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Title pageTitle: Comparing patent foramen ovale sizing by echocardiography with balloon sizing in patients
undergoing percutaneous closure.
Authors: Martin Christian Harmsen1, MD; Henrik Vase1, MD, PhD; Jens Erik Nielsen-Kudsk1, MD, DMSc;
Asger Andersen1, MD, PhD
Affiliations: 1. Department of Cardiology, Aarhus University Hospital, Aarhus, Denmark;
Running head: Echocardiographic vs. balloon sizing of PFO
Corresponding author:Asger Andersen, MD, PhD
Dep. Cardiology, Aarhus University Hospital
Palle Juul Jensens Boulevard 99
DK-8200 Aarhus N
E-mail: [email protected]
Conflict of interest:One or more of the authors have disclosed potential conflicts of interest regarding the content
herein.
Total word count: 2612
AbbreviationsPFO Patent foramen ovale
TEE Transesophageal echocardiography
LA Left atrium
RA Right atrium
TTE Transthoracic echocardiography
CI Confidence interval
AbstractObjective: To compare the size of a patent foramen ovale (PFO) evaluated by
echocardiography or peri-procedural balloon sizing in patients undergoing percutaneous PFO
closure.
Methods: The study was a single center retrospective analysis using a pre-specified
screening protocol for inclusion of 100 patients who underwent percutaneous PFO closure due to
left circulation thromboembolism. PFO size was evaluated by peri-procedural balloon sizing and
per-procedural echocardiography. Balloon sizing was compared using linear regression analysis to
echocardiography evaluated high-risk PFO features: PFO channel diastase, -channel length, number
of shunted bubbles and atrial septum mobility.
Results: Echocardiography underestimated the size of a PFO compared to balloon
sizing (2.19 (95% CI: 1.91–2.46) vs. 8.51 (95% CI: 8.02–9.00) mm, p < 0.001) and the correlation
between the sizing methods was poor (slope=0.80 (95%CI: 0.48-1.12, p<0.01, R=0.44). The
correlation between number of shunted bubbles and balloon sizing was poor (slope=0.04 (95%CI:
0.01-0.07), p=0.005, R=0.28). There were no correlation between balloon sizing and PFO channel
length (slope -0.018 (95%CI: -0.117 – 0.081), R = 0.036, p = 0.719) and atrial septal mobility
(slope 0.049, (95%CI: -0.043 – 0.141), R = 0.105, p = 0.297).
Conclusion: Defect and shunt size of a PFO measured by TEE showed a poor
correlation with PFO size determined by balloon sizing. PFO channel length and septal mobility did
not correlate to the size of a PFO measured by balloon sizing.
1 IntroductionPatent foramen ovale (PFO) can cause paradoxical embolism and ischemic stroke. In
selected patients with a prior ischemic stroke, closure of a PFO effectively reduces the risk of
recurrent strokes.1-4 The size of a PFO, number of microbubbles shunted to the LA and presence of
an atrial septum aneurism are considered high-risk factors for a PFO related ischemic stroke and it
has been suggested that patients with a high-risk PFO may benefit more from closure, than patients
without a high-risk PFO.5,6
Echocardiography is key in evaluating the presence and high-risk features of a PFO
and it is used in procedural planning before percutaneous PFO closure to ensure an optimal
procedural result. The anatomy of a PFO is however complex. It can vary from a slit-, tunnel- to
semilunar like shape and with varying sizes up to ~20 mm7 echocardiographic evaluation may be
difficult. Especially shunt- and anatomical size, which are some of the high-risk PFO features, may
be difficult to evaluate precisely as they are very dependent on the patients ability and timing of
Valsalva’s maneuver and whether the agitated saline is injected from an upper extremity or lower
extremity vein.8-10
Peri-procedural interrogation of the interatrial defect with a compliant balloon sizing
catheter is used for precise sizing of the defect to ensure an optimal device selection for closure.
The method is considered a valid tool for evaluating the anatomical size of a PFO as the compliant
balloon makes a precise cask of the PFO channel. It is however unknown how well balloon sizing
correlates to the size of a PFO evaluated by echocardiography.
We aimed to investigate the correlation between PFO sizing by pre-procedural
echocardiography and peri-balloon sizing in patients undergoing percutaneous PFO closure.
2 Methods2.1 Study Design and Patient Eligibility
Single center retrospective analysis using a pre-specified screening protocol for
inclusion of a total of 100 patients. Patients undergoing percutaneous PFO closure due to left
circulation thromboembolism were eligible for inclusion. Patients were excluded if
echocardiography or fluoroscopy were unavailable or if the echocardiographic imaging quality did
not allow the pre-specified analysis. In patients included in the study, balloon sizing was compared
to echocardiography evaluated high-risk PFO features: PFO channel diastase, -channel length,
number of shunted bubbles and atrial septum mobility.
A total of 192 patients who underwent PFO closure in the period from January 2017
through November 2018 were screened until 100 patients were included in the analysis (Fig. 1)
The study conformed to the declaration of Helsinki and the Danish Data Protection Act. All
patients consented prior to the intervention.
2.2 Data collectionMedical history was obtained from the electronic medical patient file. Analysis of
digitally stored echocardiography and fluoroscopy images was done in Impax Client 6.5.5.1608
(AGFA Healthcare N.V, Belgium) and/or EchoPACTM (version 203 GE Healthcare, Horten,
Norway). Study variables obtained by echocardiography and fluoroscopy were evaluated by a
single observer who were blinded to patient identification.
2.3 Echocardiographic analysisTransesophageal echocardiography (TEE) was used to analyze PFO anatomy: PFO
defect size was measured during Valsalva and defined as the separation of the primum septum from
the secundum septum at the left atrium (LA) end of the PFO tunnel during maximal septal bulge
into the LA. PFO channel length was measured when the septum was displaced into the LA and the
channel was visible in its full extent. Mobility of the interatrial septum was measured by the
maximal excursion of the primum septum from RA to LA during the cardiac cycle. An atrial septal
aneurysm was defined by a combined total excursion of the primum septum from RA to LA >15
mm or >10 mm to either LA or RA. Contrast echocardiography with Valsalva using intravenous
administration of agitated saline from a cubital vein was performed initially by transthoracic
echocardiography and repeated during TEE. The maximal number of air microbubbles on TEE or
transthoracic echocardiography (TTE) appearing in the LA was counted in a single frame within
three cardiac cycles after appearance of the first air bubbles in the RA. The shunt size was classified
into three groups: small (1–5 bubbles), medium (6– 25 bubbles), and large (>25 bubbles).
Anatomical PFO size measured by fluoroscopy in the anterior-posterior view and
defined as the minimum diameter of the sizing balloon (PTSR Numed, 25 mm). All PFO closure
procedures were guided by intracardiac echocardiography with the sizing balloon inflated using the
stop-flow method. Representative examples are shown in supplementary figure 1.
Interobserver variability was tested by measuring each variable in 10 randomly
selected patients by two observers blinded to patient identification.
2.4 StatisticsCorrelation between anatomical PFO size measured by balloon sizing and parameters
measured by TEE (PFO size, length, atrial septum mobility, shunt size) were evaluated with linear
regression and one-way ANOVA using IBM SPSS ver. 26. Regression results are expressed as
slope and continued variables as mean with 95% confidence intervals (CI) and the correlation
coefficient as Pearson’s R. The assumption of homogeneity of variances in the pre-specified shunt
size groups was tested and satisfied based on Levene’s F test. Boxplot of fluoroscopy and saline
contrast groups were created in Graph Pad Prism (v. 7.0c) and analyzed using one-way ANOVA
with multi comparison t-test between groups. Interobserver variability within each variable was
tested using Bland-Altman analysis plotted as difference versus average.
3 Results3.1 Patient characteristics
Patient characteristics are presented in table 1.
3.2 Balloon sizing and echocardiographic evaluation of PFO sizePFO size measured by TEE was smaller than measured by balloon sizing 2.19 (95%
CI: 1.91–2.46) vs. 8.51 (95% CI: 8.02–9.00) mm, p < 0.001). PFO channel length did not correlate
with PFO size by balloon sizing (slope -0.018 (95%CI: -0.117 – 0.081), R = 0.036, p = 0.719) and
neither did atrial septal mobility (slope 0.049, (95%CI: -0.043 – 0.141), R = 0.105, p = 0.297).
Regression analysis of PFO size measured by TEE showed a statistically significant, but poor
correlation to PFO balloon sizing as did the shunt size measured by TEE. Grouping of the patients
according to size of the PFO shunt size did not show a statistically significant difference between
the large and small group compared to the moderate group, but a difference was observed between
the small and large group (Figure 2).
3.3 Interobserver variability analysisBland-Altman plots of the interobserver variability analysis is presented in Figure 4.
4 DISCUSSIONOur results indicate that determining the shunt- and anatomical size of a PFO with
TEE correlates poorly to balloon sizing.
The patients included in the analysis where in their late forties, had some risk factors
with hypercholesterolemia and hypertension being the most predominant, and the primary reason
for PFO closure was a prior ischemic stroke. The mean size of their PFO was substantially larger
measured by balloon sizing compared to the echocardiographic sizing. Most shunts where moderate
or large. These baseline features are very similar to patients included in the REDUCE and
RESPECT trial.2,3 Not only the age and comorbidities, but also the anatomical PFO features were
very similar. Hypercholesterolemia was higher in our population, but as we counted patients on
statins as having hypercholesterolemia this merely reflects a prior stroke, and that statins was
initiated by the neurologist as standard care after a stroke.
The separation between the primum and secundum septum of a PFO have been used
to measure PFO size on TEE in key clinical trials.1-4 By using the this method, the size of a PFO
was underestimated fourfold based on means compare to balloon sizing. Not only did 2 dimensional
TEE massively underestimate the anatomical size of the PFO, but the regression analysis show that
it correlates weakly to balloon sizing of a PFO suggesting that patient selection and procedural
planning based on this entity alone should be done very cautiously. In itself this finding is not
surprising. The anatomical size of a PFO is very complex7 and using a 2-dimensional measure may
be too simple a method to evaluate the PFO anatomical size. This is also supported by findings
from others, where advanced peri-procedural 3D TEE estimates a much larger anatomical PFO size
than 2D echocardiography.11
The ability of right-to-left shunting through a PFO may be the most important risk
factor when considering the pathophysiology of paradoxical embolism. It correlates poorly with the
anatomical size of a PFO measured by balloon sizing emphasizing that the number of microbubbles
shunted is not solely determined by the size of a PFO. We know that the number of shunted
bubbles is very dependent on the patients ability and timing of Valsalva’s maneuver and whether
the agitated saline is injected from an upper extremity or lower extremity vein. 8-10 The poor
correlation can to some extend be explained by this.
The mobility of the atrial septum and the length of the PFO channel evaluated by TEE
does not correlate to the anatomical size of a PFO suggesting that these measures are independent of
the anatomical PFO size. This could explain recent results from the close and DEFENSE-PFO trial
showing that ASA was the most important predictor of recurrent stroke, not shunt size,5 but we still
do not know the how the true anatomical size of a PFO would correlate to recurrent stroke. These
findings emphasize that a PFO is a complex anatomical structure and that decision-making and
procedural planning based on PFO size evaluated with TEE should be done carefully.
4.1 LimitationsData was collected retrospectively. Echocardiographic parameters were measured
from clinical scans where no strict echocardiographic protocol was used. This may also confound
shunt evaluation, since the ability of the patient to perform a proper Valsalva maneuver, the
presence of an eustachian valve and timing of injection of the agitated saline are important to
visualize the shunting potential through a PFO. All patients had injection of agitated saline through
a cubital vein, knowing that injection though a femoral vein has higher sensitivity for PFO detection
and likely shunts more microbubbles across the PFO.11
Our test of interobserver variability showed reasonable results for PFO channel length
and shunt size, but not for measuring PFO size (separation between primum and secundum septum)
further emphasizing that this parameter should be used with caution in decision-making.
5 Conclusion
Defect and shunt size of a PFO measured by TEE showed a poor correlation with PFO
size determined by balloon sizing. PFO channel length and septal mobility did not correlate to the
size of a PFO measured by balloon sizing.
Impact on daily practice
There is a poor correlation between the size of a PFO evaluated by TEE and the
anatomical size evaluated by balloon sizing. It emphasizes that a PFO is a complex anatomical
structure that is difficult to fully evaluate by TEE and that PFO size based on TEE should be used
cautiously in decisions and per-procedural planning of closure.
Funding
Asger Andersen is funded by the Alfred Benzon FoundationJens Erik Nielsen-Kudsk is funded by
the Novo Nordisk Foundation (NNF17OC0024868/NNF17OC0029510).
Conflict of interest
Asger Andersen have retrieved travel grants from ABBOTT. Jens Erik Nielsen-Kudsk is a proctor
and consultant for Abbott and Boston Scientific. Martin Christian Harmsen and Henrik Vase have
no conflicts of interest to declare.
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Figure legends
Figure 1: Flow chart of study inclusion.PFO (Patent foramen ovale). TTE (Transthoracic echocardiography). TEE (Transesophageal
echocardiography).
Figure 2 Echo analysis A: Patent foramen ovale (PFO) Diastasis. B: PFO Length. C: Bubbles shunted through a PFO D1
& D2: Atrial septum
aneurysm with a combined deviation of 22 mm. E1 and E2: Large eustachian valve
inhibiting the contrast from reaching the septum. F: Balloon sizing. G PFO occluder in situ
Figure 3: Correlation between PFO size measured by TEE, shunt size and PFO balloon sizing.Linear regression analysis of PFO size (A) and shunt size (B) measured by TEE and balloon sizing.
Boxplot of shunt size and balloon sizing (C). Each column illustrates the mean and the quartile
distribution of balloon sizing.
Figure 4 Interobserver variabilityBland-Altman plots of difference versus average assessing echocardiographic interobserver
variability of 10 randomly selected patients analyzed by 2 observers blinded to outcome. A)
Persistent foramen ovale (PFO) channel length B) PFO size by trans esophageal echocardiography
(TEE) C) Bubbles shunted
Figures Figure 1 Flow chart of study inclusion
Figure 2 Echo and fluoroscopy analysis
Figure 3: Correlation between PFO size measured by TEE, shunt size and PFO balloon sizing.
Figure 4 Interobserver variability
Table 1Patient Characteristics n = 100
Age, years 48.7 ± 11.3
Male gender, n (%) 70 (70%)
Medical history
Diabetes, n (%) 5 (5%)
Hypertension, n (%) 27 (27%)
Current smoker, n (%) 18 (18%)
Hypercholesterolemia, n (%) 56 (56%)
Migraine, n (%) 11 (11%)
Myocardial infarction, n (%) 4 (4%)
Tromboembolic Event
Ischemic stroke, n (%) 74 (74%)
Transient ischemic attack, n (%) 19 (19%)
Systemic embolism, n (%) 7 (7%)
Morphology of the Atrial Septum
Atrial septum aneurism, n (%) 11 (11%)
Fenestrations, n (%) 2 (2%)
Chiari network, n (%) 7 (7%)
Eustachian valve, n (%) 26 (26%)
PFO balloon sizing, mm 8.5 ± 2.5
PFO echocardiography sizing, mm 2.2 ± 1.4
Shunt size small/medium/large, n (%) 23/45/32 (23/45/32%)
Table 1 Patient Characteristics