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Right Heart Catheterization

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Title: Right Heart Catheterization


1
Right Heart Catheterization basic right heart
pressure tracings
  • University of Kansas
  • August 20, 2004
  • Cardiac catheterization conference

2
The Heart
  • Year 1 Cardiology Fellowship

3
Right heart catheterization and the Swan Ganz
catheter
  • The first to demonstrate that a catheter could be
    advanced safely into the human heart was the
    German surgeon Werner Forssmann (1904-1979) who
    did the experiment on himself. A catheter similar
    to the Swan-Ganz was originally developed in 1953
    and used in dogs by the U.S. physiologists
    Michael Lategola and Hermann Rahn (1912-1990).
    Swan and Ganz introduced their catheter into
    clinical practice in 1970.Bibliography
  • W. Forssmann Die Sondierung des Rechten
    Herzens. Klinische Wochenschrift, Berlin, 1929,
    8 2085.Experiments on myself. Translated by H.
    Davies. London, St. James Press, 1974.

4
Right Heart Catheterization
  • Indications
  • Diagnosis of shock states
  • Differentiation of high- versus low-pressure
    pulmonary edema
  • Diagnosis of primary pulmonary hypertension (PPH)
  • Diagnosis of valvular disease, intracardiac
    shunts, cardiac tamponade, and pulmonary embolus
    (PE)
  • Monitoring and management of complicated AMI
  • Assessing hemodynamic response to therapies
  • Management of multiorgan system failure and/or
    severe burns
  • Management of hemodynamic instability after
    cardiac surgery
  • Assessment of response to treatment in patients
    with PPH
  • Contraindications
  • Tricuspid or pulmonary valve mechanical
    prosthesis
  • Right heart mass (thrombus and/or tumor)
  • Tricuspid or pulmonary valve endocarditis

5
Complications
  • Access
  • Pneumonthorax
  • Hemothorax
  • Tracheal perforation
  • Intracardiac
  • Stimulation of the RVOT ventricular arrhythmias
  • AV block- be aware in patients with a LBBB
    (consider a temporary pacemaker prior to
    proceding)
  • Causing a RBBB
  • Atrial arrhythmias
  • Pulmonary rupture
  • Pulmonary infarct
  • RV puncture

6
Basics - Insertion
  • The SGC is inserted percutaneously into a major
    vein (jugular, subclavian, femoral) via an
    introducer sheath. The predominance of right
    heart catheterization is performed in the
    invasive lab utilizing the femoral approach.
    Preference considerations for cannulation of the
    great veins are as follows
  • Right internal jugular vein (RIJ) - Shortest and
    straightest path to the heart
  • Left subclavian - Does not require the SGC to
    pass and course at an acute angle to enter the
    SVC (compared to the right subclavian or left
    internal jugular LIJ)
  • Femoral veins - These access points are distant
    sites, from which passing a SGC into the heart
    can be difficult, especially if the right-sided
    cardiac chambers are enlarged. Often,
    fluoroscopic assistance is necessary, but these
    sites are compressible and may be preferable if
    the risk of hemorrhage is high.

7
Sheath Insertion
  • A. Puncture vessel by needle
  • B. Flexible guidewire placed into vessel via
    needle
  • C. Needle removed and guidewire left in place,
    hole in skin is enlarged with a scalpel
  • D. Sheath and dilator placed over the guidewire
  • E. Sheath and dilator advanced into the vesssel
  • F. Dilator and sheath removed while sheath
    remains in the vessel

Modified Seldingers technique
8
Right Heart Pressures Tracings
9
Advancing Your Right Heart Catheter
  • Advance the SGC to about 20cm and inflate the
    balloon tip.
  • Initial chamber entered will be the right atrium
    and the initial pressure waveform will have 3
    positive deflections, the a, c and v waves
  • There will be an x and y descent

10
Right Atrial Pressure Tracing
  • a wave results from atrial systole
  • c wave occurs with the closure of the tricuspid
    valve and the initiation of atrial filling
  • v wave occurs with blood filling the atrium
    while the tricuspid valve is closed

11
Timing of the positive deflections
  • a wave occurs after the p wave during the PR
    interval
  • c wave when present occurs at the end of the
    QRS complex (RST junction)
  • v wave occurs after the T wave

12
Right Atrial Chamber
  • Height of the v wave is related to the atrial
    compliance and the volume of blood returning from
    the periphery
  • Height of the a wave is related to the pressure
    needed to eject forward blood flow
  • The v wave is usually smaller than the a wave in
    the right atrium

13
Right atrial hemodynamic pathology
  • Elevated a wave
  • Tricuspid stenosis
  • Decreased RV compliance
  • e.g. pulm htn, pulmonic stenosis
  • Cannon a wave
  • AV asynchrony atrium contracts against a closed
    tricuspid valve
  • e.g. AVB, Vtach
  • Absent a wave
  • Atrial fibrillation or standstill
  • Atrial flutter
  • Elevated v wave
  • Tricuspid regurgitation
  • RV failure
  • Reduced atrial compliance
  • e.g. restrictive myopathy

14
Right atrial hemodynamic pathology
Note the Cannon a wave that is occurring during
AV dysynchrony atrial contraction is occurring
against a closed tricuspid valve.
Note the large V wave that occurs with Tricuspid
regurgitation
15
Hemodynamic Pathology
  • Tricuspid Stenosis
  • Large jugular venous a waves on noted on exam
  • Notable elevated a wave with the presence of a
    diastolic gradient - gt5mmHg gradient is
    considered signficant

16
Advancing Your Right Heart Catheter
  • Continue advancing the catheter into the right
    ventricle
  • The right and left ventricular pressure tracings
    are similar.
  • The right ventricular has a shorter duration of
    systole
  • Diastolic pressure in the right ventricle is
    characterized by an early rapid filling phase,
    then slow filling phase followed by the atrial
    kick or a wave

a
17
Normal RV waveform artifact
  • Note the notch on the top of RV pressure waveform
  • This represents ringing of a fluid-filled
    catheter
  • Ringing can also be noted on the diastolic
    portion of the waveform

18
Advancing Your Right Heart Catheter
  • Advancing out the RVOT to the pulmonary artery
  • There is a systolic wave indicating ventricular
    contraction followed by closure of the pulmonic
    valve and then a gradual decline in pressure
    until the next systolic phase.
  • Closure of the pulmonic valve is indicated by the
    dicrotic notch

19
Timing of the PA pressure
  • Peak systole correlates with the T wave
  • End diastole correlates with the QRS complex

20
Hemodynamic Pathology
  • Pulmonic Stenosis
  • Notable large gradient across the pulmonic valve
    during PA to RV pullback.
  • Notable extreme increases in RV systolic
    pressures and a damped PA pressure

21
Pulmonary artery hemodynamic pathology
  • Elevated systolic pressure
  • Primary pulmonary hypertension
  • Mitral stenosis or regurgitation
  • Restrictive myopathies
  • Significant L to R shunt
  • Pulmonary disease
  • Reduced systolic pressure
  • Pulmonary artery stenosis
  • Ebsteins anomaly
  • Tricuspid stenosis
  • Tricuspid atresia
  • Reduced pulse pressure
  • Right heart ischemia
  • Pulmonary embolus
  • Tamponade
  • Bifid pulmonary artery waveform
  • Large left atrial v wave transmitted backward
  • Pulmonary artery diastolic pressure gt pulmonary
    capillary wedge pressure
  • Pulmonary disease
  • Pulmonary embolus
  • Tachycardia

22
Advancing Your Right Heart Catheter
  • With the balloon inflated advance the catheter
    until the pressure tip wedges into the distal
    pulmonary artery (pulmonary capillary wedge
    pressure)
  • Similar waveform to the left atrial waveform
    although damped

23
Pulmonary artery occlusive pressure
  • A wave represents left atrial contraction
  • C wave represents closure of the mitral valve
    although rarely actually seen
  • V wave represents filling of the left atrium
    while the mitral valve is closed

24
Pulmonary artery occlusive pressure
  • PAOP or wedge represents a static column of blood
    from the catheter tip to the pulmonary v. to
    the left atrium
  • Note the a wave is now past the QRS complex and
    the V wave is after the T wave (all delayed
    pressure transmission)

25
Pulmonary artery occlusive pressure
  • The mean PAOP or wedge pressure occurs at the QRS
    complex can also be derived from the mean
    variance.

26
Pulmonary capillary wedge pressure hemodynamic
pathology
  • Elevated mean pressure
  • Increased volume
  • Left ventricular failure
  • Tamponade
  • Obstructive atrial myxoma
  • Elevated a wave
  • Mitral stenosis
  • decreased LV compliance
  • Cannon a wave
  • AV dysynchrony
  • Elevated v wave
  • Mitral regurgitation
  • VSD
  • PCWP does not left ventricular end-diastolic
    pressure
  • Mitral stenosis
  • Left atrial myxoma
  • Cor triatriatum
  • Pulmonary venous obstruction
  • Decreased ventricular compliance
  • Increased pleural pressure

27
Hemodynamic Pathology
  • Mitral Stenosis
  • Simultaneous wedge and left ventricular pressures
    are shown demonstrating a gradient at the end of
    diastole this is consistent with mitral
    stenosis.
  • A second tracing is shown demonstrating a
    simultaneous left atrial and left ventricular
    pressure tracing once again note the gradient.
  • How does the wedge tracing and LA tracing differ?

28
Hemodynamic Pathology
  • Severe mitral Regurgitation
  • Note the large CV waves this is due to
    ventricular systolic pressures reflected through
    the pulmonary circulation
  • This patient had severe MR from a ruptured
    papillary muscle

29
Advancing Your Right Heart Catheter
  • Not a good place to be during your right heart
    cath
  • Similar waveform to the right atrial pressure
    tracing. Typically involves higher pressures and
    the v wave is gt a wave
  • V wave is greater due to resistance from the
    pulmonary veins whereas the right atrium can
    decompress into the SVC and IVC.

30
Hemodynamic Pathology
  • Mitral Regurgitation
  • Simultaneous left atrial and left ventricular
    pressures demonstrate huge v waves present.
  • The PCWP has a slight delay in the pressure
    tracing
  • Will increase the PCWP and in acute setting
    triggers pulmonary edema from the increase
    osmotic forces
  • Bad to have happen during valvuloplasty

31
Hemodynamic Pathology
Mitral Stenosis This patient underwent mitral
valvuloplasty resulting in a reduction of the
resting gradient by 10mmHg and an increase in CO
from 3.7 to 5.5LPM and a valve area from about
1.1 to 2.9 cm2
32
Left Ventricular Pressure Tracing
  • Typically obtained by passing a pigtail catheter
    across the aortic valve
  • Gives information regarding pressure changes
    across the aortic valve as well as the end
    diastolic pressures

33
Aortic Pressure waveform
  • Waveform appears similar to the PA waveform with
    a smooth rounded peak
  • Dicrotic notch noted represents sudden closure
    of the aortic valve
  • Remainder represents smooth run-off in diastole

34
Hemodynamic Pathology
  • Aortic Stenosis
  • This reflects a pullback while continuously
    recording.
  • The presence of significant aortic stenosis is
    reflected by the pressure gradient

35
Hemodynamic Pathology
  • Aortic Regurgitation
  • Note the rapidly increasing left ventricular
    end-diastolic pressure and equilibration of
    aortic and LV pressures at end-diastole

36
Measuring Cardiac Output
  • Most commonly used methods are
  • Thermodilution method
  • Fick method
  • There is no completely accurate way to assess
    cardiac output

37
Thermodilution
  • Requires bolus injection of liquid commonly
    saline - into the proximal port.
  • The change in temperature is measured by a
    thermistor mounted in the distal portion of the
    catheter
  • Pitfalls
  • Not accurate with TR
  • Overestimates cardiac output at low output states

Birkbeck injection
38
Fick Method
  • Fick Principle first described by Adolph Fick
    in 1870
  • Assumes the rate at which O2 is consumed is a
    function of the rate of blood flow times the rate
    of O2 pick up by the red blood cells

39
Fick Method
  • So cardiac output is expressed in the equation to
    the right
  • Measurements should be made in the steady state.
  • O2 consumption can be estimated
  • 3ml O2/kg or 125ml/min/m2
  • AV O2 difference is arterial venous O2 content
  • saturation X1.36 X Hgb

e.g. AO sat 95, PA sat 65 Patient wght 70kg
and Hgb 13.0
210________ (0.95-0.65) X 1.36 X 13.0 X 10 3.96
L/min
40
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41
A
42
B
43
C
44
D
45
E
46
F
47
G
48
H
49
I -PCWP tracing
50
J -PCWP
51
K
52
L
53
M
54
N
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