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CLINICAL STUDY: INTERVENTIONAL CARDIOLOGY

Management of coronary artery fistulae

Patient selection and results of transcatheter closure

Laurie R. Armsby, MD^*,*, John F. Keane, MD^*, Megan C. Sherwood, MBBS, FRACP^*, Joseph M. Forbess, MD, Stanton B. Perry, MD^* and James E. Lock, MD, FACC^*

^* Department of Cardiology, The Children’s Hospital, Harvard Medical School, Boston, Massachusetts, USA
Department of Cardiovascular Surgery, The Children’s Hospital, Harvard Medical School, Boston, Massachusetts, USA

Manuscript received March 19, 2001; revised manuscript received October 10, 2001, accepted December 21, 2001.

^* Reprint requests and correspondence: Dr. Laurie R. Armsby, Department of Cardiology, Children’s Hospital, 300 Longwood Avenue, Boston, Massachusetts 02115 USA.
armsby{at}cardio.tch.harvard.edu

	Abstract

Top Abstract Methods Results Discussion Transcatheter and surgical... Observations Study limitations Conclusions References

 
OBJECTIVES: We report short-term findings in 33 patients after transcatheter closure (TCC) of coronary artery fistulae (CAF) and compare our results with those reported in the recent transcatheter and surgical literature.

BACKGROUND: Transcatheter closure of CAF has been advocated as a minimally invasive alternative to surgery.

METHODS: We reviewed all patients presenting with significant CAF between January 1988 and August 2000. Those with additional complex cardiac disease requiring surgical management were excluded.

RESULTS: Of 39 patients considered for TCC, occlusion devices were placed in 33 patients (85%) at 35 procedures and included coils in 28, umbrella devices in 6 and a Grifka vascular occlusion device in 1. Post-deployment angiograms demonstrated complete occlusion in 19, trace in 11, or small residual flow in 5. Follow-up echocardiograms (median, 2.8 years) in 27 patients showed no flow in 22 or small residual flow in 5. Of the 6 patients without follow-up imaging, immediate post-deployment angiograms showed complete occlusion in 5 or small residual flow in 1. Thus, complete occlusion was accomplished in 27 patients (82%). Early complications included transient ST-T wave changes in 5, transient arrhythmias in 4 and single instances of distal coronary artery spasm, fistula dissection and unretrieved coil embolization. There were no deaths or long-term morbidity. Device placement was not attempted in 6 patients (15%), because of multiple fistula drainage sites in 4, extreme vessel tortuosity in 1 and an intracardiac hemangioma in 1.

CONCLUSIONS: A comparison of our results with those in the recent transcatheter and surgical literature shows similar early effectiveness, morbidity and mortality. From data available, TCC of CAF is an acceptable alternative to surgery in most patients.

Abbreviations and Acronyms   TCC   CAF   coronary artery fistulae   Cx   circumflex   ECG   electrocardiogram   LAD   left anterior descending   LCA   left coronary artery   LV   left ventricle   RA   right atrium   RCA   right coronary artery   RV   right ventricle   TCC   transcatheter closure

Transcatheter closure (TCC) of CAF has been utilized since 1983 (4,6–15). Prior reports, including our own (14), have been limited in patient number (2 to 13 patients) and follow-up data (longest mean follow-up, 1.5 years). Beginning in 1988, our institutional approach has been to attempt TCC in all patients presenting with clinically significant, isolated CAF. We present our experience to: 1) describe the techniques used in TCC of CAF; 2) report our results with this procedure; 3) compare our findings with those described in the transcatheter and recent surgical literature; and 4) outline our current indications for surgical or TCC of CAF.

	Methods

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Patient identification, selection and classification.   From our medical and surgical databases, we identified all patients with CAF who underwent a catheterization or surgical procedure between January 1988 and August 2000. After exclusion of those with additional complex cardiac disease requiring surgical management, and of those with tiny CAF found incidentally during echocardiography or catheterization, we identified 39 patients with clinically significant CAF (i.e., those producing symptoms or a typical murmur). Of the 39 patients, TCC was undertaken in 33 (TCC patient group) but not attempted in 6 patients (non-intervention patient group).

Clinical, electrocardiogram and echocardiographic assessment.   All patients underwent a cardiac evaluation, including medical history, physical examination, electrocardiogram (ECG) and echocardiogram. Echocardiographic features indicating a significant CAF included (one or more) the following: cardiac chamber dilation; narrowest color Doppler flow jet 4 mm; or reversal of flow in the descending aorta.

Transcatheter closure technique.   Femoral arterial and venous catheters were placed via percutaneous access. After collection and analysis of hemodynamic data, the anatomy and dimensions of the coronary arteries and fistulae were determined using selective (often power-assisted) coronary angiograms. Hand injections of contrast facilitated catheter positioning in the distal fistula. Due to the typically high flow rates in CAF, balloon occlusion angiography was used within the fistula to precisely identify all distal coronary branches, fistula dimensions and drainage sites. Catheter positioning within the distal fistula was often facilitated by the use of high-torque floppy wires or tracker catheters (Tracker Infusion Catheter, Medi-tech/Boston Scientific Corp., Watertown, Massachusetts), as reported by other investigators (16,17).

Feasibility of closure by a device was determined by the number and location of drainage sites, the ability to cannulate the distal fistula and the proximity of coronary branches to the optimal occlusion site. Special care was taken to avoid allowing the device to interfere with flow into any visible coronary artery. Occlusion devices included Gianturco coils (Occluding Spring Emboli; Cook Cardiology; Bloomington, Indiana), double umbrella devices (Bard PDA Umbrella, Bard Clamshell Septal Umbrella, USCI Division, C.R. Bard; CardioSEAL: Nitinol Med Techn Inc.; Boston, Massachusetts) and Gianturco Grifka vascular occlusion device (GGVOD: Cook Cardiology; Bloomington, Indiana). The selection of occlusion device was based on the anatomic features of the fistula. Coils, used primarily in smaller CAF (Fig. 1), offer advantages of smaller sheath and catheter delivery sizes and lower cost. Double umbrella devices allow more precise positioning and were used in larger fistulae with coronary branches close to the occlusion site.

View larger version (66K): [in this window] [in a new window]   Figure 1 Coronary artery fistula from right coronary artery to right atrium. (A) Single insertion site into right atrium (arrow). (B) Complete occlusion following transvenous placement of single coil (arrow).

View larger version (81K): [in this window] [in a new window]   Figure 2 Coronary artery fistula from left coronary artery to left atrium. (A) Arteriovenous wire loop enabling passage of venous catheter across the atrial septum into the fistula drainage site (arrow). (B) Angiogram following transvenous deployment of a 12-mm Rashkind device (arrow), showing coronary artery fistula occlusion and coronary artery side branches that were not evident in angiograms performed without balloon occlusion.

Data analysis.   Medical records including clinical evaluations, catheterization, ECG and echocardiographic and follow-up data were reviewed in all patients. Approval to conduct the medical record review was obtained from our Institutional Review Board.

	Results

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Transcatheter closure patient group.   Thirty-nine patients (age, 8 months to 68 years; median age, 8 years) underwent cardiac catheterization with the intent to close the CAF. Occlusion devices were placed in 33 patients (85%). Of these, two patients underwent a second catheterization for significant residual fistulae, resulting in a total of 35 procedures. Additional cardiac lesions were present in six patients, consisting of atrial arrhythmias in two patients and single instances of pulmonary atresia post Fontan procedure, aortic stenosis post Ross procedure, post heart transplant and a single left coronary artery (LCA). Thirteen patients (39%) were symptomatic (dyspnea on exertion, 8; chest pain, 3; palpitations, 1; and fatigue, 1). Continuous murmurs were present in 31 patients and systolic murmurs in 2. Pre-catheterization ECGs were normal in 25 of the 33 patients (76%), with left ventricular (LV) hypertrophy evident in 4, non-specific ST-T wave changes in 3 and right atrial (RA) enlargement in 1.

The sites of CAF origin and drainage are detailed in Figure 3. Origin from the LCA was more common than from the right, and drainage to the right heart occurred in all but two. Fistulae originated from two coronary arteries in two patients and had multiple drainage sites in three others.

View larger version (22K): [in this window] [in a new window]   Figure 3 The transcatheter closure patient group: coronary artery fistulae origin and drainage sites. Circ = circumflex artery; CS = coronary sinus; LA = left atrium; LAD = left anterior descending coronary artery; LMCA = left main coronary artery; LV = left ventricle; PA = pulmonary artery; RA = right atrium; RCA = right coronary artery; RCC = right coronary cusp; RV = right ventricle; RVOT = right ventricular outflow tract; SVC = superior vena cava.

View larger version (49K): [in this window] [in a new window]   Figure 4 Device delivery in the transcatheter closure patient group. (A) Occlusion device used. (B) Catheter approach for device delivery.

View larger version (42K): [in this window] [in a new window]   Figure 5 Residual flow following transcatheter closure of coronary artery fistula by angiography and echocardiography.

Non-intervention patient group.   Placement of an occlusion device was not attempted in 6 (15%) of the 39 patients initially considered for TCC, all but one catheterized early in our experience (1988 to 1993). These patients ranged in age from 3 weeks to 48 years (median age, 4 years) at catheterization; additional cardiac lesions were present in three patients, consisting of a single LCA in two and intracardiac hemangioma in the other. One patient was symptomatic; all had continuous murmurs. The sites of CAF origin and drainage are detailed in Table 1. Placement of a device was not attempted due to the presence of multiple fistula drainage sites in four, extreme vessel tortuosity with inability to cannulate the distal fistula (Fig. 6) in one and the presence of multiple minute drainage sites from an intracardiac hemangioma in the other. There were no immediate or late complications.

View larger version (164K): [in this window] [in a new window]   Figure 6 Angiogram showing tortuous coronary artery fistula from right coronary artery to coronary sinus (Table 1, Patient 1): occlusion not attempted as antegrade access to coronary artery fistula unsuccessful and catheter lengths insufficient to reach distal fistula from a retrograde approach.

Non-intervention patient group
Follow-up data (median, 7.4 years; range, 5.8 to 11 years) were available in only three of the six patients. They were asymptomatic: the murmur had disappeared in the patient with an intracardiac hemangioma, and echocardiograms, available in only two patients, were unchanged.

	Discussion

Top Abstract Methods Results Discussion Transcatheter and surgical... Observations Study limitations Conclusions References

 
Elective closure of significant CAF in childhood has been advocated to prevent later complications (1,5,8,11). Since its introduction in 1983 (6), TCC of these lesions is increasingly being utilized as an alternative to surgical closure.

	Transcatheter and surgical literature review

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TCC literature..   Excluding single case reports, TCC of CAF has been reported in 45 patients (5 weeks to 71 years of age; median, 12 years) since 1982 (4,7–13,15) (Table 2 ). The data from our previously published report (14) are included in our current patient group. The fistulae were isolated lesions in all but one (prior aortic valve replacement). Symptoms were reported in 18 (40%), including angina in 10, dyspnea on exertion in 6 and single instances of fatigue and poor growth. The fistulae originated from the LCA in 24 (10 from the left anterior descending [LAD], seven from the circumflex [Cx]), from the right coronary artery (RCA) in 19, and from both RCA/LCA in two. Fistulae drained to the RA in 14, right ventricle (RV) in 12, pulmonary artery in 11, coronary sinus in 3, LV in 2, bronchial artery in 2 and superior vena cava in 1.

At follow-up (1 day to 4 years; longest mean follow-up, 12 months) in 42 of 45 patients, all were asymptomatic and without late complications or deaths. At follow-up imaging studies of 33 patients (echocardiograms in 27, angiograms in 6), complete closure was reported in 91%.

Surgical literature..   Surgical series published in the past decade (1–3,18–20) consisted of 71 patients (81 fistulae) (Table 2). These patients ranged in age from 6 days to 77 years (median, 6 years); 19 had additional cardiac lesions (27%), including patent ductus arteriosus in 4, atrial septal defect and mitral regurgitation in 3 each, 2 patients each with aortic regurgitation, tetralogy of Fallot, ventricular septal defect, RCA origin atresia and coarctation of the aorta in 1. Closure of CAF was performed concurrent with additional cardiac surgical procedures in 11 patients (15%), including valve replacement, atrial or ventricular septal defect repair and patent ductus arteriosus ligation. The use of cardiopulmonary bypass was reported in 37 patients (57%). The fistulae arose from the RCA in 21 patients, the LCA in 40 (LAD in 18, Cx in 7) and both RCA/LCA in 10. Drainage sites included the RV in 28 patients, pulmonary artery in 20, RA in 18, RV outflow tract in 3 and 1 each in the left atrium and LV. There was one operative death (1.4%) secondary to myocardial infarction (19). Other complications included arrhythmia in five, transient ischemic changes on ECG in one and stroke in another. There were no reported late post-operative deaths. Follow-up was available in 65 patients (range, 0.1 to 21.1 years; longest mean follow-up, 7.2 years), and all were asymptomatic. Follow-up imaging studies were reported in only 21 (30%) of the 70 survivors (angiography, 13; echocardiography, 8), with complete closure rates in these ranging from 50% to 100% (1,18,20).

	Observations

Top Abstract Methods Results Discussion Transcatheter and surgical... Observations Study limitations Conclusions References

 
The origin and drainage sites in the TCC and surgical literature are similar to our data except for our lower incidence of drainage to a pulmonary artery. Delivery of the occlusion device (usually coils) was more often performed via a retrograde approach in the transcatheter literature (89%) compared with our series (54%). Follow-up imaging was available in 75% of the patients reported in the transcatheter literature, 30% of surgical patients and 82% of patients in our series. Because of this wide disparity in follow-up imaging data, a valid comparison of documented closure of CAF between the techniques is difficult. However, given the available data, complete closure by transcatheter and surgical techniques are comparable, as are rates of early and late complications (Table 2).

While we have found TCC of CAF feasible in most patients, features that may render CAF unsuitable for this technique include those with extreme vessel tortuosity, multiple drainage sites and coronary branches at the site of optimal device positioning. The ability to cannulate the distal fistula and avoid flow interference through nearby coronary branches is mandatory for successful TCC. Early in our experience (prior to 1994), we determined that CAF with multiple drainage sites precluded an attempt at TCC; however, with experience and improvements in catheterization equipment and occlusion devices, we have subsequently successfully closed fistulae with this characteristic in three patients.

An "ideal" study to provide a rigorous comparison of transcatheter versus surgical therapy would necessitate a randomized multicenter trial with fixed entry criteria, similar operator skills at each of the institutions and an extended period of follow-up. The technique of therapy would need to remain largely fixed during the course of the study. Without the data from such a trial, we have adopted the following therapeutic strategy: 1) those with CAF and additional complex heart disease requiring surgery are referred for surgical repair; 2) patients with a clinically significant CAF (i.e., producing symptoms or a typical murmur) are referred for catheterization, where the fistula anatomy is further defined; 3) those with suitable anatomy undergo TCC, while those unsuitable for TCC are offered surgical ligation or are followed up medically.

With regard to tiny CAF now being diagnosed with improved color flow Doppler technology, we currently, as do other investigators (20,21), follow such patients without intervening, because the incidence of cardiac complications is low and there is the possibility of spontaneous closure. There are others, however, who disagree with this strategy (5,22).

	Study limitations

Top Abstract Methods Results Discussion Transcatheter and surgical... Observations Study limitations Conclusions References

 
A meaningful comparison of transcatheter and surgical closure of CAF is limited by (a) small patient numbers and (b) the paucity of follow-up imaging, especially in the surgical literature. Additionally, although we have limited our review of the surgical literature to series that were published within the past decade, each of these includes patients treated prior to this

	Conclusions

Top Abstract Methods Results Discussion Transcatheter and surgical... Observations Study limitations Conclusions References

 
With increased experience and improved devices and techniques, TCC of CAF is emerging as a successful therapeutic strategy. The safe and effective results of both surgical closure and TCC support the current convention of elective closure of clinically significant CAF in childhood. The preferred method of approach for any individual patient will depend on the anatomy of the fistula, the presence or absence of associated defects and the experience of the interventional cardiologists and surgeons.

	Footnotes

 
Dr. Armsby was, in part, supported by NIH training grant T32 HLO7572-16. Dr. Lock is a co-inventor of the Clamshell-CardioSEAL device and his institution receives royalties on its commercial sales; and he also participates in regulatory studies of this device.

	References

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