HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Michel Pellerin Denis Bouchard Raymond Cartier Louis P. Perrault Michel Carrier Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Dürrleman, N. Articles by Carrier, M. Search for Related Content PubMed PubMed Citation Articles by Dürrleman, N. Articles by Carrier, M. Related Collections Valve disease

J Thorac Cardiovasc Surg 2004;127:1388-1392
© 2004 The American Association for Thoracic Surgery

Surgery for acquired cardiovascular disease

Prosthetic valve thrombosis: Twenty-year experience at the Montreal Heart Institute

^a Departments ofDepartment of Surgery, Montreal Heart Institute, Montreal, Quebec, Canada
^b Department of Medicine, Montreal Heart Institute, Montreal, Quebec, Canada

Received for publication September 5, 2003; revisions received November 24, 2003; accepted for publication December 11, 2003.

^* Address for reprints: Michel Carrier, MD, Department of Surgery, Montreal Heart Institute, 5000 Belanger Street, Montreal, Quebec H1T 1C8, Canada
michel.carrier{at}icm-mhi.org

	Abstract

Top Abstract Materials and methods Results Discussion References

 
BACKGROUND: Prosthetic valve thrombosis is a life-threatening complication. We reviewed the incidence, risk factors, and treatment strategies of this rare complication.

METHODS: From February 1981 through January 2001, 5430 valve operations were performed in 4924 patients at the Montreal Heart Institute. Of this cohort, 39 patients presented with prosthetic valve thrombosis and had complete follow-up data obtained from our prospective valve clinic database.

RESULTS: In this series 82% of patients were women, and the mean age was 58 ± 11 years. The underlying pathology involved the mitral valve in 75% of cases. Most prosthetic valve thromboses occurred with mechanical prostheses (95%). The time interval from first valve replacement to prosthetic valve thrombosis was 39 ± 42 months. The most frequent clinical presentation was severe congestive heart failure (44%). On prosthetic valve thrombosis presentation, the international normalized ratio was less than 2.5 in 54%, with inadequate anticoagulation management in 26% and poor compliance in 26%. Eighty-two percent of patients underwent a surgical procedure, consisting of thrombectomy in 47%, mitral valve replacement in 47%, and aortic valve replacement in 6% of patients. The 30-day operative mortality and total in-hospital mortality after prosthetic valve thrombosis were 25% and 41%, respectively. The 10-year actuarial survival after prosthetic valve thrombosis was 46% ± 10%.

CONCLUSION: Inadequate level of anticoagulation is the most important factor involved in the pathogenesis of prosthetic valve thrombosis. The overall mortality rate despite surgical treatment remains high. This study underscores the importance of meticulous surveillance of anticoagulation therapy in patients with prosthetic valves.

The purpose of this report is to review the clinical experience with the medical and surgical management of PVT in a large surgical cohort of patients undergoing valve replacement at the Montreal Heart Institute.

	Materials and methods

Top Abstract Materials and methods Results Discussion References

 
From February 1981 through January 2001, 5430 valve operations were performed in 4924 patients. From this cohort, 39 (0.8%) patients were rehospitalized for PVT. The clinical records prospectively gathered by a specialized team at the local valve clinic were reviewed. Preoperative clinical data, initial valve procedure, diagnostic features of valve thrombosis, and management before, during, and after the operation were recorded. The incidence of valve thrombosis according to valve localization was analyzed. Several factors were analyzed to define the risk factors for PVT development, including sex, aortic versus mitral position, and single- versus double-valve replacement.

Clinical data at the initial operation
Thirty-nine patients presented with PVT, 7 (18%) men and 32 (82%) women (Table 1). Mean age at the time of PVT diagnosis was 58 ± 11 years. Sixteen (41%) patients were in atrial fibrillation before the initial valve replacement, and 4 (10%) patients had a permanent pacemaker. Thirty-four (87%) patients were in New York Heart Association (NYHA) functional class III or IV before the first valve replacement. The initial pathology involved the mitral valve in 29 (75%) cases, whereas aortic valve disease and double-valve disease (mitral and aortic) accounted for 4 (10%) and 6 (15%) patients of the cohort, respectively. The first valve replacement was a redo intervention in 8 (21%) patients. Eleven (28%) patients presented with a history of prior thromboembolic complications, including retinal artery thrombosis, leg ischemia, stroke, pulmonary embolism, or left atrial appendage thrombosis.

Left atrial diameter measured by means of echocardiography was 53 ± 13 mm at the time of the first intervention. Preoperatively, cardiac dyskinesia was identified in 13 (33%) patients by means of transthoracic echocardiography (TTE) or ventriculography.

Initial valve surgery
Most initial valve replacements were performed with Carbomedics prostheses (72%), including one patient having a tricuspid valve replacement with a Carbomedic prosthesis for severe tricuspid regurgitation. Left atrial appendage resection was performed in 2 (5%) patients. Postoperative left ventricular ejection fraction was greater than 45% in most patients (26/31 [84%]). Mean initial intensive care unit length of stay was 5 ± 4 days, and mean hospital stay was 13 ± 7 days.

Anticoagulation protocol
Anticoagulation was initiated 48 hours after all valvular procedures (heparin and warfarin). When aspirin was added to the anticoagulation regimen, it was started on postoperative day 1. Patients were discharged with an international normalized ratio (INR) in the target range of 2.5 to 3.5 and were followed at the anticoagulation clinic.

Statistical analysis
Data are expressed as means ± SDs or medians when appropriate. Univariate analysis was performed with the Student t test for parametric data and the Pearson ² test for proportions. Analysis of survival was performed by using the Kaplan-Meier method. The statistical analyses were performed with NCSS 2001 (NCSS Statistical Software, Kaysville, Utah).

	Results

Top Abstract Materials and methods Results Discussion References

 
Thrombosis
The distribution of PVTs according to the site of valve implantation was as follows: 26 (67%) mitral, 6 (15%) aortic, 6 (15%) double, and 1 (3%) tricuspid replacement. PVT involved mechanical prostheses in 25 (96%) of 26 instances in the mitral position and in 5 (83%) of 6 valves in the aortic position. The only thrombosis of a tricuspid valve was with a mechanical prosthesis.

Among double-valve prosthesis recipients (6 patients), PVTs were in the mitral prosthesis in 5 (83%) patients, and a bivalvular thrombosis was seen in 1 (17%) patient. In the mitral valve replacement group, more patients had atrial fibrillation than in the aortic valve replacement group (46% vs 0%, P = .04). In the aortic position only 50% (3/6) were considered eligible for a surgical procedure after PVT diagnosis versus 88% (23/26) in the mitral position (P = .03).

Diagnosis of PVT
The mean interval between the first valve replacement and the occurrence of PVT was 39 ± 42 months (range, 0-120 months). There were 8 (21%) early thromboses (<30 days after the first valve replacement) and 31 (79%) late thromboses. The median time between the diagnosis of PVT and surgical treatment was 2 days (range, 0-138 days; 2 days in late PVT and 2.5 days in early PVT).

Symptoms at presentation were dyspnea in 22 (56%) patients, modification of heart murmur in 5 (13%) patients, cardiogenic shock in 5 (13%) patients, and miscellaneous symptoms (abdominal pain, syncope, or stroke) in 6 (15%) patients. In one patient PVT was a fortuitous echocardiographic finding. The majority of patients (34 [87%]) with PVT were in NYHA functional class III or IV at the time of diagnosis. Two patients were in respiratory-cardiac arrest, and 1 patient was undergoing mechanical ventilation and considered to be NYHA functional class IV. Overall, the most frequent clinical finding was congestive heart failure (17 [44%] patients). Occurrence of thromboembolism (stroke or limb or organ ischemia) between initial valve replacement and the occurrence of valve thrombosis was reported in 9 (23%) patients.

The diagnosis of PVT was made with TTE in 21 (54%) patients, transesophageal echocardiography in 8 (21%) patients, and angiography in 3 (8%) patients. The diagnosis was established in 2 (5%) patients in the operating room and in 5 (13%) patients at postmortem examination. The INR recorded at the time of thrombosis was less than 2.5 in 21 (54%) patients (Table 2).

Atrial fibrillation was present in 45% (14/31) of patients with late valve thrombosis versus 25% (2/8) of those with early PVT (P = .01). Pannus formation was present along with the thrombus at the time of the operation in 50% (19/38) of patients, and this was more frequent in those with late valve thrombosis (18/30 [60%]) than in those with early PVT (1/8 [13%]; P = .01).

Thrombus
The characteristics of thrombi were reviewed in 38 of 39 patients. Thrombi were found in the left atrium in 16 (16/38 [42%]) patients, in the left ventricular cavity in 1 (1/38 [3%]) patient, and in both cavities in 21 (21/38 [55%]) patients. In patients with aortic valve thrombosis, 29% (2/6) had thrombi on the aortic side only, and 71% (4/6) had thrombi in the left ventricle.

Pathologic findings showed that the thrombus was fresh in 34% (13/38), old in 13% (5/38), and had both characteristics in 53% (20/38) of patients. Old and fresh thrombi were defined according to pathologic structural organization.

Thrombi were larger than 5 mm in 89% (34/38), mobile in 58% (22/38), and obstructive in 89% (34/38).

Management of patients with PVT and early mortality
All patients were started on intravenous heparin as soon as the diagnosis was suspected. Six (15%) of 39 patients received thrombolytic therapy during 23 ± 21 hours (range, 0-48 hours) by using streptokinase in 5 patients and rTPA in another patient. Thrombolysis was attempted as a definitive treatment in 5 (83%) patients because of the poor general medical condition of the patients. In 1 patient thrombolysis was used to allow an improvement of cardiac performance to enable the transfer to our tertiary care center.

In the thrombolysis group (n = 6), 2 (33%) patients died, one from cardiogenic shock and one from hemorrhagic stroke. Three (50%) patients were redirected toward surgical intervention after failure of thrombolysis, and another was transferred to the operating room while receiving the thrombolytic treatment.

Overall, 5 patients died before reaching the operating room in the earlier part of the experience. The thrombotic event occurred before the use of thrombolysis.

In the surgical group 28 patients underwent emergency operations without prior thrombolysis, and 4 patients underwent operations after thrombolysis. Two patients died immediately on chest opening without possible resuscitation, and one patient could not be weaned from cardiopulmonary bypass (3/32 [9%]).

A redo median sternotomy was used in 27 (84%) of 32 patients, and a right anterolateral thoracotomy was performed in 5 patients. Video-assisted thrombectomy of the prosthesis was performed in 14 (47%) of 30 patients treated surgically, and valve replacement was required in 16 (53%) of 30 patients. When the thrombosed prosthetic valve was replaced, simultaneous thrombectomy of cardiac cavities was performed. One patient had a mitral replacement and a concomitant thrombectomy of the right atrium. Among the 16 patients who underwent valve replacement, 14 had mitral valve replacement and 2 underwent aortic valve replacement. All patients with early PVT underwent video-assisted thrombectomy without the necessity for valve replacement. The crossclamping time averaged 75 ± 32 minutes (range, 16-133 minutes), and the cardiopulmonary bypass time was 118 ± 48 minutes (range, 31-217 minutes).

The operative mortality rate was 9% (3/32). Overall, hospital mortality of all patients with valve thrombosis was 41% (16/39). The overall hospital mortality was higher in the early PVT group (6/8 [75%]) compared with that in the late PVT group (10/31 [32%]; P = .03).

Cardiac complications occurred in 14% (4/29; low cardiac output, cardiogenic shock, complete atrioventricular block, and tamponade), 21% (6/29) presented with multiple organ dysfunction, 10% (3/29) experienced a neurologic complication (stroke), and coagulopathy occurred in 7% (2/29).

Postoperative care
The oral anticoagulation regimen after surgical treatment of PVT consisted of warfarin alone in 14 (14/25 [56%]) patients and a combination of warfarin and aspirin in 11 (11/25 [44%]) patients (dose range, 80-325 mg die). The mean hospital stay was 13 ± 9 days (range, 3-48 days), and the mean intensive care unit stay was 7 ± 9 days (range, 1-48 days).

Long-term survival and recurrence of PVT
The 10-year actuarial survival rate was 46% ± 10% (Figure 1). The cause of long-term death was sudden death in 3 patients. Three patients had recurrence of valve thrombosis and died (2 after rereplacement and one after thrombectomy). Two had severe left ventricular dysfunction, and one had a hypercoagulation status associated with an autoimmune disease.

View larger version (14K): [in this window] [in a new window]   Figure 1. Survival after initial valve replacement surgery.

	Discussion

Top Abstract Materials and methods Results Discussion References

 
The present study suggests that surgical intervention should be performed in most patients with PVT after the shortest possible delay between diagnosis and the intervention. Thrombolysis appears only useful as a medical bridge to an operation. PVT thrombolysis did not have a good rate of success in our group of patients as a primary treatment. The second observation of this study is that PVT could be prevented in most patients with better management of the anticoagulation treatment.

Valve thrombosis is a rare but lethal complication of valvular prosthetic replacement.^8,9 The clinical presentation varies from insidious dyspnea to cardiac arrest. Establishing the diagnosis might be quite difficult, and some series have been reported as being made at postmortem examination in up to 50% of cases.⁴ In a recent study the delay between first symptoms to hospitalization ranged from 1 to 45 days.¹⁰ Previous studies have shown that a delay in diagnosis and long duration of symptoms resulted in a higher mortality.¹¹ Clinical examination is a poor diagnostic tool.¹² A normal TTE scan with a strong clinical suspicion of PVT dictates an extensive investigation with transesophageal echocardiography.¹³

Mechanical valves, tilting disc vales, caged ball valves, mitral position, and poor patient compliance with the anticoagulation treatment are the most frequently related risks factors for PVT reported in the literature. Buttard and colleagues¹⁰ found inadequate systemic oral anticoagulation at the time of diagnosis in 45%: 27% for medical reasons (surgical intervention, neurologic events, or pregnancy) and 17% because of poor patient compliance. A direct relationship has already been established between inadequate anticoagulation and valve thrombosis by several authors, as is suggested in the present study.^14-16

Early PVT was associated with a worse prognosis and significantly higher in-hospital rates compared with those with late occurrence of the thrombotic event.

Pannus formation, defined as an excessive wound fibrosis around a prosthetic valve, has recently been studied in patients with PVT^7,17 and could be found in 25% of patients as early as the first postoperative month.¹⁰ In the present series the precise role of pannus in the pathogenesis of valve thrombosis remains unknown, but it was found to be more frequent in female patients, in patients with late thrombosis, and in survivors. The presence of pannus was correlated with a better prognosis and is a definite indication for prosthetic valve rereplacement.

Several studies have examined the role of thrombolysis in the management of PVT.^18,19 Recently, Roudaut and coworkers²⁰ conducted a retrospective study of 110 patients treated with fibrinolytic therapy and concluded that the treatment should be reserved for selected patients (those with tricuspid thrombosis, critically ill patients, and patients with contraindications to surgical intervention).

In our experience thrombolysis is indicated in those who could not tolerate cardiopulmonary bypass and those with severe hemodynamic compromise to improve cardiac function and to allow transfer to a tertiary care center for definitive surgical treatment.

On the basis of the present experience, patients with PVT should undergo emergency surgery. Valve thrombectomy is performed in patients with fresh thrombi related to recent change in the anticoagulation management, and valve replacement is done in all other patients. If patient compliance with the medication at long term is an issue, a bioprosthetic valve should be implanted. When thrombectomy is performed, the ventricular cavity is inspected with a videothoracoscope.²¹ A laryngeal mirror can also be useful in this situation. Prosthetic thrombectomy is a safe, rapid, and simple procedure in a limited number of patients. Before discharge, aspirin (80-325 mg die) is added to warfarin treatment. By optimizing the level of anticoagulation and by helping endothelialization of the prosthetic valve, aspirin might improve survival.

Mortality in patients with PVT remains high. The most common precipitating factors for valve thrombosis are inadequate anticoagulation and poor patient compliance, underscoring the need for both patient- and physician- oriented education. Although less invasive than surgical intervention, thrombolysis can be reserved for patients necessitating transfer to a tertiary care center. Surgical intervention remains the mainstay of treatment for patients with PVT.

	Acknowledgments

 
We thank Ismael El Hamamsy, MD, and Louis-Mathieu Stevens, MD, for their precious help in this work.

	References

Top Abstract Materials and methods Results Discussion References

 

1. Edmunds LH Jr, Clark RE, Cohn LH, Grunkemeier GL, Miller DC, Weisel RD. Guidelines for reporting morbidity and mortality after cardiac valvular operations. Ad Hoc Liaison Committee for Standardizing Definitions of Prosthetic Heart Valve Morbidity of The American Association for Thoracic Surgery and The Society of Thoracic Surgeons. J Thorac Cardiovasc Surg. 1996;112:708–711[Free Full Text]
   
2. Hammermeister KE, Sethi GK, Henderson WG, Oprian C, Kim T, Rahimtoola S. A comparison of outcomes in men 11 years after heart-valve replacement with a mechanical valve or bioprosthesis. Veterans Affairs Cooperative Study on Valvular Heart Disease. N Engl J Med. 1993;328:1289–1296[Abstract/Free Full Text]
   
3. Nunez L, Iglesias A, Sotillo J. Entrapment of leaflet of St. Jude medical cardiac valve prosthesis by minuscule thrombus: report of two cases. Ann Thorac Surg. 1980;29:566–569[Abstract]
   
4. Kontos GJ Jr, Schaff HV, Orszulak TA, Puga FJ, Pluth JR, Danielson GK. Thrombotic obstruction of disc valves: clinical recognition and surgical management. Ann Thorac Surg. 1989;48:60–65[Abstract]
   
5. Sivasubramanian S, Vijayshankar CS, Krishnamurthy SM, Santhosham R, Dwaraknath V, Rajaram S. Surgical management of prosthetic valve obstruction with the Sorin tilting disc prosthesis. J Heart Valve Dis. 1996;5:548–552[Medline]
   
6. Mustapha R, Philip I, Bohm G, Depoix JP, Enguerand D, Debauchez M, et al. Thrombosis of heart valve prostheses: favourable and prognostic factors based on a study of 41 patients. Ann Chir. 1994;48:243–247[Medline]
   
7. Deviri E, Sareli P, Wisenbaugh T, Cronje SL. Obstruction of mechanical heart valve prostheses: clinical aspects and surgical management. J Am Coll Cardiol. 1991;17:646–650[Abstract]
   
8. Cannegieter SC, Rosendaal FR, Briet E. Thromboembolic and bleeding complications in patients with mechanical heart valve prostheses. Circulation. 1994;89:635–641[Abstract/Free Full Text]
   
9. Horstkotte D, Burckhardt D. Prosthetic valve thrombosis. J Heart Valve Dis. 1995;4:141–153[Medline]
   
10. Buttard P, Bonnefoy E, Chevalier P, Marcaz PB, Robin J, Obadia JF, et al. Mechanical cardiac valve thrombosis in patients in critical hemodynamic compromise. Eur J Cardiothorac Surg. 1997;11:710–713[Abstract]
    
11. Tsai KT, Lin PJ, Chang CH, Chu JJ, Chang JP, Kao CL, et al. Surgical management of thrombotic disc valve. Ann Thorac Surg. 1993;55:98–101[Abstract]
    
12. Kontos GJ Jr, Schaff HV. Thrombotic occlusion of a prosthetic heart valve: diagnosis and management. Mayo Clin Proc. 1985;60:118–122[Medline]
    
13. Gueret P, Vignon P, Fournier P, Chabernaud JM, Gomez M, LaCroix P, et al. Transesophageal echocardiography for the diagnosis and management of nonobstructive thrombosis of mechanical mitral valve prosthesis. Circulation. 1995;91:103–110[Abstract/Free Full Text]
    
14. Massad M, Fahl M, Slim M, Haddad R, Dagher I, Alam S, et al. Thrombosed Bjork-Shiley standard disc mitral valve prosthesis. J Cardiovasc Surg (Torino). 1989;30:976–980[Medline]
    
15. Venugopal P, Kaul U, Iyer KS, Rao IM, Balram A, Das B, et al. Fate of thrombectomized Bjork-Shiley valves. A long-term cinefluoroscopic, echocardiographic, and hemodynamic evaluation. J Thorac Cardiovasc Surg. 1986;91:168–173[Abstract]
    
16. Butchart EG, Lewis PA, Grunkemeier GL, Kulatilake N, Breckenridge IM. Low risk of thrombosis and serious embolic events despite low-intensity anticoagulation. Experience with 1,004 Medtronic Hall valves. Circulation. 1988;78(suppl):I66–77
    
17. Rizzoli G, Guglielmi C, Toscano G, Pistorio V, Vendramin I, Bottio T, et al. Reoperations for acute prosthetic thrombosis and pannus: an assessment of rates, relationship and risk. Eur J Cardiothorac Surg. 1999;16:74–80[Abstract/Free Full Text]
    
18. Roudaut R, Labbe T, Lorient-Roudaut MF, Gosse P, Baudet E, Fontan F, et al. Mechanical cardiac valve thrombosis. Is fibrinolysis justified? Circulation. 1992;86(suppl 5):II8–15
    
19. Roudaut R, Lafitte S, Roudaut MF, Perron JM, Labeque JN, Pradeau V, et al. Fibrinolysis and thrombosis of mechanical valvular prosthesis: risk stratification by transesophageal echocardiography. Arch Mal Coeur Vaiss. 2002;95:897–902[Medline]
    
20. Roudaut R, Lafitte S, Roudaut MF, Courtault C, Perron JM, Jais C, et al. Fibrinolysis of mechanical prosthetic valve thrombosis: a single-center study of 127 cases. J Am Coll Cardiol. 2003;41:653–658[Abstract/Free Full Text]
    
21. Carrier M, Pellerin M, Dagenais F, Perrault LP, Petitclerc R, Pelletier LC. Videoassisted thrombectomy of mechanical prosthetic heart valves. J Heart Valve Dis. 1999;8:404–406[Medline]
    

This article has been cited by other articles:

				N Allou, P Piednoir, C Berroeta, S Provenchere, H Ibrahim, G Baron, P Montravers, B Iung, I Philip, and N Ajzenberg Incidence and risk factors of early thromboembolic events after mechanical heart valve replacement in patients treated with intravenous unfractionated heparin Heart, October 15, 2009; 95(20): 1694 - 1700. [Abstract] [Full Text] [PDF]

				A. Vahanian, B. Iung, L. Piérard, R. Dion, and J. Pepper CHAPTER 21 Valvular Heart Disease ESC Textbook of Cardiovascular Medicine, January 1, 2009; 2(1): med-9780199566990-chapter - med-9780199566990-chapter. [Abstract] [Full Text] [PDF]

				C. J. Boos and H. J. Marshall Factors in Warfarin Therapy Discontinuation Arch Intern Med, September 22, 2008; 168(17): 1932 - 1932. [Full Text] [PDF]

				F. M. Caceres-Loriga Prosthetic valve thrombosis: is it time for a new consensus conference? Eur J Echocardiogr, July 1, 2008; 9(4): 413 - 414. [Full Text] [PDF]

				R. W. Emery, A. M. Emery, A. Knutsen, and G. V. Raikar Aortic Valve Replacement with a Mechanical Cardiac Valve Prosthesis Card. Surg. Adult, January 1, 2008; 3(2008): 841 - 856. [Full Text]

				P. W. X. Foley, R. Sharma, and P. R Karla Beware of prosthetic valve thrombosis despite therapeutic anticoagulation Emerg. Med. J., March 1, 2007; 24(3): e18 - e18. [Abstract] [Full Text] [PDF]

				S. H. Rahimtoola The year in valvular heart disease J. Am. Coll. Cardiol., January 4, 2005; 45(1): 111 - 122. [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Michel Pellerin Denis Bouchard Raymond Cartier Louis P. Perrault Michel Carrier Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Dürrleman, N. Articles by Carrier, M. Search for Related Content PubMed PubMed Citation Articles by Dürrleman, N. Articles by Carrier, M. Related Collections Valve disease