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Late Re-operation for Aortic and Mitral Starr-Edwards Ball Valve Prostheses

Department of Surgery, Kurume University School of Medicine, Kurume, Japan

For reprint information contact: Shigeaki Aoyagi, MD Tel: 81 942 317 661 Fax: 81 942 358 967 Email: aoyagi{at}med.kurume-u.ac.jp, Department of Surgery (2), Kurume University School of Medicine, 67 Asahi-machi, Kurume 830-0011, Japan.

	ABSTRACT

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Starr-Edwards ball valves removed more than 15 years after implantation were retrospectively investigated macroscopically. Eight patients required re-operation. Valve models used in the initial operations were a non-cloth-covered valve in 2 patients and a cloth-covered valve in 6. Two patients had replacement of an aortic ball valve (model 1260 and model 2320) and 6 underwent mitral valve replacement (model 6120 in one, model 6320 in 5). The mean time to re-operation was 23.0 ± 4.8 years after implantation. Cloth wear causing significant hemolysis was observed in all cloth-covered valves, regardless of valve position. Autologous tissue growth was noted on the orifice ring and struts in both aortic and mitral prostheses. Thrombus formation was not found in any of the valves. Ball variance in silicone rubber balls was mild in the non-cloth-covered valves, even in the aortic position. The most significant problem with the cloth-covered ball valve was cloth wear. Cloth wear should always be considered when 15 years or more have passed since valve implantation. Significant hemolysis, elevation of lactate dehydrogenase values, and echocardiographic detection of transvalvular regurgitation are diagnostic of cloth wear, and are indications for replacement of a cloth-covered ball valve.

	INTRODUCTION

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The Starr-Edwards (S-E) ball valve prosthesis was the first artificial cardiac valve introduced for valvular heart disease in 1961.¹ Since the first clinical use of the original S-E ball valve, several modifications in materials and design have been made to improve the hemodynamic performance and durability, and to decrease the incidence of thromboembolism. This valve prosthesis has shown excellent durability, however, some specific complications have also been experienced, such as cloth wear, embolism, pannus formation, and ball variance.^2–8 We examined 8 S-E ball valves that were removed from the aortic or mitral position more than 15 years after implantation. The diagnostic and therapeutic strategies for complications related to the S-E ball valve are discussed.

	PATIENTS AND METHODS

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The S-E ball valve was employed for replacement of left heart valves at our hospital between 1965 and 1975; 46 patients received a ball valve in the aortic or mitral position. Of the 24 long-term survivors, 8 required re-operation due to prosthetic valve dysfunction or progression of other cardiac valve diseases. The clinical characteristics of these 8 patients are summarized in Table 1. The 2 aortic S-E ball valves were replaced at 20 and 28 years after implantation, and the 6 valves in the mitral position were explanted after 15 to 30 years (mean, 23 years). Indications for re-operation are listed in Table 1. Replacement of the S-E ball valve with a mechanical bileaflet valve was performed under moderate hypothermic cardiopulmonary bypass and cardioplegic arrest, through a median sternotomy incision in all 8 patients. The S-E ball valves removed at re-operation were studied for cloth wear, pannus formation, thrombus, and ball variance.

	RESULTS

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View larger version (61K): [in this window] [in a new window]   Figure 1. Explanted aortic (A) and mitral (B) cloth-covered ball valves showing severely disrupted fabric.

View larger version (72K): [in this window] [in a new window]   Figure 2. An explanted aortic non-cloth-covered ball valve (A) and mitral cloth-covered ball valve (B). There was no autologous tissue growth on the bare metallic struts, but it was clearly observed on the struts of the cloth-covered ball valve. Discoloration and small spots of lipid infiltration were also seen on the silicone rubber ball (A).

Significant hemolysis was noticed in 6 patients who had a cloth-covered ball valve with cloth wear; one had a model 2320 aortic valve and 5 had a model 6320 mitral valve. Serum lactate dehydrogenase levels were remarkably high in all 6, and total bilirubin levels were over 1.2 mg·dL^–1 in 4 of the 6 patients. Blood smears revealed fragmentation of erythrocytes in 3 patients. Hematologic data in these 6 patients are summarized in Table 2. Systemic embolism was experienced in one patient with a model 2320 aortic ball valve. After the 4^th postoperative year, transient cerebral ischemic attacks occurred 4 times during the next 15 years. At re-operation, severe cloth wear was found in this ball valve (Figure 1A).

	DISCUSSION

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Three models of the S-E ball valve prostheses, non-cloth-covered, cloth-covered, and a composite strut (track) model, were introduced for clinical use. The non-cloth-covered valves (models 1260 and 6120) had bare metallic struts composed of Stellite without any cloth covering, and a silicone rubber ball. In the cloth-covered valves (model 2320 aortic and model 6320 mitral), the metallic struts and orifice ring were completely covered by Dacron or Teflon cloth, and a hollow Stellite ball was incorporated. The composite strut models (2400 aortic and 6400 mitral) resembled the model 2320 aortic and 6320 mitral valves except that it had metallic tracks on the inner aspect of the cloth-covered struts. Only the first two types of S-E ball valve were implanted in our hospital.

Ball variance due to lipid infiltration as well as thromboembolism was a major problem with the non-cloth-covered ball valve. However, ball variance occurred mainly in the model 1000 aortic prosthesis, and only a few cases of abnormal poppets showing discoloration have been reported in the model 1260 aortic prosthesis that was employed in our series. In our experience, discoloration was found on the silicone rubber ball in the model 1260 aortic and 6120 mitral prostheses implanted 28 and 26 years previously, respectively, but moderate or severe ball variance was not observed even 25 years or more after implantation. Although the introduction of cloth-covered ball valve prostheses has substantially reduced the incidence of thromboembolism in patients receiving anticoagulant therapy, cloth-covered valves have been associated with problems of cloth wear resulting in hemolysis and systemic arterial embolization.^1,2 Cloth wear was found in all of the model 2320 and 6320 cloth-covered ball valves used in our 6 patients. In an early report from the New York Veterans Administration Hospital, 4 (3.3%) of 121 survivors with cloth-covered aortic S-E valve prostheses, and one (1.2%) of 83 survivors with cloth-covered mitral S-E valve prostheses had re-operations for consequences of cloth wear, an overall incidence of 2.5%.³ Similarly, one Japanese study initially reported that cloth wear of the S-E ball valve was more frequent and remarkable in the aortic position than in the mitral position.² A recent follow-up study over 15 years from the same group has emphasized that cloth wear is frequently detected not only in the aortic position but also in the mitral position.¹⁰

The two major complications due to cloth wear are cloth fiber emboli to the systemic circulation and hemolysis with or without regurgitation across the prosthesis. According to a previous study, cloth fiber emboli can occur with either aortic or mitral valve prostheses, while clinically significant hemolysis is associated only with the aortic prosthesis.⁸ In our experience, however, significant hemolysis was seen in 6 patients, and 5 of them had a ball valve in the mitral position. A sail or parachute effect of the worn cloth in the bloodstream jet plays an important role in the severe hemolysis caused by cloth wear of the S-E valve prostheses (Figure 3). This effect creates increased turbulence and accelerated hemolysis.^11,12 Thus, it is logical that significant hemolysis due to cloth wear can occur with S-E valves even in the mitral position. Based on our experience and that of others, even when no clinical findings that suggest significant cloth wear have been demonstrated, cloth wear should always be considered when 15 years or more have passed after valve replacement with a cloth-covered S-E ball valve.²

View larger version (91K): [in this window] [in a new window]   Figure 3. Transthoracic echocardiogram demonstrating excessive tissue attached to the cage of the prosthesis, which was fluttering in the blood stream; a sail or parachute effect of the worn cloth in the bloodstream jet is also observed (white arrow). LA = left atrium, LV = left ventricle.

	REFERENCES

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1. Starr A, Edwards ML. Mitral replacement: clinical experience with a ball-valve prosthesis. Ann Surg 1961;154:726–40.[Medline]

2. Tsukamoto S, Shiono M, Orime Y, Hata H, Yagi S, Okumura H, et al. Macroscopic aspects of cloth-covered Starr-Edwards prostheses at reoperation: what the precursory valve teaches us. J Heart Valve Dis 1998;7:556–60.[Medline]

3. Shah A, Dolgin M, Tice DA, Trehan N. Complications due to cloth wear in cloth-covered Starr-Edwards aortic and mitral valve prostheses—and their management. Am Heart J 1978;96:407–14.[Medline]

4. Akiyama K, Anzai N. Cerebral and myocardial infarcts due to deterioration of cloth-cover of Starr-Edwards mitral valve 16 years after replacement. Nippon Kyobu Geka Gakkai Zasshi 1990;38:2133–6.[Medline]

5. Sakata K, Ishikawa S, Ohtaki A, Otani Y, Suzuki M, Kawashima O, et al. Malfunctioning Starr-Edwards mitral valve 21 years after installation. J Cardiovasc Surg (Torino) 1997;38:81–2.[Medline]

6. Yoshida K, Fujii G, Suzuki S, Ishida H, Shimomura T, Matsuura A. Reoperation for a Starr-Edwards aortic valve implanted 28 years earlier. Jpn J Thorac Cardiovasc Surg 2002;50:341–2.[Medline]

7. Murakami M, Tanaka H, Watanabe M, Shimizu M, Sunamori M. Severe hemolysis due to cloth wear 23 years after aortic valve replacement on a Starr-Edwards ball valve model 2320. Cardiovasc Surg 2002;10:284–6.[Medline]

8. Allen WB, Karp RB, Kouchoukos NT. Mitral valve replacement Starr-Edwards cloth-covered composite-seat prosthesis. Arch Surg 1974;109:642–7.[Abstract/Free Full Text]

9. Grunkemeier GL, Starr A. Late ball variance with the Model 1000 Starr-Edwards aortic valve prosthesis. Risk analysis and strategy of operative management. J Thorac Cardiovasc Surg 1986;91:918–23.[Abstract]

10. Ye Z, Shiono M, Sezai A, Inoue T, Hata M, Niino T, et al. Reoperation for a patient 25 years after a Starr-Edwards ball mitral valve was installed. Ann Thorac Cardiovasc Surg 2002;8:311–5.[Medline]

11. Pluth JR, Broadbent JC, Barnhorst DA, Danielson GK. Aortic and mitral valve replacement with cloth-covered Braunwald-Cutter prosthesis. A three-year follow-up. Ann Thorac Surg 1975;20:239–48.[Abstract]

12. Jonas RA, Garratt-Boyes BG, Kerr AR, Whitlock RM. Late follow-up of the Braunwald-Cutter valve. Ann Thorac Surg 1982;33:554–61.[Abstract]

13. Friedli B, Aerichide N, Grondin P, Campeau L. Thromboembolic complications of heart valve prostheses. Am Heart J 1971;81:702–8.[Medline]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted 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): Shigeaki Aoyagi Shuji Fukunaga Permission Requests Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Aoyagi, S. Articles by Egawa, N. Search for Related Content PubMed PubMed Citation Articles by Aoyagi, S. Articles by Egawa, N. Related Collections Valve disease