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. 2015 Sep 9;10:115. doi: 10.1186/s13019-015-0320-z

Acquired Gerbode defect following endocarditis of the tricuspid valve: a case report and literature review

Edvin Prifti 1, Fadil Ademaj 2,, Arben Baboci 3, Aurel Demiraj 2
PMCID: PMC4565022  PMID: 26353810

Abstract

The Gerbode’s defect is a communication between the left ventricle and right atrium. It is usually congenital, but rarely is acquired, as a complication of endocarditis, myocardial infarction, trauma, or after previous cardiac surgery. The acquired Gerbode defect with involvement of the tricuspid valve acquired after bacterial endocarditis can be challenging to repair. We present a rare case of young woman, with endocarditis of the tricuspid valve and acquired Gerbode defect without previous cardiac surgery. She underwent successful surgical closure of the Gerbode defect and reconstruction of the septal leaflet of the tricuspid valve using a an autologous pericardial patch. A total of 20 other cases were reported with acquired Gerbode defect due to endocarditis in patients without previous cardiac surgery. Three other cases presented acquired Gerbode defect due to myocardial infarction and two due to chest trauma. Another series of 62 patients presented acquired Gerbode defect after previous cardiac surgery. Surgical treatment is always feasible with excellent outcome. However the percutanous transcatheter closure remains an excellent option especially in high risk patients.

Keywords: Acquired, Gerbode, defect

Introduction

The communication between the left ventricle and right atrium was firstly reported in 1838 by Thurman [1]. In 1957, Gerbode et al. [2] reported the first 5 cases with such a heart defect undergoing successful surgical repair. Such a defect is usually congenital, but rarely is acquired, as a complication of endocarditis [3], myocardial infarction, blunt chest trauma or after previous cardiac surgery [4]. This can be anatomically possible because the normal tricuspid valve is more apically displaced than the mitral valve. Acquired Gerbode defects with large septal destructions and vegetations involving the tricuspid valve can be challenging and might require complex patch repair. We present a case of our patient with this uncommon complication of endocarditis, simulating severe pulmonary hypertension.

Case report

A 40 year old lady from Kosovo, was referred to our hospital for severe pulmonary arterial hypertension and a mass in right atrium suspected for vegetation. About one month before, she was admitted in another hospital and received iv medication. The patient was febrile and the C-reactive protein, white cell count and erythrocyte sedimentation rate were elevated. Blood cultures demonstrated a methacilin sensitive Staphylococcus aureus growth.

Transthoracic echocardiograhy demonstrated a mobile, irregularly shaped, oscillating and highly mobile mass, located above the tricuspid valve septal leaflet (Fig. 1b). A clear jet across a small defect between left ventricle and right atrium consistent with Gerbode type defect was identified. The direction of the Doppler signal also leads to the true diagnosis (Fig. 1a). Cardiac magnetic resonance demonstrated a supravalvular flow associated with infravalvular jet according to the type C acquired Gerbode defect (Fig. 1c and 1d). A normal lung scan excluded pulmonary embolism. The tricuspid regurgitation was considered mild- to- moderate with estimated pulmonary arterial systolic pressure about 60-80 mmHg.

Fig. 1.

Fig. 1

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a Transesophageal echocardiography demonstrating the shunt between the left ventricle and right atrium. b Transthoracic echocardiography demonstrating the vegetation inserted above the septal leaflet of the tricuspid valve. c Cardiac magnetic resonance demonstrating a communication between the left ventricle and right atrium and right ventricle according to (d). C-type acquired Gerbode defect representing a supravalvular combined with n infravalvular communication between the left and right side of the heart

The patients underwent surgery after 2 weeks of antiobiotic therapy. Through a right atriotomy, large vegetation was attached to the septal leaflet and anterior leaflet of tricuspid valve was identified. On removal of the vegetation, a defect was found communicating between the left ventricle and right atrium (Fig. 2a and 2b). This defect represented an acquired Gerbode defect and was closed by two 5/0 pledgeted prolene sutures (Fig. 2c). Then the septal leaflet of tricuspid valve was resected and was replaced with a trimmed autologous pericardial patch. Anteriorly the newly created septal leaflet was attached to the anterior leaflet. Then, two synthetic chorda were employed (Fig. 2d). The hydraulic maneuver demonstrated trivial tricuspid valve regurgitation (Fig. 2c). Then the right atrium was closed. After an uneventfully post-operative period, the patient was discharged home in good clinical condition. Echocardiogram demonstrated trivial tricuspid valve regurgitation and no residual shunt. One year later the patient was doing well. The transthoracic echocardiography at follow-up demonstrated a moderate tricuspid valve regurgitation and no residual shunt.

Fig. 2.

Fig. 2

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a Intraoperative view demonstrating the acquired Gerbode defect after removing the septal leaflet and part of the anterior leaflet of the tricuspid valve. b A diagram representing the extension of the destructed valvular tissue. c Hydraulic maneuver after closure of the acquired Gerbode defect and reconstruction of the septal leaflet of the tricuspid valve. d A diagram demonstrating the final view of the operation

Comment

Gerbode described such a defect as a congenital atrioventricular shunt originating from the interventricular membranous septum with regurgitation into the right atrium through a defect or cleft in the tricuspid valve leaflet [2]. Less common is the acquired form of a Gerbode defect, which is often associated with bacterial endocarditis [524], myocardial infarction [2527], blunt chest trauma [28, 29] or post previous cardiac surgical procedures [30, 31].

After a careful revision of the literature we found 25 other reported cases with acquired Gerbode defect without previous cardiac surgery. In 22 of them, including our case, the cause was endocarditis. Only 4 patients were females. 7 out 21 cases presented endocarditis due to Staphylococcus aureus, usually involving the aortic valve extending below the aortic annulus onto the upper part of the interventricular septum. Infective tissue destruction leads to a perforation of the septum creating a communication between the left ventricle and the right atrium. However 8 out of 21 cases including our case presented tricuspid valve endocarditis causing an acquired Gerbode defect (Table 1). In difference to the endocarditis of the left side, in the tricuspid valve endocarditis the vegetations and destructed tissue are located in the right side so, it might be more than enough the closure of the communication only on the right side, if healthy tissue is present as in our case. The mortality was almost 9 % in patients with endocarditis. Also the postoperative complications such as renal failure was identified in 3 patients (13.6 %) and complete atrioventricular block in 3 patients (13.6 %). The high incidence of the complete atrioventricularf block might be explained with the closed vicinity of the Gerbode defect with the conduction system and atrioventricular node. Interestingely in none of the cases with Gerbode defect without prior cardiac surgery undergoing surgical correction is reported recurrence of the communication between the left ventricle and right atrium or endocarditis recurrence.

Table 1.

Patients with acquired Gerbode defect without prior cardiac surgery

Author (Ref) Year Gender/Age Location Bacteria Diagnosis Treatment Outcome
1. Battin [5] 1991 Male/15 na na TTE Surgery Survived
2. Saiki [6] 1994 Male/42 MV,AV Streptococcus hemolyticus TTE, Surgery Survived
3. Katoh [7] 1994 Male/58 TV na na Surgery Survived
4. Elian [8] 1995 Male/64 TV Staphylococcus aureus TTE, TEE, CC Surgery Survived
5. Velebit [9] 1995 Male/ 30 BAV Staphylococcus aureus TEE, CC Surgery Survived(AVB)
6. Winslow [10] 1995 Male/ 30 AV Staphylococcus aureus TTE, TEE Surgery Survived
7. Michel [11] 1996 Male/52 AV Streptococcus viridans TTE, TEE Conservative Survived
8. Alphonso [12] 2003 Male/ 63 AV Culture negative TTE Surgery Survived
9. Raja [13] 2006 Male/47 RA Staphylococcus aureus TTE, TEE Surgery Survived(RF)
10. Fukui [14] 2007 Male/57 TV, AV, MV na TEE Surgery Survived
11. Tatewaki [15] 2008 Female/7 TV, AV, MV Staphylococcus aureus TEE, CT Surgery Survived
12. Inouel [16] 2009 Female/21 AV Culture negative TTE, TEE Surgery Survived
13. Cortez-Dias [17] 2009 Male/59 MV Staphylococcus aureus TTE, TEE Conservative Died(AVB, RF)
14. Mendoza [18] 2009 Female/52 AV Streptococcus mutans TTE, CT Surgery Survived
15. Hori [19] 2010 Male/41 BAV na TTE Surgery Survived
16. Matt [20] 2010 Male/35 AV Hemophilus aphrophilus TTE,TEE Surgery Survived(AVB)
17. Ota [21] 2011 Male/71 AV Streptococcus pneumonia TTE,TEE Surgery Survived
18. Pillai [22] 2011 Male/12 TV Culture negative TEE Surgery Survived
19. Carpenter [23] 2012 Male/22 TV Staphylococcus lugdunensis TEE, CT Surgery Survived
20. Hsu [24] 2014 Male/40 BAV Cardiobacterium hominis TEE, Surgery Died(RF)
21. Prifti et al. 2015 Female/40 TV Staphylococcus aureus TTE, TEE Surgery Survived
Area of myocardial infarction
22. Hole [25] 1995 Male/63 Inferior myocardial infarction TTE Surgery Survived
23. Jobic [26] 1997 Female/72 Inferior myocardial infarction TTE, TEE Surgery Died (RF)
24. Newman [27] 1996 Male/72 Inferior myocardial infarction Trauma TTE, TEE Surgery Died
25. Venkatesh [28] 1996 Male/16 Blunt trauma TTE, TEE Surgery Survived
26. Selinger [29] 1998 Male/70 Bullet, trauma TTE,TEE,CC Surgery Survived
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Legend: TTE Transthoracic echocardiography, TEE Transesophageal echocardiography, CC Cardiac catheterization, CT Cardiac tomography, na not available, AV Aortic valve, BAV Bicuspid Aortic Valve, MV Mitral valve, TV Tricuspid valve, RF Renal Failure, AVB Complete atrioventricular block

Three other cases acquired Gerbode defect post myocardial infarction were found in the literature and all of them presented inferior myocardial infarction. 2 of them died after surgery. Two other patients were found with acquired Gerbode defect due to blunt chest trauma or bullet penetration. The overall mortality in 26 patients without prior cardiac surgery was 15.4 %. The postoperative hospital stay was less than 2 weeks in the survived cases.

Interestingely, acquired Gerbode defect after previous cardiac surgery was found in 62 other patients (Table 2). 26 of them underwent surgical closure of the defect and 18 percutaneous closure employing different occlude devices. 11 patients did not undergo any interventional procedure, probably due to small shunt or high operative risk. Most of the patients were undergone previously aortic valve surgery or mitral valve surgery. However the mortality, in this group of patients despite all of them were redo operations, was almost 3.2% extremely lower than patients undergoing first time cardiac surgical procedure (Table 1).

Table 2.

Patients with acquired Gerbode defect undergoing previous cardiac surgery

Author Year Gender Age Diagnostic tool Previous procedure Treatment Outcome
1. Katta et al. 1994 Male 54 TTE,TEE Endomyocardial biopsy Conservative Survived
2. Dzwonczyk et al. 1995 Male 25 TTE ASD repair na na
3. Dzwonczyk et al. 1995 Female 72 TTE AVR, VSD repair na na
4. Fukui et al. 2000 Male 53 TEE MVR x 2 Surgery Survived
5. Benisty et al. 2000 Male 72 TTE, TEE MVR Surgery n.a.
6. Benisty et al. 2000 Male 73 TTE, TEE MVR x 3, AVR Surgery n.a.
7. Weinrich et al. 2001 Female 58 TEE, CC MVRx 2 Surgery Survived
8. Wasserman et al. 2002 Male 78 TTE, TEE, AVR Surgery Survived
9. Cabalka et al. 2005 Female 70 TTE, TEE MVR x 2 Percutaneous Survived
10. Lorber et al. 2006 Female 78 TTE, CC MVR Percutaneous Survived
11. Ramasubbu et al. 2006 Male 41 TEE Aortic root reconstruction Surgery Survived
12. Ramasubbu et al. 2006 Female 44 TEE Aortic root reconstruction Conservative Survived
13. Trehan et al. 2006 Male 22 TTE, MRI, CC VSD + sinus valsalva repair Percutaneous Survived
14. Martinez et al. 2007 Female 70 TTE MVR Percutaneous Survived
15. Martinez et al. 2007 Male 67 TTE AVR Percutaneous Survived
16. Uslu et al. 2007 Male 54 TTE MVR Surgery Survived
17. Hilberath et al. 2007 Male 68 TEE AVR + endocarditis Surgery Survived
18. Frigg et al. 2008 Female 77 TEE, CC AVR Surgery Survived
19. Moaref et al. 2008 Female 51 TEE MVR Surgery na
20. Aoyagi et al. 2008 Female 71 TTE, CC MVR, TV repair Surgery Survived
21. Rothman et al. 2008 Male 86 TTE, CC MVR Percutaneous Survived
22. Hansalia et al. 2009 Female 46 TTE AVR Surgery Survived
23. Yared et al. 2009 Male 60 TTE, TTE AVR+ endocarditis na na
24. Gorki et al. 2009 Female 69 na AVR + endocarditis na na
25. Subramaniam et al. 2009 Male 60 TEE, CT AVR Surgery Survived
26. Amirghofran et al. 2009 Female 51 TEE MVR Surgery Survived
27. Silbiger et al. 2009 Female 30 TTE, CC VSD repair Conservative Survived
28. Cheema et al. 2009 Female 31 MRI VSD repair Conservative Survived
29. Can et al. 2009 Male 72 TTE AV nod ablation Conservative Survived
30. Can et al. 2009 Male 68 Autopsy AV nod ablation na Died
31. Dadkhah et al. 2009 Female 73 TEE TV repair Conservative Survived
32. Mohapatra et al 2009 Female 22 TEE MVR (RF) Surgery Survived
33. Sun et al. 2010 na na na MVR Surgery na
34. Sun et al. 2010 na na na MVR na na
35. Pursnani et al. 2010 Male 78 TTE, TEE AVR Surgery Survived
36. Sharma et al. 2011 Male 80 TTE AV nod ablation Conservative Survived
37. Kumar et al. 2011 Female 59 TEE AVRx2 + endocarditis Surgery Survived
38. Zhu et al. 2012 Baby 6 months TTE, TEE ASD, VSD repair Percutaneous Survived
39. Bochard-Villanueva 2012 Male 63 TEE, CT AVR+ endocarditis Surgery Survived
40. Vallakati et al. 2012 Female 53 TTE AVR Conservative Survived
41. Elmistekawy et al. 2012 Male 59 TEE AVR Surgery Survived
42. Dores et al. 2012 Male 50 TTE, TEE AVR, MVR Surgery Survived
43. Yurdakul et al. 2012 Male 68 TEE AVR Surgery Survived
44. Mousavi et al. 2012 Female 76 TEE, MRI AVR Conservative Survived
45. Ozdogan et al. 2012 Female 31 TTE, TEE MVRx2 + endocarditis Surgery Died
46. Anderson et al. 2012 na na na AVR na na
47. Toprak et al. 2013 Male 32 TTE, TEE AVR Conservative Survived
48. Notarangelo et al. 2013 n.a. 69 TTE, TEE MVR Percutaneous Survived
49. Sinisalo et al. 2013 Male 75 TTE, TEE, CC AVR Percutaneous Survived
50. Sinisalo et al. 2013 Female 23 TEE, CC VSD repair Percutaneous Survived
51. Sinisalo et al. 2013 Male 10 TEE, CC ASD, VSD repair Percutaneous Survived
52. Sinisalo et al. 2013 Male 8 TEE, CC VSD repair Percutaneous Survived
53. Dangol et al. 2013 Male 6 months TTE,TEE,CC ToF repair Percutaneous Survived
54. Lee et al. 2013 Male 3 months TTE, CC ASD, PDA, VSD repair Percutaneous Survived
55. Poulin et al. 2013 Female 75 TTE,TEE MVR Percutaneous Survived
56. Primus et al. 2013 Female 76 TTE,TEE AVR Conservative Survived
57. Chaturvedi et al. 2013 Male 62 TTE, MRI AVR Percutaneous Survived
58. Tayama et al. 2014 Male 75 TTE, CC MV and TV repair Surgery Survived
59. Hussain et al. 2014 Male 45 TTE, TEE AVRx2 Surgery Survived
60. Chamsi-Pasha et al 2014 Male 67 TTE, TEE MVR, TVR Surgery Survived
61. Taskesen et al. 2014 Male 74 TTE, TEE AVRx2 Percutaneous Survived
62. Fanari et al 2015 Female 50 TTE, CT AVR Percutaneous Survived
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Patients with acquired Gerbode defect undergoing previous cardiac surgery

Legend: TTE Transthoracic echocardiography, TEE Transesophageal echocardiography, CC Cardiac catheterization, CT Cardiac tomography, MRI Magnetic resonance, na-not available, AVR Aortic valve replacement, MVR Mitral valve replacement, TV Tricuspid valve, ASD Atrial septal defect, VSD Ventricular septal defect, ToF Tetralogy of Fallot, PDA Patent ductus arteriosum

The diagnosis was made in most of the cases by transthoracic and transesophageal echocardiography. It seems that echocardiographic examination is the most frequently diagnostic tool employed in these patients. Identification of an actual communication is often extremely difficult, so a careful and meticulous echocardiogram should be done in order to prevent echocardiographic misinterpretation of this defect as pulmonary arterial hypertension. The large systolic pressure gradient between the left ventricle and the right atrium would expectedly result in a high velocity systolic Doppler flow signal in right atrium and it can be sometimes mistakably diagnosed as tricuspid regurgitant jet simulating pulmonary arterial hypertension. However cardiac catheterization, cardiac tomography or magnetic resonance such as in our case offers valuable information. Interestingely our case after been diagnosed with Gerbode defect underwent cardiac magnetic resonance which revealed a class C acquired Gerbode defect as previously described [4].

Treatment of the acquired Gerbode defect depends on symptoms, magnitude of shunt, flow volume, concomitant anatomic abnormalities and co-morbidities. Asymptomatic, chronic, small defects can be managed conservatively.

Percutaneous transcatheter closure techniques have been employed in almost 25% of patients, mostly in high risk surgical candidates due to previous valve replacement, advanced age, anti-coagulation, and multiple comorbidities. Advanced cardiac imaging techniques such as transesophageal echocardiography provide excellent images for guidance in device sizing and deployment. The Amplatzer duct occluder device is a mainstay in treatment as it provides less radial force [30] than the muscular ventricular septal defect closure device causing fewer complications [31].

In most of the cases with acquired Gerbode defect a simple direct suture might be enough to close the defect [12] such as in our case, although large Gerbode defect associated with partial or total distruction of the tricuspid valve can be much more challenging. In such cases reconstruction or replacement of the tricuspid valve might be required. Tatewaki et al. [15] describe a pericardial patch closure with sutures from the ventricular side of the tricuspid valve through the leaflets. Others reported a Dacron patch closure with septal leaflet reimplantation onto the patch [9, 12], an annuloplasty ring implantation, or tricuspid valve replacement [5, 8, 9, 12]. Matt et al. [20] presented a double plicated patch combining a defect closure and reconstruction of the tricuspid valve annulus and septal leaflet. In our case we closed the defect from the right side using two single pledgeted prolene suture and reconstruct the septal and anterior tricuspid valve leaflets using an autologous pericardial patch. This technique allowed us to perform a complex right-sided defect repair with one patch that might be advantageous in an infective situation. Such a technique might allow an extensive reconstruction of the tricuspid valve, if necessary.

As conclusion, the acquired Gerbode defect a rare form of intracardiac shunt, but its incidence has been increasing during the last decades. Increased numbers of invasive and repeat cardiovascular procedures and infective endocarditis have led to this increase in acquired Gerbode defect. Surgical treatment is always feasible with excellent outcome. However the percutanous transcatheter closure remains an excellent option especially in high risk patients.

Conclusion

The acquired Gerbode defect a rare form of intracardiac shunt, but its incidence has been increasing during the last decades. Increased numbers of invasive and repeat cardiovascular procedures and infective endocarditis have led to this increase in acquired Gerbode defect. Surgical treatment is always feasible with excellent outcome. However the percutanous transcatheter closure remains an excellent option especially in high risk patients.

Consent

Written informed consent was obtained from the patient for publication of this Case report and any accompanying images. A copy of the written consent is available for review by the Editor-in-Chief of the Journal of Cardiothoracic Surgery.

Footnotes

Competing interests

We declare that we do not have any competing or financial interests with this manuscript.

Authors’ contribution

FA and AD diagnosed the patient and followed the patient postoperatively. EP and AB performed the surgery. All authors were involved on the literature review and manuscript writing process. All authors read and approved the final manuscript.

Authors’ information

Edvin Prifti, MD, PhD, Fadil Ademaj, MD, Arben Baboci, MD, Aurel Demiraj, MD.

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