Laparoscopic adrenalectomy is the standard of care for hyperfunctioning benign adrenal disorders, such as pheochromocytomas and cortisol- or androgen-producing adenomas. It is also a therapeutic option for aldosterone-producing adenomas (APAs), adrenal hyperplasia resistant to medical treatment, and adrenocorticotropic hormone (ACTH)-dependent hypercortisolism, in which the source of ACTH production cannot be removed. Although considered safe, it is associated with an overall mortality of 0.2% and a mean length of stay of 3.3 days 1. Computed tomography (CT)-guided percutaneous instillation of sclerosing agents, such as absolute ethanol or acetic acid, has been used as an alternative treatment for adrenal lesions because these agents lead to coagulative necrosis 2–9. Potential advantages over laparoscopic surgery include lower complication rates, reduced length of stay and lower costs; however, few reports have been published to date, and none reported long-term follow-up data. The objective of this study was to evaluate the safety and efficacy of CT-guided percutaneous ethanol ablation (PEA) in a group of patients with hyperfunctioning benign adrenal disorders with long-term follow-up.

We presented here the long-term results of CT-PEA for the treatment of hormonally active adrenal lesions.

According to our results, PEA does not appear to be a reasonable alternative treatment to hormonally active adrenal lesions. Overall, the success rate was low (only one out of nine patients, 11.1%, was cured) and the incidence of complications was high (seven out of eleven procedures, 63.6%).

Other groups have reported treating functioning adrenal lesions with percutaneous chemical ablation (Table 2), for a total of 40 pheochromocytomas 5, 18 APAs 3,6–9 and 12 cortisol-producing adenomas (CPA) 6,7,9. Except for one patient who did not present a complete response to treatment 7 and another who recurred four years after ablation and was successfully retreated 8, both of them with APA, all other patients were considered to have been successfully treated. The only complications reported by these groups were pain 6,7,9, periprocedural increase in blood pressure 5,7,9 and adrenal insufficiency in one case 9. One patient, with a cortisol-producing adenoma, had severe pain and marked hypertension during the procedure, prompting its interruption, and had no complications when retreated during epidural anesthesia 7. No treatment was performed under general anesthesia by these groups.

Although technical differences, such as the ablating agent employed (acetic acid or ethanol), volume instilled, size of lesions, and number of treatment sessions performed, might play a role in explaining the seemingly better results reported in the literature, we believe that our longer follow-up data show that late recurrence may limit treatment in patients with PEA. Excluding the patient who underwent adrenalectomy one month after the ablation and who was clinically controlled, our patients who improved with PEA needed surgery 39, 68, 83 and 96 months after ablation, and only one was still cured after 110 months of follow-up; this pattern of late recurrence, also described by Chang et al 8, might not have been more often described due to the other published follow-ups ranging from 15 to 54 months.

PEA proved to be an even less effective procedure for the treatment of hypercortisolism secondary to nonfocal adrenal diseases, such as Cushing disease or macronodular hyperplasia. In our limited series, only one of the three patients with macronodular hyperplasia (subject 1) developed remission after ablation (lasting 10 and 68 months, after the second and third treatment sessions, respectively). The single patient with Cushing disease was also not cured after undergoing one session of bilateral adrenal PEA. Whether a greater number of ablation sessions or the use of acetic acid in these cases could have yielded better results remains unclear.

We observed significant cardiovascular side effects of PEA in several of these patients with adrenal disorders. All of the patients with pheochromocytoma received alpha-1 adrenergic receptor antagonists for at least one month before the procedure, as is typically done before adrenalectomy 12, although it did not prevent intraprocedural hypertension. Hypertensive crisis is a known complication of surgical treatment of this disorder 13. During adrenalectomy for pheochromocytoma, adrenal vein clamping prevents part of the catecholamines stored in the tumor from entering the blood circulation, and they are removed with tumor excision. Consequently, severe hypertension may occur during tumor manipulation in surgery but not after its completion; hypotension is the most common hemodynamic complication in the postoperative period 13. However, in adrenal PEA, catecholamines may be released during or after treatment, and hypertension might be observed several hours after the procedure. Additionally, similar to post adrenalectomy, we also observed postprocedural hypotension in one of our patients. Hypertensive crisis during adrenal PEA has not been previously reported. However, this complication, associated with a non-severe ventricular arrhythmia in one case 14, has been described in patients undergoing radiofrequency or cryoablation of nonfunctioning adrenal lesions 14–16 and metastatic pheochromocytomas and paragangliomas 17.

In patients without pheochromocytoma, cardiovascular effects included hypotension, CNS depression and hypoxemia, myocardial infarction, and tachyarrhythmia associated with hypertension. Hypotension and CNS depression and hypoxemia observed in subject 4 could have resulted from the systemic effects of ethanol 18, as was also reported in one subject treated by Minowada et al 19; this may have been potentiated by prior benzodiazepine and opiate administration. Hypotension has also been observed in image-guided PEA for treating other organs, such as hepatocellular carcinoma in the liver and several cases of cardiovascular collapse have been reported 20,21. Acute myocardial infarction followed by an unremarkable coronary angiography may have been related to an increased myocardial demand secondary to left myocardial hypertrophy and a lower oxygen supply as a result of hypotension and transitory hypoxemia; transient elevation of pulmonary artery pressure and myocardial depression may also result from ethanol spilling into the systemic circulation 22. Retrospectively, another diagnostic possibility (which has more recently been reported after adrenal cryoablation (15)) would have been the apical ballooning syndrome: it corresponds to reversible cardiomyopathy precipitated by stress that presents with clinical features of myocardial infarction, with elevation of cardiac enzymes, and temporary left ventricular dyskinesia without obstructive coronary disease 23. Cardiac arrhythmias may be related to both hyperaldosteronism 24 and ethanol 25.

The complications of adrenal PEA herein reported prompted us to change from doing the procedure under sedation to under general anesthesia. Patients with pheochromocytoma who undergo PEA, similar to those who undergo adrenalectomy 13, might need admittance to an intensive care unit due to hemodynamic instability. General anesthesia, mechanical ventilation and invasive blood pressure monitoring may be important for performing adrenal PEA safely.

The ideal volume of ethanol administered in PEA is unclear. Although prior studies of sclerotherapy of vascular anomalies with ethanol suggest that volumes greater than 1.0 mL/kg are associated with acute morbidity or toxicity 22, most of our patients were treated with smaller volumes and still developed complications. The low ethanol volumes used in Xiao's study 6 might be safer, although a higher number of sessions may be required. Wang et al 5 treated forty benign pheochromocytomas after intraprocedural phentolamine and reported no hypertensive crisis; the volume of ethanol instilled in their case was reported to be “equivalent to size of the tumor”.

More recently, image-guided radiofrequency ablation (RFA) has also been successfully used for treating benign functioning adrenal lesions 26–31. Whereas the ethanol distribution within tumors is limited by septa and can be unpredictable, RFA creates a relatively homogeneous ablation zone. It has already been shown to be more effective than PEA for treating hepatocellular carcinoma (HCC) 32,33. Analysis of the pooled results from these cohorts 26–31 is very promising: a total of 55 lesions have been treated (44 APA, 7 CPA, 3 pheochromocytomas and 1 sex steroid-producing tumor), with biochemical success in 51 patients and clinical success in 53 of them. Further studies should compare RFA to laparoscopic adrenalectomy, the current gold standard for hyperfunctioning adrenal lesions.

Our study has some limitations. It included a small sample size and heterogeneous population. Its retrospective design limits the availability of patient data.

In summary, our results indicate that ethanol ablation of benign adrenal lesions involves significant risks and lacks long-term efficacy.

Frenk NE and Sebastianes F were responsible for data collection and analysis, and manuscript writing. Lerario AM and Fragoso MC were responsible for the project development and manuscript editing. Mendonca BB was responsible for the project development and manuscript editing. Menezes MR was responsible for the project development, data analysis and manuscript editing.