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CLINICAL STUDY: VALVE DISEASE

Reoperation for prosthetic aortic valve obstruction in the era of echocardiography: trends in diagnostic testing and comparison with surgical findings

Steven E. Girard, MD, PhD^*, Fletcher A. Miller, Jr., MD, FACC^*, Thomas A. Orszulak, MD, Charles J. Mullany, MD, Samantha Montgomery, MS, William D. Edwards, MD, Henry D. Tazelaar, MD, Joseph F. Malouf, MD, FACC^* and A. Jamil Tajik, MD, FACC^*

^* Division of Cardiovascular Disease, Mayo Clinic and Mayo Foundation, Rochester, Minnesota, USA
Division of Internal Medicine, Mayo Clinic and Mayo Foundation, Rochester, Minnesota, USA
Division of Cardiovascular Surgery, Section of Biostatistics, Mayo Clinic and Mayo Foundation, Rochester, Minnesota, USA
Division of Anatomic Pathology, Mayo Clinic and Mayo Foundation, Rochester, Minnesota, USA

Manuscript received April 12, 2000; revised manuscript received August 23, 2000, accepted October 2, 2000.

Reprint requests and correspondence: Dr. Fletcher A. Miller, Jr., Mayo Clinic, 200 First Street, SW, Rochester, Minnesota 55905
miller.fletcher{at}mayo.edu

	Abstract

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OBJECTIVES

We sought to: 1) identify trends in the diagnostic testing of patients with prosthetic aortic valve (AVR) obstruction who undergo reoperation and 2) compare diagnostic test results with pathologic findings at surgery.

BACKGROUND

It is unclear whether Doppler transthoracic echocardiography (TTE) and transesophageal echocardiography (TEE) have reduced hemodynamic catheterization rates.

METHODS

We reviewed 92 consecutive cases of AVR reoperation at a single center from 1989 to 1998, comparing 49 cases of mechanical AVR obstruction (group A) to 43 cases of bioprosthetic obstruction (group B). Preoperative Doppler TTE was performed in all cases.

RESULTS

In group A cases, there was a marginally significant trend towards lower catheterization rates for the Gorlin AVR area, from 36% in 1989 to 1990 to 10% in 1997 to 1998 (p = 0.07), but diagnostic TEE utilization (47% of cases) did not vary. The cause of mechanical AVR obstruction was pannus in 26 cases (53%), mismatch (P-PM) in 19 (39%) and thrombosis in 4 (8%). The mechanism (pannus/thrombus vs. mismatch) was identified in 10% by TTE and 49% by TEE (p < 0.001). In group B cases, hemodynamic catheterization rates (21%) and diagnostic TEE utilization (21%) did not vary with time. Obstruction was caused by structural degeneration in 37 cases (86%), thrombosis in 3 (7%), mismatch in 2 (5%) and pannus in 1 (2%). The mechanism was correctly identified in 63% by TTE and in 81% by TEE (p = 0.18).

CONCLUSIONS

Doppler TTE is the primary means to diagnose AVR obstruction; hemodynamic catheterization is not routinely needed. In unselected patients with mechanical AVR obstruction, TEE differentiation of pannus or thrombus from mismatch is challenging.

Abbreviations and Acronyms   AVR = aortic valve replacement   DVI = dimensionless velocity index   EOA = effective orifice area   MVR = mitral valve replacement   TEE = transesophageal echocardiography   TTE = transthoracic echocardiography

	Methods

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Study patients.   The research protocol was approved by the Institutional Review Board of the Mayo Foundation. There were 368 repeat aortic valve procedures at Mayo Clinic Rochester, Minnesota, from 1989 through 1998. We excluded patients who refused consent for research authorization and those with complex cyanotic heart disease, valved conduits and active endocarditis. Among 312 cases without an exclusion, we identified 92 with AVR obstruction according to pretreatment echocardiographic or catheterization hemodynamics. "Obstruction" was defined as a mean AVR gradient >1 standard deviation above the normal value and an effective orifice area (EOA) at least 1 standard deviation below the normal value for prosthetic type and size (5). We divided the study cohort into 2 groups for analysis: 49 cases of reoperation for mechanical AVR obstruction in group A; and 43 cases of reoperation for bioprosthetic AVR obstruction in group B.

Echocardiography.   Transthoracic echocardiography studies were performed in all patients and included two-dimensional, color-flow and Doppler examinations using commercially available systems and published methods (6,7). The mean prosthetic AVR gradient was determined using the short form of the modified Bernoulli equation, and the prosthetic EOA was estimated using the velocity modification of the continuity equation (8,9). Based on the interpretation of a staff echocardiologist, we reported one of the following mechanisms of AVR obstruction: thrombus/pannus, mismatch, structural deterioration or indeterminate. The criteria for an echocardiographic diagnosis of obstructing thrombus/pannus were restriction in occluder motion and/or an abnormal echogenic mass attached to the prosthesis. A diagnosis of prosthesis–patient mismatch was made if the AVR occluder motion and two-dimensional images appeared normal. If imaging was inadequate to identify a mechanism of obstruction the study was defined as indeterminate.

TEE examinations were performed in 61 cases according to previously published standards using commercially available systems (10,11), with multiplane probes in 27 cases (44%), biplane probes in 21 (34%) and monoplane probes in 13 (21%). We recorded the TEE diagnosis of the mechanism of obstruction as in the TTE studies and did not attempt to differentiate pannus from thrombus. Intraoperative (IO) TEE was performed at the surgeons’ discretion to assist perioperative management.

Hemodynamic catheterization and fluoroscopy.   After echocardiography, the mean AVR pressure gradient was determined by hemodynamic catheterization in 24 patients (12), and the effective orifice area was estimated using the Gorlin equation in 18 (13). Among 12 patients with a mechanical AVR who underwent catheterization, the mean gradient was determined by transseptal puncture (n = 8), direct left ventricular puncture (n = 3) or retrograde passage of a catheter across a ball-cage valve (n = 1). Fluoroscopy was performed in 16 of 49 (33%) patients with mechanical AVR obstruction using previously reported methods (14).

Surgical and pathological examination.   Prosthetic valve complications were coded according to current guidelines for reporting morbidity and mortality after cardiac valvular operations (15). Based on direct surgical inspection and pathological examination, the mechanism of obstruction was classified as one of the following mutually exclusive categories: thrombosis, pannus, mismatch or structural deterioration. Patients with predominantly thrombus and minimal pannus were included in the thrombosis group; those with predominantly pannus and minimal thrombus were categorized in the pannus group.

Statistical analysis.   Continuous variables were compared using the Wilcoxon rank sum test, and categorical variables were compared by the ² test or Fisher exact test. To analyze for time trends, two year groups were compared using the Cochran–Armitage trend test. Pearson’s correlation coefficient was used to compare continuous variables of interest, and Cox proportional hazards model was used to determine predictors of hospital mortality (SAS Institute, Cary, North Carolina).

	Results

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Clinical presentation of AVR obstruction.   The clinical profile of the study population (group A versus group B) is presented in Tables 1 and 2. Group B patients were older than group A patients; they were also more likely to have a history of congestive heart failure (CHF) or previous coronary artery bypass surgery (CABG). Group A patients were more likely to have rheumatic heart disease or a prior mitral valve replacement (MVR) than group B patients. The duration of symptoms before the diagnosis of AVR obstruction was >1 month in 60 of 77 (78%) patients who reported symptoms, and only two patients (3%) reported symptoms for <1 week.

View larger version (14K): [in this window] [in a new window]   Figure 1 Temporal trends in hemodynamic catheterization rates for AVR area among patients with prosthetic aortic valve (AVR) obstruction undergoing reoperation. Filled circles = cases of mechanical AVR obstruction. Cochran–Armitage Trend test p = 0.07. Open circles = cases of bioprosthetic AVR obstruction.

Mechanism of mechanical AVR obstruction.   The pathologic mechanism of mechanical AVR obstruction was pannus overgrowth in 26 cases (53%), mismatch in 19 (39%) and thrombosis in four (8%). Minor quantities of pannus were found in four cases of mechanical AVR thrombosis, but no thrombus was identified in 26 cases of obstructing pannus. Although Doppler TTE was crucial in diagnosing mechanical AVR obstruction, TTE imaging correctly identified the pathologic mechanism in only five of 49 (10%) studies (Table 5). Diagnostic TEE utilization averaged 47% of group A cases and did not vary over time. The pathologic mechanism (pannus/thrombus vs. mismatch) of mechanical AVR obstruction was correctly diagnosed in 17 of 35 cases (49%) by TEE. There were 11 (33%) indeterminate TEE studies, and the TEE mechanism of mechanical AVR obstruction was incorrect in 7 (20%). Nondiagnostic TEE images were attributed to acoustic shadowing from a mechanical MVR in eight of 11 (73%) of the indeterminate cases. A TEE diagnosis of mismatch was correct in 11 of 18 (61%) cases. We did not detect a significant difference in the diagnostic accuracy of multiplane versus monoplane or biplane TEE examinations.

Of 16 patients with mechanical AVR who underwent preoperative cardiac fluoroscopy, the test was abnormal in three of three (100%) patients with AVR thrombosis, five of eight (63%) patients with pannus and zero of five (0%) patients with mismatch. Among 12 patients who underwent TEE and fluoroscopy, both studies were abnormal in four patients (three with thrombosis, one with pannus), and both studies were normal or indeterminate in six patients (three with mismatch, three with pannus). Two patients with abnormal fluoroscopy and indeterminate or normal TEE images had obstructing pannus at surgery. There were no patients who had abnormal TEE images and normal cardiac fluoroscopy.

Mechanism of bioprosthetic AVR obstruction.   In group B, the pathologic mechanism of obstruction was structural deterioration in 37 (86%) cases, thrombosis in 3 (7%), mismatch in 2 (5%) and pannus ingrowth in 1 (2%). Two-dimensional TTE imaging correctly identified the pathologic mechanism in 63% of cases (Table 6), and TEE correctly identified the mechanism in 81% (p = 0.18). Utilization of diagnostic TEE averaged 21% of group B cases and did not significantly vary over time.

	Discussion

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Rahimtoola defined prosthesis-patient mismatch as a condition in which high pressure gradients occur through normally functioning prosthetic valves (22). Severe mismatch may result in clinical symptoms and an increased hazard for major adverse cardiac events in a manner analogous to the obstruction of native valves (23). Therefore, we included prosthesis-patient mismatch as a cause of obstruction, although these patients were typically not reported in earlier series. Guidelines for timing operation in patients with native aortic valve stenosis may assist in the management of patients with presumed mismatch and severe AVR obstruction (3).

Hemodynamic catheterization.   Because of high false negative rates for fluoroscopy and for TTE before the availability of Doppler echocardiography, Kontos concluded that catheterization was the diagnostic procedure of choice in suspected cases of prosthetic obstruction (24). Among cases of mechanical AVR obstruction, we report a temporal trend towards decreasing use of hemodynamic catheterization to only 10% of cases in 1997 to 1998. There was no significant decline in hemodynamic catheterization of patients with bioprosthetic obstruction, likely because of convenient access to the left ventricle at the time of coronary angiography. However, even among patients with bioprosthetic obstruction, hemodynamic catheterization was infrequent—21% of cases over the past decade. Thus, routine hemodynamic catheterization of patients with suspected AVR obstruction is not necessary. For patients with small (21 mm) bileaflet mechanical prostheses, hemodynamic catheterization may be necessary to exclude significant pressure recovery, particularly if surgical therapy is contemplated for apparent mismatch (25).

We attribute the modest correlation (R = 0.50) between catheter and Doppler mean prosthetic gradients to differences in autonomic tone and pharmacotherapy because the studies were not performed simultaneously. Previous data suggested a much stronger correlation between the techniques when Doppler TTE was performed simultaneously with the invasive hemodynamic measurements (12).

Role of transthoracic echocardiography.   Doppler echocardiography provides a quantitative, reproducible measure of prosthetic obstruction, which is suggested by a progressive increase in the prosthetic valve gradient and a decline in the EOA or DVI (26–28). Doppler TTE was the initial diagnostic test for all patients in our study, before fluoroscopy, hemodynamic catheterization or TEE. Although Doppler TTE is crucial in the identification of patients with significant prosthetic obstruction, classification of the pathologic mechanism of AVR obstruction is difficult using TTE imaging alone.

Role of transesophageal echocardiography.   TEE imaging has been advocated to clarify the mechanism of prosthetic obstruction and to identify candidates for thrombolytic therapy (29). Our results highlight the following limitations of TEE in determining the pathologic mechanism of mechanical AVR obstruction: nondiagnostic images may result from acoustic shadowing in patients with mechanical mitral prostheses, and obstructing pannus overgrowth may not be visualized by TEE, particularly if the occluder motion is not grossly restricted. The lower diagnostic accuracy of TEE in determining the pathological mechanism of obstruction in our series compared with previous studies may be attributed to several factors. First, the sensitivity of imaging techniques depends on the severity and mechanism of prosthetic obstruction. For instance, massive acute AVR thrombosis is more readily diagnosed than a small rim of obstructing pannus, and pannus was far more common than thrombus in our series. Secondly, we included cases of prosthesis-patient mismatch, a diagnosis of exclusion confirmed only by surgical inspection and the resolution of obstruction after implantation of a larger prosthesis; previous series did not include these patients. Finally, although we specifically sought to define the accuracy of TEE for clarifying the etiology of AVR obstruction, other series have included both aortic and mitral prostheses.

Study limitations.   Because we studied cases of AVR obstruction treated at a single tertiary medical institution over the past decade, referral introduces several potential biases that may limit the applicability of our results to other centers. For instance, mechanical AVR thrombosis may be underrepresented in our study if such patients received thrombolytic therapy locally. However, only two patients were treated with thrombolytics at our institution over this same time period. We speculate that the small number of patients in our study did not allow us to detect a significant difference in the diagnostic accuracy of TEE examinations conducted with multiplane versus biplane or monoplane probes. Finally, the classification of a single pathologic mechanism of obstruction is subjective and an oversimplification in some cases.

Clinical implications.   We show that hemodynamic catheterization is not necessary for the clinical management of the majority of patients with AVR obstruction who undergo reoperation. In a population of patients compulsive about maintaining therapeutic anticoagulation, pannus overgrowth is a more common indication for mechanical AVR reoperation than thrombosis. Although our results suggest that a TEE or fluoroscopic diagnosis of mismatch is provisional, empiric thrombolytic therapy in these patients does not appear to be warranted. Only one of 29 (3%) group A patients with normal or indeterminate TEE images had AVR thrombosis at reoperation. Furthermore, patients undergoing isolated AVR reoperation for obstruction, regardless of the etiology, are at low risk—there was no hospital mortality in 49 consecutive cases at the Mayo Clinic during the past decade (upper 95% CI of 7.3%).

Patients with suspected AVR obstruction should undergo a comprehensive Doppler TTE examination because this is the primary test to confirm or exclude obstruction. Transesophageal echocardiography or fluoroscopy may be indicated if thrombosis of an obstructed prosthesis is suspected clinically and treatment with thrombolytics is contemplated. However, a normal or indeterminate TEE does not confirm a diagnosis of mismatch, as pannus may be present in a significant proportion of these cases. Further studies are needed to clarify the role of serial Doppler TTE examinations for this group.

	Footnotes

 
Support by the Mayo Clinic and Foundation, Rochester, Minnesota.

	References

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