was covered at GCSE, the lesson has been planned to build on this prior knowledge whilst adding the key details which will enable students to provide A-level standard answers. The primary focus is the identification of the different structures of the heart but it also challenges their ability to recognise the important relationship to function. For example, time is taken to ensure that students can explain why the atrial walls are thinner than the ventricular walls and why the right ventricle has a thinner wall than the left ventricle. Opportunities are taken throughout the lesson to link this topic to the others found in topic 3 including those which have already been covered like circulatory systems as well as those which are upcoming such as the initiation of heart action. There is also an application question where students have to explain why a hole in the ventricular septum would need to be repaired if it doesn’t naturally close over time.

This lesson describes the Krebs cycle as a stage of aerobic respiration that liberates energy to produce ATP and reduced NAD and releases carbon dioxide. The PowerPoint and accompanying resource have been designed to cover specification point [c] in topic 3 of A2 unit 3 of the WJEC A-level Biology specification. The lesson begins with a version of the Impossible game where students have to spot the connection between 8 of the 9 terms and will ultimately learn that this next stage is called the Krebs cycle. The main part of the lesson challenges the students to use descriptions of the main steps of the cycle to continue their diagram of the reactions. Students are continually exposed to key terminology such as decarboxylation and dehydrogenation and they will learn where carbon dioxide is lost and reduced NAD and FAD are generated. They will also recognise that ATP is synthesised by substrate level phosphorylation. The final task challenges them to apply their knowledge of the cycle to work out the numbers of the different products and to calculate the number of ATP that must be produced in the next stage This lesson has been designed to tie in with the other uploaded lessons on glycolysis and the electron transport chain (in oxidative phosphorylation).

This lesson describes the concept of homeostasis using negative feedback control and also describes the role of positive feedback. The PowerPoint and accompanying resources have been designed to cover specification points (a & b) in topic 7 of A2 unit 3 of the WJEC A-level Biology specification and explains how this feedback control maintains systems within narrow limits but has also been planned to provide important details for upcoming topics such as osmoregulation. The normal ranges for blood glucose concentration, blood pH and body temperature are introduced at the start of the lesson to allow students to recognise that these aspects have to be maintained within narrow limits. A series of exam-style questions then challenge their recall of knowledge from AS units 1 & 2 and the earlier topics in A2 unit 3 as they have to explain why it’s important that each of these aspects is maintained within these limits. The students were introduced to homeostasis at GCSE, so this process is revisited and discussed, to ensure that students are able to recall that this is the maintenance of a state of dynamic equilibrium. A quick quiz competition is used to reveal negative feedback as a key term and students will learn how this form of control reverses the original change and biological examples are used to emphasise the importance of this system for restoring levels to the limits (and the optimum). The remainder of the lesson explains how positive feedback differs from negative feedback as it increases the original change and the role of oxytocin in birth and the movement of sodium ions into a neurone are used to exemplify the action of this control system.

This lesson describes how the cells of the proximal tubule in the nephron of the kidney are adapted for reabsorption. The PowerPoint and accompanying resource which is filled with tasks have been designed to cover specification point [e] in topic 7 of A2 unit 3 of the WJEC A-level Biology specification and builds on the knowledge gained in the previous lessons on the structure of the nephron and the functions of the mammalian kidney. The lesson begins by challenging the students to recall the substances that are found in the glomerular filtrate so that each of them can be considered over the course of the rest of the lesson. Moving forwards, the first of the numerous discussion points which are included in the lesson is used to get students to predict the component of the filtrate which won’t be found in the urine when they are presented with pie charts from each of these situations. Upon learning that glucose is 100% reabsorbed, along with most of the ions and some of the water, the rest of the lesson focuses on describing the relationship between the structure of the proximal tubule and the function of selective reabsorption. Again, this section begins by encouraging the students to discuss and to predict which structures they would expect to find in a section of the kidney if the function is to reabsorb. They are given the chance to see the structure (as shown in the cover image) before each feature is broken down to explain its importance. Time is taken to look at the role of the cotransporter proteins to explain how this allows glucose, along with sodium ions, to be reabsorbed from the lumen of the PCT into the epithelial cells. The final part of the lesson focuses on urea and how the concentration of this substance increases along the tubule as a result of the reabsorption of some of the water.

A highly detailed set of 2 lessons (35 slides) on the topic of rearranging the formula. Over the course of the two lessons, they build up gradually with a culmination of some of the more difficult questions on this topic met at GCSE. Students are reminded of the meaning of the "subject of the formula" and then introduced to inverse operations. Students are guided through the simple questions involving one move to rearrange before looking at two moves and then questions which involve indices and square roots. The second lesson looks at the hardest questions, involving additional Mathematical skills such as factorising. Progress checks are constant throughout the two lessons so that any misconceptions can be quickly addressed. These lessons were designed for students studying GCSE but can be used with KS3 students appropriately too

A detailed lesson presentation (37 slides) that looks at the different motions that are represented on a velocity-time graph and guides students through using these graphs to calculate the distance travelled by an object. The lesson begins by challenging the students to construct a velocity-time graph by using a displayed guide and using their knowledge of drawing a distance-time graph. Moving forwards, the students will match terms of motion to the lines on the graph and time is taken to make links to the physics equations that allow acceleration and deceleration to be calculated. Students will also learn that they can use a velocity-time graph to calculate the distance travelled. A worked example is used to show them how to tackle these questions. There are regular progress checks throughout the lesson so that students can assess their understanding of this topic. This lesson has been designed for GCSE students but could be used with higher ability KS3 students

An informative lesson presentation (30 slides) that ensures that students know the meaning of the independent, dependent and control variables in an investigation and are able to identify them. Students are challenged to use their definitions to spot the independent and dependent variable from an investigation title. Moving forwards, they are shown how they can use tables and graphs to identify them. The rest of the lesson focuses on the control variables and how these have to be controlled to produce valid results This lesson is suitable for students of all ages studying Science as it is such a key skill

A highly engaging and information lesson presentation (46 slides) which guides students through the steps needed to construct an accurate distance-time graph and then teaches them how to interpret the motions that are shown by the different lines. The lesson challenges the students to work out the type of graph that should be used to present the data and to suggest which factor from the blank table should go on the x-axis. Using the results that they obtain, a step-by-step guide is used to walk students through constructing the graph. This includes deciding on scales to ensure they are even and make the most of the available paper. Student will see the four key terms of motion associated with these graphs (acceleration, deceleration, constant speed and stationary) and will be able to use their graph to work out which lines go with which motion. Moving forwards, students will be shown how to calculate speed from the graph. There are progress checks throughout the lesson so that students can assess their understanding of the topic. This lesson has been designed for GCSE students but is perfectly suitable for KS3 students too.

This clear and concise lesson explains how the inheritance of two or more genes that have loci on the same autosome demonstrates autosomal linkage. The engaging PowerPoint and associated resource have been designed to cover the part of point 6.1.2 (b[ii]) of the OCR A-level Biology A specification which states that students should be able to demonstrate and apply their knowledge and understanding of the use of phenotypic ratios to identify autosomal linkage. This is a topic which can cause confusion for students so time was taken in the design to split the concept into small chunks. There is a clear focus on how the number of original phenotypes and recombinants can be used to determine linkage and suggest how the loci of the two genes compare. Important links to other topics such as crossing over in meiosis are made to enable students to understand how the random formation of the chiasma determines whether new phenotypes will be seen in the offspring or not. Linkage is an important cause of variation and the difference between observed and expected results and this is emphasised on a number of occasions. The main task of the lesson acts as an understanding check where students are challenged to analyse a set of results involving the inheritance of the ABO blood group gene and the nail-patella syndrome gene to determine whether they have loci on the same chromosome and if so, how close their loci would appear to be. This lesson has been written to tie in with the other lessons from module 6.1.2 (Patterns of Inheritance)

An engaging and informative lesson which uses a murder mystery style concept to challenge the students to use a range of identification tests to detect the cations and identify the killer. Students will enjoy the range of practical experiments which feed into the plot and allow them to find out who the owner of the belt buckle and earring back that were found at the crime scene. This lesson has been designed for GCSE students (14 - 16 year olds in the UK) but could be used as part of a forensic science project or alike

This is a detailed and engaging lesson presentation which focuses on the properties of the elements found in group 1 of the Periodic Table, the alkali metals. Students are challenged throughout the lesson to be able to link their observations of the reactions to the properties. Once they have learnt that the reactivity increases as they move down the group, time is taken to go over this in detail so that students can explain why sodium is more reactive than lithium (and so on) in terms of electron configuration. Progress checks are embedded throughout the lesson so that students have the opportunity to assess their understanding. This lesson has been designed for GCSE students (14 - 16 year olds in the UK) but is suitable for younger students who may be carrying out a project on the Periodic Table

A concise and engaging lesson, which looks at chemical and physical changes with the key objective that students can recognise the differences between the two. Key terminology is used throughout, such as irreversible and practical examples are discussed. A number of short sharp quiz competitions are used to maintain motivation as well as checking on the understanding. This lesson is suitable for KS3 and GCSE students (11 - 16 year olds in the UK)

A fully resourced lesson, which includes differentiated worksheets, and guides the students through the process of extracting aluminium. There are close links throughout the lesson to the reactivity series and electrolysis so that the students are able to understand how the knowledge of all of these is brought together. Students will meet cryolite and recognise why this is used in the process and will finish off by writing half equations to show the products at the electrodes. This lesson has been designed for GCSE students (14 - 16 year olds in the UK)

A whole lesson on the topic of active transport which includes a concise lesson presentation (20 slides) and a set of questions that are used to check on the students’ understanding. This lesson is designed for GCSE students (14 - 16 year olds in the UK) but could be used with A-level students who are covering the topic of movement across cell membranes. The main focus of the lesson is to get students to understand that this is an active process which moves substances against the concentration gradient and therefore needs energy for this process. The final part of the lesson looks at the different types of questions that can accompany this topic and a step-by-step guide is used to answer a difficult longer answer question as a class.

A fully resourced lesson which guides students through writing decay equations to represent alpha and beta decay. This lesson includes a lesson presentation (41 slides) and differentiated worksheets. Time is taken at the beginning of the lesson to ensure that students know the sub-atomic particles that are found in an alpha particle and a beta particle so that they can understand why the atomic and mass numbers are affected during the decay. Moving forwards, a step-by-step guide is used to show students how to write both types of equations. There are regular progress checks throughout the lesson so that students can check their understanding. This lesson has been written for GCSE students (14 - 16 year olds in the UK)

A fully-resourced lesson that looks at the topic of osmosis and how the movement of water between a cell and the solution can affect the appearance of an animal and a plant cell. This lesson includes a detailed and engaging lesson presentation (42 slides) and differentiated worksheets that include exam questions that can be set as homework. There is a lot of key terminology associated with this topic and time is taken to ensure that students understand the meaning of each of these terms before moving forwards. Students are introduced to the different types of solutions and then a step-by-step guide is used to show them how to compare the water potential of the solution and the cell and then how this will determine which was water moves. The main task is differentiated so that students are challenged and can access the work. This lesson has been designed for GCSE students (14 - 16 year olds in the UK) but is also suitable for A-level students

A detailed lesson presentation which guides students through calculating the current, potential difference and resistance in series and parallel circuits. The lesson begins by challenging the students to recognise whether three displayed facts relate to series or parallel circuits. Students are then given a chance to remind themselves of the differences between the circuits in terms of these three physical factors. The rest of the lesson uses a step-by-step guide format to show the students how to work through a circuit calculation by combining their knowledge of the circuit with application of the V = IR equation. Progress checks have been written throughout the lesson so that students can constantly assess their understanding. This lesson has been designed for GCSE students