The Upper Airway and Cardiopulmonary Exercise Testing

Download Report

Transcript The Upper Airway and Cardiopulmonary Exercise Testing 

The Upper Airway and
Cardiopulmonary Exercise Testing
Carl Mottram, BA RRT RPFT FAARC
Director - Pulmonary Function Labs & Rehabilitation
Associate Professor of Medicine - Mayo Clinic College of
Medicine
Cardiopulmonary Exercise Testing
• Oxygen consumption (VO2max)
•Index of cardiopulmonary
fitness (gold standard)
• Cardiovascular response
• Ventilatory limitation and
breathing strategies
• Gas Exchange
• Metabolic calculations and
derivatives
Determinates of Exercise Ventilatory Response
• Ventilatory demand
• Metabolic demand
• Neuroregulatory and behavior factors
• Dead space ventilation
• Body weight
• Mechanical limitations imposed by
lungs and chest wall
• Chest wall deformity
Determinates of Exercise Ventilatory
Response
• Mechanical limitations imposed by lungs
• Intrinsic Lung Disease
• Obstructive pulmonary disease
• Restrictive disease
• Airway tone
• Bronchodilation or bronchoconstriction
• Upper airway
Determining Ventilatory Limitation
• Ventilatory Capacity (VEcap)
• Maximal Voluntary Ventilation (MVV)
• FEV1
• Flow limitation
• FV loops during exercise
• End-exercise PaCO2
Ventilatory Capacity - MVV
• MVV – 10 - 12 second maneuver that
is extrapolated to a minute ventilation
• FEV1 x 35 or 40
• Advantages:
• General approximation of ventilatory
capacity
• Readily and widely available, no
analysis needed
Ventilatory Capacity MVV
• Disadvantages:
•Volitional effort
•Breathing strategy is
different
•MVV is not a sustained
maneuver
•MVV tested before
exercise does not take
into account
bronchodilation
Johnson BD, Weisman IM, Zeballos RJ, Beck KC.
Chest 1999;116:488–503.
Freedman S. Resp Physiology (8) 230-244, 1970
Ventilatory Capacity
2
0
0
• Ventilatory or
1
8
0
1
6
0
Breathing reserve:
.
V
C
a
p
a
c
i
t
y
E
.
V
R
e
s
e
r
v
e
E
1
4
0
•Ventilatory capacity -
1
0
0
8
0
MinuteVntilaon,l/min
VEmax
•20-30 liters (10-15 L
minimum)
•20-40%
1
2
0
• “Ventilatory limitation”
6
0
4
0
.
V
T
h
r
e
s
h
o
l
d
E
2
0
0
0
.
00
.
51
.
01
.
52
.
02
.
53
.
03
.
54
.
0
O
x
y
g
e
n
C
o
n
s
u
m
p
t
i
o
n
,
l
/
m
i
n
Mottram CD. 10th Ed. Ruppel’s Manual of
Pulmonary Function Testing Chap. 7
Ventilatory Limitation
60.00
50.00
MVV = 43
VE
40.00
Pred. VO2
1.8 l/m
30.00
20.00
10.00
0.00
0
500
1000
VO2
1500
2000
Flow-Volume Loop Analysis
• Quantify flow limitation
rather than a pseudoventilatory capacity
1
2
1
0
M
F
V
L
8
• Define maximal flow-volume
e
x
t
F
V
L
loop (envelope)
4
• Use IC maneuvers to
2
Flow,l/sec
determine changes in EELV
V
o
lo
f
F
L
6
R
e
s
t
F
V
L
0
2
R
e
s
t
I
C
• Johnson BD. Weisman IM. Zeballos
RJ. Beck KC. Chest. 116(2):488-503,
1999 Aug
4
6
e
x
t
I
C
8
1
0
0
1
2
3
4
V
o
l
u
m
e
,l
5
6
The Journal of Clinical Investigation Volume 48 1969
• 10 normal subjects
•The major goal of this
study was to relate the
expiratory pressures
during exercise to the
pressures associated with
flow limitation.
Flow Volume Loop Profiles
10
8
Flow (L/sec)
6
4
Ex
2
0
2
Ex
1
2
3
4
Rest
5
1
2
3
4
5
Rest
4
6
8
Normal
Severe COPD
Mottram CD. 10th Ed. Ruppel’s Manual of Pulmonary Function Testing Chap. 7
Flow-Volumes Loop Analysis
• Suspicion of flow limitation
• Obstruction
• Restriction
• Intra or extra-thoracic obstruction
• Vocal chord dysfunction (VCD)
• Other pseudo-asthma - severe obesity
• Breathing kinetics
• Location of tidal breathing on the absolute
lung volume scale
• EEVL/TLC
J Appl Physiol 99: 1912–1921, 2005
• Twenty-four prepubescent
children
•Thirteen sportive children
(10.8 + 1.1 y.o.)
•Eleven untrained children
(10.5 + 1.0 y.o.)
Eur Respir J 2004; 24: 378–384
• 20 asthmatics in a stable
condition and aged 32+13 yrs
with a FEV1 of 101+ 21%
pred.
• Conclusion: In asthmatics with
exercise-induced tidal
expiratory flow limitation, the
exercise capacity is reduced as
a result of dynamic
hyperinflation.
• 22
years-old female
• Cough, chest tightness and
wheezing
• Diagnosed with EIB with no
response to BD
• Normal flow volume curve at rest
Sawtooth Pattern
Breathing Kinetics: FVL Analysis
Normal
Breathing Kinetics: FVL Analysis
Flow limitation
Breathing Kinetics: FVL Analysis
Inappropriate Shift
Breathing Kinetics: FVL Analysis
Vocal Cord Dysfunction
Breathing Kinetics: FVL Analysis
Pseudo – Asthma “type 2”
Patient JB
• 16 y.o. male with a chief complaint of
exertional dyspnea
• Evaluation of suspected asthma
• Wrestling and cross-country
• Meds: Flovent, singulair, Xopenex
Patient JB
Patient JB
Patient JB
Patient CL
• 27 yo female with chief
complaint of exertional
dyspnea
• PMH: Tetralogy of Fallot with
absent pulmonary valve
syndrome status post complete
repair
• CPET ordered to evaluate
cardiac versus pulmonary
Patient CL
Patient CL
Patient EW
• 12 y.o. female referred for prolong QT
syndrome and exercise intolerance
• HPI:
• Sports physical triggered and ECG
which was read as borderline prolonged
QT.
• Chest pain and wheezing with exercise
• PE: Unremarkable
Patient EW
• ECHO: normal
• Spirometry: FVC 3.17 (95%), FEV1
2.78 (97%), ratio 87.7%
• Normal spirometry
• CPET with FV Loops ordered to r/o
EIB or vocal chord dysfunction
Patient EW
• Normal sinus rhythm, normal ECG
Exercise
Workload
Time
O2 saturation (SpO2)
VO2
VO2/kg
R
Cardiac Function
Heart Rate
Blood Pressure CUFF
Oxygen Pulse
Ventilation
Minute Ventilation
watts
min:sec
%
l/min
ml/kg
REST Maximum
160 Pred Max %Pred Max
12:00
98
95
0.299
2.079
2.343
89
34.5
0.74
1.04
bpm
mmHg
VO2/HR
73
94/56
4
192
152/54
11
199
170/88
96
89/61
1/min
8.0
67.6
108.0
63
Interpretation: Normal
exercise tolerance,
evidence of VCD
Patient ID: EW816
Laryngoscope, 109:136-139,1999
• To compare laryngoscopically observed changes in
the larynx during exercise in persons (2) with
exercise-induced laryngomalacia (EIL) with
changes in asymptomatic control subjects (8).
Laryngoscope, 116:52–57, 2006
• 12 normal subjects and
4 patients with DOE
and noisy breathing
• Conclusion: Continuous
laryngoscopy with
exercise was easy to
perform and well tolerated
Laryngoscope, 119:1776–1780, 2009
Respiratory Medicine (2009) 103, 1911-1918
• 151 of 166 patients
with inspiratory
distress during
exercise
Eur Arch Otorhinolaryngol
(2009) 266:1929–1936
• The aims of this study were to
establish a scoring system for
laryngeal obstruction as visualized
during the CLE-test as well as to
assess reliability and validity of
this scoring system.
• Conclusion: The CLE-test scoring system is
a reliable and valid method that can be used
to assess degree of laryngeal obstruction in
patients with symptoms of EIIS
CPET with FV loops and Direct Laryngoscopy
Patient AJ
• 18 year-old athletic female complaining of
dyspnea and wheezing with exertion
• HPI:
• Inspiratory wheezing, epigastric pain and
tight feeling around the shoulders and
neck with exertion
• Symptoms start after a minute or so of
sprinting or 5-10 min. of regular exercise
• Symbicort, Singulair and Xopenex x 1 year
with no improvement
ENT and speech path consult
Laryngoscopy:
• Thick secretions
• Normal mobility of the true vocal folds
with full abduction and complete adduction
• The subglottis was clear
• No paradoxical vocal fold when she
attempted to mimic her dyspneic episodes
Patient AJ
Patient AJ
• Diagnosis: Arytenoid collapse
(laryngeal dysfunction)
• Patient was seen again by ENT and
underwent arytenoidectomy
Patient TB
• 14 y.o. female with a chief complaint of
dyspnea on exertion
• PMH
• Asthma “wheezing with colds”
• Mother described “breathing attacks”
• CXR: Normal
• Meds: Symbicort, Xopenex
Patient TB
Patient TB
Patient TB
Baseline
Immediate Post- Exercise
Summary
• Flow volume loop analysis is beneficial
in defining flow limitation and other
breathing abnormalities during exercise
• Continuous video laryngoscopy is a
well tolerated procedure that can assist
in characterizing structural
abnormalities of the upper airway.
Questions?