http://orcid.org/0000-0002-7090-0106
Figures
Abstract
Background
There are limited data about the role of endoscopic ultrasound-guided tissue acquisition (EUS-TA), by fine needle aspiration (EUS-FNA) or biopsy (EUS-FNB), in the evaluation of the adrenal glands (AG). The primary aim was to assess the diagnostic yield and safety. The secondary aims were the malignancy predictors, and to create a predictive model of malignancy.
Methods
This was a retrospective nationwide study involving all Spanish hospitals experienced in EUS-TA of AGs. Inclusion period was from April-2003 to April-2016. Inclusion criteria: all consecutive cases that underwent EUS-TA of AGs. EUS and cytopathology findings were evaluated. Statistical analyses: diagnostic accuracy of echoendoscopist’s suspicion using cytology by EUS-TA, as gold standard; multivariate logistic regression model to predict tumor malignancy.
Results
A total of 204 EUS-TA of AGs were evaluated. Primary tumor locations were lung70%, others19%, and unknown11%. AG samples were adequate for cytological diagnosis in 91%, and confirmed malignancy in 60%. Diagnostic accuracy of the endosonographer's suspicion was 68%.
The most common technique was: a 22-G (65%) and cytological needle (75%) with suction-syringe (66%). No serious adverse events were described. The variables most associated with malignancy were size>30mm (OR2.27; 95%CI, 1.16–4.05), heterogeneous echo-pattern (OR2.11; 95%CI, 1.1–3.9), variegated AG shape (OR2.46; 95%CI, 1–6.24), and endosonographer suspicion (OR17.46; 95%CI, 6.2–58.5). The best variables for a predictive multivariate logistic model of malignancy were age, sex, echo-pattern, and AG-shape.
Citation: Martin-Cardona A, Fernandez-Esparrach G, Subtil JC, Iglesias-Garcia J, Garcia-Guix M, Barturen Barroso A, et al. (2019) EUS-guided tissue acquisition in the study of the adrenal glands: Results of a nationwide multicenter study. PLoS ONE 14(6): e0216658. https://doi.org/10.1371/journal.pone.0216658
Editor: Pascal A. T. Baltzer, Medical University of Vienna, AUSTRIA
Received: December 19, 2018; Accepted: April 25, 2019; Published: June 6, 2019
Copyright: © 2019 Martin-Cardona et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the manuscript and its Supporting Information files.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The adrenal gland (AG) is a frequent location where metastatic cells settle in patients with known primary tumor, mainly of the lung, involving a poor prognosis and a change in management. Previous data show that the incidence of AG masses in patients with lung cancer ranges from 4% to 18%, of which 40% are malignant [1,2]. However, up to two-thirds of adrenal masses, in lung cancer, are benign adenomas [3]. The data provided by imaging techniques cannot accurately differentiate between a benign and a malignant mass in clinical practice, and the need to obtain material is common [4–6].
The available data have shown that percutaneous image-guided tissue acquisition (TA) of the AG has a high sensitivity and accuracy in diagnosing AG lesions. However this technique yields nondiagnostic samples in up to 19% of cases and is not exempt from adverse events (AE), such as needle tract metastasis, hemorrhage, and pneumothorax [7–10].
On the other hand, endoscopic ultrasound-guided TA, by fine needle aspiration (EUS-FNA) or fine needle biopsy (EUS-FNB) has proven to be very effective in obtaining samples of various targets (lymph nodes, subepithelial tumours, and pancreas). To date, however, there are few studies published showing that EUS-FNA in the study of AG is a minimally invasive technique with less AE compared with percutaneous guided punctures [3, 10–13]. It is reported that EUS-FNA of AGs is sensitive and useful to differentiate between malignant and benign masses in cases of suspected enlarged AG by imaging tests [3]. Other reports manifest that some EUS features can be associated with malignancy (e.g., abnormal shape of the AG), but the data are limited [12,13].
The primary aim of this multicenter study was to analyze the diagnostic yield and safety of EUS-TA in the study of AG. Our secondary aims were to determine predictors of malignancy, and to create a preclusive predictive model of malignancy.
Methods
Patients and study characteristics
This was a retrospective study, consisting of a noncomparative review of a nationwide database involving all Spanish hospitals experienced in EUS-TA of AG. All partners of the Spanish Group of Endoscopic Ultrasound were invited by mail to participate. Finally, 17 Spanish centers accepted the invitacion. Inclusion period: from April 2003 to April 2016. Inclusion Criteria: All AGs (right and left) punctured by EUS during the inclusion period. Exclusion criteria: loss of contact or information after the procedure. A CRF was designed by the IP center and recollected as a database from the other centers.
The following variables were reviewed: demographic details, clinical data, staging procedures, endoscopic findings, technical details, cytological data, medication with potential risk-bleeding, follow-up data, incidents, and AEs. All imaging parameters were reviewed and taken from the original written reports. This project was developed in accordance with the ethical approval of the Institutional Review Board (Comité Ético de Investigación Clínica, Hospital Universitari de Bellvitge, code PR344/15, 7 january 2016).
EUS guided TA technique
All patients provided written informed consent previous to the procedure. All EUS-guided TA were performed by an experienced endosonographer. Deep sedation was assisted by endoscopist or anesthesiologist, depending on the sedation protocol of each center. A linear array echoendoscope (Olympus GF-UCT140-AL5 or UCT-180, Pentax EG-3870UTK or EG-3270UK, Fujifilm EG-580UT) was used to identify and puncture the suspected AG. Left AGs were evaluated from the stomach, and right AGs from the duodenum. EUS-guided puncture was performed using a fine needle (25 or 22G in size), either cytological (EchoTipUltra, Cook; ExpectEndoscopic Ultrasound Aspiration Needle, BostonSC; BeaconFNA exchange system, Medtronic-Covidien) or cytohistopathological (EchoTip ProCore, Cook; SharkCoreFNB exchange system, Medtronic-Covidien). Color Doppler imaging was used to avoid interposal vessels. The suction technique applied, if any (stylet slow-pull vs. standard suction), and type and size of needle were items selected at the discretion of the endosonographer. In patients with antiplatelet or anticoagulant therapy, the recommendations of the international guidelines were followed (i.e., European Society of Gastrointestinal Endoscopy or British Society of Gastroenterology, 2008) [14]. EUS-guided FNA of a left AG example is shown in Fig 1.
A Endoscopic ultrasound-guided fine-needle aspiration of the adrenal gland with a dominant nodule. B Adenocarcinoma of the adrenal gland histopathology. H&E, orig. mag. ×400. Courtesy of Dr. Isabel Catala.
EUS image characteristics
The AGs were classified into four types based on morphology and shape: (i) seagull shape; (ii) seagull shape with a nodule or enlargement of one limbs, (iii) global enlarged AG preserving the seagull shape, (iv) variegated morphology (Fig 2).
A Usual ‘seagull shape’. B Nodule located in a lateral wing. C Global enlargement conserving the ‘seagull shape’. D Variegated morphology.
The following measurements were made according to the EUS image: AG length was the greatest extension between the end of the two wings, and the thickness was measured at the widest body of the AG. The echogenicity was classified as hypoechoic, hyperechoic, or isoechoic. The echo-pattern was divided into homogeneous and heterogeneous.
Finally, the suspected diagnosis was collected according to the experienced endosonographer’s judgement: suspicion of benignity, malignancy, or undetermined AG.
Cytological examination
Samples were prepared in the procedure room as a rapid on-site evaluation (ROSE) or without ROSE, depending of each center’s protocol. The cytology was categorized according to the following groups: malignant, suspicion of malignancy, benign, atypical cells, and insufficient sample. All specimens were examined by a cytopathologist for a definitive diagnosis. Immunohistochemistry data were recorded. Final diagnoses were: normal AG, adenoma of AG, pheochromocytoma, and metastasis of known tumour or unknown primary tumor.
Imaging procedures
Computed tomography (CT), scan evaluation: the morphology of the AG was assessed as normal or pathological, according to the radiologists of each center (increase of global size, presence of nodules or masses, irregular margins). The largest AG diameter (mm) was recorded.
Positron emission tomography (PET) scan study: the SUV (standard uptake value) of the affected AG was analyzed in comparison with the baseline collection from the patient's liver in the same study according to one of the following options: hypercaptation, normocaptation, or hypocaptation.
Statistical analysis
Nominal categorical variables were described by the number of cases, the percentage of the total for category, and the number of missing data. Ordinal categorical variables were described as nominal categorical, or by the number of cases, median, interquartile range, and number of missing data. Continuous variables were described by the number of cases, mean, standard deviation, median, first and third quartile, and number of missing data.
Diagnostic accuracy of echoendoscopist’s suspicion was analysed using cytology obtained by EUS-TA, as gold standard. Sensivity (S), specifity (Sp), predicte values (PV) and area under the ROC curve, were estimated.Diagnostic performance of EUS-guided TA was defined as the total amount of conclusive citopathology results (malignancy plus benignity) excluding the inconclusive results (atypical cells, suspect, insufficient sample).
Dependent variable of the study was cytology result. Independent variables of the study were CT scan morphology, PET scan uptake, echogenicity, echo pattern, endoscopist suspicion, AG size, AG shape and puncture technique features.
A multivariate logistic model was estimated to cytology result. Odds ratios (OR) and confidence interval at 95% were reported. The model was fitted using stepways selection focusing on lowering the Akaike Information Criteria because it penalizes the model for complexity. Model goodness of fit was evaluated using the Chi-square statistic to compare observed vs expected. To evaluate discrimination, the c statistic of Hosmer-Lemeshow was used, which for dichotomous outcome variables is equivalent to the area under the ROC curve (Receiver Operating Characteristic). The Hosmer-Lemeshow test is a goodness of fit especially for risk prediction models. A goodness of fit test measures how well your data fits the model. This test is usually accompained by a classifcation table of observed and expected frequencies.
Whenever possible, estimators were accompanied by a confidence interval at 95%. Statistical significance was set at a probability level <0.05. The statistical package used to process the data and carry out the analysis was R version 3.2.5 for Windows. (S1 and S2 Dataset).
Results
Patient data
A total of 200 patients and 204 AGs were collected, with a mean age of 65 years (SD 9.7), mostly men (152; ratio 3.1). The most common indication of EUS-guided puncture was a patient with primary pulmonary tumor, and the left AG was more usual. Demographic and clinical characteristics are detailed in Table 1.
Endoscopic and imaging procedures
Technical aspects of EUS-guided puncture are summarized in Table 2. The standard suction, with syringe, was the most frequently used modality (66.18%), and the median number of passes was 2.0 (interquartile range: 1.0 to 3.0). Most of the deep sedations were controlled by an anesthesiologist (67.16%), and the rest by endoscopists (32.35%).
Data related to the imaging for the staging are detailed in Table 3. A pathological morphology in the CT scan report and a hypercaptation in the PET scan were the most common findings. Information related to the EUS findings is reflected in Table 4: hypoechogenicity, heterogeneous pattern, and a seagull shape with enlargement of one of the limbs, or variegated were noteworthy.
The diagnostic yield was 91.17%: malignant plus benign final diagnostic results. Samples were nondiagnostic in 8.83% including atypia (0.98%), suspicious but not conclusive (2.94%), and insufficient (4.90%) (Table 5). No significant differences between FNA or FNB needles were found.
Endosonographer suspicion based on the EUS image, was classified as benign or malignant in 81% of EUS procedures (19% was undetermided). Diagnostic accuracy of this was 68%. In Fig 3 are detailed S, Sp and PVs for the endosonographer suspicion using cytology, obtained by EUS-TA, as gold standard.
Area under the curve: 0.70. Predictive value positive (PV+), predictive value negative (PV-).
Safety
Only one case of self-limiting post-procedural fever was detected, with negative blood tests. It is of note that 10.5% AGs were treated with anticoagulant therapy and 19% were treated with antiplatelet therapy, without any cases of bleeding. Two cases of unknown pheochromocytoma were punctures without concomitant hypertensive crises during the EUS procedure. In the majority of cases, no specific study for pheochromocytoma was performed previous to the endoscopy procedure. No procedure-related mortality was reported.
Univariate and multivariate analysis
A lower age, pathological image in CT scan, hypercaptation in PET scan, variegated AG shape, size > 30mm, heterogeneous EUS pattern, and suspicion of malignancy by the endoscopist were statistically associated with a malignant cytology result. In contrast, hypoechoic AG and lateral nodule AG shape were not associated with malignancy (Table 6).
Univariate analysis (n-186).
A predictive model for malignancy was formulated using multivariate logistic regression (Table 7 and S1 Fig). The final model included two demographic factors, age and sex, and two factors measured by EUS, echo pattern and AG shape. Among the factors ruled out were echogenicity and AG size > 30mm. Neither CT scan morphology nor PET scan uptake were considered for inclusion in the model. The selection of variables was taken in a count depending the objectivity and clinical impact for each one. Although the variable 'EUS suspicion' was the most predictive parameter in the univariate analysis, it had not been 'included' in the multivariate analysis because it is a subjective variable and operator-depending.
The derived prediction model had good discrimination with area under the ROC curve 74% 95%CI 66% to 82% (Fig 4). Calibration was also acceptable, with good observed/expected ratio for all strata of predicted risk. In Table 8, patient’s malignacy probability (calculated with the estimated model) were grouped by decils and the observed event rates in each decil are presented. In the first decil of risk, with a probability of malignacy that ranged from 0.17 to 0.43, 6 of 18 malignacy cases were observed; in the last decil of risk, with a probability of malignacy that ranged from 0.88 to 0.97, 17 of 18 malignacy cases were observed. Hosmer and Lemeshow goodness of fit test suggested a rasonable fit of data to the estimated model (Chi2 5.8 p-value = 0.6689). Finally, a cut-off of malignacy probability defined two groups of patients: those with a postive result (probability of malignacy equal or above 0.4) and those with a negative result (probability of malignacy below 0.4). Among positive patients 112 of 161 cases malignacy was found and among negative patients 5 of 13 cases malignacy.
Estimator of the area under the curve: 0.74 CI 95% [0.66–0.82]. Area under the ROC curve was estimated using the final model with the following factors: age, sex, echo pattern and adrenal gland shape.
Discussion
This was a nationwide multicenter study with the largest number of cases of AG punctured by EUS-TA, FNA or FNB, to date. All procedures were performed by a dedicated endosonographer expert in the diagnosis and staging of digestive and lung cancer. This study supports the concept, previously introduced by other authors, that EUS-TA is a safe and accurate, minimally invasive technique, and it may be considered as the first choice in the study of suspicion in AGs, basically when this information can really help to the treatment strategy [3,11–13].
Nowadays, most imaging tests (PET, CT) are very powerful and reliable methods for the staging of many tumors. But, specifically in the study of AGs, these tests still have some limitations, and there remains the need to obtain biological material for pathological study. In the radiological imaging literature, there is an evident limitation in the accuracy of these imaging tests, as there is a considerable number of false-negatives (metastases misdiagnosed as adenomas) and false-positives (adenomas classified as metastases) [2,15,16]. In the same line, this current study has revealed a considerable percentage of cases with a benign profile in the EUS image that obtained a result of malignancy in cytology. This suggests that it is still essential to obtain a pathological sample to confirm a suspicion of metastasis that will produce a change in the therapeutic attitude: radical surgical treatment is ruled out and treatment with systemic chemotherapy or a palliative option are chosen instead.
There are many reasons to consider EUS-TA an attractive technique for the evaluation of suspicious AGs. One obvious advantage of this endosonographer technique is in a lung cancer scenario, where the EUS-TA can combine evaluation of a mediastinal tumor and of an enlarged AG during the same procedure, plus without any irradiation [3].
A recent review on the role of EUS-FNA in the diagnosis of adrenal lesions considered 17 original articles (seven case reports, ten case series) including a total of 416 cases [11]. The average AG size was 25.9mm; FNA needle size used was 19, 22, and 25 G, and the average number of passes was two. A total of 25 right AGs were documented, no major AEs were reported, and only one adrenal hemorrahge case was detected [17]. Regarding EUS image findings, it is of note that a hypoechoic feature (usually related to malignancy) was not associated with a malignant cytological result [11,18]. In the same line, Eloubeidi et al reported interesting findings: on a multivariable analysis an altered AG shape was a significant predictor of malignancy, whereas a size >30mm and hypoechoic nature were not [13]. Based on size >30mm alone, EUS had limited accuracy (68%). This finding is in striking contrast to the strong correlation of this variable with the accuracy of the imaging tests [15].
This nationwide study reinforces the hypothesis that EUS-TA of AGs is a reproducible and feasible technique, clearly assumable in endoscopy units that routinely perform this procedure. The high diagnostic yield, with a small percentage of nondiagnostic biopsies and insufficient samples, is similar to the data that come from an expert single-center in this area [10,13]. No differences were encountered between cytological or cytohistological needles, and the rate of confirmed malignancy was high, explained by the elevated proportion of lung cancer staging included in this study. All patients were managed according to the cytological results obtained by EUS-TA, a well-accepted method by oncologist and surgeons. Another strength offered by this multicenter study is that it provides the largest case series of right AG punctures via transduodenal approach with a similar prevalence (6%), compared with the recent review by Patil et al [11,19].
It is important to note that some variables related to the EUS image (variegated AG shape, heterogeneous echo-pattern, size >30mm) were clearly associated with the malignancy diagnosis, but the most accurate variable of EUS image was the endosonographer’s opinion. When it was analyzed using the cytology, obtained by EUS-TA as a gold standard, the endoscopist’s opinion showed an excellent S, good diagnostic accuracy but low Sp. This highlights the observation that EUS is an operator-depenent procedure, and the intuition of the endoscopist is more credible and valuable than each variable taken separately.
As in previous papers, a hypoechoic EUS feature was not associated with a diagnosis of malignancy by EUS-FNA [13,18]. In our opinion, the repetition of this finding in this study can be considered a validation of the hypothesis that a hypoecohoic AG does not mean a malignant AG, and does not exclude the performance of an EUS-TA.
The presented model allows estimation of the probability of a diagnosis of malignancy. The best variables for the predictive multivariate logistic model were age, sex, echo pattern, and AG shape determined by EUS. This model has an excellent S, good positive PV and negative PV, but low Sp. Therefore, the probability of predicting the positive pathological AG is very high, but the probability of predicting how negative the non-pathological AG is, is low. It should be borne in mind that, due to a diagnosis confirmation bias, estimation of S and Sp is very likely to be high and low, respectively.
In addition, both the probability of having a pathological AG and presenting a positive result as well as the probability of having a non-pathological AG and presenting a negative result are > 75%. But these results are determined by the prevalence; if the estimated prevalence (63% of malignant AG confirmed by EUS-TA in this study) does not reflect the usual prevalence of pathological AG, the PPV value and the NPV value will not be credible and should be ruled out.
No serious AEs were documented in this current study and other studies of EUS-FNA in the AG, in contrast with the AE rate related to percutaneous biopsy [7–9]. No other organ except the gastric or duodenal wall is punctured to access the AG. In this study no 19G needles were used; only ‘fine’ (22 or 25 G) needles were utilized. This may have minimized AEs associated with puncture, such as bleeding and perforation. The use of cytohistological FNB needles (‘core’, with a more agressive tip design) was not related to more AEs.
Regarding the risk of puncture of a previously undicovered pheochromocytoma, in this study this occurred in two cases that were diagnosed with EUS-TA in which no previous urine studies were performed. Although some authors recommend that urine studies should be performed prior to attempting an AG guided-puncture, EUS-FNA of pheochromocytomas and paragangliomas has been reported as safe [20–21]. Perhaps it would be safer to rule out pheochromocytoma prior to puncturing an AG in patients without cancer, but in cases with known primary malignancy, this may not be necessary [22].
Limitations
Our study has some limitations. Firstly, there is variability among the different centers, with varying levels of expertise among the endosonographers; this may have instroduced some bias in the results (e.g., technical aspects, measuring AG, interpretation of AG shape). Secondly, the high proportion of lung cancers cases may have introduced a selection bias in the study population. Thirdly, a retrospective study is associated with a lack of patient contact and missed follow-ups; this is associated with a loss of some AEs.
There is also the limitation of the predictive model: the number of data used, although they are all available to date, did not allow us to reserve part of these to perform a validation of the model. Validation in a different sample of the development of the model presented here is pending. Although the statistics to evaluate the predictive capacity of the model are quite satisfactory, they may be under- or over-estimated due to a diagnostic confirmation bias or because of a higher or lower than expected prevalence of malignancy in the sample.
In conclusion, EUS-TA of the AG is a safe, minimally invasive procedure, with an excellent diagnostic yield. Some EUS image features are associated with a diagnosis of malignancy, and this study suggests the possibility of developing a malignancy-predictive model for us prior to the EUS procedure.
Supporting information
S1 Fig. Multivariate logistic model of malignancy.
Variables and their statistical association with the malignancy risk. Adrenal gland (AG).
https://doi.org/10.1371/journal.pone.0216658.s001
(TIF)
Acknowledgments
The authors are grateful to Dr. Isabel Catala for her scientific advice on the cytopathological findings, and her courtesy in facilitating the cytopathology image.
List of membership of the Spanish Group for EUS-Guided TA in the adrenal gland: Martin-Cardona, A (Hospital Universitari Bellvitge); Fernández-Esparrach, G (Hospital Clínic de Barcelona); Subtil, JC (Clínica Universitaria de Navarra); Iglesias-Garcia, J (Hospital Clínico Universitario de Santiago de Compostela); Garcia-Guix, M (Hospital Universitari de Bellvitge); Gallarreta V (Hospital Universitari de Bellvitge); Barturen, A (Hospital Universitario Las Cruces); Gimeno-Garcia, AZ (Hospital Universitario de Canarias); Esteban, JM (Hospital Clínico San Carlos); Pardo, A (Hospital Universitario Joan XXIII); Velasco-Guardado, A (Hospital Universitario de Salamanca); Vazquez-Sequeiros, E (MD Anderson Madrid); Loras, C (Hospital Universitari de Terrassa); Martinez-Moreno, B (Hospital General Universitario de Alicante); Aparicio, JR (Hospital General Universitario de Alicante; Castellot, A (Hospital Insular de Gran Canaria); Huertas, C (Hospital Dr. Josep Trueta Girona); Martínez-Lapiedra, M (Instituto Oncológico Valenciano); Sanchez-Yague, A (Hospital Costa Sol);Teran, A (Hospital Universitario Marqués de Valdecilla); Morales, VJ (Hospital Clínic de Barcelona); Betes, M (Clínica Universitaria de Navarra); DelaIglesia, D (Hospital Clínico Universitario de Santiago de Compostela); Sanchez-Montes, C (Hospital Clínic de Barcelona); Lozano, MD (Clínica Universitaria de Navarra); Lariño-Noia, J (Hospital Clínico Universitario de Santiago de Compostela); Gines A (Hospital Clínic de Barcelona); Cristian Tebe (IDIBELL, Barcelona); and Gornals JB (Hospital Universitari de Bellvitge) as lead autor, E-mail: jgornals@bellvitgehospital.cat.
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