Background
Pheochromocytomas and paragangliomas (PPGLs) are neuroendocrine tumors. The annual incidence of PPGLs is 0.8 per 100,000 person-years [
1], and they affect an estimated 500 to 1600 patients per year in the United States [
2]. An estimated incidence of malignant PPGL in the United States in 2002 was 93 per 400 million persons [
3]. Although primary PPGLs are usually resected surgically, metastatic lesions can be treated using percutaneous imaging-guided thermal ablation [
4,
5]. This is considered an optimal approach for treatment of focal unresectable metastatic lesions in the liver, bone, and lungs [
6,
7]. Two major modalities of ablation are hyperthermic (radiofrequency ablation) and hypothermic (cryoablation).
Surgical manipulation of PPGLs may induce hemodynamic oscillations due to catecholamine release from the tumor. Before the routine clinical introduction of preprocedural adrenergic blockade, resection of PPGL was associated with high morbidity and mortality [
8]. Currently, it is a widely established practice for patients with PPGLs to undergo preprocedural pharmacologic treatment with α-adrenergic receptor blockers or calcium channel blockers [
9‐
12]. This practice is designed to attenuate hypertensive crises during tumor manipulation. However, despite adrenergic receptor blockade, hemodynamic volatility is still frequently observed [
13,
14]. We recently reported hemodynamic oscillations during open and laparoscopic operations of PPGL [
15,
16]; however, we lack the knowledge regarding the extent of hemodynamic fluctuations during ablation of extra-adrenal PPGL metastases. In this study, we aim to describe intraprocedural hemodynamics for patients with nonfunctional and functional metastatic PPGL lesions, and their periprocedural outcomes.
Methods
This study was approved by the Mayo Clinic Institutional Review Board in November 2014 (No. 13–004137), with the last modification approved in November 2017 (No. 14–008336). In compliance with Minnesota Statute 144.335, all patients during Mayo Clinic visits are asked to provide written informed research consent, and those who refuse are excluded from reviews (in general this represents less than 5% of patients). All patients included in the present study had research authorization on file. This study conformed to the requirements of the STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) guidelines.
Patient selection
For this historical cohort study, we searched the Mayo Clinic, Rochester, Minnesota, PPGL Registry maintained by the Division of Endocrinology, Diabetes, Metabolism, and Nutrition to identify adult patients who were treated for metastatic lesions in radiology suites using minimally invasive thermal ablation, from January 1, 2000, through December 31, 2016. This study partially overlaps with an earlier report from our institution that focuses on efficacy and safety of radiofrequency ablation and cryoablation therapy [
17].
Preprocedural adrenergic receptor blockade
For patients with PPGL, the aim of preoperative pharmacologic preparation is to blunt hemodynamic oscillations related to catecholamines released during procedural manipulation. Exceptions to the use of blockade are nonsecretory parasympathetic-derived skull base and neck PPGLs [
18]. The details of our protocol used before surgical resection have been previously reported [
13,
15,
16]. Our practice for preablation preparation of patients with metastatic PPGL lesions includes administering the same adrenergic blocking agents that are used for the surgical resection of a primary PPGL [
19]. Briefly, treatment with phenoxybenzamine, a noncompetitive α
1,2-adrenoceptor antagonist, is initiated 7 to 14 days before intervention. Alternative treatment is with selective α
1-adrenergic blockers (eg, doxazosin). If the heart rate remains above 80 beats/min, a β-adrenergic receptor antagonist is added 2 to 5 days before surgery. The drugs are titrated to effect; if normotension is not achieved, a calcium channel blocker may be added. For patients with inadequate response to therapy (with low-normal blood pressures), or if a large release of catecholamines is anticipated, metyrosine is added to block the rate-limiting step of catecholamine synthesis.
Data abstraction
For identified patients, medical, surgical, and anesthesia records were reviewed as previously described [
20]. We abstracted data on demographics; preoperative pharmacologic preparation; preoperative blood pressures, major comorbid conditions (diabetes mellitus, cardiac disease, stroke or history of transient ischemic attack), and medications used for preoperative control of blood pressure and heart rate (α- and β-adrenergic receptor antagonists, calcium channel blockers, and metyrosine); location and functional status of the primary tumor and metastatic lesions; and type of procedure (cryoablation, radiofrequency ablation). Tumor status was designated as
functional, from preprocedural plasma and 24-hour urine fractionated metanephrine levels, if the concentration of at least 1 of the following was higher than the reference range: urine total metanephrines (≥1300 mcg/24 h), urine metanephrine (≥400 mcg/24 h), urine normetanephrine (≥900 mcg/24 h), plasma-free metanephrine (≥0.5 nmol/L), or plasma normetanephrine (≥0.9 nmol/L).
From our electronic anesthesia database, we retrieved the maximum and minimum systolic, diastolic, and mean arterial blood pressures and heart rates for each procedure. Intraoperative blood pressure and heart rate variation were quantified using the range of the intraoperative values for a given patient (difference between maximum and minimum values recorded during the procedure). Intraoperative variables reviewed were any infusion of potent vasoactive drugs, intravenous fluids, and blood products. Perioperative complications (postoperative hemodynamic instability requiring treatment, unplanned intensive care unit [ICU] admission, bleeding, and death) were also abstracted. Only complications that occurred during index hospitalization are described in this report.
Statistical analysis
Categorical data are presented as numbers (percentages), and continuous data are reported as mean (±SD) or median (interquartile range). Comparison of intraoperative hemodynamics between patients with functional and nonfunctional tumors was performed with the Fisher exact test or t test; 2-tailed P values 0.05 or less were considered significant. Because some patients underwent multiple ablations, analyses were performed including only the first ablation per patient and also including all ablations. For analyses performed using all ablations we assumed that all ablations are independent. Statistical analyses were performed with SAS software, version 9.4 (SAS Institute Inc).
Discussion
Our main finding is that patients with metastatic PPGLs, even when pretreated with adrenergic blocking agents, may experience substantial intraprocedural hemodynamic instability. A nonfunctional metastatic lesion, as assessed from normal preprocedural plasma catecholamine/metanephrine concentrations, does not guarantee intraprocedural hemodynamic stability, especially if the metastatic lesion originates from a primary tumor that was functional. Although percutaneous ablation of metastatic PPGL may be considered a ‘minimally invasive’ intervention, it may be associated with severe complications.
Hemodynamic volatility is common during open or laparoscopic PPGL resection. The concentration of catecholamines in PPGL tumors may be high [
21], and intraoperative catecholamine surge has been observed during surgical adrenalectomy of not only functional PPGLs [
22] but also PPGLs with negative biochemistry [
9,
23‐
25]. Healthy adrenal glands contain an abundance of catecholamines, and percutaneous ablation of normal adrenal parenchyma can induce their release. In an animal model, Yamakado et al. [
26] reported blood pressure and catecholamine surges during radiofrequency ablation of adrenal glands. Espinosa De Ycaza et al.
4 reviewed hemodynamics during thermal ablation of metastases from renal or lung tumors to adrenal gland, and found that ablation of lesions in adrenal glands may also be associated with hypertensive urgencies. Similarly, Fintelmann et al. [
27] examined the risk of catecholamine release during ablation of nonhormonally active adrenal gland metastases, and reported that the presence of normal adrenal tissue and larger tumor diameter were associated with increased catecholamine surge. In contrast to these studies that examined hemodynamics during ablation of metastases of nonhormonally active tumors to adrenal gland, the present study quantifies hemodynamic oscillations during ablation of
extra-adrenal metastatic lesions, many of which were hormonally active PPGL metastases.
Although plasma catecholamine concentrations during ablation were not measured in our patients, the pattern of intraprocedural hemodynamics was consistent with catecholamine release from PPGL. The large blood pressure oscillations were encountered during ablation of functional metastatic lesions (see Fig.
3b) and also during ablation of nonfunctional metastatic lesions originating from functioning PPGL tumor (see Fig.
3c). This suggests that when anticipating hemodynamic volatility, it is important to review the patient’s history and to consider the secreting functionality of not only treated metastatic lesions but also the originating tumor. Therefore, nonfunctional status of a metastatic lesion, as assessed from nonelevated preprocedural catecholamine/metanephrine levels, cannot guarantee intraprocedural hemodynamic stability [
23].
The majority of our patients were pretreated with α-adrenergic blockade, but despite that we still observed large hemodynamic oscillations during ablations. This is consistent with previous observations that preoperative adrenergic blockade cannot entirely eliminate intraoperative hemodynamic oscillations in these patients [
13,
15,
16]. In our series, 1 patient was admitted to the ICU after ablation for treatment of severe hypertension despite the fact that he received comprehensive preoperative adrenergic blockade (Table
5). In another patient, systolic blood pressure peaked at 280 mm Hg during ablation despite preprocedural adrenergic blockade. This illustrates that despite preoperative pharmacologic blockade, anesthesiologists must be vigilant and prepared for management of extreme hemodynamic variations when dealing with PPGL metastatic lesions. Furthermore, the maximum blood pressures observed during ablation of functional metastatic lesions were comparable to the values we recently reported for surgical resection of primary functional tumors [
16]. This should alert anesthesiologists that when providing anesthesia for ablation of metastatic PPGLs in radiology suites, the preparation for hemodynamic management should match standards used for the surgical resection. However, despite large hemodynamic oscillations during ablations no major cardiovascular complications were noted in our case series, likely because the patients were relatively young and without major preexisting cardiovascular comorbidities.
Limitations and strengths
The main limitation of our study is related to the historical cohort study design and retrospective retrieval of data. Our study cannot assess the efficacy of preprocedural adrenergic blockade, because the majority of our patients with metastatic PPGL receive these medications. Furthermore, we did not measure intraprocedural serum catecholamines; therefore, we cannot establish causality between observed hemodynamic instability and catecholamine release, although this remains the most plausible explanation, as previously shown [
26].
Conclusion
Patients with functional PPGL metastatic lesions had greater intraprocedural blood pressure variability than those with nonfunctional lesions. A normal preprocedural plasma catecholamine/metanephrine level does not ensure intraprocedural hemodynamic stability, especially if the primary tumor was functional. Although ‘minimally invasive’, percutaneous ablation of metastatic PPGL may be associated with severe complications.
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