Vol 75, No 8 (2017)
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Published online: 2017-08-17

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Kardiologia Polska 2017 nr 08-5

 

ARTYKUŁ ORYGINALNY / ORYGINAL ARTICLE

Impact of post-dilatation on the reduction of paravalvular leak and mortality after transcatheter aortic valve implantation

Paweł Kleczyński, Artur Dziewierz, Marzena Daniec, Maciej Bagieński, Łukasz Rzeszutko, Danuta Sorysz, Jarosław Trębacz, Robert Sobczyński, Marek Tomala, Dariusz Dudek

Institute of Cardiology, Jagiellonian University, Medical College, Krakow, Poland

Address for correspondence:
Paweł Kleczyński, MD, PhD, Institute of Cardiology, Jagiellonian University, Medical College, ul. Kopernika 17, 31–501 Kraków, Poland, tel: +48 12 424 71 81,
fax: +48 12 424 71 84, e-mail: kleczu@interia.pl
Received: 30.12.2016 Accepted: 30.03.2017

Abstract

Background: Post-implantation paravalvular leak (PVL) remains a significant complication of transcatheter aortic valve implantation (TAVI). More importantly, its occurrence may impact long-term mortality.

Aim: We sought to evaluate the effects of balloon post-dilatation (PD) on the reduction of PVL and mortality in patients undergoing TAVI.

Methods: A total of 101 consecutive patients undergoing TAVI were enrolled. Angiography, echocardiography, and the aortic regurgitation index (ARI) were used to assess the severity of PVL before and after balloon PD. Patients were divided into two groups based whether or not PD after TAVI was performed. Reduction of PVL, change of ARI, and clinical outcomes were assessed.

Results: Balloon post-dilatation was performed in 23 (22.8%) patients. In 95.6%, PVL reduction was successful (no or mild PVL). PD increased the ARI from 23.4% (22.4–24.0) to 27.1% (26.1–28.3); p < 0.001. Thirty-day mortality rate was 14.1% in the PD (–) group vs. 0.0% in the PD (+) group; p = 0.07. One-year mortality (21.8% vs. 4.3%, p = 0.97) and procedural stroke rate (7.7% vs. 8.7%, p = 0.99) were not different between the groups.

Conclusions: Balloon post-dilatation may be a safe and effective technique to reduce moderate to severe PVL after TAVI.

Key words: aortic stenosis, transcatheter aortic valve implantation, paravalvular leak, post-dilatation

Kardiol Pol 2017; 75, 8: 742–748

INTRODUCTION

Transcatheter aortic valve implantation (TAVI) is a less invasive treatment option for elderly, high-risk patients with symptomatic severe aortic stenosis (AS) than surgical aortic valve replacement. TAVI improves survival and quality of life in inoperable patients as compared to medical treatment of severe AS [1–3]. However, post-implantation paravalvular leak (PVL) remains a significant TAVI-related complication [4]. Importantly, the presence of PVL may worsen clinical outcomes of patients undergoing TAVI [5]. It is present in up to 70% of all patients undergoing TAVI, and more than mild PVL has been reported in about 10–15% of all TAVI patients [1, 6–14]. Angio­graphy and echocardiography are useful tools to quantify the degree of PVL immediately after deployment of the prosthesis and can be used to identify patients who might benefit from optimisation techniques. Combining invasive haemodynamic measurements with assessment of the aortic regurgitation index (ARI) and imaging may be even more accurate than imaging alone [9, 15, 16]. Balloon post-dilatation (PD) can reduce PVL by achieving a better expansion of the prosthesis and optimal sealing of the paravalvular space. Valve-in-valve implantation is another option to overcome significant PVL, especially if the implantation position is more deep or more shallow than expected [17–19]. However, data on the impact of PD on long-term outcomes after TAVI are scarce. The aim of our study was to evaluate whether balloon PD is safe and effective in reducing PVL after TAVI and to assess its impact on mortality.

METHODS

A total of 101 consecutive high-risk elderly patients with severe symptomatic AS undergoing TAVI were enrolled between November 2008 and November 2014. Patient screening and selection was performed by a multidisciplinary Heart Team supported by clinical and imaging resources. TAVI procedures were performed using Edwards Sapien, Edwards Sapien XT, Edwards Sapien 3 (Edwards Lifesciences, Irvine, USA) Medtronic Corevalve, EvolutR (Medtronic Inc., Minneapolis, USA), and JenaValve (JenaValve Technology, Munich, Germany). Access routes were transfemoral, transapical, and direct aortic. Procedures were performed under general anaesthesia or sedation. Balloon aortic valvuloplasty was performed in each case. Baseline characteristics, and procedural and outcomes data was collected and analysed prospectively. After valve deployment, the degree of PVL was routinely assessed by aortic root angiography (30 mL contrast dye at a flow rate of 15 mL/s) according to the visually estimated density of opacification of the left ventricle (LV) into three degrees adapted from the VARC-2 criteria: mild (reflow of contrast in the outflow tract and middle portion of the LV but clearing with each beat), moderate (reflow of contrast in the whole LV cavity with incomplete washout in a single beat and faint opacification of the entire LV over several cardiac cycles), and severe (opacification of the entire LV with the same intensity as in the aorta and persistence of the contrast after a single beat) and with echocardiography [20]. In all patients, a 6 Fr pigtail catheter was placed approximately 2 cm above the aortic valve. In all patients, haemodynamics were assessed and calculation of the ARI was performed to quantify the extent of PVL more precisely and to have a point of reference before PD was carried out. The ARI was calculated according to the following formula: ([diastolic blood pressure – left ventricular end-diastolic pressure]/systolic blood pressure) × 100%, from 5 to 10 min after valve deployment or PD. A detailed description of ARI assessment and its limitations were described previously [9]. In patients with more than mild angiographically detected PVL and/or an ARI < 25%, PVL was evaluated by echocardiography, preferably transesophageal echocardio­graphy, and if confirmed, a PD was performed. In patients with suboptimal frame expansion causing more than mild PVL, PD was performed to obtain a better expansion of the prosthesis stent frame and a better sealing of the paravalvular space. PD was performed by adding 1–2 cc of contrast dye to the delivery system of balloon expandable valves used during TAVI. For self-expandable prostheses, a 1:1 balloon to aortic native annulus was used for PD (Osypka VACS II, Osypka AG, Germany). The primary endpoint of our study was the change of the PVL grade and ARI after PD in patients undergoing TAVI. Secondary endpoints were the severity of PVL defined according to the VARC-2 criteria, all-cause mortality at 30 days and one year, and post-procedural stroke rate. Patients were divided into two groups based whether or not balloon PD after TAVI was performed. The study protocol was approved by the institutional Ethical Board.

Statistical analysis

Results are presented as numbers of patients (percentages) or the median (interquartile range [IQR]) where applicable. Differences between groups were tested using χ2 test and the Fisher’s exact test for dichotomous variables, and the Mann-Whitney U-test for continuous variables. Changes in the ARI between pre, immediately after, and post TAVI were analysed with Wilcoxon signed-rank test. Changes in the proportions of patients with none, mild, moderate, and severe PVL between pre, immediately after, and post TAVI were tested with χ2 test. In addition, changes in the proportions of patients with “none/mild” vs. “moderate/severe” PVL were analysed using McNemar’s test. The difference in mortality between patients with and without PD after TAVI during 12-month follow-up was assessed by the Kaplan-Meier method and log-rank test. All tests were two-tailed, and a p value < 0.05 was considered statistically significant. All sta- tistical analysis was performed using SPSS 15.0 (SPSS, Inc., Chicago, IL, USA).

RESULTS

A total of 101 consecutive patients underwent TAVI. Baseline characteristics are shown in Table 1. PD was performed in 23 (22.8%) patients. Patients were divided based on the need for PD into two groups: with [PD (+), 23 patients] and without PD [PD (–), 78 patients]. Procedural data are summarised in Table 2. No annular rupture was observed in the PD (+) group. The transfemoral access was used in 73.1% of patients in the PD (–) group and in 91.3% in the PD (+) group (p < 0.001). Interestingly, the fluoroscopy time, radiation dose, and contrast medium volume were higher in patients without PD (Table 2). No difference in the size of prosthesis, annulus dimensions, and cover index between groups was found. In 95.6% of patients PVL reduction was successful (no or mild PVL). Detailed data presenting severity of PVL before and immediately after prosthesis deployment and at the end of the TAVI procedure after PD is shown in Figure 1A (for all patients) and Figure 1B (for patients requiring PD). PD increased the ARI from 23.4% (22.4–24.0) to 27.1% (26.1–28.3); p < 0.001. No coronary obstruction in the PD (+) group was noted. A trend towards increased 30-day mortality was observed in the PD (–) group (14.1% vs. 0.0%; p = 0.07). In contrast, no differences in stroke (7.7% vs. 8.7%; p = 0.99) and myocardial infarction (3.8% vs. 4.3%; p = 0.99) rates were observed. One-year mortality rate (21.8% vs. 4.3%, p = 0.07, Fig. 2) was higher in the PD (–) group, but no statistical significance was found.

Table 1. Baseline characteristics

 

All patients (n = 101)

Post-dilatation (–) (n = 78)

Post-dilatation (+) (n = 23)

p

Age, median (IQR) [years]

81.0 (76.0–84.0)

81.0 (77.0–84.0)

82.0 (72.5–84.0)

0.80

Age ≥ 80 years

59 (58.4%)

46 (59.0%)

13 (56.5%)

0.83

Men

40 (39.6%)

31 (39.7%)

9 (39.1%)

0.96

Body mass index, median (IQR) [kg/m2]

28.0 (25.2–31.1)

27.9 (25.6–30.6)

27.8 (25.6–31.3)

0.95

eGFR median, (IQR) [mL/min/1.73 m2]

61.0 (39.0–81.0)

60.0 (43.0–76.5)

70.0 (43.5–81.0)

0.32

NYHA class:

 

 

 

0.019

I

0 (0.0%)

0 (0.0%)

0 (0.0%)

 

II

17 (16.8%)

9 (11.5%)

8 (34.8%)

 

III

74 (73.3%)

62 (79.5%)

12 (52.2%)

 

IV

10 (9.9%)

7 (9.0%)

3 (13.0%)

 

Arterial hypertension

94 (93.1%)

71 (91.0%)

23 (100.0%)

0.35

Diabetes mellitus

35 (34.7%)

28 (35.9%)

7 (30.4%)

0.80

Atrial fibrillation

35 (34.7%)

24 (30.8%)

11 (47.8%)

0.13

History of MI

31 (30.7%)

25 (32.1%)

6 (26.1%)

0.59

PCI

29 (28.7%)

21 (26.9%)

8 (34.8%)

0.46

CABG

17 (16.8%)

14 (17.9%)

3 (13.0%)

0.76

Chronic total occlusion

9 (8.9)

9 (11.5)

0 (0.0)

0.11

COPD

12 (11.9%)

9 (11.5%)

3 (13.0%)

0.99

Stroke/transient ischaemic attack

10 (9.9%)

9 (11.5%)

1 (4.3%)

0.45

Pacemaker

11 (11.1%)

10 (13.2%)

1 (4.3%)

0.45

Logistic Euroscore I, median (IQR) [%]

14.0 (10.0–22.5)

17.0 (10.0–23.0)

11.0 (8.0–14.5)

0.08

STS, median (IQR) [%]

12.0 (5.0–24.0)

9.0 (5.0–20.0)

21.0 (8.5–30.0)

0.13

TG max, median (IQR) [mm Hg]

87.0 (71.5–108.0)

87.0 (70.5–106.5)

79.5 (62.0–90.0)

0.19

TG mean, median (IQR) [mm Hg]

51.0 (42.5–66.5)

52.0 (43.0–65.0)

48.5 (38.0–52.0)

0.26

AVA, median (IQR) [cm2]

0.6 (0.4–0.8)

0.7 (0.6–0.8)

0.8 (0.6–1.0)

0.20

LVEF, median (IQR) [%]

60.0 (47.5–65.0)

60.0 (47.0–65.0)

62.0 (48.0–65.0)

0.51

Aortic regurgitation:

 

 

 

0.11

0

35 (34.7%)

24 (30.8%)

11 (47.8%)

 

1

51 (50.5%)

44 (56.4%)

7 (30.4%)

 

2

14 (13.9%)

9 (11.5%)

5 (21.7%)

 

3

1 (1.0%)

1 (1.3%)

0 (0.0%)

 

AVA — aortic valve area; CABG — coronary artery bypass graft; COPD — chronic obstructive pulmonary disease; eGFR — estimated glomerular filtration rate; IQR — interquartile range; LVEF — left ventricular ejection fraction; MI — myocardial infarction; NYHA — New York Heart Association; PCI — percutaneous coronary intervention; STS — The Society of Thoracic Surgeons; TG — transvalvular gradient

Table 2. Procedural and follow-up data

 

All patients (n = 101)

Post-dilatation (–) (n = 78)

Post-dilatation (+) (n = 23)

p

Transfemoral access

78 (77.2%)

57 (73.1%)

21 (91.3%)

< 0.001

Transapical access

21 (20.8%)

21 (26.9%)

0 (0.0%)

 

Transaortic access

2 (2.0%)

0 (0.0%)

2 (8.7%)

 

Medtronic CoreValve

20 (19.8%)

13 (16.7%)

7 (30.4%)

0.22

Edwards Sapien

77 (76.2%)

61 (78.2%)

16 (69.6%)

 

Jena Valve

4 (4.0%)

4 (5.1%)

0 (0.0%)

 

Prosthesis size:

 

 

 

0.86

23 mm

16 (15.8%)

14 (17.9%)

2 (8.7%)

 

25 mm

2 (2.0%)

2 (2.6%)

0 (0.0%)

 

26 mm

48 (47.5%)

36 (46.2%)

12 (52.2%)

 

27 mm

1 (1.0%)

1 (1.3%)

0 (0.0%)

 

29 mm

29 (28.7%)

21 (26.9%)

8 (34.8%)

 

31 mm

5 (5.0%)

4 (5.1%)

1 (4.3%)

 

Prosthesis size, median (IQR) [mm]

26.0 (26.0–29.0)

26.0 (26.0–29.0)

26.0 (26.0–29.0)

0.35

Annulus size, median (IQR) [mm]

23.0 (22.0–25.0)

23.0 (21.8–25.0)

23.0 (22.0–24.8)

0.50

Cover index, median (IQR) [%]

11.5 (8.7–15.4)

11.5 (8.7–15.3)

13.5 (10.3–15.4)

0.33

Ellipticity index, median (IQR) [%]

1.2 (1.0–1.2)

1.2 (1.0–1.2)

1.2 (1.0–1.3)

0.77

AR index before, median (IQR) [%]

28.4 (25.0–29.9)

29.4 (27.9–30.5)

23.4 (22.4–24.0)

< 0.001

AR index before < 25%

25 (24.8%)

4 (5.1%)

21 (91.3%)

< 0.001

AR index after, median (IQR) [%]

27.1 (26.1–28.3)

27.1 (26.1–28.3)

AR index after < 25%

1 (0.9%)

1 (4.3%)

Radiation dose, median (IQR) [mGy]

733.0 (634.0–831.5)

783.0 (678.0–841.0)

631.0 (606.0–739.5)

< 0.001

Contrast medium load, median (IQR) [mL]

100.0 (75.0–150.0)

100.0 (100.0–150.0)

75.0 (75.0–75.0)

< 0.001

Fluoroscopy time, median (IQR) [min]

14.0 (13.0–15.5)

14.0 (13.0–16.0)

13.0 (12.0–14.0)

0.013

TG max after TAVI, median (IQR) [mm Hg]

14.5 (10.8–19.0)

14.0 (10.6–19.0)

14.0 (10.0–19.0)

0.93

TG mean after TAVI, median (IQR) [mm Hg]

8.0 (6.0–10.0)

8.0 (6.0–9.6)

7.5 (6.0–11.0)

0.75

LVEF after, median (IQR) [%]

49.0 (42.8–60.0)

50.0 (44.0–60.0)

47.0 (38.5–49.5)

0.09

AR — aortic regurgitation; IQR — interquartile range; LVEF — left ventricular ejection fraction; TAVI — transcatheter aortic valve implantation; TG — transvalvular gradient

308441.jpg 

Figure 1. Severity of paravalvular leak (PVL) before and immediately after prosthesis deployment and at the end of the transcatheter aortic valve implantation (TAVI) procedure; A. For all patients; B. For patients requiring balloon post-dilatation); *p-value from χ2 test; **p-value from McNemar’s test for changes in the proportions of patients with “none/mild” vs. “moderate/severe” PVL

308426.jpg 

Figure 2. Kaplan–Meier curves for survival for patients stratified by the need for balloon post-dilatation (PD)

We also performed a subanalysis of balloon-expandable valves (Edwards and Jena Valve) vs. self-expandable valves (Corevalve) in terms of PVL occurrence after prosthesis deployment, PD, and access site. More than mild PVL after prosthesis deployment, after PD, and at the end of TAVI procedure were present in 16 (19.8%), 16 (19.8%), and two (2.5%) patients in the balloon expandable valves group vs. eight (40.0%), seven (35.0%), and four (20.0%) patients in the self-expanding valves group (p = 0.08; p = 0.23; p = 0013), respectively.

DISCUSSION

Many factors may contribute significantly to clinical outcomes after TAVI. For instance, the presence of coronary artery disease and the occurence periprocedural ischaemic complications may worsen clinical outcomes [21, 22]. Another potential factor is the presence of PVL after TAVI. Importantly, PVL remains the factor linked directly to the procedure itself. Moderate-to-severe PVL had been previously identified as an independent predictor of death between 30 days and one year after TAVI with Medtronic CoreValve [23]. An impact of PVL on medium-term prognosis has recently been demonstrated also for the Edwards SAPIEN prosthesis [7]. Meta-analyses of multiple studies in the high-risk populations showed that moderate or severe PVL is an important determinant of mortality regardless of the implanted valve type [24, 25]. The occurrence of PVL after TAVI might be more frequent after direct valve implantation without balloon PD, resulting in more frequent PD afterwards [12].

We confirmed that balloon PD can effectively and safely reduce the degree of PVL after TAVI when the primary result of the implantation of the prosthesis is not optimal. PD has been performed due to frame under-expansion in most cases, and it was required in 22.7% of patients. This rate was quite similar to that reported in previous studies with a post-dilation rate of 30% to 38% after implantation of self-expanding prostheses and 28% to 41% for balloon-expandable valves [15, 17, 23, 24, 26]. PD might be associated with a higher rate of cardiovascular complications, conduction disturbances, annulus rupture, coronary obstruction, and cerebral embolism leading to stroke [1, 4]. These findings were not confirmed in our study because no differences in cardiovascular complications such as coronary obstruction, stroke, and death were observed. Interestingly, a trend towards improved mortality in patients with PD was noted. However, worse short- and long-term outcomes in patients without PD are possibly related to higher rates of blood transfusion and overall higher risk profile (logistic Euroscore I, NYHA class).

Post-implantation PVL is routinely assessed by control aortography and quantified according to VARC-2 criteria [20]. Echocardiography is helpful to identify the mechanism of PVL such as suboptimal frame expansion due to severe calcification in the native valve. The accurate assessment of PVL is an important means for determining the effectiveness of procedure. To quantify PVL grade more accurately, besides angiography and echocardiography, we used the previously validated ARI, for which a cut-off value of 25 has been shown to be an independent predictor of one-year mortality after TAVI [9]. The ARI is a useful parameter to identify the need of PD but also to quantify the success of PD (additionally to imaging modalities) [9, 15]. Moreover, recently Sinning et al. [27] have shown that ARI integrating pre- and post-procedural haemodynamic status increases the discriminatory value of post-procedural ARI and is useful to identify patients with unfavourable prognosis. The difference in radiation dose, fluoroscopy time, and contrast load between patients with and without PD may be caused by some differences in baseline characteristics and more frequent use of the transapical approach in the PD (+) group.

Limitations of the study

The present investigation represents a single-centre experience with a relatively small sample size, which could be regarded as a limitation of the study. Because the study was not randomised we can expect some important differences in baseline characteristics between the two groups, which may influence mortality as well as other clinical outcomes. The limited sample size did not allow us to use a propensity matching technique to control for selection bias. Thus, the results, especially in terms of clinical outcomes, should be considered exploratory and hypothesis generating. The ARI might be confounded by high systemic blood pressure, diastolic dysfunction, myocardial ischaemia during and after valve deployment or PD, as well as the use of vasopressors during TAVI, and other causes that may lead to an increase of LV end-diastolic pressure leading to false positive ARI. Likewise, the heart rate and its undeniable influence on the diastolic aortic blood pressure affects the ARI. In spite of several limitations, our study represents the complete analysis of consecutive patients without any exclusion criteria and with follow-up data available for all patients.

CONCLUSIONS

Balloon post-dilatation may be safe and effective technique to reduce moderate to severe PVL after TAVI.

Conflict of interest: none declared

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Cite this article as: Kleczyński P, Dziewierz A, Daniec M, et al. Impact of post-dilatation on the reduction of paravalvular leak and mortality after transcatheter aortic valve implantation. Kardiol Pol. 2017; 75(8): 742–748, doi: 10.5603/KP.2017.0152.




Polish Heart Journal (Kardiologia Polska)