Edexcel International A Level Biology Respiration PDF

Summary

These notes cover the topic of respiration in biology, including the different stages of aerobic respiration (glycolysis, link reaction, Krebs cycle, electron transport chain), anaerobic respiration, and other related concepts and practical investigations for A Level biology. The Edexcel International A Level notes are suitable for undergraduate students.

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Edexcel International A Level Your notes
Biology
Respiration
Contents
7.1 Overview of Respiration
7.2 Glycolysis
7.3 Link Reaction & Krebs Cycle
7.4 The Electron Transport Chain
7.5 Anaerobic Respiration
7.6 Respiratory Quotient
7.7 Core Practical 15: Investigation of Respiration in Yeast
7.8 Core Practical 16: Respirometer to Calculate RQ

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7.1 Overview of Respiration
Your notes
Overview of Respiration
Glucose is the main respiratory substrate used by cells
Aerobic respiration is the process of breaking down a respiratory substrate in order to produce ATP
using oxygen
The equation for aerobic respiration:
glucose + oxygen → carbon dioxide + water + energy
C6H1206 + 6 O2 → 6 CO2 + 6 H20 + 2870kJ
The energy that is released during the process is used to phosphorylate (add a phosphate) ADP to form
ATP
ATP provides energy for other biological processes in cells
The process of aerobic respiration using glucose can be split into four stages which each occurs at a
particular location in a eukaryotic cell:
Glycolysis takes place in the cell cytoplasm
The Link reaction takes place in the matrix of the mitochondria
The Krebs cycle takes place in the matrix of the mitochondria
Oxidative phosphorylation occurs at the inner membrane of the mitochondria
These chemical reactions are controlled by intracellular enzymes that catalyses reactions within the
cell
Ensuring that the energy trapped within the chemical bonds of the glucose molecule is released
gradually and not all at once
A sudden release of such a large amount of energy would result in an increase in body temperature to
levels that would denature enzymes
The enzyme that catalyses these reactions the slowest will determine the overall rate of aerobic
respiration
Several coenzymes are required during respiration to transfer various molecules involved in the
process
NAD and FAD are the coenzymes responsible for transferring hydrogen between molecules
Depending on whether they give or take hydrogen, they are able to reduce or oxidise a molecule
Coenzyme A is responsible for the transfer of acetate (also known as acetic acid) from one
molecule to another
Although glucose is the main fuel for respiration, organisms can also break down other molecules (such
as fatty acids or amino acids) to be respired
Four Stages of Respiration Table

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Your notes

Structure of mitochondria
Mitochondria have two phospholipid membranes
The outer membrane is:
Smooth
Permeable to several small molecules
The inner membrane is:
Folded (cristae)
Less permeable
The site of the electron transport chain (used in oxidative phosphorylation)
Location of ATP synthase enzymes (used in oxidative phosphorylation)
The intermembrane space:
Has a low pH due to the high concentration of protons
The concentration gradient across the inner membrane is formed during oxidative
phosphorylation and is essential for ATP synthesis
The matrix:
Is an aqueous solution within the inner membranes of the mitochondrion
Contains ribosomes, enzymes and circular mitochondrial DNA necessary for mitochondria to
function

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Your notes

The structure of a mitochondrion

Exam Tip
It’s important to know the exact locations of each stage. It is not enough to say the Krebs cycle takes
place in the mitochondria, you need to say it takes place in the matrix of the mitochondria.

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7.2 Glycolysis
Your notes
Glycolysis
Glycolysis is the first stage of respiration
It does not require oxygen to take place and is therefore the first step for both aerobic and anaerobic
respiration
Glucose is only partially oxidised during glycolysis
It takes place in the cytoplasm of the cell and involves:
Trapping glucose in the cell by phosphorylating the molecule
Oxidising triose phosphate (by losing hydrogen)
It results in the production of
2 Pyruvate (3C) molecules which moves into the matrix of mitochondria to be used during the link
reaction
Net gain 2 ATP
2 reduced NAD, which will be used during a later stage called oxidative phosphorylation
Under anaerobic conditions, glycolysis produces lactic acid or lactate instead of pyruvate
Steps of glycolysis
Phosphorylation of glucose (a hexose sugar)
Two molecules of ATP are required to provide the two phosphates needed for the
phosphorylation of glucose
This produces
Two molecules of triose phosphate
Two molecules of ADP
Oxidation of triose phosphate
After triose phosphate loses hydrogen, it forms two molecules of pyruvate
The hydrogen ions are collected by NAD which reduces the coenzyme
This forms two reduced NAD or NADH
Even though a total of four ATP molecules were produced during glycolysis, two of them were
used to phosphorylate glucose
There was therefore a net gain of two ATP molecules

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Your notes

The process of glycolysis

Exam Tip
It may seem strange that ATP is used and also produced during glycolysis. At the start ATP is used
to make glucose more reactive (it is usually very stable) and to lower the activation energy of the
reaction. Since 2 ATP are used and 4 are produced during the process, there is a net gain of 2 ATP per
glucose molecule.

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7.3 Link Reaction & Krebs Cycle
Your notes
Link Reaction & Krebs Cycle
The Link reaction
The end product of glycolysis is pyruvate
Pyruvate contains a substantial amount of chemical energy that can be further utilised in respiration to
produce more ATP
The enzymes and coenzymes that are required for the link reaction are found in the mitochondrial
matrix
When oxygen is available pyruvate will enter the mitochondrial matrix and aerobic respiration will
continue
Pyruvate moves across the double membrane of the mitochondria via active transport
It requires a transport protein and a small amount of ATP
Once in the mitochondrial matrix pyruvate takes part in the link reaction

Pyruvate enters the mitochondrial matrix from the cytosol (cytoplasm) by active transport
The link reaction takes place in the matrix of the mitochondria
It is referred to as the link reaction because it links glycolysis to the Krebs cycle
The steps are:
Pyruvate is oxidised (hydrogen is removed) by enzymes to produce acetate, CH3CO(O) (also
known as acetic acid)
Pyruvate is also decarboxylated (carbon is removed) in the form of carbon dioxide
Reduction of NAD to NADH or reduce NAD by collecting hydrogen from pyruvate
Acetate combines with coenzyme A to form acetyl coenzyme A (acetyl CoA)
No ATP is produced during the link reaction
It produces:
Acetyl coA

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Carbon dioxide (CO2)
Reduced NAD (NADH)
pyruvate + NAD + CoA → acetyl CoA + carbon dioxide + reduced NAD Your notes

The link reaction occurs in the mitochondrial matrix. It dehydrogenates and decarboxylates the three-
carbon pyruvate to produce the two-carbon acetyl CoA that can enter the Krebs Cycle
Every molecule of glucose produces two pyruvate molecules
The link reaction and the Krebs cycle will therefore occur twice for every molecule of glucose
Thus, each molecule of glucose will produce:
Two molecules of acetyl CoA
Two molecules of CO2
Two molecules of reduced NAD
The Krebs Cycle
The Krebs cycle (sometimes called the citric acid cycle) consists of a series of enzyme-controlled
reactions
2 carbon (2C) Acetyl CoA enters the circular pathway from the link reaction in glucose metabolism
Acetyl CoA formed from fatty acids (after the breakdown of lipids) and amino acids enters directly
into the Krebs Cycle from other metabolic pathways
4 carbon (4C) oxaloacetate accepts the 2C acetyl fragment from acetyl CoA to form the 6 carbon
(6C) citrate
Coenzyme A is released in this reaction to be reused in the next link reaction
Citrate is then converted back to oxaloacetate through a series of oxidation-reduction (redox)
reactions

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Your notes

The Krebs Cycle uses acetyl CoA from the link reaction and the regeneration of oxaloacetate to
produce reduced NAD, reduced FAD and ATP
Regeneration of oxaloacetate
Oxaloacetate is regenerated in the Krebs cycle through a series of redox reactions
Decarboxylation of citrate
Releasing 2 CO2 as waste gas
Oxidation (dehydrogenation) of citrate
Releasing H atoms that reduce coenzymes NAD and FAD
These will be used during oxidative phosphorylation
3 NAD and 1 FAD → 3NADH + H+ and 1 FADH2
Substrate linked phosphorylation
A phosphate is transferred from one of the intermediates to ADP, forming 1 ATP to supply energy
Because two acetyl-CoA molecules are produced from each glucose molecule, two cycles are
required per glucose molecule
Therefore, at the end of two cycles, the products are:

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Two ATP
Six NADH (reduced NAD)
Two FADH2 (reduced FAD) Your notes
Four CO2

Exam Tip
The Krebs cycle is often referred to as cyclical or circular. This is because the acceptor molecule
oxaloacetate is regenerated throughout the reaction so that it can start all over again by adding
another acetyl CoA.
You may be asked to name the important molecules in the Krebs cycle like oxaloacetate and citrate.
It is also worth noting how the number of carbon atoms in the substrate molecule changes as the cycle
progresses.

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7.4 The Electron Transport Chain
Your notes
The Electron Transport Chain
Oxidative phosphorylation is the last stage of aerobic respiration
It takes place at the inner mitochondrial membrane
It results in the production of many molecules of ATP and the production of water from oxygen
The current model for oxidative phosphorylation is the chemiosmotic theory
The model states that energy from electrons is passed through a chain of proteins in the
membrane, known as the electron transport chain
This energy is used to pump protons (hydrogen ions) against their concentration gradient into
the intermembrane space
The protons are then allowed to flow by facilitated diffusion through a channel enzyme called ATP
synthase into the matrix
The energy of the protons flowing down their concentration gradient is harnessed (a bit like water
flowing through a hydroelectric damn) resulting in the phosphorylation of ADP into ATP by ATP
synthase
Outline of oxidative phosphorylation
Hydrogen atoms are donated by reduced NAD (NADH) and reduced FAD (FADH2) from the Krebs Cycle
Hydrogen atoms split into protons (H+ ions) and electrons
The high energy electrons enter the electron transport chain and release energy as they move through
the electron transport chain
The energy released is used to transport protons across the inner mitochondrial membrane from
the matrix into the intermembrane space
A concentration gradient of protons is established between the intermembrane space and the matrix
The protons return to the matrix via facilitated diffusion through the channel enzyme ATP synthase
The movement of protons down their concentration gradient provides energy for ATP synthesis
Oxygen acts as the 'final electron acceptor' and combines with protons and electrons at the end of
the electron transport chain to form water
The electron transport chain
The electron transport chain is made up of a series of membrane proteins/ electron carriers
They are positioned close together which allows the electrons to pass from carrier to carrier
The inner membrane of the mitochondria is impermeable to hydrogen ions so these electron carriers
are required to pump the protons across the membrane to establish the concentration gradient

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Your notes

Oxidative phosphorylation via the chemiosmotic theory occurs on the inner mitochondrial membrane
and requires NADH and FADH2 from the Krebs Cycle. It produces water and many molecules of ATP
Oxidative phosphorylation uses energy from reduced NAD and FAD to produce ATP
3 ATP molecules for every reduced NAD molecule
2 ATP molecules for every reduced FAD molecule
For every molecule of glucose a total of 38 ATP molecules can be produced during aerobic respiration
Number of ATP Molecules Produced During Aerobic Respiration per Glucose Molecule Table

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Your notes

Exam Tip
Examiners often ask why oxygen is so important for aerobic respiration. Oxygen acts as the final
electron acceptor. Without oxygen the electron transport chain cannot continue as the electrons
have nowhere to go. Without oxygen accepting the electrons (and hydrogen ions) the reduced
coenzymes NADH and FADH2 cannot be oxidised to regenerate NAD and FAD, so they can’t be used in
further hydrogen transport.
It is important to use the correct terminology when describing hydrogen; ensure you understand when
to use "hydrogen" and when to use "hydrogen ions/protons".

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7.5 Anaerobic Respiration
Your notes
Anaerobic Respiration
Sometimes cells experience conditions with little or no oxygen
There are several consequences when there is not enough oxygen available for respiration:
There is no final acceptor (oxygen) of electrons from the electron transport chain
The electron transport chain stops functioning
No more ATP is produced via oxidative phosphorylation
Reduced NAD and FAD aren’t oxidised by an electron carrier
No oxidised NAD and FAD are available for dehydrogenation in the Krebs cycle
The Krebs cycle stops
The link reaction also stops
However, there is still a way for cells to produce some ATP in low oxygen conditions through anaerobic
respiration
Anaerobic pathways
Some cells are able to oxidise the reduced NAD produced during glycolysis so it can be used for
further hydrogen transport
This means that glycolysis can continue and small amounts of ATP are still produced
Different cells use different pathways to achieve this
Yeast and microorganisms use ethanol fermentation
Other microorganisms and mammalian muscle cells use lactate fermentation
Lactate fermentation
In this pathway reduced NAD transfers hydrogen to pyruvate to form lactate
NAD can now be reused in glycolysis
Pyruvate is reduced to lactate by enzyme lactate dehydrogenase
Pyruvate is the hydrogen acceptor
The final product lactate can be further metabolised
A small amount of ATP is produced

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Your notes

The pathway of lactate fermentation
Processing Lactate
Lactate (lactic acid) can build up in the cells after a period of time
After lactate is produced two things can happen:
It can be oxidised back to pyruvate which is then channelled into the Krebs cycle for ATP
production
It can be converted into glucose by the liver cells for use during respiration or for storage (in the
form of glycogen)
The oxidation of lactate back to pyruvate needs extra oxygen
This extra oxygen is referred to as an oxygen debt
It explains why animals breathe deeper and faster after exercise
Ethanol fermentation
In this pathway reduced NAD transfers its hydrogens to ethanal to form ethanol
In the first step of the pathway pyruvate is decarboxylated to ethanal
Producing CO2
Then ethanal is reduced to ethanol by the enzyme alcohol dehydrogenase
Ethanal is the hydrogen acceptor
Ethanol cannot be further metabolised; it is a waste product
Ethanol fermentation occurs in yeast and plant cells

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Your notes

The pathway of ethanol fermentation

Exam Tip
Note that ethanol fermentation is a two-step process (lactate fermentation is a one-step process).
Carbon dioxide is also produced alongside the waste ethanol. This waste ethanol is what makes yeast
vital in producing alcoholic drinks like beer!

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7.6 Respiratory Quotient
Your notes
Respiratory Quotient
The respiratory quotient (RQ) is the ratio of carbon dioxide molecules produced to oxygen molecules
taken in during respiration
RQ = CO2 ÷ O2

The formula for the Respiratory Quotient
RQ values of different respiratory substrates
Carbohydrates, lipids and proteins have different typical RQ values
This is because of the number of carbon-hydrogen bonds differs in each type of biological molecule
More carbon-hydrogen bonds means that more hydrogen atoms can be used to create a proton
gradient
More hydrogens means that more ATP molecules can be produced
More oxygen is therefore required to breakdown the molecule (in the last step of oxidative
phosphorylation to form water)
When glucose is aerobically respired equal amounts of carbon dioxide are produced to oxygen taken
in, meaning it has an RQ value of 1

During the breakdown of glucose, six molecules of oxygen is used and six molecules of carbon dioxide
is produced. This results in an RQ value of 1 (6CO2 ÷ 6O2)
RQ Values For Different Respiratory Substrates Table

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Your notes

Some questions may ask you to suggest what substrate is being respired during an experiment based
on the RQ value – so make yourself familiar with the values in the table
Calculating RQ values
The respiratory quotient is calculated from respiration equations
It involves comparing the ratios of carbon dioxide given out to oxygen taken in
The formula for this is:

Equation to calculate the RQ value of a respiratory substrate
For aerobic respiration the RQ will typically be less than 1 since oxygen is being used to break down the
substrate
Should the RQ of an organism be greater than 1, it may indicate that anaerobic respiration is occurring,
since very little to no oxygen is used
If you know the molecular formula of the substrate being aerobically respired then you can create a
balanced equation to calculate the RQ value
In a balanced equation the number before the chemical formula can be taken as the number of
molecules/moles of that compound
This is because the same number of molecules of any gas take up the same volume e.g. 12
molecules of carbon dioxide take up the same volume as 12 molecules of oxygen
Glucose has a simple 1:1 ratio and RQ value of 1 but other substrates have more complex ratios leading
to different RQ values

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Worked example
Your notes
Linoleic acid (a fatty acid found in nuts) has the molecular formula C18H32O2. Calculate the RQ value of
this lipid.

Step 1: Write down the respiration equation
C18H32O2 + O2 → CO2 + H2O
Step 2: Balance the equation
C18H32O2 + 25O2 → 18CO2 + 16H2O
Step 3: Use the RQ formula
RQ = CO2 ÷ O2
RQ = 18 ÷ 25
RQ = 0.72

Worked example
During ethanol fermentation in lettuce roots, glucose is partially broken down. This process is
represented by the following equation:
glucose → ethanol + carbon dioxide
Calculate the RQ value.

Step 1: Write down the respiration equation
C6H12O6 → C2H5OH + CO2
Step 2: Balance the equation
C6H12O6 → 2C2H5OH + 2CO2
Step 3: Use the RQ formula
RQ = CO2 ÷ O2
RQ = 2 ÷ 0
RQ = ∞ (infinity)

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Exam Tip
Your notes
Make sure the respiration equation you are working with is fully balanced before you start doing any
calculations to find out the RQ value.

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7.7 Core Practical 15: Investigation of Respiration in Yeast
Your notes
Investigation of Respiration in Yeast
A redox indicator is a substance that changes colour when it is reduced or oxidised
DCPIP and methylene blue are redox indicators
They are used to investigate the effects of temperature and substrate concentration on the rate
of anaerobic respiration in yeast
These dyes can be added to a suspension of living yeast cells as they don’t damage cells
Yeast can respire both aerobically and anaerobically, in this experiment it is their rate of anaerobic
respiration that is being investigated
Mechanism
Dehydrogenation happens regularly throughout the different stages of aerobic respiration
The hydrogens that are removed from substrate molecules are transferred to the final stage of aerobic
respiration, oxidative phosphorylation, via the hydrogen carriers NAD and FAD
The enzyme dehydrogenase catalyses the production of reduced NAD in glycolysis
When DCPIP or methylene blue are present they take up hydrogens from the organic compounds and
get reduced instead of NAD
Both redox indicators undergo the same colour change when they are reduced
Blue → colourless
The faster the rate of respiration, the faster the rate of hydrogen release and the faster the dyes get
reduced and change colour
This means that the rate of colour change can correspond to the rate dehydrogenase would be
working at and therefore, the rate of respiration in yeast
The rate of respiration is inversely proportional to the time taken
Rate of respiration (sec-1) = 1 ÷ time (sec)
Apparatus
Yeast
Glucose solution
Test tubes
Stopwatch
DCPIP
Method - Temperature
1. Add a set volume of yeast suspension to test tubes containing a certain concentration of glucose
2. Put the test tube in a temperature-controlled water bath and leave for 5 minutes to ensure the water
temperature is correct and not continuing to increase or decrease
3. Add a set volume of DCPIP to the test tube and start the stopwatch immediately

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4. Stop the stopwatch when the solution becomes colourless or lose all blue colour
This is subjective and therefore the same person should be assigned this task for all repeat
experiments Your notes
5. Record the time taken for a colour change to occur once the dye is added
Repeat across a range of temperatures. For example, 30oC, 35oC, 40oC, 45oC
6. The effect of substrate concentration can be investigated by adding different concentrations of a
substrate to the suspension of yeast cells and recording the time taken for a colour change to occur
once the dye is added
For example, 0.1% glucose, 0.5% glucose, 1.0% glucose

Methylene blue or DCPIP is added to a solution of anaerobically respiring yeast cells in a glucose
solution. The rate at which the solution turns from blue to colourless gives the rate of dehydrogenase
activity
Controlling other variables
It is important when investigating one variable to ensure that the other variables in the experiment are
being controlled

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Volume of dye added: if there is more dye molecules present then the time taken for the colour
change to occur will be longer
Volume of yeast suspension: when more yeast cells are present the rate of respiration will be Your notes
inflated
Type of substrate: yeast cells will respire different substrates at different rates
Concentration of substrate: if there is limited substrate in one tube then the respiration of those
yeast cells will be limited
Temperature: an increase or decrease in temperature can affect the rate of respiration due to
energy demands and kinetic energy changes. The temperature of the dye being added also needs
to be considered
pH: a buffer solution can be used to control the pH level to ensure that no enzymes are denatured
Interpretation of results
A graph should be plotted of temperature against time
As the temperature increases, the rate of respiration also increases so the time taken for the solution
to go colourless reduces
This means hydrogens are released by the reactions more quickly, hence the DCPIP accepts
electrons/hydrogens more quickly until all molecules of DCPIP are reduced. This means that it will
take less time to turn from blue to colourless
At extreme high temperatures, the enzyme may denature and meaning the colour change may not
occur

Exam Tip
Although the DCPIP and methylene blue undergo a colour change from blue to colourless it is
important to remember that the yeast suspension in the test tube may have a slight colour (usually
yellow). That means when the dye changes to colourless there may still be an overall yellow colour in
the test tube. If this is the case it can be useful to have a control tube containing the same yeast
suspension but with no dye added, then you can tell when the dye has completely changed colour.

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7.8 Core Practical 16: Respirometer to Calculate RQ
Your notes
Using a Respirometer to Calculate RQ
Respirometers are used to measure and investigate the rate of oxygen consumption during
respiration in organisms
They can also be used to calculate respiratory quotients
The experiments usually involve organisms such as seeds or invertebrates
Apparatus
Respirometer
Glass beads
Germinating seeds
These will be actively respiring and consuming oxygen
Test tubes
Soda-lime pellets (or potassium hydroxide)
To absorb the carbon dioxide produced
Stopwatch

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Your notes

A respirometer set up to measure the rate of respiration
Method
1. Measure oxygen consumption: set up the respirometer and run the experiment with both tubes for a
set amount of time (e.g. 30 minutes)
2. As the seeds consume oxygen, the volume of air in the test tube will decrease (CO2 produced during
respiration is absorbed by soda lime or KOH)

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3. This reduces the pressure in the capillary tube and manometer fluid will move towards the test tube
containing the seeds
4. Measure the distance moved by the liquid in a given time Your notes
5. Use this measurement to calculate the change in gas volume within a given time, x cm3 min-1
6. Reset the apparatus: allow air to re-enter the tubes via the screw cap and reset the manometer fluid
using the syringe
7. Run the experiment again: remove the soda-lime from both tubes and use the manometer reading to
calculate the change in gas volume in a given time, y cm3 min-1
Equation for calculating change in gas volume
The volume of oxygen consumed (cm3 min-1) can be worked out using the diameter of the capillary
tube r (cm) and the distance moved by the manometer fluid h (cm) in a minute using the formula:
πr 2 h

Calculations
x tells us the volume of oxygen consumed by respiration within a given time
y tells us the volume of oxygen consumed by respiration within a given time minus the volume of carbon
dioxide produced within a given time
y may be a positive or negative value depending on the direction that the manometer fluid moves
(up = positive value, down = negative value)
The two measurements x and y can be used to calculate the RQ

Equation to calculate RQ values using a respirometer

Worked example
During a respirometer experiment using blow fly larvae, the volume of oxygen consumed was 2.9
cm3min-1. The soda lime was removed from both test tubes and the experiment was repeated. The
change in gas volume was -0.8 cm3min-1. Calculate the RQ value for the blow fly larvae.

x = 2.9 cm3min-1
y = -0.8 cm3min-1

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Step 1: Write down equation

x+y Your notes
RQ =
x
Step 2: Substitute values

2.9 − 0.8
RQ =
2.9
Step 3: Calculate RQ

RQ = 0. 72
Interpretation of results
Respirometers can be used in experiments to investigate how different factors affect the RQ of
organisms over time
E.g. temperature – using a series of water baths
When an RQ value changes it means the substrate being respired has changed
Some cells may also be using a mixture of substrates in respiration e.g. An RQ value of 0.85
suggests both carbohydrates and lipids are being used
This is because the RQ of glucose is 1 and the RQ of lipids is 0.7
Under normal cell conditions the order substrates are used in respiration: carbohydrates, lipids then
proteins
The RQ can also give an indication of under or overfeeding:
An RQ value of more than 1 suggests excessive carbohydrate/calorie intake
An RQ value of less than 0.7 suggests underfeeding

Exam Tip
There are several ways you can manage variables and increase the reliability of results in respirometer
experiments:
Use a controlled water bath to keep the temperature constant
Have a control tube with an equal volume of inert material to the volume of the organisms to
compensate for changes in atmospheric pressure
Repeat the experiment multiple times and use an average

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