Spirometry is test of lung function.ppt
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Mar 04, 2025
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About This Presentation
Spirometry (meaning the measuring of breath) is the most common of the pulmonary function tests (PFTs). It measures lung function, specifically the amount (volume) and/or speed (flow) of air that can be inhaled and exhaled. Spirometry is helpful in assessing breathing patterns that identify conditio...
Slide Content
Meassuring lung
functions
Prof.dr D. Bokonjic
functions
Prof.dr D. Bokonjic
Pulmonary Function Tests
Pulmonary function tests (PFT’s) are breathing tests to
find out how well you move air in and out of your lungs
and how well oxygen enters your blood stream.
The most common PFT’s are spirometry, diffusion
studies, and body plethysmography
Sometimes only one test is done, other times all tests will
be scheduled on the same day
Pulmonary function tests (PFT’s) are breathing tests to
find out how well you move air in and out of your lungs
and how well oxygen enters your blood stream.
The most common PFT’s are spirometry, diffusion
studies, and body plethysmography
Sometimes only one test is done, other times all tests will
be scheduled on the same day
Lung function tests can be
used...
Compare your lung function with known standards that
show how well your lungs should be working.
Measure the effect of chronic diseases like asthma,
chronic obstructive lung disease (COPD), or cystic
fibrosis on lung function.
Identify early changes in lung function that might show
a need for a change in treatment.
Detect narrowing in the airways.
used...
Compare your lung function with known standards that
show how well your lungs should be working.
Measure the effect of chronic diseases like asthma,
chronic obstructive lung disease (COPD), or cystic
fibrosis on lung function.
Identify early changes in lung function that might show
a need for a change in treatment.
Detect narrowing in the airways.
Lung function tests can be
used...
Decide if a medicine (such as a bronchodilator) could be
helpful to use.
Show whether exposure to substances in your home or
workplace may have harmed your lungs.
Determine your ability to tolerate surgery and medical
procedures.
used...
Decide if a medicine (such as a bronchodilator) could be
helpful to use.
Show whether exposure to substances in your home or
workplace may have harmed your lungs.
Determine your ability to tolerate surgery and medical
procedures.
To get the most accurate results
from your breathing tests
Do not smoke for at least 1 hour before the test.
Do not drink alcohol for at least 4 hours before the test.
Do not exercise heavily for at least 30 minutes before the test.
Do not wear tight clothing that makes it difficult for you to
take a deep breath.
Do not eat a large meal within 2 hours before the test.
Ask your health care provider if there are any medicines you
should not take on the day of your test.
from your breathing tests
Do not smoke for at least 1 hour before the test.
Do not drink alcohol for at least 4 hours before the test.
Do not exercise heavily for at least 30 minutes before the test.
Do not wear tight clothing that makes it difficult for you to
take a deep breath.
Do not eat a large meal within 2 hours before the test.
Ask your health care provider if there are any medicines you
should not take on the day of your test.
What is spirometry?
Spirometry is used to measure lung volumes and air flow.
Alongside clinical assessment, it is an essential tool used
in the diagnosis, assessment and monitoring of Chronic
Obstructive Pulmonary Disease (COPD),
May contribute to the diagnosis of asthma and detect
restrictive respiratory conditions.
Spirometry is used to measure lung volumes and air flow.
Alongside clinical assessment, it is an essential tool used
in the diagnosis, assessment and monitoring of Chronic
Obstructive Pulmonary Disease (COPD),
May contribute to the diagnosis of asthma and detect
restrictive respiratory conditions.
What measurements are
undertaken using spirometry?
Relaxed or slow vital capacity (VC). The volume of air
that can be slowly expelled from the lung from maximal
inspiration to maximum expiration
Forced vital capacity (FVC). The volume of air that can
be forcibly expelled from the lung from maximal
inspiration to maximum expiration.
Forced Expiratory Volume in 1 second (FEV1). The
volume of air that can be forcibly expelled from
maximum inspiration in the first second
undertaken using spirometry?
Relaxed or slow vital capacity (VC). The volume of air
that can be slowly expelled from the lung from maximal
inspiration to maximum expiration
Forced vital capacity (FVC). The volume of air that can
be forcibly expelled from the lung from maximal
inspiration to maximum expiration.
Forced Expiratory Volume in 1 second (FEV1). The
volume of air that can be forcibly expelled from
maximum inspiration in the first second
What measurements are
undertaken using spirometry?
FEV1/FVC ratio. The FEV1/FVC ratio is the FEV1
expressed as a percentage of the FVC (or VC if that is
greater). i.e. the proportion of the vital capacity exhaled
in the first second. It distinguishes between a reduced
FEV1 due to restrictive lung volume and that due to
obstruction. Obstruction is defined as an FEV1/FV ratio
less than 70%
Forced Expiratory Volume in 6 seconds (FEV6). The
volume of air that can be forcibly expelled from
maximum inspiration in six seconds.
undertaken using spirometry?
FEV1/FVC ratio. The FEV1/FVC ratio is the FEV1
expressed as a percentage of the FVC (or VC if that is
greater). i.e. the proportion of the vital capacity exhaled
in the first second. It distinguishes between a reduced
FEV1 due to restrictive lung volume and that due to
obstruction. Obstruction is defined as an FEV1/FV ratio
less than 70%
Forced Expiratory Volume in 6 seconds (FEV6). The
volume of air that can be forcibly expelled from
maximum inspiration in six seconds.
Flow volume curve
Abnormal spirometry
Abnormal spirometry is divided into restrictive and
obstructive ventilatory patterns.
Restrictive patterns appearin conditions where the lung
volume is reduced e.g. interstitial lung diseases, scoliosis.
The FVC and FEV1 are reduced proportionately
Obstructive patterns appear when the airways are
obstructed e.g. due to asthma or COPD. The FEV1 is
reduced more than the FVC
Abnormal spirometry is divided into restrictive and
obstructive ventilatory patterns.
Restrictive patterns appearin conditions where the lung
volume is reduced e.g. interstitial lung diseases, scoliosis.
The FVC and FEV1 are reduced proportionately
Obstructive patterns appear when the airways are
obstructed e.g. due to asthma or COPD. The FEV1 is
reduced more than the FVC
Predicted values
Predicted normal values can be calculated and depend on
age, sex, height, mass and ethnicity.
FEV1 is often expressed as a percentage of the predicted
value for any person of similar age sex, and height with
adjust ments for ethnic origin.
FEV1 % predicted is used to classify the severity of COPD.
National and international guidelines use the levels of
FEV1 <80%, <50% or <30% predicted to define moderate,
severe or very severe disease
Predicted normal values can be calculated and depend on
age, sex, height, mass and ethnicity.
FEV1 is often expressed as a percentage of the predicted
value for any person of similar age sex, and height with
adjust ments for ethnic origin.
FEV1 % predicted is used to classify the severity of COPD.
National and international guidelines use the levels of
FEV1 <80%, <50% or <30% predicted to define moderate,
severe or very severe disease
Types of spirometry testing
Baseline testing. Used to investigate lung function where
diagnosis has not been established.
Post-bronchodilator testing. Investigative: To diagnose
obstructive conditions where baseline spirometry shows
an obstructive pattern. Monitoring: To monitor clinical
progress in diagnosed asthma and COPD
Reversibility testing May help to differentiate asthma
from COPD.
Baseline testing. Used to investigate lung function where
diagnosis has not been established.
Post-bronchodilator testing. Investigative: To diagnose
obstructive conditions where baseline spirometry shows
an obstructive pattern. Monitoring: To monitor clinical
progress in diagnosed asthma and COPD
Reversibility testing May help to differentiate asthma
from COPD.
What equipment is required
to conduct spirometry?
Spirometer (must meet ISO standard 26783).
Small hand-held meters which provide digital
readings(but no visual display) are a cheap option which
may be useful as a screening tool to identify people with
abnormal readings who should be assessed by full
diagnostic spirometry
One-way disposable mouthpieces and nose clips
Bacterial and viral filters (selected patients with any risk
of infection)
to conduct spirometry?
Spirometer (must meet ISO standard 26783).
Small hand-held meters which provide digital
readings(but no visual display) are a cheap option which
may be useful as a screening tool to identify people with
abnormal readings who should be assessed by full
diagnostic spirometry
One-way disposable mouthpieces and nose clips
Bacterial and viral filters (selected patients with any risk
of infection)
What equipment is required
to conduct spirometry?
Accurate height measures –calibrated according to
manufacturer’s instructions
Short-acting bronchodilators for reversibility testing and
suitable means for delivery (volumatic/nebuliser
to conduct spirometry?
Accurate height measures –calibrated according to
manufacturer’s instructions
Short-acting bronchodilators for reversibility testing and
suitable means for delivery (volumatic/nebuliser
Contraindications to
spirometry testing
Absolute
Active infection e.g. AFB positive TB until treated for 2
weeks
Conditions that may cause serious consequences to health
if aggravated by forced expiration e.g. dissecting/unstable
aortic aneurysm, pneumothorax, recent surgery (abdominal,
thoracic, neurosurgery, eye surgery)
spirometry testing
Absolute
Active infection e.g. AFB positive TB until treated for 2
weeks
Conditions that may cause serious consequences to health
if aggravated by forced expiration e.g. dissecting/unstable
aortic aneurysm, pneumothorax, recent surgery (abdominal,
thoracic, neurosurgery, eye surgery)
Contraindications to
spirometry testing
Relative
Suspected respiratory infection in the last 4-6 weeks requiring
antibiotics or steroids
Undiagnosed chest symptoms e.g. haemoptysis
Any condition which may be aggravated by forced expiration e.g. prior
pneumothorax, history of myocardial infarction, stroke or embolism in
the last 3 months, previous thoracic, abdominal or eye surgery
Perforated ear drum. Acute disorders such as nausea and vomiting
Confusion, communication problems
spirometry testing
Relative
Suspected respiratory infection in the last 4-6 weeks requiring
antibiotics or steroids
Undiagnosed chest symptoms e.g. haemoptysis
Any condition which may be aggravated by forced expiration e.g. prior
pneumothorax, history of myocardial infarction, stroke or embolism in
the last 3 months, previous thoracic, abdominal or eye surgery
Perforated ear drum. Acute disorders such as nausea and vomiting
Confusion, communication problems
Common errors in spirometry
testing
Poor seal around mouthpiece
Hesitation or false start
Early termination of exhalation: a ‘short blow’ which has not
achieved the full FVC
Poor intake of breath
Poor forced expiratory effort. Cough during procedure
Incorrect data entered into the spirometer prior to testing
Spirometer not calibrated and verified
testing
Poor seal around mouthpiece
Hesitation or false start
Early termination of exhalation: a ‘short blow’ which has not
achieved the full FVC
Poor intake of breath
Poor forced expiratory effort. Cough during procedure
Incorrect data entered into the spirometer prior to testing
Spirometer not calibrated and verified
Calibration
Calibration of spirometry test equipment should be
performed using a certificated 3 litre syringe and
following
The manufacturer’s recommended procedures. For a
device to be within calibration limits it must read +/- 3%
of true.
Calibration should be verified prior to each
clinic/session or after every 10th patient (which ever
comes first). A calibration log should be maintained
Calibration of spirometry test equipment should be
performed using a certificated 3 litre syringe and
following
The manufacturer’s recommended procedures. For a
device to be within calibration limits it must read +/- 3%
of true.
Calibration should be verified prior to each
clinic/session or after every 10th patient (which ever
comes first). A calibration log should be maintained
Preparation of the patient
Explain to the patient that they will need to breathe in until
they have completely filled their lungs, then blow out as hard
and fast as they can into the mouthpiece until the lungs are
completely empty.
This could take a few seconds longer than feels comfortable.
— demonstrate the correct posture and the amount of force
needed when exhaling.
— explain that this process will be repeated at least three times,
and that several more attempts may be needed to get reliable
results.
Explain to the patient that they will need to breathe in until
they have completely filled their lungs, then blow out as hard
and fast as they can into the mouthpiece until the lungs are
completely empty.
This could take a few seconds longer than feels comfortable.
— demonstrate the correct posture and the amount of force
needed when exhaling.
— explain that this process will be repeated at least three times,
and that several more attempts may be needed to get reliable
results.
Measuring expiratory and
inspiratory flow
Sit upright with their legs uncrossed and their feet flat on
the floor, without leaning forward
Place the mouthpiece in their mouth and close their lips
to form a tight seal
Breathe normally for 2–3 breaths
Breathe in rapidly and deeply until their lungs are
completely full
inspiratory flow
Sit upright with their legs uncrossed and their feet flat on
the floor, without leaning forward
Place the mouthpiece in their mouth and close their lips
to form a tight seal
Breathe normally for 2–3 breaths
Breathe in rapidly and deeply until their lungs are
completely full
Measuring expiratory and
inspiratory flow
Without pausing for more than 2 seconds, blast air out as
hard and fast as possible and for as long as possible, until
their lungs are completely empty or they cannot possibly
blow out any longer
Keeping a tight seal on the mouthpiece, breathe in again
as forcefully and fully as possible
Remove the mouthpiece and breathe normally
inspiratory flow
Without pausing for more than 2 seconds, blast air out as
hard and fast as possible and for as long as possible, until
their lungs are completely empty or they cannot possibly
blow out any longer
Keeping a tight seal on the mouthpiece, breathe in again
as forcefully and fully as possible
Remove the mouthpiece and breathe normally
Measuring expiratory flow
Sit upright with their legs uncrossed and their feet flat on the
floor, without leaning forward
Breathe in rapidly and deeply until their lungs are completely full
Immediately place the mouthpiece in their mouth and close their
lips to form a tight seal
Without pausing for more than 2 seconds, blast air out as hard
and fast as possible and for as long as possible, until their lungs
are completely empty or they cannot possibly blowout any longer.
Remove the mouthpiece and breathe normally
Sit upright with their legs uncrossed and their feet flat on the
floor, without leaning forward
Breathe in rapidly and deeply until their lungs are completely full
Immediately place the mouthpiece in their mouth and close their
lips to form a tight seal
Without pausing for more than 2 seconds, blast air out as hard
and fast as possible and for as long as possible, until their lungs
are completely empty or they cannot possibly blowout any longer.
Remove the mouthpiece and breathe normally
Accetability
Spirometry results are acceptable if the testing session yields
manoeuvres (blows) that:
— meet objective criteria for determining that maximal effort
was achieved and acceptable FEV1 and/or FVC
measurements were obtained (usually termed ‘acceptability’)
— meet criteria for consistency across multiple manoeuvres
(usually termed ‘repeatability’).
However, occasionally FEV1 or FVC measurements may be
clinically usable even if they are not technically acceptable.
Spirometry results are acceptable if the testing session yields
manoeuvres (blows) that:
— meet objective criteria for determining that maximal effort
was achieved and acceptable FEV1 and/or FVC
measurements were obtained (usually termed ‘acceptability’)
— meet criteria for consistency across multiple manoeuvres
(usually termed ‘repeatability’).
However, occasionally FEV1 or FVC measurements may be
clinically usable even if they are not technically acceptable.
Pulmonary diffusion test
Lung diffusion testing determines how well oxygen
moves from your lungs to your blood. It’s a type of
pulmonary function test. It helps your healthcare
provider understand how well your lungs are working.
During the test, you breathe in a gas that contains a
small amount of carbon monoxide. The test measures
how much carbon monoxide passes from your lungs to
your blood, or the “diffusing capacity for carbon
monoxide” (DLCO for short). It’s also called transfer
factor for carbon monoxide (TLCO).
Lung diffusion testing determines how well oxygen
moves from your lungs to your blood. It’s a type of
pulmonary function test. It helps your healthcare
provider understand how well your lungs are working.
During the test, you breathe in a gas that contains a
small amount of carbon monoxide. The test measures
how much carbon monoxide passes from your lungs to
your blood, or the “diffusing capacity for carbon
monoxide” (DLCO for short). It’s also called transfer
factor for carbon monoxide (TLCO).
When you breathe air in, the oxygen travels through your airways into small
air sacs (alveoli).
From there, your blood picks up the oxygen as it travels through nearby
blood vessels (capillaries). A number of factors determine how well oxygen
transfers from your lungs to your blood (diffusion), including:
The amount of surface area in your alveoli.
The amount of blood in your capillaries.
The concentration of hemoglobin (a protein that carries oxygen) in your
blood.
The thickness of the membrane between your alveoli and capillaries. Excess
fluid in your alveoli.
air sacs (alveoli).
From there, your blood picks up the oxygen as it travels through nearby
blood vessels (capillaries). A number of factors determine how well oxygen
transfers from your lungs to your blood (diffusion), including:
The amount of surface area in your alveoli.
The amount of blood in your capillaries.
The concentration of hemoglobin (a protein that carries oxygen) in your
blood.
The thickness of the membrane between your alveoli and capillaries. Excess
fluid in your alveoli.
What is lung diffusion testing
(DLCO) used for?
Understand what’s causing certain symptoms such as
shortness of breath, coughing or wheezing.
Assess lung damage.
Screen for certain lung diseases.
Understand how an underlying disease is affecting your
lung function.
Get information on how well a treatment is working.
(DLCO) used for?
Understand what’s causing certain symptoms such as
shortness of breath, coughing or wheezing.
Assess lung damage.
Screen for certain lung diseases.
Understand how an underlying disease is affecting your
lung function.
Get information on how well a treatment is working.
A DLCO test uses a special mixture of gas to measure how well oxygen and
carbon dioxide are moving between your lungs and your blood.
During the test, you breathe in a gas that’s a mixture of nitrogen and oxygen
plus:
A small amount of carbon monoxide (not enough to hurt you), which should
move easily from your lungs to your blood.
A tracer gas, like helium. A tracer gas isn’t absorbed into your blood and helps
measure the amount of carbon monoxide absorbed.
When you breathe in, your blood absorbs some or all of the carbon monoxide
from the gas in your lungs. When you breathe out into the machine, it measures
how much carbon monoxide your blood absorbed based on how much is left in
the gas you breathed out.
carbon dioxide are moving between your lungs and your blood.
During the test, you breathe in a gas that’s a mixture of nitrogen and oxygen
plus:
A small amount of carbon monoxide (not enough to hurt you), which should
move easily from your lungs to your blood.
A tracer gas, like helium. A tracer gas isn’t absorbed into your blood and helps
measure the amount of carbon monoxide absorbed.
When you breathe in, your blood absorbs some or all of the carbon monoxide
from the gas in your lungs. When you breathe out into the machine, it measures
how much carbon monoxide your blood absorbed based on how much is left in
the gas you breathed out.
What should I know before
doing a diffusion test?
Do not smoke and stay away from others who are
smoking on the day of the test.
If you are on oxygen, you will usually be asked to be off
oxygen for a few minutes before taking this test.
doing a diffusion test?
Do not smoke and stay away from others who are
smoking on the day of the test.
If you are on oxygen, you will usually be asked to be off
oxygen for a few minutes before taking this test.
What are diffusion studies?
Like spirometry, this test is done by having you breathe into
a mouthpiece connected to a machine. You will be asked to
empty your lungs by gently breathing out as much air as you
can.
Then you will breathe in a quick (but deep breath), hold your
breath for 10 seconds, and then breathe out as instructed.
You will do the test several times. It usually takes about 30
minutes to complete this test
Like spirometry, this test is done by having you breathe into
a mouthpiece connected to a machine. You will be asked to
empty your lungs by gently breathing out as much air as you
can.
Then you will breathe in a quick (but deep breath), hold your
breath for 10 seconds, and then breathe out as instructed.
You will do the test several times. It usually takes about 30
minutes to complete this test
What are diffusion studies?
During a DLCO test, a technician will put a clip over your nose or a mask on your
face. They’ll have you:
Put your mouth over a mouthpiece attached to a machine. The machine will deliver
the gas mix. It will also measure and record your results throughout the test.
Take a few normal, steady breaths.
Inhale deeply and exhale completely.
Breathe in quickly through your mouth.
Hold your breath for 10 seconds or as long as you can.
Breathe out.
Your technician may wait a few minutes and repeat the test at least one more time.
During a DLCO test, a technician will put a clip over your nose or a mask on your
face. They’ll have you:
Put your mouth over a mouthpiece attached to a machine. The machine will deliver
the gas mix. It will also measure and record your results throughout the test.
Take a few normal, steady breaths.
Inhale deeply and exhale completely.
Breathe in quickly through your mouth.
Hold your breath for 10 seconds or as long as you can.
Breathe out.
Your technician may wait a few minutes and repeat the test at least one more time.
Results
The results of a lung diffusion test are given in a percentage of
what they expect your DLCO to be (predicted value). Not
everyone’s expected DLCO value is the same. It’s based on
factors like age and sex. Your results could be:
Normal DLCO: Between 75% and 140% of the predicted
value.
Mildly reduced DLCO: 60% to 75% or the lower limit of
normal (LLN) predicted value.
Severely reduced DLCO: Less than 40% of the predicted value.
The results of a lung diffusion test are given in a percentage of
what they expect your DLCO to be (predicted value). Not
everyone’s expected DLCO value is the same. It’s based on
factors like age and sex. Your results could be:
Normal DLCO: Between 75% and 140% of the predicted
value.
Mildly reduced DLCO: 60% to 75% or the lower limit of
normal (LLN) predicted value.
Severely reduced DLCO: Less than 40% of the predicted value.
LOW DLCO
Many things can cause a low DLCO. Some specific causes includes
Smoking.
Cystic fibrosis.
COPD.
Emphysema.
Sarcoidosis and other interstitial lung diseases.
Heart and blood conditions, like pulmonary embolism, pulmonary arterial
hypertension, congestive heart failure and anemia.
Autoimmune disorders like mixed connective tissue disease, scleroderma and lupus
(SLE).
Many things can cause a low DLCO. Some specific causes includes
Smoking.
Cystic fibrosis.
COPD.
Emphysema.
Sarcoidosis and other interstitial lung diseases.
Heart and blood conditions, like pulmonary embolism, pulmonary arterial
hypertension, congestive heart failure and anemia.
Autoimmune disorders like mixed connective tissue disease, scleroderma and lupus
(SLE).
High DLCO
Some conditions cause you to have a higher DLCO than expected. These include:
Obesity.
Asthma.
Exercising before the test.
High altitude.
Bleeding in your lungs.
Cardiac shunt.
Heart failure.
Polycythemia vera.
Some conditions cause you to have a higher DLCO than expected. These include:
Obesity.
Asthma.
Exercising before the test.
High altitude.
Bleeding in your lungs.
Cardiac shunt.
Heart failure.
Polycythemia vera.
What is body plethysmography?
Body plethysmography is a test to find out how much air is
in your lungs after you take in a deep breath, and how
much air is left in your lungs after breathing out as much as
you can.
No matter how hard you try, you can never get all of the air
out of your lungs.
Measuring the total amount of air your lungs can hold and
the amount of air left in your lungs after you breathe out
gives your healthcare provider information about how well
your lungs are working and helps guide your treatment.
Body plethysmography is a test to find out how much air is
in your lungs after you take in a deep breath, and how
much air is left in your lungs after breathing out as much as
you can.
No matter how hard you try, you can never get all of the air
out of your lungs.
Measuring the total amount of air your lungs can hold and
the amount of air left in your lungs after you breathe out
gives your healthcare provider information about how well
your lungs are working and helps guide your treatment.
What is body plethysmography?
The volume-constant whole-body plethysmograph isa
chamber resembling a glass-walled telephone box in shape
and volume (about 700e1000 L). During measurement the
box is closed with an airtight seal, except for a small
controlled leak that is used to stabilize the internal pressure
by allowing for equilibration of slow pressure changes,
One pressure transducer serves to measure the pressure
inside the box relative to ambient pressure, another one is
placed close to the mouth for recording mouth pressure
during a shutter maneuver.
The volume-constant whole-body plethysmograph isa
chamber resembling a glass-walled telephone box in shape
and volume (about 700e1000 L). During measurement the
box is closed with an airtight seal, except for a small
controlled leak that is used to stabilize the internal pressure
by allowing for equilibration of slow pressure changes,
One pressure transducer serves to measure the pressure
inside the box relative to ambient pressure, another one is
placed close to the mouth for recording mouth pressure
during a shutter maneuver.
The shutter mechanism can be used to deliberately block the airflow by
transient occlusion.
Moreover, respiratory flow rate is recorded by conventional equipment,
such as pneumotachograph,
You will be asked to wear a nose clip and you will be given instructions
on how to breathe through the mouthpiece.
You will be asked to take short, shallow breaths through the mouthpiece
when it is blocked for a few seconds, which may be uncomfortable.
If you have difficulty with being in closed spaces (claustrophobia),
mention this to your provider ordering the test.
transient occlusion.
Moreover, respiratory flow rate is recorded by conventional equipment,
such as pneumotachograph,
You will be asked to wear a nose clip and you will be given instructions
on how to breathe through the mouthpiece.
You will be asked to take short, shallow breaths through the mouthpiece
when it is blocked for a few seconds, which may be uncomfortable.
If you have difficulty with being in closed spaces (claustrophobia),
mention this to your provider ordering the test.
What is body plethysmography?
This will avoid any misunderstanding and discomfort to
you.
It usually takes about 15 minutes to complete.
Some PFT labs will use other tests instead of
plethysmography to measure the total volume of air in
your lungs
This will avoid any misunderstanding and discomfort to
you.
It usually takes about 15 minutes to complete.
Some PFT labs will use other tests instead of
plethysmography to measure the total volume of air in
your lungs
What should be done before
this test?
If you are on oxygen, you will usually be asked to be off
oxygen during this test.
Let the staff know if you have difficulty in closed spaces
this test?
If you are on oxygen, you will usually be asked to be off
oxygen during this test.
Let the staff know if you have difficulty in closed spaces
Practical consideration
Obviously, the “thoracic gas volume (TGV)” determined
in this way is that at occlusion; it is commonly
performed at the end of expiration, i.e. under the
condition of mechanical relaxation.
This volume is the “functional residual capacity assessed
by body plethysmography” (FRC, more specifically
FRCpleth).
Occasionally the expression “intrathoracic gas volume
(ITGV)” is used as synonym for FRCpleth.
Obviously, the “thoracic gas volume (TGV)” determined
in this way is that at occlusion; it is commonly
performed at the end of expiration, i.e. under the
condition of mechanical relaxation.
This volume is the “functional residual capacity assessed
by body plethysmography” (FRC, more specifically
FRCpleth).
Occasionally the expression “intrathoracic gas volume
(ITGV)” is used as synonym for FRCpleth.
Practical consideration
In practical measurements there is a small deviation
from this, as a small initial inspiratory volume has to be
detected in order to reliably define the end of expiration,
After the first occlusion maneuver, patients should
continue to breathe normally until they have
recoveredfrom potential changes in FRC subsequent to
the maneuver.
In practical measurements there is a small deviation
from this, as a small initial inspiratory volume has to be
detected in order to reliably define the end of expiration,
After the first occlusion maneuver, patients should
continue to breathe normally until they have
recoveredfrom potential changes in FRC subsequent to
the maneuver.
Practical consideration
There are two ways to continue the measurement after
the last occlusion maneuver. If possible, the patient
should perform a maximal expiration to determine
expiratory reserve volume (ERV) without potential for
intermediate shifts in FRC.
This should be followed by a maximal inspiration to
determine inspiratory vital capacity (IVC)
There are two ways to continue the measurement after
the last occlusion maneuver. If possible, the patient
should perform a maximal expiration to determine
expiratory reserve volume (ERV) without potential for
intermediate shifts in FRC.
This should be followed by a maximal inspiration to
determine inspiratory vital capacity (IVC)
Practical consideration
Residual volume (RV) can then be calculated as FRC minus ERV
Probably the best choice is to take median FRC and maximum
ERV for this.
Next, total lung capacity (TLC) is computed as the sum of RV
and the maximal IVC from all satisfactory respiratory
maneuvers.
For patients with dyspnea it might be difficult to perform these
linked maneuvers immediately after opening of the shutter.
These patients should be allowed for a few cycles of quiet
breathing before initiation of the ERV maneuver.
Residual volume (RV) can then be calculated as FRC minus ERV
Probably the best choice is to take median FRC and maximum
ERV for this.
Next, total lung capacity (TLC) is computed as the sum of RV
and the maximal IVC from all satisfactory respiratory
maneuvers.
For patients with dyspnea it might be difficult to perform these
linked maneuvers immediately after opening of the shutter.
These patients should be allowed for a few cycles of quiet
breathing before initiation of the ERV maneuver.
Airway resistance
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