Unit 23: The Continuation of Life

Unit 23: The Continuation of Life
Higher Human Biology Unit 23: The Continuation of Life Chapter 23: Removal of Materials from the Blood. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Mrs Smith Ch22 The delivery of nutrients to cells
Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. Describe the role of the liver in: Conservation of useful substances Detoxification of toxic materials Removal of bilirubin Production of urea 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

Removal of materials from the body
The circulatory system is vital for the removal of materials from the body. The main organs that help remove unwanted materials are: The lungs The liver The kidney 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Mrs Smith Ch23 The Removal of Materials from Blood
1. The Lungs Carbon Dioxide is a waste product of respiration CO2 is transported to the lungs, via the blood plasma, to be removed from the body in the form of bicarbonate ions (HCO-3). As blood flows through the pulmonary system these bicarbonate ions combine with hydrogen ions (H+) to form carbonic acid (H2CO3). An enzyme then breaks the carbonic acid down into water and CO2: H2CO3 CO2 H2O + enzyme Concentration of CO2 in blood plasma > Concentration CO2 in air So CO2 diffuses out of the blood into the lungs down a concentration gradient. Breathing, which exhales air rich in CO2, maintains this gradient. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Diffusion in the alveoli
22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Excretion of carbon dioxide
Excretion = the elimination of waste products of metabolism e.g. Removal of CO2 (waste product of respiration) at the lungs. Release of bile pigment in bile. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

2. Role of Liver The liver removes materials from the blood by: Conservation of useful substances. e.g. glucose, plasma proteins Detoxification of toxic materials which are potentially toxic. Removal of bilirubin and its excretion as bile. Production of urea. Liver maintains a stable internal environment, and provides cells with optimum conditions 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Liver: Conservation of useful substances
Glucose Level regulated excess stored as glycogen which can be converted to glucose as needed. Components of blood plasma Regulated Stable internal environment maintained living cells have optimum conditions for growth & development 3 types of Plasma proteins Maintains a stable pool some undergo deamination in the liver meanwhile new molecules are synthesised 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Detoxification of toxic materials
Certain substances which gain access to or are produced by the body as a result of metabolic reactions are potentially toxuc. They would do the body harm if left unaltered. These substances are detoxified by liver cells. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Detoxification occurs in one of 4 ways
Substances are detoxified by liver cells in one of 4 ways….. Chemical Alteration Chemical Breakdown Chemical attachment (conjugation). Uptake by macrophages 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

A. Chemical alteration Biologically active molecules (e.g. Drugs) are rendered inactive by being chemically altered in the liver. The products are then excreted in bile or released into the bloodstream and removed by the kidneys. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

B. Chemical breakdown Hydrogen peroxide, a highly toxic by-product of metabolism is broken down by the enzyme catalase into harmless substances. Liver cells are rich in catalase. 2H2O2 O2 2H2O + catalase TOXIC Harmless 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

B. Chemical breakdown Alcohol (ethanol) gets converted in the liver, by a series of enzyme –controlled steps to acetyl CoA, which acts as a respiratory substrate for aerobic respiration. Too much alcohol damages cells. Regular consumption of alcohol to excess can cause permanent liver damage leading to a fatal liver condition called cirrhosis. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

C. Chemical attachement
Some unwanted substances (e.g. Certain types of food preservative) become attached to liver cells to the amino acid glycerine. This acts as a molecular label which is recognised as waste by the kidneys and excreted. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

D. Uptake by macrophages
Foreign particles are removed by macrophages (phagocytic cells) which line the liver’s blood vessels. If for example an animal is injected intravenously with a suspension of carbon particles, samples of liver obtained only minutes later show numerous carbon-laden macrophage cells. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Liver: Detoxification of Materials: SUMMARY
Toxic substances, that have either been eaten or produced in metabolic reactions, must be destroyed to prevent them harming the body. Liver cells detoxify such substances. Detoxification by liver cells Uptake by macrophages Macrophages line the liver’s blood vessels removing foreign particles Chemical alteration Biologically active molecules altered in the liver. Chemical attachment (conjugation) Unwanted substance become attached by liver cells to the amino acid glycine. Products excreted in bile or released into blood and removed by kidneys This acts as a chemical label which is recognised as a waste by the kidneys and excreted Chemical breakdown (see next page)

Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. 3. Describe the role of the liver in: Conservation of useful substances Detoxification of toxic materials Removal of bilirubin Production of urea 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

3. Removal of bilirubin When red blood cells reach the end of their 120 day life span, they are destroyed by macrophage cells in the liver, bone marrow and spleen, Haemoglobin is broken down by theses cells into a yellow pigment called bilirubin. Biliruben is releases into the blood giving blood plasma its yellowish colour. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Excretion of bilirubin
Bilirubin molecules, removed from the blood plasma by the liver, are added to bile with the aid of enzymes and become bile pigment (Conjugated bilirubin). This has no useful role in digestion so is released in bile. In the gut, bilirubin is converted by bacteria to the brown pigment that gives faeces its brown colour. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

4. Jaundice Bilirubin accumulates in the bloodstream when:
Liver cells can’t absorb bilirubin (due to illness e.g. hepatitis). The bile duct becomes blocked preventing the release of bile to small intestine. Red blood cell destruction is excessively high. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

4. Jaundice Jaundice is caused by excessively high concentrations of bilirubin. Baby’s can be screened for Bilirubin using a light meter that is placed on the baby’s head. 22/04/2017

Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. Determining the quantity of urea in urine samples 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

Production of Urea: Deamination
Unlike carbohydrate and lipid, protein is not stored in the body. Excess amino acids are absorbed from the gut then undergo deamination in liver cells. De-amination needs oxygen It produces an organic acid It produces ammonia which goes to the ornithine cycle. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

5. Production of urea During this process, the amino acid is broken down to form ammonia and an organic acid. Organic acid (Kreb cycle intermediate or pyruvic acid) Used for energy release in respiation Breakdown of amino acids Ammonia + CO2 Passes into blood and leaves the liver by the hepatic vein. It is removed from the blood at the kidneys. Very toxic Urea + H2O Less toxic 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Fate of deaminated amino acids
Depending on which amino acid has been deaminated the organic acid may be pyruvic acid or one of Krebs Cycle intermediates. It can then enter the respiratory pathway or be used for energy release. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Ornithine cycle Since ammonia is formed during deamination of an amino acid is highly toxic, it is immediately passed to the ornithine cycle. This cycle is controlled by enzymes in the liver cells. Here Ornithine is constantly regenerated. During this cycle , ammonia reacts with carbon dioxide to form less toxic urea and water. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Urea production During the conversion of ammonia into urea, two molecules of ammonia and one molecule of carbon dioxide combine to form one molecule of urea and one of water. Assisting this process there is a cyclical conversion of ornithine into citrulline, arginine, and then back to ornithine again. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Where does the urea go? Urea is then passed into the bloodstream and then leaves the liver by the hepatic vein. It is removed from blood by the kidneys. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Determining the quantity of urea in ‘urine’ samples
The combination of urea with water is catalysed by the enzyme urease: urease + Urea H2O ammonium carbonate (an alkali) The quantity of urea in the original solution is directly related to the quantity of alkali produced. This can be determined by the volume of acid needed to neutralise the alkali. Methyl orange, an indicator, is used to show the change from alkali (orange) to acid (red). 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Using solutions of known concentration to plot a calibration graph
Using urea solutions of known concentration a calibration graph can be drawn. Four solutions of know urea concentration are made up. Following enzyme activity at 37oC, each solution is titrated against hydrochloric acid. The volume of hydrochloric acid needed to neutralise the alkali in each solution is indicated by methyl orange changing colour. This is repeated for each conc many times and results are pooled and averaged. The results are then plotted to make a calibration graph. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Urea Concentration Calibration Curve

Using a calibration graph to calculate the urea content of unknown samples
The following experiment is carried out on a sample of urine (urea concentration unknown) and compared to the calibration curve. Many repeats done to increase reliability of results. to increase surface area to aid mixing of enzyme & substrate + 2 crushed urease tablets Flasks shaken at 15min intervals After 90 mins, 20 drops of methyl orange added + 0.1M HCl until indictor turns red In water bath at 37oC for 90 mins Optimum temperature for enzyme activity 50 cm3 urea solution (urea + water) 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Task: Torrance-TYK pg178 Qu 1-3
22/04/2017 Mrs Smith Ch20: Transport Mechanisms - The Cardiac Cycle

Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. Label a diagram of a kidney nephron Explain the mechanism of kidney function to include Ultrafiltration 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

6. Structure of the Kidney 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

6.The Kidneys: Structure
Each kidney has about a million tiny filtering units called nephrons. 22/04/2017

Each nephron is composed of several part
glomerulus nephron Bowman's capsule blood capillaries collecting duct The capillaries in the glomerulus are narrower than the capillary that supplied it with blood. What effect will this have on the blood pressure in the glomerulus?

Nephrons Each nephron is composed of several parts. A glomerulus is enclosed in a cup-shaped Bowman’s capsule which leads into a long kidney tubule surrounded by a dense network of blood capillaries. Two regions of the tubule possess several twists and turns and are therefore described as convoluted. The proximal convoluted tubule is the twisted region at the greater distance from the Bowman’s capsule. The long, U-shaped stretch of tubule between the convoluted regions is called the loop of Henle. Each kidney tubule leads to a communal collecting duct. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Knot of tiny blood vessels
The Kidney Nephron Has many twists & turns Knot of tiny blood vessels The blood enters the nephron via the renal artery and leaves via the renal vein. At the glomerulus the blood is filtered and the filtrate gathers in the bowman’s capsule. The filtrate then passes along the tubule to the communal collecting duct. Bowman’s capsule Loop of Henle 22/04/2017

The Kidneys: Function: Production of Urine
The kidneys remove waste material from the blood and excrete them in urine. The production of urine involves the ultrafiltration of blood reabsorption of useful materials from the filtrate. Since urine contains urea, a nitrogenous waste, the kidneys are described as organs of nitrogenous excretion. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

7. Ultrafiltration Ultrafiltration happens at the Bowman’s capsule. Blood containing waste products enters the kidney by the renal artery which divides into about a million branches each supplying a glomerulus. Each glomerulus consists of a coiled knot of blood capillaries. This arrangement enables a large surface area of blood vessel to be in contact with the inner lining of the Bowman’s capsule. It is at this interface ultrafiltration takes place 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Ultrafiltration- Basement membrane filter.
The layer of cells which makes up the capillary wall of a glomerulus differs from a normal capillary because..... It has pores which are large enough to let ALL the substances within plasma pass through. The porous layer is attached to a highly permeable thin layer of non-living material called the basement membrane. The basement membrane has no pores but acts as a filter that... Allows small molecules such as glucose, water, salts & urea to pass through. Prevents large molecules of plasma protein from leaving the blood stream. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

into the cavity of Bowman’s capsule by the basement membrane
Protein molecules pass through the fenestrated endothelial layer of the capillaries, but are prevented from passing into the cavity of Bowman’s capsule by the basement membrane ions urea water protein glucose 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Blood Pressure Plasma proteins which remain in the blood plasma tend to draw water back from the filtrate in the capsule by osmosis. In addition filtrate already present in the capsule tends to resist the delivery of further filtrate into the capsule. Successful ultrafiltration of blood depends on the blood in the glomeruli being at high enough pressure to overcome both of these factors and force filtrate out of the plasma. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Ultrafiltration and Blood Pressure.
High blood pressure in the glomerulus is needed to force the filtrate out of the blood plasma. This is maintained because: The blood vessels leading to the glomerulus come from the renal artery, which is a branch from the aorta so carries blood at high pressure The blood vessels entering the glomerulus are wider than the blood vessels leaving it, causing a bottle-neck and the blood to be squeezed Did you know? An adult has ~ 4.5 l of blood, but the kidneys filter ~ 1500 l of blood/day! 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Ultrafiltration – Rate of production of filtrate and urine.
A human adult contains about 4.5 litres of blood. During its continuous circulation round the body, blood repeatedly enters the kidneys and undergoes filtration. Each day a human adult’s kidneys filter a total volume of around 1500 litres of blood and produce about 180 litres of glomerular filtrate. However the production of urine is only about 1-2 litres. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. Explain the mechanism of kidney function to include Re-absorption 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

8. Reabsorption About 180 l of glomerular filtrate is produced every day but only 1-2 l of urine is produced, because ~ 99% of the water in the filtrate is reabsorbed into the bloodstream. Apart from the plasma proteins and water, the chemicals in blood plasma and glomerular filtrate are very similar. Reabsorption occurs at various points along the tubule that come into contact with the blood capillaries. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

A. Reabsorption of Salts:
Proximal convoluted tubule Glucose & amino acids absorbed by epithelial cells lining the tubule. 90% Sodium ions (Na+) from glomerular filtrate actively pumped across epithelial cells, as they are combined with Chloride (Cl-) ions in the form of salt, they to pass into the blood 22/04/2017

Active transport Facilitated diffusion Diffusion Sodium ions in the lumen of the proximal convoluted tubule 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Proximal convoluted tubule
A. Reabsorption of Water: Proximal convoluted tubule Water The active transport of glucose, sodium ions (and other solutes such as amino acids) into the blood stream reduces the blood plasma's concentration relative to that of the glomerular filtrate. Water therefore passes into blood by osmosis. This movement of water is a form of passive transport and does not require energy. About 85% of water is reabsorbed from the proximal convoluted tubule. 22/04/2017

of the filtered fluid is reabsorbed back into the blood
The transport of glucose, amino acids and ions into the epithelial cells creates a gradient of water potential across the lining of the tubule; water is therefore withdrawn from the tubule by osmosis, such that approximately 85% of the filtered fluid is reabsorbed back into the blood 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Reabsorption of Glucose : Proximal convoluted tubule
Image source: people.eku.edu Epithelial cells are structurally suited to their function: Many microvilli for large surface area Many mitochondria to provide energy for active transport (of glucose) Carrier molecules carry glucose across cell membranes 22/04/2017

interstitial fluid lumen epithelial cells microvilli intercellular spaces many mitochondria 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Diabetes Untreated sufferers of diabetes mellitus have so much glucose in their blood plasma that some of the glucose in the glomerular filtrate is not reabsorbed by the epithelial cells of the proximal convoluted tubules. This is excreted in urine. 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

B. Reabsorption: Loop of Henle
Each U-shaped loop of Henle lies in the medulla Consists of a descending limb and an ascending limb At the descending limb Water is reabsorbed back into the bloodstream by Osmosis Salts are not reabsorbed here At the ascending limb water is not reabsorbed as the thick wall of the tubule is impermeable to water Salts are pumped out of the filtrate into the tissue fluid This creates a low water concentration by high solute concentration

C. Reabsorption: Distal convoluted tubule
Sodium chloride (salt) is reabsorbed from the distal convoluted tubule by being actively pumped into the bloodstream, but in smaller quantities. Water also passes from the distal convoluted tubule into the bloodstream 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

D. Reabsorption: Collecting Duct
Because the medullary tissue fluid has a low water concentration (due to the action at the ascending limb of the loop of Henle) the kidney tissues can reabsorb lots of water by osmosis from the collecting ducts. The volume of water needed to return the bloods water concentration to normal is reabsorbed from the filtrate. The rest is passed out in the urine. 22/04/2017

D. Reabsorption from Collecting Duct is controlled by the hormone ADH
Image source: No ADH Present - Collecting Duct is NOT permeable to water and large volume of urine is produced ADH Present - Collecting Duct is permeable to water and a small volume of urine is produced Mrs Smith Ch23 The Removal of Materials from Blood 22/04/2017

Reabsorption – Summary
Proximal convoluted tubule Glucose Active Transport Salt (Sodium+Chloride ions) Active Transport Water Osmosis Descending Loop of Henle Ascending Loop of Henle Salts (Sodium+Chloride ions) Active Transport Distal Convoluted Tubule Salts (Sodium+Chloride ions) Active Transport 22/04/2017

Learning Intentions Success Criteria To understand how the liver, lungs and kidneys are involved in the removal of materials from the blood. Analyse data on glomerular filtrate, tubule fluid and urine composition and rates of production 22/04/2017 Mrs Smith Ch22 The delivery of nutrients to cells

Role of ADH Water content of blood too low
Water content of blood too high Salt eaten or much sweating Too much water drunk Water content of blood normal Brain releases little ADH Brain releases much ADH High volume of water passes into blood Low volume of water passes into blood High volume of water reabsorbed by kidney Low volume of water reabsorbed by kidney Small volume of concentrated urine passed to the bladder High volume of dilute urine passed to the bladder 22/04/2017

ADH and Osmoregulation
The volume of water reabsorbed varies greatly. This is regulated by the concentration of anti-diuretic hormone (ADH) present in the bloodstream. ADH increases the permeability to water of the distal convoluted tubules & collecting ducts. Regulation of Blood Water Concentration 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood Image source:

ADH and Osmoregulation High Water Concentration
When the water concentration of the blood is high, very little ADH is released into the blood stream from the pituitary gland. The distal convoluted tubules and collecting ducts remain practically impermeable to water and almost none is reabsorbed from these regions of tubule. A large volume of dilute urine is therefore. produced 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

ADH and Osmoregulation Low Water Concentration
When the water concentration of the blood is low, the situation is reversed and a small volume of concentrated urine is produced. This mechanism allows the kidneys to plat an osmoregulatory role in the maintenance of the body’s internal steady state. (more in chapter 24) 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Task: Torrance-TYK pg183 Qu 1-3
22/04/2017 Mrs Smith Ch20: Transport Mechanisms - The Cardiac Cycle

Task: Torrance AYK pg184/185 Qu’s 1-6
22/04/2017 Mrs Smith Ch19 The need for transport

Mrs Smith Ch19 The need for transport
Essay Questions: SQA 2005 2005 Describe the function of the liver under the following headings Production of urea. (2) Metabolism of carbohydrates. (5) Breakdown of red blood cells. (3) 22/04/2017 Mrs Smith Ch19 The need for transport

Guide to ‘H’ Grade Essays Essay 35 pg83
Discuss the role of the liver under the following headings Metabolism of protein.(5) Detoxification (5) Conservation of useful substances (5) 22/04/2017 Mrs Smith Ch19 The need for transport

Guide to ‘H’ Grade Essays Essay 35 pg83
Give an account of the role of the kidneys with reference to the following: Ultrafiltration (8) Reabsorption (7) 22/04/2017 Mrs Smith Ch19 The need for transport

TASK: Match the correct word with its meaning on each page! 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Word Meaning Kidney Renal artery Renal vein Ureter Bladder Urethra ADH Hormone Pituitary gland Carries unpurified blood to the kidney Carries purified blood away from the kidney Chemical messenger Carries urine from the kidney to the bladder Gland that releases ADH Stores urine Carries urine out of body Organ that filters the blood Hormone that regulates water balance 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Word Meaning Network of very thin blood vessels U-shaped kidney tubule that reabsorbs water into the bloodstream Tiny knot of blood capillaries in the Bowman’s capsule where filtration of the blood occurs Cup-shaped structure that collects glomerular filtrate from the blood Tiny filtering unit in the kidney Glomerulus Bowman’s capsule Blood capillaries Nephron Loop of Henle 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Word Meaning Waste liquid excreted by the body Tube that carries urine away from several kidney tubules Nitrogen containing waste product made in the liver from surplus amino acids Fluid produced from filtration of the blood in a glomerulus Artificial filtration of blood through a selectively permeable membrane to remove waste products Collecting duct Dialysis Glomerular filtrate Urine Urea 22/04/2017 Mrs Smith Ch23 The Removal of Materials from Blood

Unit 23: The Continuation of Life

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