Abstract

INTRODUCTION

Mycotic aortic aneurysm (MAA) is a life-threatening condition. Endovascular repair (EVAR) of aortic aneurysms has been found to be a safe and effective alternative to open repair. We aimed to present the short- to medium-term outcomes for EVAR of MAA in our cohort.

METHODS

We conducted a retrospective study of 23 consecutive patients with MAA who underwent EVAR in our hospital from January 2008 to July 2017.

RESULTS

The mean age of our study population was 62 years. The mean aneurysmal size was 3.2 cm. Abdominal MAAs (n = 16, 70%) were the most common, followed by thoracic MAAs (n = 4, 17%). There was no 30-day mortality in our cohort. Endoleak (Types 1, 3, 4) was detected in 3 (13%) cases. At the one-month surveillance computed tomography aortogram, all patients had a reduction in aneurysmal size and 5 (22%) had complete aneurysmal sac resolution. 7 (30%) patients had sac resolution at six months and 8 (35%) patients, at 12 months. The overall survival was 91%, 80% and 61% at one, 12 and 60 months, respectively.

CONCLUSION

EVAR is a feasible and durable method for the repair of MAA, with a five-year overall survival of 61%. All patients in our study had a reduction in aneurysmal size at one month, with 65% having complete aneurysmal sac resolution by 12 months.

 Keywords: endovascular aortic repair, mycotic aortic aneurysms

INTRODUCTION

Mycotic aortic aneurysm (MAA) is a life-threatening condition that represents 0.5%–2.6% of all aortic pathologies.(1) Patients who develop these aneurysms commonly have multiple risk factors for an immunocompromised state. In addition, they tend to present with concomitant sepsis, which puts them at high surgical risk.(2) Classically, the standard approach consists of aggressive intravenous (IV) antibiotic therapy with open surgical debridement of the aneurysm and surrounding infected tissue, as well as extra-anatomic or in situ bypass.(3,4) However, outcomes are poor, especially in the elderly, with mortality and morbidity rates of up to 43%.(5)

Endovascular repair (EVAR) of aortic aneurysms provides a safe and effective alternative to a largely invasive approach,(6,7) with multiple benefits, including reduction of massive blood loss, lower incidence of early mortality/morbidity and avoidance of aortic cross-clamping, which predisposes a patient to prolonged distal ischaemia.(8,9) This is especially so in high-risk surgical patients. However, EVAR has various limitations – the infected material and debris are left inside the patient, which increases the risk of the prosthesis being infected, as well as persistent or recurrent sepsis. Other challenges include rupture of the aorta above or below the graft owing to continued infection,(5) and other conventional EVAR risks such as endoleak, contrast-induced nephropathy and embolic or thrombotic events. In this study, we aimed to present the short- to medium-term outcomes for EVAR of MAA, especially in terms of sac resolution, as well as a review of the current available literature.

METHODS

We conducted a single-institution retrospective review of 23 patients who underwent EVAR of MAA in our hospital from January 2008 to July 2017. The diagnosis of MAA was based on a combination of the following criteria: (a) clinical presentation (fever, pain, sepsis); (b) biochemical results (leucocytosis, elevated inflammatory markers like C-reactive protein); and (c) radiological findings (large aneurysms that were ruptured/contained, periaortic gas).

A common study protocol was applied, with the collected data consisting of patient demographics, comorbidities, biochemistry upon presentation, aneurysm characteristics (size and morphology), duration of antibiotic therapy, operative data, postoperative complications and radiological surveillance results. Devices used to repair the aneurysms consisted of stent grafts from Medtronic (Minneapolis, MN, USA), Cook Medical (Bloomington, IN, USA) and Endologix (Irvine, CA, USA).

All patients received broad-spectrum empirical IV antibiotics 1–90 days preoperatively in consultation with the infectious diseases (ID) physician. Patients with positive blood cultures were switched to organism-specific antibiotics once the results were out, while the remaining patients continued with broad-spectrum antibiotics. 11 patients were considered stable and underwent early stenting after control of systemic sepsis with antibiotics, while the other 12 underwent emergency repairs. Postoperatively, the patients completed six weeks of targeted IV antibiotics followed by targeted lifelong suppressive antibiotics upon consultation with the ID physician. They also received regular reviews: clinical examination, biochemical testing and follow-up computed tomography (CT) at one, six and 12 months. All patients with negative blood cultures were prescribed Bactrim (trimethoprim and sulfamethoxazole).

Investigated factors were analysed using descriptive statistics. Percentages were used for categorical data and means with standard deviations for continuous data. Kaplan-Meier survival analysis was performed to ascertain the survival rates at pre-determined intervals. All data analysis was performed using IBM SPSS Statistics version 21.0 for Windows (IBM Corp, Armonk, NY, USA).

RESULTS

During the nine-year study period, 23 patients (21 male and 2 female) with MAA were identified (Table I). The mean age of the study population was 62 (range 42–80) years. The median clinical follow-up duration was 19 (range 2–143) months. 17 (74%) patients had at least one risk factor for an immunocompromised state, the most common being diabetes mellitus (48%), followed by human immunodeficiency virus (22%), chronic steroid use (17%) and chronic kidney disease (17%). 16 (70%) patients had positive blood cultures, with Salmonella enterica being the most common organism identified (n = 11, 48%).

Table I

Patient characteristics (n = 23).

Upon presentation, 12 (52.2%) patients had fever, 14 (60.9%) had leukocytosis (> 10 × 109/L), 12 (52.2%) had anaemia (male < 12 g/dL, female < 10 g/dL), 17 (73.9%) had elevated C-reactive protein (> 5 mg/L) and 21 (91.3%) had hypoalbuminaemia (< 35 g/L). The mean preoperative antibiotic duration at the time of operative repair was 15 (range 1–90) days. Postoperatively, all patients received lifelong antibiotics.

Abdominal MAAs (n = 16, 70%) were the most common, followed by thoracic MAAs (n = 4, 17%) and common iliac aneurysms (n = 3, 13%). 6 (26%) patients presented with a ruptured aneurysm and 1 (4%) patient had an aorto-enteric fistula. The mean aneurysmal size was 3.2 (range 1.1–6.8) cm. The mean operation time was 132 (range 64–310) minutes. The mean amount of blood loss was 112 (range 50–300) mL and the average duration of stay in the intensive care unit or high-dependency unit was 2.25 (range 1–10) days. There was no 30-day mortality, and the mean length of hospital stay was 31 (range 5–84) days (Table II). After repair, 9 (39.1%) patients contracted nosocomial infections, 8 (34.8%) required a second operation, 7 (30.4%) had acute kidney injury and 5 (21.7%) had cardiac complications. One patient had thrombosis of the left common iliac artery.

Table II

Operative data and outcomes (n = 23).

Endoleak (Types 1, 3, 4) was detected in 4 (17%) patients, for which they underwent stent re-lining after detection on surveillance imaging. 3 (13%) patients required image-guided drainage of peri-aortic abscesses and 1 (4%) patient required a laparotomy and excision of an aorto-oesophageal fistula with duodenal-jejunal anastomosis. 2 (9%) patients suffered from recurrent aneurysm-related sepsis, and there was one aneurysm-related mortality (secondary to aorto-oesophageal fistula). Other causes of mortality included pneumonia secondary to systemic lupus erythematosus, metastatic lung cancer, malignant pleural effusion secondary to oesophageal carcinoma, enterococcaemia secondary to psoas abscess and ischaemic heart disease. Of the other five cases of mortality, only one patient underwent an emergency repair.

At one-month surveillance CT aortogram, all patients showed a reduction in the size of the aneurysm; of these, 5 (22%) patients had complete aneurysmal sac resolution, 7 (30%) had sac resolution at six months and 8 (35%) had sac resolution at 12 months. The overall survival was 91%, 86%, 80% and 61% at one, six, 12 and 60 months, respectively (Table II, Fig. 1). There was no difference in survival between those who underwent elective and emergency repair, as the causes of mortality in this series were largely unrelated to the aneurysm, with the exception of the one case of aorto-oesophageal fistula.

Fig. 1

Kaplan-Meier survival curve shows overall survival of 91%, 80% and 61% at 1, 12 and 60 months, respectively.

DISCUSSION

Despite advances in perioperative optimisation and antimicrobial regimes, an optimal treatment strategy for MAA has yet to be agreed upon. Although EVAR is now widely used and generally acceptable, the decision to rely solely on EVAR as the therapeutic gold standard is uncertain. Kim et al reported good short- and medium-term outcomes in their series with open repair of MAA despite their patients being at high risk for open surgery.(10) Hybrid therapy (combination of EVAR and open surgery) remains an option, especially for those with recurrent sepsis. However, for some physicians, placing a prosthetic material in an infected field is counter-intuitive, even controversial.

Studies have shown that Salmonella infections are more common in the Asian population compared to their Western counterparts.(11) A review of the existing literature (Table III) found that out of seven studies conducted in the East, six reported Salmonella as the most common organism identified in blood cultures.(12-17) This corresponds to our finding – 70% of our patients who had positive blood cultures were positive for Salmonella. Salmonella-related aneurysms are also known to have rapid disease progression and a risk of early rupture. This is because Salmonella tends to adhere to vascular endothelium, especially if it is diseased by atherosclerosis.(12)

Table III

Endovascular repair of mycotic aortic aneurysms in the literature.

Kritpracha et al reported that EVAR had a poor outcome in patients with fistula complication.(16) This is also noted in our study, as the only aneurysm-related death was secondary to an aorto-oesophageal fistula, likely because these patients tend to present with overwhelming sepsis and shock, and are unable to recover owing to their advanced age and comorbidities. Our centre had overall higher rates of nosocomial infections as well as cardiac and kidney complications compared to those reported in the current literature. This could be due to the advanced age of our patient population and their various comorbidities, which precluded them to a difficult postoperative recovery. Our centre’s endoleak rate of 17% is comparable to that of other studies (range 0%–34%).(2,12,17) Of note, the Type 3 and 4 endoleaks that occurred in this series were from the older-generation stent grafts, and such leaks are exceedingly rare with the advent of modern devices.

Our five-year survival rate of 61% was similar to that of other studies,(18,19) while our in-hospital mortality rate was also comparable to that reported in other studies,(12,13,20,21) with a mean rate of 10% (range 0%–25%). Compared with open surgery, which showed in-hospital mortality rates of 12%–27%,(3,9,11) our in-hospital mortality rate for EVAR was much lower, at 0%. Thus, EVAR as the first-line treatment in patients with MAA is a reasonable approach owing to its low in-hospital mortality rate. Notably, most of the identified studies did not report the five-year survival rates owing to the lack of follow-up.

In our study, the reported sac resolution rates of 22%, 30% and 35% at one, six and 12 months, respectively, are one of the first few reported and should be a documented follow-up marker for future studies. We noted that five studies in the current literature had published their CT surveillance results (Table IV). Of these, three studies reported complete resolution of the aneurysmal sac in their surviving patient population(6,18,22) and two studies reported a significant reduction in aneurysmal size after seven and 12 months, respectively.(23,24) However, as these papers had only a small sample population of 1–8 patients, it is difficult to draw any statistically meaningful conclusions from them.

Table IV

Studies documenting MAA sac resolution after EVAR.

Compliance to antibiotic therapy is of utmost importance. As recurrent infection cannot be excluded, lifelong antibiotic therapy and radiological surveillance are mandatory. This is especially so in our patient population, most of whom were frail and immunosuppressed and hence, might not have been able to mount an early response to recurrent infection. However, there is no universal agreement on the mandatory use of lifelong antibiotic therapy; in some centres, antibiotic therapy may be discontinued if there is no clinical or radiological evidence of ongoing sepsis.(1,9,25)

The main limitation of the current study is its small sample size owing to the rarity of the disease, making it impossible to reach statistically meaningful conclusions. Other limitations include the retrospective nature of the study and the existence of patient selection bias. Furthermore, the median follow-up duration of 19 months is not long enough to identify all cases of late aneurysm-related mortality, especially in patients who underwent EVAR. Therefore, an extended, multi-institutional study that compares the outcomes of open repair and EVAR would be recommended.

In conclusion, EVAR was a feasible and durable method for repairing MAA in our patients who were on lifelong antibiotics. Although the aortic interventions performed were successful, immunocompromised patients had difficult postoperative recoveries. All our patients saw a reduction in aneurysmal size at one month, with 65% having complete aneurysmal sac resolution by 12 months. The recurrence rate for aneurysm-related sepsis was low at 9%, and the five-year overall survival rate was acceptable at 61%.
 
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