Pulmonary-Function-Tests and it's importance ppt
187 views
91 slides
Mar 26, 2024
Slide 1 of 91
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
About This Presentation
A brief presentation on pulmonary function test and it's importance
Slide Content
Lung Volumes and Capacities
PFT tracings have:
Four Lung volumes: tidal
volume, inspiratoryreserve
volume, expiratory reserve
volume, and residual
volume
Five capacities:, inspiratory
capacity, expiratory
capacity, vital capacity,
functional residual capacity,
and total lung capacity
Addition of 2 or more volumes comprise a capacity.
www.anaesthesia.co.in
PFT tracings have:
Four Lung volumes: tidal
volume, inspiratoryreserve
volume, expiratory reserve
volume, and residual
volume
Five capacities:, inspiratory
capacity, expiratory
capacity, vital capacity,
functional residual capacity,
and total lung capacity
Addition of 2 or more volumes comprise a capacity.
www.anaesthesia.co.in
Lung Volumes
•Tidal Volume(TV): volume of air
inhaled or exhaled with each
breath during quiet breathing (6-
8 ml/kg)
•Inspiratory Reserve Volume
(IRV): maximum volume of air
inhaled from the end-inspiratory
tidal position.(1900-3300ml)
•Expiratory Reserve Volume
(ERV): maximum volume of air
that can be exhaled from resting
end-expiratory tidal position.(
700-1000ml).
www.anaesthesia.co.in
•Tidal Volume(TV): volume of air
inhaled or exhaled with each
breath during quiet breathing (6-
8 ml/kg)
•Inspiratory Reserve Volume
(IRV): maximum volume of air
inhaled from the end-inspiratory
tidal position.(1900-3300ml)
•Expiratory Reserve Volume
(ERV): maximum volume of air
that can be exhaled from resting
end-expiratory tidal position.(
700-1000ml).
www.anaesthesia.co.in
Lung Volumes
•Residual Volume (RV):
–Volume of air remaining
in lungs after maximium
exhalation (20-25 ml/kg)
(1700-2100ml)
–Indirectly measured
(FRC-ERV)
–It can not be measured
by spirometry
www.anaesthesia.co.in
•Residual Volume (RV):
–Volume of air remaining
in lungs after maximium
exhalation (20-25 ml/kg)
(1700-2100ml)
–Indirectly measured
(FRC-ERV)
–It can not be measured
by spirometry
www.anaesthesia.co.in
Lung Capacities
•Total Lung Capacity(TLC): Sum of
all volume compartments or
volume of air in lungs after
maximum inspiration (4-6 L)
•Vital Capacity (VC): TLC minus RV
or maximum volume of air exhaled
from maximal inspiratorylevel.
(60-70 ml/kg) (3100-4800ml)
•Inspiratory Capacity(IC): Sum of
IRV and TV or the maximum
volume of air that can be inhaled
from the end-expiratory tidal
position. (2400-3800ml).
•Expiratory Capacity (EC): TV+ ERV
www.anaesthesia.co.in
•Total Lung Capacity(TLC): Sum of
all volume compartments or
volume of air in lungs after
maximum inspiration (4-6 L)
•Vital Capacity (VC): TLC minus RV
or maximum volume of air exhaled
from maximal inspiratorylevel.
(60-70 ml/kg) (3100-4800ml)
•Inspiratory Capacity(IC): Sum of
IRV and TV or the maximum
volume of air that can be inhaled
from the end-expiratory tidal
position. (2400-3800ml).
•Expiratory Capacity (EC): TV+ ERV
www.anaesthesia.co.in
Lung Capacities (cont.)
•Functional Residual
Capacity (FRC):
–Sum of RV and ERV or the
volume of air in the lungs at
end-expiratory tidal
position.(30-35 ml/kg) (2300-
3300ml).
–Measured with multiple-
breath closed-circuit helium
dilution, multiple-breath
open-circuit nitrogen
washout, or body
plethysmography.
–It can not be measured by
spirometry)
www.anaesthesia.co.in
•Functional Residual
Capacity (FRC):
–Sum of RV and ERV or the
volume of air in the lungs at
end-expiratory tidal
position.(30-35 ml/kg) (2300-
3300ml).
–Measured with multiple-
breath closed-circuit helium
dilution, multiple-breath
open-circuit nitrogen
washout, or body
plethysmography.
–It can not be measured by
spirometry)
www.anaesthesia.co.in
VOLUMES, CAPACITIES AND THEIR
CLINICAL SIGNIFICANCE
1)TIDAL VOLUME (TV):
VOLUME OF AIR INHALED/EXHALED IN EACH BREATH
DURING QUIET RESPIRATION.
N –6-8 ml/kg.
TV FALLS WITH DECREASE IN COMPLIANCE, DECREASED
VENTILATORY MUSCLE STRENGTH.
2)INSPIRATORY RESERVE VOLUME (IRV):
MAX. VOL. OF AIR WHICH CAN BE INSPIRED AFTER A
NORMAL TIDAL INSPIRATION i.e. FROM END INSPIRATION PT.
N-1900 ml-3300 ml.
www.anaesthesia.co.in
CLINICAL SIGNIFICANCE
1)TIDAL VOLUME (TV):
VOLUME OF AIR INHALED/EXHALED IN EACH BREATH
DURING QUIET RESPIRATION.
N –6-8 ml/kg.
TV FALLS WITH DECREASE IN COMPLIANCE, DECREASED
VENTILATORY MUSCLE STRENGTH.
2)INSPIRATORY RESERVE VOLUME (IRV):
MAX. VOL. OF AIR WHICH CAN BE INSPIRED AFTER A
NORMAL TIDAL INSPIRATION i.e. FROM END INSPIRATION PT.
N-1900 ml-3300 ml.
www.anaesthesia.co.in
CONTINUED………
3) EXPIRATORY RESERVE VOLUME (ERV):
MAX. VOLUME OF AIR WHICH CAN BE EXPIRED AFTER A
NORMAL TIDAL EXPIRATION i.e. FROM END EXPIRATION
PT.
N-700 ml –1000 ml
4) INSPIRATORY CAPACITY (IC) :
MAX. VOL. OF AIR WHICH CAN BE INSPIRED AFTER A
NORMAL TIDAL EXPIRATION.
IC = IRV + TV
N-2400 ml –3800 ml.
www.anaesthesia.co.in
3) EXPIRATORY RESERVE VOLUME (ERV):
MAX. VOLUME OF AIR WHICH CAN BE EXPIRED AFTER A
NORMAL TIDAL EXPIRATION i.e. FROM END EXPIRATION
PT.
N-700 ml –1000 ml
4) INSPIRATORY CAPACITY (IC) :
MAX. VOL. OF AIR WHICH CAN BE INSPIRED AFTER A
NORMAL TIDAL EXPIRATION.
IC = IRV + TV
N-2400 ml –3800 ml.
www.anaesthesia.co.in
CONTINUED………..
4)VITAL CAPACITY: COINED BY JOHN
HUTCHINSON.
MAX. VOL. OF AIR EXPIRED AFTER A MAX.
INSPIRATION .
MEASURED WITH VITALOGRAPH
VC= TV+ERV+IRV
N-3.1-4.8L. OR 60-70 ml/kg
VC IS COSIDERED ABNORMAL IF ≤ 80% OF
PREDICTED VALUE
www.anaesthesia.co.in
4)VITAL CAPACITY: COINED BY JOHN
HUTCHINSON.
MAX. VOL. OF AIR EXPIRED AFTER A MAX.
INSPIRATION .
MEASURED WITH VITALOGRAPH
VC= TV+ERV+IRV
N-3.1-4.8L. OR 60-70 ml/kg
VC IS COSIDERED ABNORMAL IF ≤ 80% OF
PREDICTED VALUE
www.anaesthesia.co.in
FACTORS INFLUENCING VC
•PHYSIOLOGICAL:
physical dimensions-directly proportional to ht.
SEX –more in males : large chest size, more
muscle power, more BSA.
AGE –decreases with increasing age
STRENGTH OF RESPIRATORY MUSCLES
POSTURE –decreases in supine position
PREGNANCY-unchanged or increases by 10% (
increase in AP diameter In pregnancy)
www.anaesthesia.co.in
•PHYSIOLOGICAL:
physical dimensions-directly proportional to ht.
SEX –more in males : large chest size, more
muscle power, more BSA.
AGE –decreases with increasing age
STRENGTH OF RESPIRATORY MUSCLES
POSTURE –decreases in supine position
PREGNANCY-unchanged or increases by 10% (
increase in AP diameter In pregnancy)
www.anaesthesia.co.in
CONTINUED………
•PATHOLOGICAL:
DISEASE OF RESPIRATORY MUSCLES
ABDOMINAL CONDITION : pain, dis. and
splinting
www.anaesthesia.co.in
•PATHOLOGICAL:
DISEASE OF RESPIRATORY MUSCLES
ABDOMINAL CONDITION : pain, dis. and
splinting
www.anaesthesia.co.in
FACTORS DECREASING VITAL CAPACITY
1)Alteration in muscle power-d/t drugs, n-m
dis., cerebral tumours.
2)Pulmonary diseases –pneumonia, chronic
bronchitis, asthma, fibrosis, emphysema,
pulmonary edema,.
3)Space occupying lesions in chest-tumours,
pleural/pericardial effusion, kyphoscoliosis
4)Abdominal tumours, ascites.
www.anaesthesia.co.in
1)Alteration in muscle power-d/t drugs, n-m
dis., cerebral tumours.
2)Pulmonary diseases –pneumonia, chronic
bronchitis, asthma, fibrosis, emphysema,
pulmonary edema,.
3)Space occupying lesions in chest-tumours,
pleural/pericardial effusion, kyphoscoliosis
4)Abdominal tumours, ascites.
www.anaesthesia.co.in
5) Depression of respiration : opioids/ volatile
agents
6) Abdominal splinting –abdominal binders,
tight bandages, hip spica.
7)Abdominal pain –decreases by 50% & 75% in
lower & upper abdominal Surgeries
respectively.
8) Posture –by altering pulmonary Blood
volume.
www.anaesthesia.co.in
agents
6) Abdominal splinting –abdominal binders,
tight bandages, hip spica.
7)Abdominal pain –decreases by 50% & 75% in
lower & upper abdominal Surgeries
respectively.
8) Posture –by altering pulmonary Blood
volume.
www.anaesthesia.co.in
DIFFERENT POSTURES AFFECTING VC
•POSITION
TRENDELENBERG
LITHOTOMY
PRONE
RT. LATERAL
LT. LATERAL
•DECREASE IN VC
14.5%
18%
10%
12%
10%
www.anaesthesia.co.in
•POSITION
TRENDELENBERG
LITHOTOMY
PRONE
RT. LATERAL
LT. LATERAL
•DECREASE IN VC
14.5%
18%
10%
12%
10%
www.anaesthesia.co.in
VC CONTINUED…….
•VC correlates with capability for deep
breathing and effective cough.
•So in post operative period if VC falls below 3
times VC–artificial respiration is needed to
maintain airway clear of secretions.
www.anaesthesia.co.in
•VC correlates with capability for deep
breathing and effective cough.
•So in post operative period if VC falls below 3
times VC–artificial respiration is needed to
maintain airway clear of secretions.
www.anaesthesia.co.in
CONTINUED…….
6) TOTAL LUNG CAPACITY :
Maximum volume of air attained in lungs after
maximal inspiration.
N-4-6 l or 80-100 ml/kg
TLC= VC + RV
7) RESIDUAL VOLUME (RV):
Volume of air remaining in the lungs after
maximal expiration.
N-1570 –2100 ml OR 20 –25 ml/kg.
www.anaesthesia.co.in
6) TOTAL LUNG CAPACITY :
Maximum volume of air attained in lungs after
maximal inspiration.
N-4-6 l or 80-100 ml/kg
TLC= VC + RV
7) RESIDUAL VOLUME (RV):
Volume of air remaining in the lungs after
maximal expiration.
N-1570 –2100 ml OR 20 –25 ml/kg.
www.anaesthesia.co.in
CONTINUED……
8) FUNCTIONAL RESIDUAL CAPACITY (FRC):
Volume of air remaining in the lungs after
normal tidal expiration, when there is no airflow.
N-2.3 -3.3 L OR 30-35 ml/kg.
FRC = RV + ERV
Decresesunder anaesthesia
•with spontaneous Respiration –decreases by
20%
•With paralysis –decreases by 16%
www.anaesthesia.co.in
8) FUNCTIONAL RESIDUAL CAPACITY (FRC):
Volume of air remaining in the lungs after
normal tidal expiration, when there is no airflow.
N-2.3 -3.3 L OR 30-35 ml/kg.
FRC = RV + ERV
Decresesunder anaesthesia
•with spontaneous Respiration –decreases by
20%
•With paralysis –decreases by 16%
www.anaesthesia.co.in
FACTORS AFFECTING FRC
•FRC INCREASES WITH
•Increased height
•Erect position (30% more than in supine)
•Decreased lung recoil (e.g. emphysema)
•FRC DECREASES WITH
•Obesity
•Muscle paralysis (especially in supine)
•Supine position
•Restrictive lung disease (e.g. fibrosis, Pregnancy)
•Anaesthesia
•FRC does NOT change with age.
www.anaesthesia.co.in
•FRC INCREASES WITH
•Increased height
•Erect position (30% more than in supine)
•Decreased lung recoil (e.g. emphysema)
•FRC DECREASES WITH
•Obesity
•Muscle paralysis (especially in supine)
•Supine position
•Restrictive lung disease (e.g. fibrosis, Pregnancy)
•Anaesthesia
•FRC does NOT change with age.
www.anaesthesia.co.in
FUNCTIONS OF FRC
•Oxygen store
•Buffer for maintaining a steady arterial po2
•Partial inflation helps prevent atelectasis
•Minimisethe work of breathing
•Minimisepulmonary vascular resistance
•Minimisedv/q mismatch
-only if closing capacity is less than frc
•Keep airway resistance low (but not minimal
www.anaesthesia.co.in
•Oxygen store
•Buffer for maintaining a steady arterial po2
•Partial inflation helps prevent atelectasis
•Minimisethe work of breathing
•Minimisepulmonary vascular resistance
•Minimisedv/q mismatch
-only if closing capacity is less than frc
•Keep airway resistance low (but not minimal
www.anaesthesia.co.in
Pulmonary Function Tests
•The term encompasses a wide variety of
objective tests to assess lung function
•Provide objective and standardized
measurements for assessing the presence and
severity of respiratory dysfunction.
www.anaesthesia.co.in
•The term encompasses a wide variety of
objective tests to assess lung function
•Provide objective and standardized
measurements for assessing the presence and
severity of respiratory dysfunction.
www.anaesthesia.co.in
GOALS
To predict the presence of pulmonary
dysfunction
To know the functional nature of disease
(obstructive or restrictive. )
To assess the severity of disease
To assess the progression of disease
To assess the response to treatment
To identify patients at increased risk of morbidity
and mortality, undergoing pulmonary resection.
www.anaesthesia.co.in
To predict the presence of pulmonary
dysfunction
To know the functional nature of disease
(obstructive or restrictive. )
To assess the severity of disease
To assess the progression of disease
To assess the response to treatment
To identify patients at increased risk of morbidity
and mortality, undergoing pulmonary resection.
www.anaesthesia.co.in
To wean patient from ventilator in icu.
Medicolegal-to assess lung impairment as a
result of occupational hazard.
Epidemiological surveys-to assess the
hazards to document incidence of disease
To identify patients at perioperative risk of
pulmonary complications
GOALS, CONTINUED……..
www.anaesthesia.co.in
Medicolegal-to assess lung impairment as a
result of occupational hazard.
Epidemiological surveys-to assess the
hazards to document incidence of disease
To identify patients at perioperative risk of
pulmonary complications
GOALS, CONTINUED……..
www.anaesthesia.co.in
INDICATIONS OF PFT IN PAC
TISI GUIDELINES FOR PREOPERATIVE
SPIROMETRY
Age > 70 yrs.
Morbid obesity
Thoracic surgery
Upper abdominal surgery
Smoking history and cough
Any pulomonarydisease
www.anaesthesia.co.in
TISI GUIDELINES FOR PREOPERATIVE
SPIROMETRY
Age > 70 yrs.
Morbid obesity
Thoracic surgery
Upper abdominal surgery
Smoking history and cough
Any pulomonarydisease
www.anaesthesia.co.in
INDICATIONS FOR PREOPERATIVE
SPIROMETRY
•ACP GUIDELINES FOR PREOPERATIVE
SPIROMETRY
Lung resection
H/o smoking, dyspnoea
Cardiac surgery
Upper abdominal surgery
Lower abdominal surgery
Uncharacterized pulmonary disease(defined as
history of pulmonary Disease or symptoms and
no PFT in last 60 days)
www.anaesthesia.co.in
SPIROMETRY
•ACP GUIDELINES FOR PREOPERATIVE
SPIROMETRY
Lung resection
H/o smoking, dyspnoea
Cardiac surgery
Upper abdominal surgery
Lower abdominal surgery
Uncharacterized pulmonary disease(defined as
history of pulmonary Disease or symptoms and
no PFT in last 60 days)
www.anaesthesia.co.in
BED SIDE PFT
1) Sabrasezbreath holding test:
•Ask the patient to take a full but not too deep breath & hold it as
long as possible.
>25 SEC.-NORMAL Cardiopulmonary Reserve (CPR)
15-25 SEC-LIMITED CPR
<15 SEC-VERY POOR CPR (Contraindication for elective surgery)
25-30 SEC -3500 ml VC
20 –25 SEC -3000 ml VC
15 -20 SEC -2500 ml VC
10 -15 SEC -2000 ml VC
5 -10 SEC -1500 ml VC
www.anaesthesia.co.in
1) Sabrasezbreath holding test:
•Ask the patient to take a full but not too deep breath & hold it as
long as possible.
>25 SEC.-NORMAL Cardiopulmonary Reserve (CPR)
15-25 SEC-LIMITED CPR
<15 SEC-VERY POOR CPR (Contraindication for elective surgery)
25-30 SEC -3500 ml VC
20 –25 SEC -3000 ml VC
15 -20 SEC -2500 ml VC
10 -15 SEC -2000 ml VC
5 -10 SEC -1500 ml VC
www.anaesthesia.co.in
BED SIDE PFT
2) Single breath count:
After deep breath, hold it and start counting till the
next breath.
N-30-40 COUNT
Indicates vital capacity
www.anaesthesia.co.in
2) Single breath count:
After deep breath, hold it and start counting till the
next breath.
N-30-40 COUNT
Indicates vital capacity
www.anaesthesia.co.in
BED SIDE PFT
3) SCHNEIDER’S MATCH BLOWING TEST:
MEASURES Maximum Breathing Capacity.
Ask to blow a match stick from a distance of 6”
(15 cms) with-
Mouth wide open
Chin rested/supported
No purse lipping
No head movement
No air movement in the room
Mouth and match at the same level
www.anaesthesia.co.in
3) SCHNEIDER’S MATCH BLOWING TEST:
MEASURES Maximum Breathing Capacity.
Ask to blow a match stick from a distance of 6”
(15 cms) with-
Mouth wide open
Chin rested/supported
No purse lipping
No head movement
No air movement in the room
Mouth and match at the same level
www.anaesthesia.co.in
BED SIDE PFT
•Can not blow out a match
–MBC < 60 L/min
–FEV1 < 1.6L
•Able to blow out a match
–MBC > 60 L/min
–FEV1 > 1.6L
•MODIFIED MATCH TEST:
DISTANCE MBC
9” >150 L/MIN.
6” >60 L/MIN.
3” > 40 L/MIN.
www.anaesthesia.co.in
•Can not blow out a match
–MBC < 60 L/min
–FEV1 < 1.6L
•Able to blow out a match
–MBC > 60 L/min
–FEV1 > 1.6L
•MODIFIED MATCH TEST:
DISTANCE MBC
9” >150 L/MIN.
6” >60 L/MIN.
3” > 40 L/MIN.
www.anaesthesia.co.in
BED SIDE TEST
4) COUGH TEST: DEEP BREATH F/BY COUGH
ABILITY TO COUGH
STRENGTH
EFFECTIVENESS
INADEQUATE COUGH IF: FVC<20 ML/KG
FEV1 < 15 ML/KG
PEFR < 200 L/MIN.
VC ~ 3 TIMES TV FOR EFFECTIVE COUGH.
A wet productive cough / self propagated paraoxysms
of coughing –patient susceptible for pulmonary
Complication.
www.anaesthesia.co.in
4) COUGH TEST: DEEP BREATH F/BY COUGH
ABILITY TO COUGH
STRENGTH
EFFECTIVENESS
INADEQUATE COUGH IF: FVC<20 ML/KG
FEV1 < 15 ML/KG
PEFR < 200 L/MIN.
VC ~ 3 TIMES TV FOR EFFECTIVE COUGH.
A wet productive cough / self propagated paraoxysms
of coughing –patient susceptible for pulmonary
Complication.
www.anaesthesia.co.in
BED SIDE TEST
5) FORCED EXPIRATORY TIME:
After deep breath, exhale maximally and
forcefully & keep stethoscope over trachea &
listen.
N FET –3-5 SECS.
OBS.LUNG DIS. -> 6 SEC
RES. LUNG DIS.-< 3 SEC
www.anaesthesia.co.in
5) FORCED EXPIRATORY TIME:
After deep breath, exhale maximally and
forcefully & keep stethoscope over trachea &
listen.
N FET –3-5 SECS.
OBS.LUNG DIS. -> 6 SEC
RES. LUNG DIS.-< 3 SEC
www.anaesthesia.co.in
BED SIDE PFT
6) WRIGHT PEAK FLOW METER: Measures PEFR (Peak Expiratory Flow
Rate)
N –MALES-450-700 L/MIN.
FEMALES-350-500 L/MIN.
<200 L/ MIN. –INADEQUATE COUGH EFFICIENCY.
7) DEBONO WHISTLE BLOWING TEST: MEASURES PEFR.
Patient blows down a wide bore tube at the end of which is a
whistle, on the side is a hole with adjustable knob.
As subject blows → whistle blows, leak hole is gradually increased
till the intensity of whistle disappears.
At the last position at which the whistle can be blown , the PEFR can
be read off the scale.
www.anaesthesia.co.in
6) WRIGHT PEAK FLOW METER: Measures PEFR (Peak Expiratory Flow
Rate)
N –MALES-450-700 L/MIN.
FEMALES-350-500 L/MIN.
<200 L/ MIN. –INADEQUATE COUGH EFFICIENCY.
7) DEBONO WHISTLE BLOWING TEST: MEASURES PEFR.
Patient blows down a wide bore tube at the end of which is a
whistle, on the side is a hole with adjustable knob.
As subject blows → whistle blows, leak hole is gradually increased
till the intensity of whistle disappears.
At the last position at which the whistle can be blown , the PEFR can
be read off the scale.
www.anaesthesia.co.in
MEASUREMENT OF TV & MV
8)Wright respirometer: measures tv, mv(15 secstimes 4)
•Simple and rapid
•Instrument-compact, light and portable.
•Disadvantage: It under-reads at low flow rates and over-reads at high flow
rates.
•Can be connected to endotrachealtube or face mask
•Prior explanation to patients needed.
•Ideally done in sitting pos.
•MV-instrument record for 1 min. And read directly
•TV-calculated and dividing MV by counting Respiratory Rate.
•Accurate measurement in the range of 3.7-20l/min.(±10%)
•USES: 1)BED SIDE PFT
• 2) ICU –WEANIG PTS. FROM Ventilation.
www.anaesthesia.co.in
8)Wright respirometer: measures tv, mv(15 secstimes 4)
•Simple and rapid
•Instrument-compact, light and portable.
•Disadvantage: It under-reads at low flow rates and over-reads at high flow
rates.
•Can be connected to endotrachealtube or face mask
•Prior explanation to patients needed.
•Ideally done in sitting pos.
•MV-instrument record for 1 min. And read directly
•TV-calculated and dividing MV by counting Respiratory Rate.
•Accurate measurement in the range of 3.7-20l/min.(±10%)
•USES: 1)BED SIDE PFT
• 2) ICU –WEANIG PTS. FROM Ventilation.
www.anaesthesia.co.in
DEBONO’S WHISTLE
www.anaesthesia.co.in
www.anaesthesia.co.in
BED SIDE PFT
9) MICROSPIROMETERS –MEASURE VC.
10) BED SIDE PULSE OXIMETRY
11) ABG.
www.anaesthesia.co.in
9) MICROSPIROMETERS –MEASURE VC.
10) BED SIDE PULSE OXIMETRY
11) ABG.
www.anaesthesia.co.in
CATEGORIZATION OF PFT
1)MECHANICAL VENTILATORY FUNCTIONS OF
LUNG / CHEST WALL:
A) STATIC LUNG VOLUMES & CAPACITIES –VC, IC, IRV,
ERV, RV, FRC.
B)DYNAMIC LUNG VOLUMES –FVC, FEV1, FEF 25-75%,
PEFR, MVV, RESP. MUSCLE STRENGTH
C)VENTILATION TESTS –TV, MV, RR.
www.anaesthesia.co.in
1)MECHANICAL VENTILATORY FUNCTIONS OF
LUNG / CHEST WALL:
A) STATIC LUNG VOLUMES & CAPACITIES –VC, IC, IRV,
ERV, RV, FRC.
B)DYNAMIC LUNG VOLUMES –FVC, FEV1, FEF 25-75%,
PEFR, MVV, RESP. MUSCLE STRENGTH
C)VENTILATION TESTS –TV, MV, RR.
www.anaesthesia.co.in
CATEGORIZATION OF PFT
2) GAS-EXCHANGE TESTS:
A) Alveolar-arterial po2 gradient
B) Diffusion capacity
C) Gas distribution tests-single breath
N
2test.
-Multiple Breath N
2test
-Helium dilution method.
-Radio Xescinitigram.
D) ventilation –perfusion tests
A) ABG
B) single breath CO
2elimination test
C) Shunt equation
www.anaesthesia.co.in
2) GAS-EXCHANGE TESTS:
A) Alveolar-arterial po2 gradient
B) Diffusion capacity
C) Gas distribution tests-single breath
N
2test.
-Multiple Breath N
2test
-Helium dilution method.
-Radio Xescinitigram.
D) ventilation –perfusion tests
A) ABG
B) single breath CO
2elimination test
C) Shunt equation
www.anaesthesia.co.in
CATEGORIZATION OF PFT
3) CARDIOPULMONARY INTERACTION:
A) Qualitative tests:
-History , examination
-Abg
-Stair climbing test
B) Quantitative tests
-6 min. Walk test (gold standard)
www.anaesthesia.co.in
3) CARDIOPULMONARY INTERACTION:
A) Qualitative tests:
-History , examination
-Abg
-Stair climbing test
B) Quantitative tests
-6 min. Walk test (gold standard)
www.anaesthesia.co.in
STATIC LUNG VOLUMES AND
CAPACITIES
•SPIROMETRY : CORNERSTONE OF ALL
PFTs.
•John hutchinson –invented spirometer.
•“Spirometry is a medical test that
measures the volume of air an individual
inhales or exhales as a function of time.”
•Measures VC, FVC, FEV1, PEFR.
•CAN’T MEASURE –FRC, RV, TLC.
www.anaesthesia.co.in
CAPACITIES
•SPIROMETRY : CORNERSTONE OF ALL
PFTs.
•John hutchinson –invented spirometer.
•“Spirometry is a medical test that
measures the volume of air an individual
inhales or exhales as a function of time.”
•Measures VC, FVC, FEV1, PEFR.
•CAN’T MEASURE –FRC, RV, TLC.
www.anaesthesia.co.in
PREREQUISITIES
•Prior explanation to the patient
•Not to smoke /inhale bronchodilators 6 hrs
prior or oral bronchodilators 12hrs prior.
•Remove any tight clothings/ waist belt/
dentures
•Pt. Seated comfortably
If obese, child < 12 yrs-standing
www.anaesthesia.co.in
•Prior explanation to the patient
•Not to smoke /inhale bronchodilators 6 hrs
prior or oral bronchodilators 12hrs prior.
•Remove any tight clothings/ waist belt/
dentures
•Pt. Seated comfortably
If obese, child < 12 yrs-standing
www.anaesthesia.co.in
PREREQUISITES
•Nose clip to close nostrils.
•Exp. Effort shld last ≥ 4 secs.
•Should not be interfered by coughing, glottic
closure, mechanical obstruction.
•3 acceptable tracings taken & largest value is
used.
www.anaesthesia.co.in
•Nose clip to close nostrils.
•Exp. Effort shld last ≥ 4 secs.
•Should not be interfered by coughing, glottic
closure, mechanical obstruction.
•3 acceptable tracings taken & largest value is
used.
www.anaesthesia.co.in
SPIROMETER
•Double walled cylinder with water to maintain
water tight seal
•Inverted bell (9 l) attached to pulley which
carries a counterweight and pen –moves up
and down as volume of bell changes
•BREATHING ASSEMBLY i.E. Unidirectional
breathing valves with mouth piece.
www.anaesthesia.co.in
•Double walled cylinder with water to maintain
water tight seal
•Inverted bell (9 l) attached to pulley which
carries a counterweight and pen –moves up
and down as volume of bell changes
•BREATHING ASSEMBLY i.E. Unidirectional
breathing valves with mouth piece.
www.anaesthesia.co.in
Flow-Volume Curves and Spirograms
•Two ways to record results of FVC maneuver:
–Flow-volume curve---flow meter measures flow
rate in L/s upon exhalation; flow plotted as
function of volume
–Classic spirogram---volume as a function of time
www.anaesthesia.co.in
•Two ways to record results of FVC maneuver:
–Flow-volume curve---flow meter measures flow
rate in L/s upon exhalation; flow plotted as
function of volume
–Classic spirogram---volume as a function of time
www.anaesthesia.co.in
Normal Flow-Volume Curve and
Spirogram
www.anaesthesia.co.in
Spirogram
www.anaesthesia.co.in
Spirometry Interpretation: So what
constitutes normal?
•Normal values vary and depend on:
–Height
–Age
–Gender
–Ethnicity
www.anaesthesia.co.in
constitutes normal?
•Normal values vary and depend on:
–Height
–Age
–Gender
–Ethnicity
www.anaesthesia.co.in
Acceptable and Unacceptable
Spirograms (from ATS, 1994)
www.anaesthesia.co.in
Spirograms (from ATS, 1994)
www.anaesthesia.co.in
Measurements Obtained from the FVC
Curve
•FEV
1---the volume exhaled during the first second of the FVC
maneuver
•FEF 25-75%---the mean expiratory flow during the middle half
of the FVC maneuver; reflects flow through the small (<2 mm
in diameter) airways
•FEV
1/FVC---the ratio of FEV1 to FVC X 100 (expressed as a
percent); an important value because a reduction of this ratio
from expected values is specific for obstructive rather than
restrictive diseases
www.anaesthesia.co.in
Curve
•FEV
1---the volume exhaled during the first second of the FVC
maneuver
•FEF 25-75%---the mean expiratory flow during the middle half
of the FVC maneuver; reflects flow through the small (<2 mm
in diameter) airways
•FEV
1/FVC---the ratio of FEV1 to FVC X 100 (expressed as a
percent); an important value because a reduction of this ratio
from expected values is specific for obstructive rather than
restrictive diseases
www.anaesthesia.co.in
Spirometry Interpretation: Obstructive
vs. Restrictive Defect
•Obstructive Disorders
–Characterized by a limitation
of expiratory airflow so that
airways cannot empty as
rapidly compared to normal
(such as through narrowed
airways from bronchospasm,
inflammation, etc.)
Examples:
–Asthma
–Emphysema
–Cystic Fibrosis
•Restrictive Disorders
–Characterized by reduced
lung volumes/decreased lung
compliance
Examples:
–Interstitial Fibrosis
–Scoliosis
–Obesity
–Lung Resection
–Neuromuscular diseases
–Cystic Fibrosis
www.anaesthesia.co.in
vs. Restrictive Defect
•Obstructive Disorders
–Characterized by a limitation
of expiratory airflow so that
airways cannot empty as
rapidly compared to normal
(such as through narrowed
airways from bronchospasm,
inflammation, etc.)
Examples:
–Asthma
–Emphysema
–Cystic Fibrosis
•Restrictive Disorders
–Characterized by reduced
lung volumes/decreased lung
compliance
Examples:
–Interstitial Fibrosis
–Scoliosis
–Obesity
–Lung Resection
–Neuromuscular diseases
–Cystic Fibrosis
www.anaesthesia.co.in
Normal vs. Obstructive vs. Restrictive
(Hyatt,
2003)
www.anaesthesia.co.in
(Hyatt,
2003)
www.anaesthesia.co.in
Spirometry Interpretation: Obstructive
vs. Restrictive Defect
•Obstructive Disorders
–FVC nl or↓
–FEV1 ↓
–FEF25-75% ↓
–FEV1/FVC ↓
–TLC nl or ↑
•Restrictive Disorders
–FVC ↓
–FEV1 ↓
–FEF 25-75% nl to ↓
–FEV1/FVC nl to ↑
–TLC ↓
www.anaesthesia.co.in
vs. Restrictive Defect
•Obstructive Disorders
–FVC nl or↓
–FEV1 ↓
–FEF25-75% ↓
–FEV1/FVC ↓
–TLC nl or ↑
•Restrictive Disorders
–FVC ↓
–FEV1 ↓
–FEF 25-75% nl to ↓
–FEV1/FVC nl to ↑
–TLC ↓
www.anaesthesia.co.in
Spirometry Interpretation: What do the
numbers mean?
•FVC
•Interpretation of %
predicted:
–80-120% Normal
–70-79%Mild reduction
–50%-69% Moderate reduction
–<50% Severe reduction
FEV1
Interpretation of % predicted:
–>75% Normal
–60%-75% Mild obstruction
–50-59% Moderate obstruction
–<49% Severe obstruction
•<25 y.o. add 5% and >60 y.o.
subtract 5
www.anaesthesia.co.in
numbers mean?
•FVC
•Interpretation of %
predicted:
–80-120% Normal
–70-79%Mild reduction
–50%-69% Moderate reduction
–<50% Severe reduction
FEV1
Interpretation of % predicted:
–>75% Normal
–60%-75% Mild obstruction
–50-59% Moderate obstruction
–<49% Severe obstruction
•<25 y.o. add 5% and >60 y.o.
subtract 5
www.anaesthesia.co.in
Spirometry Interpretation: What do the
numbers mean?
•FEF 25-75%
•Interpretation of %
predicted:
–>79% Normal
–60-79%Mild
obstruction
–40-59%Moderate
obstruction
–<40% Severe obstruction
•FEV1/FVC
•Interpretation of
absolutevalue:
–80 or higher
Normal
–79 or lower
Abnormal
www.anaesthesia.co.in
numbers mean?
•FEF 25-75%
•Interpretation of %
predicted:
–>79% Normal
–60-79%Mild
obstruction
–40-59%Moderate
obstruction
–<40% Severe obstruction
•FEV1/FVC
•Interpretation of
absolutevalue:
–80 or higher
Normal
–79 or lower
Abnormal
www.anaesthesia.co.in
What about lung volumes and obstructive
and restrictive disease?
(From Ruppel,
2003)
www.anaesthesia.co.in
and restrictive disease?
(From Ruppel,
2003)
www.anaesthesia.co.in
MEASUREMENTS OF VOLUMES
•TLC, RV, FRC –MEASURED USING
Nitrogen washout method
Inert gas (helium) dilution method
Total body plethysmography
www.anaesthesia.co.in
•TLC, RV, FRC –MEASURED USING
Nitrogen washout method
Inert gas (helium) dilution method
Total body plethysmography
www.anaesthesia.co.in
CONTINUED………..
1) HELIUM DILUTION METHOD:
Patient breathes in and out of a spirometerfilled with 10%
helium and 90% o2, till conc. In spirometerand lung
becomes same (equilibirium).
As no helium is lost; (as he is insoluble in blood)
C1 X V1 = C2 ( V1 + V2)
V2 = V1 ( C1 –C2)
C2
V1= VOL. OF SPIROMETER
V2= FRC
C1= Conc.ofHe in the spirometerbefore equilibrium
C2 = Conc, of He in the spirometerafter equilibrium
www.anaesthesia.co.in
1) HELIUM DILUTION METHOD:
Patient breathes in and out of a spirometerfilled with 10%
helium and 90% o2, till conc. In spirometerand lung
becomes same (equilibirium).
As no helium is lost; (as he is insoluble in blood)
C1 X V1 = C2 ( V1 + V2)
V2 = V1 ( C1 –C2)
C2
V1= VOL. OF SPIROMETER
V2= FRC
C1= Conc.ofHe in the spirometerbefore equilibrium
C2 = Conc, of He in the spirometerafter equilibrium
www.anaesthesia.co.in
CONTINUED………
2) TOTAL BODY PLETHYSMOGRAPHY:
Subject sits in an air tight box. At the end of normal exhalation –shuttle of
mouthpiece closed and pt. is asked to make resp. efforts. As subject
inhales –expands gas volume in the lung so lung vol. increases and box
pressure rises and box vol. decreases.
BOYLE’S LAW:
PV = CONSTANT (at constant temp.)
For Box –p1v1 = p2 (v1-∆v)
For Subject –p3 x v2 =p4 (v2 -∆v)
P1-initial box pr. P2-final box pr.
V1-initial box vol. ∆ v-change in box vol.
P3-initial mouth pr., p4-final mouth pr.
V2-FRC
www.anaesthesia.co.in
2) TOTAL BODY PLETHYSMOGRAPHY:
Subject sits in an air tight box. At the end of normal exhalation –shuttle of
mouthpiece closed and pt. is asked to make resp. efforts. As subject
inhales –expands gas volume in the lung so lung vol. increases and box
pressure rises and box vol. decreases.
BOYLE’S LAW:
PV = CONSTANT (at constant temp.)
For Box –p1v1 = p2 (v1-∆v)
For Subject –p3 x v2 =p4 (v2 -∆v)
P1-initial box pr. P2-final box pr.
V1-initial box vol. ∆ v-change in box vol.
P3-initial mouth pr., p4-final mouth pr.
V2-FRC
www.anaesthesia.co.in
CONTINUED………
DIFFERENCE BETWEEN THE TWO METHODS:
•In healthy people there is very little difference.
•Gas dilution technique measures only the
communicating gas volume.
•Thus,
•Gas trapped behind closed airways
•Gas in pneumothorax
•=> are not measured by gas dilution technique,
but measured by body plethysmograph
www.anaesthesia.co.in
DIFFERENCE BETWEEN THE TWO METHODS:
•In healthy people there is very little difference.
•Gas dilution technique measures only the
communicating gas volume.
•Thus,
•Gas trapped behind closed airways
•Gas in pneumothorax
•=> are not measured by gas dilution technique,
but measured by body plethysmograph
www.anaesthesia.co.in
CONTINUED………
3) N2 WASH OUT METHOD:
•Following a maximal expiration (RV) or normal expiration (FRC), Pt.
inspires 100% O2 and then expires it into spirometer( free of N2)
→ over next few minutes (usually 6-7 min.), till all the N2 is washed
out of the lungs. N2 conc. of spirometeris calculated followed by
total vol.ofAIR exhaled. As air has 80% N2 → so actual FRC/RV is
calculated.
•E.g. Total vol. collected = 50 L (as N2 makes 80% of FRC on
•room air)
• Measured N2 = 5%
• vol. of N2 in bag = 50 x .05 = 2.5L
• 2.5 L = X L
• .80 FRC 1 FRC
• X = 3.125 l (THIS IS PT’S FRC)
www.anaesthesia.co.in
3) N2 WASH OUT METHOD:
•Following a maximal expiration (RV) or normal expiration (FRC), Pt.
inspires 100% O2 and then expires it into spirometer( free of N2)
→ over next few minutes (usually 6-7 min.), till all the N2 is washed
out of the lungs. N2 conc. of spirometeris calculated followed by
total vol.ofAIR exhaled. As air has 80% N2 → so actual FRC/RV is
calculated.
•E.g. Total vol. collected = 50 L (as N2 makes 80% of FRC on
•room air)
• Measured N2 = 5%
• vol. of N2 in bag = 50 x .05 = 2.5L
• 2.5 L = X L
• .80 FRC 1 FRC
• X = 3.125 l (THIS IS PT’S FRC)
www.anaesthesia.co.in
PROBLEMS WITH N2 WASH OUT
METHOD
•Atelectasismay result from washout of
nitrogen from poorly ventilated lung zones
(obstructed areas)
•Elimination of hypoxic drive in CO
2retainers
is possible
•Underestimates FRC due to underventilation
of areas with trapped gas
www.anaesthesia.co.in
METHOD
•Atelectasismay result from washout of
nitrogen from poorly ventilated lung zones
(obstructed areas)
•Elimination of hypoxic drive in CO
2retainers
is possible
•Underestimates FRC due to underventilation
of areas with trapped gas
www.anaesthesia.co.in
MEASUREMENT OF DYNAMIC LUNG
VOLUMES
•TIMED EXPIRED SPIROGRAMS
www.anaesthesia.co.in
FEF
25–75%= forced
expiratory flow during
expiration of 25 to 75% of
the FVC; FEV
1= forced
expiratory volume in the
first second of forced vital
capacity maneuver; FVC =
forced vital capacity (the
maximum amount of air
forcibly expired after
maximum inspiration).
VOLUMES
•TIMED EXPIRED SPIROGRAMS
www.anaesthesia.co.in
FEF
25–75%= forced
expiratory flow during
expiration of 25 to 75% of
the FVC; FEV
1= forced
expiratory volume in the
first second of forced vital
capacity maneuver; FVC =
forced vital capacity (the
maximum amount of air
forcibly expired after
maximum inspiration).
FORCED VITAL CAPACITY (FVC)
Max vol. Of air which can be expired out as forcefully and
rapidly as possible, following a maximal inspiration to
TLC.
Exhaled volume is recorded with respect to time.
Indirectly reflects flow resistance property of airways.
Normal healthy subjects have VC = FVC.
Prior instruction to patients, practice attempts as it
needs patient cooperation and effect.
Exhalation should take at least 4 sec and should not be
interrupted by cough, glotticclosure or mechanical
obstruction.
www.anaesthesia.co.in
Max vol. Of air which can be expired out as forcefully and
rapidly as possible, following a maximal inspiration to
TLC.
Exhaled volume is recorded with respect to time.
Indirectly reflects flow resistance property of airways.
Normal healthy subjects have VC = FVC.
Prior instruction to patients, practice attempts as it
needs patient cooperation and effect.
Exhalation should take at least 4 sec and should not be
interrupted by cough, glotticclosure or mechanical
obstruction.
www.anaesthesia.co.in
FORCED VITAL CAPACITY IN 1 SEC.
(FEV1)
Forced expired vol. In 1 sec during fvc
maneuver.
Expressed as an absolute value or % of fvc.
N-FEV1 (1 SEC)-75-85% OF FVC
FEV2 (2 SEC)-94% OF FVC
FEV3 (3 SEC)-97% OF FVC
www.anaesthesia.co.in
(FEV1)
Forced expired vol. In 1 sec during fvc
maneuver.
Expressed as an absolute value or % of fvc.
N-FEV1 (1 SEC)-75-85% OF FVC
FEV2 (2 SEC)-94% OF FVC
FEV3 (3 SEC)-97% OF FVC
www.anaesthesia.co.in
CONTINUED……
CLINICAL RANGE (FEV1)
• 3 -4.5 L
• 1.5 –2.5 L
• <1 L
• 0.8 L
• 0.5 L
PATIENT GROUP
•NORMAL ADULT
•MILD –MOD.OBSTRUCTION
•HANDICAPPED
•DISABILITY
•SEVERE EMPHYSEMA
www.anaesthesia.co.in
CLINICAL RANGE (FEV1)
• 3 -4.5 L
• 1.5 –2.5 L
• <1 L
• 0.8 L
• 0.5 L
PATIENT GROUP
•NORMAL ADULT
•MILD –MOD.OBSTRUCTION
•HANDICAPPED
•DISABILITY
•SEVERE EMPHYSEMA
www.anaesthesia.co.in
CONTINUED……
FEV1 –Decreased in both obstructive &
restrictive lung disorders.
FEV1/FVC –Reduced in obstructive disorders.
NORMAL VALUE IS 75 –85 % (FEV1/FVC)
< 70% OF PREDICTED VALUE –MILD OBST.
< 60% OF PREDICTED VALUE –MODERATE OBST.
< 50% OF PREDICTED VALUE –SEVERE OBST.
www.anaesthesia.co.in
FEV1 –Decreased in both obstructive &
restrictive lung disorders.
FEV1/FVC –Reduced in obstructive disorders.
NORMAL VALUE IS 75 –85 % (FEV1/FVC)
< 70% OF PREDICTED VALUE –MILD OBST.
< 60% OF PREDICTED VALUE –MODERATE OBST.
< 50% OF PREDICTED VALUE –SEVERE OBST.
www.anaesthesia.co.in
CONTINUED……
DISEASE STATES FVC FEV1 FEV1/FVC
1)OBSTRUCTIVE NORMAL ↓ ↓
2) STIFF LUNGS ↓ ↓ NORMAL
3 ) RESP. MUSCLE
WEAKNESS
↓ ↓ NORMAL
www.anaesthesia.co.in
DISEASE STATES FVC FEV1 FEV1/FVC
1)OBSTRUCTIVE NORMAL ↓ ↓
2) STIFF LUNGS ↓ ↓ NORMAL
3 ) RESP. MUSCLE
WEAKNESS
↓ ↓ NORMAL
www.anaesthesia.co.in
PEAK EXPIRATORY FLOW RATE (PEFR)
-It is the max. Flow rate during fvcmaneuver in the initial 0.1
sec.
-PEFR DETERMINED BY : 1) Function of caliber of airways
2) Expiratory muscle strength
3) Pt’s coordination & effort
-Estimated by 1) drawing a tangent to steepest part of FVC
spirogram(error prone)
2) average flow during the litreof gas expired after
initial 200 ml during fvcmaneuver.
-.
www.anaesthesia.co.in
-It is the max. Flow rate during fvcmaneuver in the initial 0.1
sec.
-PEFR DETERMINED BY : 1) Function of caliber of airways
2) Expiratory muscle strength
3) Pt’s coordination & effort
-Estimated by 1) drawing a tangent to steepest part of FVC
spirogram(error prone)
2) average flow during the litreof gas expired after
initial 200 ml during fvcmaneuver.
-.
www.anaesthesia.co.in
-Normal value in young adults (<40 yrs)= 500l/min
-Measured with pneumotachograph / Wright peak flow
meter
-Wright peak flow meter -valuable tool in identifying
gross pulmonary Disability at bedside.
-Less unpleasant & less
Exhaustive
-Clinical significance -values of <200/l-impaired
coughing & hence likelihood of post-op complication
www.anaesthesia.co.in
-Measured with pneumotachograph / Wright peak flow
meter
-Wright peak flow meter -valuable tool in identifying
gross pulmonary Disability at bedside.
-Less unpleasant & less
Exhaustive
-Clinical significance -values of <200/l-impaired
coughing & hence likelihood of post-op complication
www.anaesthesia.co.in
FORCED MID-EXPIRATORY FLOW RATE
(FEF25%-75%):
•Maximum Mid expiratory Flow rate
•Max. Flow rate during the mid-expiratory part of FVC maneuver.
•Effort independent
•Misnomer, as FEF
25-75%decreased by
1) marked reduction in exp. Effort
2)submaximalinspiration b4 maneuver → ↓FVC → ↓ FEF
25-
75%
•It may decrease with truly max. Effort as compared to slightly
submaximaleffort as dynamic airway compression occurs with
maximal effort.
•N value –4.5-5 l/sec. Or 300 l/min.
•Upto2l/sec-acceptable.
•CLINICAL SIGNIFICANCE: SENSITIVE & IST INDICATOR OF
OBSTRUCTION OF SMALL DISTAL AIRWAYS
www.anaesthesia.co.in
(FEF25%-75%):
•Maximum Mid expiratory Flow rate
•Max. Flow rate during the mid-expiratory part of FVC maneuver.
•Effort independent
•Misnomer, as FEF
25-75%decreased by
1) marked reduction in exp. Effort
2)submaximalinspiration b4 maneuver → ↓FVC → ↓ FEF
25-
75%
•It may decrease with truly max. Effort as compared to slightly
submaximaleffort as dynamic airway compression occurs with
maximal effort.
•N value –4.5-5 l/sec. Or 300 l/min.
•Upto2l/sec-acceptable.
•CLINICAL SIGNIFICANCE: SENSITIVE & IST INDICATOR OF
OBSTRUCTION OF SMALL DISTAL AIRWAYS
www.anaesthesia.co.in
MAXIMUM BREATHING CAPACITY:
(MBC/MVV)
•MAX. VOLUNTARY VENTILATION
Largest volume that can be breathed per minute by voluntary
effort , as hard & as fast as possible.
N –150-175 l/min.
Estimate of max. Ventilation available to meet increased
physiological demand.
Measured for 12 secs –extrapolated for 1 min.
MVV = FEV1 X 35
www.anaesthesia.co.in
(MBC/MVV)
•MAX. VOLUNTARY VENTILATION
Largest volume that can be breathed per minute by voluntary
effort , as hard & as fast as possible.
N –150-175 l/min.
Estimate of max. Ventilation available to meet increased
physiological demand.
Measured for 12 secs –extrapolated for 1 min.
MVV = FEV1 X 35
www.anaesthesia.co.in
CONTINUED…….
•Discrepancy b/w FEV1 and MVV means inconsistent /
submaximal inspiratory effort
•MBC/MVV altered by-airway resistance
-Elastic property
-Muscle strength
-Learning
-Coordination
-Motivation
www.anaesthesia.co.in
•Discrepancy b/w FEV1 and MVV means inconsistent /
submaximal inspiratory effort
•MBC/MVV altered by-airway resistance
-Elastic property
-Muscle strength
-Learning
-Coordination
-Motivation
www.anaesthesia.co.in
RESPIRATORY MUSCLE STRENGTH
Evaluated by measuring max. Static resp. Pressure with
anaeroidgauge
•Pressures are generated against occluded airway
during a max. Forced insp/exp. Effort
MAX STATIC INSP. PRESSURE: (PIMAX)-
•Measured when inspiratorymuscles are at their
optimal length i.e. at RV
•PI MAX = -125 CM H2O
•CLINICAL SIGNIFICANCE:
IF PI MAX< 25 CM H2O –Inability to take deep breath.
www.anaesthesia.co.in
Evaluated by measuring max. Static resp. Pressure with
anaeroidgauge
•Pressures are generated against occluded airway
during a max. Forced insp/exp. Effort
MAX STATIC INSP. PRESSURE: (PIMAX)-
•Measured when inspiratorymuscles are at their
optimal length i.e. at RV
•PI MAX = -125 CM H2O
•CLINICAL SIGNIFICANCE:
IF PI MAX< 25 CM H2O –Inability to take deep breath.
www.anaesthesia.co.in
CONTINUED…….
•MAX. STATIC EXPIRATORY PRESSURE (PEMAX):
Measured after full inspiration to TLC
N VALUE OF PEMAX IS =200 CM H20
PEMAX < +40 CM H20 –Impaired cough ability
Particularly useful in pts with NM Disorders during
weaning
www.anaesthesia.co.in
•MAX. STATIC EXPIRATORY PRESSURE (PEMAX):
Measured after full inspiration to TLC
N VALUE OF PEMAX IS =200 CM H20
PEMAX < +40 CM H20 –Impaired cough ability
Particularly useful in pts with NM Disorders during
weaning
www.anaesthesia.co.in
PHYSIOLOGICAL DETERMINANTS OF
MAX. FLOW RATES
1)DEGREE OF EFFORT-driving pressure generated by muscle
contraction (PEmax& PI max)
2)ELASTIC RECOIL PRESSURE OF LUNG: (PL)
Tendency to recoil or collapse d/t PL
PL increases from RV (2-3) to TLC (20-30)
Opposed by Pcw(recoil pr. Of chest wall)
Prs=Pl + Pcw= 0 at FRC-resting state
(Prs-recoil pr.ofresp.system)
3) AIRWAY RESISTANCE: (Raw):
Determined by the calibreof airways
Decreases as lung volincreases (hyperbolic curve)
Raw high at RV & low at TLC
www.anaesthesia.co.in
MAX. FLOW RATES
1)DEGREE OF EFFORT-driving pressure generated by muscle
contraction (PEmax& PI max)
2)ELASTIC RECOIL PRESSURE OF LUNG: (PL)
Tendency to recoil or collapse d/t PL
PL increases from RV (2-3) to TLC (20-30)
Opposed by Pcw(recoil pr. Of chest wall)
Prs=Pl + Pcw= 0 at FRC-resting state
(Prs-recoil pr.ofresp.system)
3) AIRWAY RESISTANCE: (Raw):
Determined by the calibreof airways
Decreases as lung volincreases (hyperbolic curve)
Raw high at RV & low at TLC
www.anaesthesia.co.in
Continued……
DISEASE MSL. STRENGTH Raw PL
N-M WEAKNESS ↓ N N
EMPHYSEMA N N ↓
ASTHMA/BRONCHI
TIS
N ↑ N
PERIPHERAL
AIRWAY DIS.
N N N
www.anaesthesia.co.in
DISEASE MSL. STRENGTH Raw PL
N-M WEAKNESS ↓ N N
EMPHYSEMA N N ↓
ASTHMA/BRONCHI
TIS
N ↑ N
PERIPHERAL
AIRWAY DIS.
N N N
www.anaesthesia.co.in
MEASUREMENT OF AIRWAY
RESISTANCE
1) Raw-Body plethysmography
2) Forced expiratory maneuvers:
Peak expiratory flow (PEF)
FEV1
3) Response to bronchodialtors (FEV1)
www.anaesthesia.co.in
RESISTANCE
1) Raw-Body plethysmography
2) Forced expiratory maneuvers:
Peak expiratory flow (PEF)
FEV1
3) Response to bronchodialtors (FEV1)
www.anaesthesia.co.in
Spirometry Pre and Post Bronchodilator
•Obtain a flow-volume loop.
•Administer a bronchodilator.
•Obtain the flow-volume loop again a minimum of 15
minutes after administration of the bronchodilator.
•Calculate percent change (FEV1 most commonly
used---so % change FEV 1= [(FEV1 Post-FEV1
Pre)/FEV1 Pre] X 100).
•Reversibility is with 12% or greater change.
www.anaesthesia.co.in
•Obtain a flow-volume loop.
•Administer a bronchodilator.
•Obtain the flow-volume loop again a minimum of 15
minutes after administration of the bronchodilator.
•Calculate percent change (FEV1 most commonly
used---so % change FEV 1= [(FEV1 Post-FEV1
Pre)/FEV1 Pre] X 100).
•Reversibility is with 12% or greater change.
www.anaesthesia.co.in
AIRWAY PARTITIONING AND
BEHAVIOUUR
•UPPER (EXTRATHORACIC)
Surrounding soft tissue unsupporting
Collapses during inspiration
Expands during expiration
•INTRATHORACIC
Outer surface exposed to pleural pressure
Expands during inspiration
Collapses during expiration
•DISTAL (PULMONARY)
Intimately related to lung tissue
Collapses as expiration proceeds
www.anaesthesia.co.in
BEHAVIOUUR
•UPPER (EXTRATHORACIC)
Surrounding soft tissue unsupporting
Collapses during inspiration
Expands during expiration
•INTRATHORACIC
Outer surface exposed to pleural pressure
Expands during inspiration
Collapses during expiration
•DISTAL (PULMONARY)
Intimately related to lung tissue
Collapses as expiration proceeds
www.anaesthesia.co.in
FLOW VOLUME LOOPS
•Do FVC maneuver and then inhale as rapidly
and as much as able.
•This makes an inspiratory curve.
•The expiratory and inspiratory flow volume
curves put together make a flow volume loop.
www.anaesthesia.co.in
•Do FVC maneuver and then inhale as rapidly
and as much as able.
•This makes an inspiratory curve.
•The expiratory and inspiratory flow volume
curves put together make a flow volume loop.
www.anaesthesia.co.in
Flow-Volume Loops
(Rudolph and
Rudolph, 2003)
www.anaesthesia.co.in
(Rudolph and
Rudolph, 2003)
www.anaesthesia.co.in
How is a flow-volume loop helpful?
•Helpful in evaluation of air flow limitation on inspiration and
expiration
•In addition to obstructive and restrictive patterns, flow-
volume loops can show provide information on upper airway
obstruction:
–Fixed obstruction: constant airflow limitation on inspiration and
expiration—such as in tumor, tracheal stenosis
–Variable extrathoracic obstruction: limitation of inspiratory flow,
flattened inspiratory loop—such as in vocal cord dysfunction
–Variable intrathoracic obstruction: flattening of expiratory limb; as in
malignancy or tracheomalacia
www.anaesthesia.co.in
•Helpful in evaluation of air flow limitation on inspiration and
expiration
•In addition to obstructive and restrictive patterns, flow-
volume loops can show provide information on upper airway
obstruction:
–Fixed obstruction: constant airflow limitation on inspiration and
expiration—such as in tumor, tracheal stenosis
–Variable extrathoracic obstruction: limitation of inspiratory flow,
flattened inspiratory loop—such as in vocal cord dysfunction
–Variable intrathoracic obstruction: flattening of expiratory limb; as in
malignancy or tracheomalacia
www.anaesthesia.co.in
TESTS FOR GAS EXCHANGE FUNCTION
1) ALVEOLAR-ARTERIAL O2 TENSION GRADIENT:
Sensitive indicator of detecting regional V/Q inequality
N value in young adult at room air = 8 mmhgto upto
25 mmhgin 8
th
decade (d/t decrease in PaO2)
AbNhigh values at room air is seen in asymptomatic
smokers & chr. Bronchitis (min. symptoms)
PAO2 = PIO2 –PaCo2
R
www.anaesthesia.co.in
1) ALVEOLAR-ARTERIAL O2 TENSION GRADIENT:
Sensitive indicator of detecting regional V/Q inequality
N value in young adult at room air = 8 mmhgto upto
25 mmhgin 8
th
decade (d/t decrease in PaO2)
AbNhigh values at room air is seen in asymptomatic
smokers & chr. Bronchitis (min. symptoms)
PAO2 = PIO2 –PaCo2
R
www.anaesthesia.co.in
CONTINUED……..
2) DYSPNEA DIFFENRENTIATION INDEX (DDI):
-To d/f dyspnea due to resp/ cardiac d’s
DDI = PEFR x PaCO2
1000
-DDI-Lower in resp. pathology
www.anaesthesia.co.in
2) DYSPNEA DIFFENRENTIATION INDEX (DDI):
-To d/f dyspnea due to resp/ cardiac d’s
DDI = PEFR x PaCO2
1000
-DDI-Lower in resp. pathology
www.anaesthesia.co.in
CONTINUED……
3) DIFFUSING CAPACITY OF LUNG: defined as the
rate at which gas enters into bld. divided by its
driving pr.
DRIVING PR: gradient b/w alveoli & end capillary
tensions.
Fick’slaw of diffusion : Vgas= Ax D x (P1-P2)
T
D= diffusion coeff= solubility
√MW
www.anaesthesia.co.in
3) DIFFUSING CAPACITY OF LUNG: defined as the
rate at which gas enters into bld. divided by its
driving pr.
DRIVING PR: gradient b/w alveoli & end capillary
tensions.
Fick’slaw of diffusion : Vgas= Ax D x (P1-P2)
T
D= diffusion coeff= solubility
√MW
www.anaesthesia.co.in
CONTINUED…….
•DL IS MEASURED BY USING CO, COZ:
A)High affinity for Hbwhich is approx. 200
times that of O2 , so does not rapidly build
up in plasma
B)Under N condition it has low bldconc≈ 0
C)Therefore, pulmconc.≈0
www.anaesthesia.co.in
•DL IS MEASURED BY USING CO, COZ:
A)High affinity for Hbwhich is approx. 200
times that of O2 , so does not rapidly build
up in plasma
B)Under N condition it has low bldconc≈ 0
C)Therefore, pulmconc.≈0
www.anaesthesia.co.in
SINGLE BREATH TEST USING CO
•Pt inspires a dilute mixture of CO and hold the
breath for 10 secs.
•CO taken up is determined by infrared
analysis:
• DlCO = CO ml/min/mmhg
• PACO –PcCO
•N range 20-30 ml/min./mmhg.
•DLO2 = DLCO x 1.23
www.anaesthesia.co.in
•Pt inspires a dilute mixture of CO and hold the
breath for 10 secs.
•CO taken up is determined by infrared
analysis:
• DlCO = CO ml/min/mmhg
• PACO –PcCO
•N range 20-30 ml/min./mmhg.
•DLO2 = DLCO x 1.23
www.anaesthesia.co.in
DLCO decreases in-
•Emphysema, lung resection, pul. Embolism, anaemia
•Pulmonary fibrosis, sarcoidosis-increased thickness
•DLCO increases in:
(Cond. Which increase pulm, bldflow)
Supine position
Exercise
Obesity
L-R shunt
www.anaesthesia.co.in
•Emphysema, lung resection, pul. Embolism, anaemia
•Pulmonary fibrosis, sarcoidosis-increased thickness
•DLCO increases in:
(Cond. Which increase pulm, bldflow)
Supine position
Exercise
Obesity
L-R shunt
www.anaesthesia.co.in
TESTS FOR CARDIOPLULMONARY
INTERACTIONS
•Reflects gas exchange, ventilation, tissue O2,
CO.
•QUALITATIVE-history, exam, ABG, stair
climbing test
•QUANTITATIVE-6 minute walk test
www.anaesthesia.co.in
INTERACTIONS
•Reflects gas exchange, ventilation, tissue O2,
CO.
•QUALITATIVE-history, exam, ABG, stair
climbing test
•QUANTITATIVE-6 minute walk test
www.anaesthesia.co.in
CONTINUED…….
•1) STAIR CLIMBING TEST:
•If able to climb 3 flights of stairs without stopping/dypnoeaat
his/her own pace-↓edmorbidity & mortality
•If not able to climb 2 flights –high risk
•2) 6 MINUTE WALK TEST:
-Gold standard
-C.P. reserve is measured by estimating max. O2 uptake during
exercise
-Modified if pt. can’t walk –bicycle/ arm exercises
-If pt. is able to walk for >2000 feet during 6 min pd,
-VO2 max > 15 ml/kg/min
-If 1080 feet in 1 min : VO2 of 12ml/kg/min
-Simultaneously oximetryis done & if Spo2 falls >4%-high risk
www.anaesthesia.co.in
•1) STAIR CLIMBING TEST:
•If able to climb 3 flights of stairs without stopping/dypnoeaat
his/her own pace-↓edmorbidity & mortality
•If not able to climb 2 flights –high risk
•2) 6 MINUTE WALK TEST:
-Gold standard
-C.P. reserve is measured by estimating max. O2 uptake during
exercise
-Modified if pt. can’t walk –bicycle/ arm exercises
-If pt. is able to walk for >2000 feet during 6 min pd,
-VO2 max > 15 ml/kg/min
-If 1080 feet in 1 min : VO2 of 12ml/kg/min
-Simultaneously oximetryis done & if Spo2 falls >4%-high risk
www.anaesthesia.co.in
EVALUATION OF PT. FOR LUNG
RESECTION
GOALS:
1) to identify pts at risk of increased post-op
morbidity & mortality
2) to identify pts who need short-term or long
term post-op ventilatory support.
Lung resection may be f/by –inadequate gas
exchange, pulm HTN & incapacitating
dyspnoea.
www.anaesthesia.co.in
RESECTION
GOALS:
1) to identify pts at risk of increased post-op
morbidity & mortality
2) to identify pts who need short-term or long
term post-op ventilatory support.
Lung resection may be f/by –inadequate gas
exchange, pulm HTN & incapacitating
dyspnoea.
www.anaesthesia.co.in
CONTINUED…..
•Removal of entire lung is likely to be tolerated
if pre-op pulmfunction meets the following
criteria:
•A) FEV1 > 2 L or FEV1/FVC of atleast50%
•B) MVV > 50% of predicted value
•C) RV/ TLC < 50%
•If any of these criteria is not full filled –go for
more invasive & sophisticated, split lung
function tests.
www.anaesthesia.co.in
•Removal of entire lung is likely to be tolerated
if pre-op pulmfunction meets the following
criteria:
•A) FEV1 > 2 L or FEV1/FVC of atleast50%
•B) MVV > 50% of predicted value
•C) RV/ TLC < 50%
•If any of these criteria is not full filled –go for
more invasive & sophisticated, split lung
function tests.
www.anaesthesia.co.in
CONTINUED……
•A predicted post op FEV1 Of atleast800ml is
required to perform pneumonectomy
•If not-risk of significant resting CO2 retention &
dyspnoeais high.
•IF Sxinevitable –invasive tests : Pulmonary artery
occlusion test
•If after occlusion of pulmartery of segment to be
resectedis not followed by pulmHtn( mean
pulmart pr > 35 mmhg) AND hypoxemia(PaO2
<45 mmhg) –Assure that remaining lung can
accommodate entire C.O.
www.anaesthesia.co.in
•A predicted post op FEV1 Of atleast800ml is
required to perform pneumonectomy
•If not-risk of significant resting CO2 retention &
dyspnoeais high.
•IF Sxinevitable –invasive tests : Pulmonary artery
occlusion test
•If after occlusion of pulmartery of segment to be
resectedis not followed by pulmHtn( mean
pulmart pr > 35 mmhg) AND hypoxemia(PaO2
<45 mmhg) –Assure that remaining lung can
accommodate entire C.O.
www.anaesthesia.co.in
THANKYOU
www.anaesthesia.co.in
www.anaesthesia.co.in
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 187
- Slides 91
- Age 615 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
30 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
32 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
30 views
14
Fertility awareness methods for women in the society
Isaiah47
29 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
26 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
28 views