Bronchogenic cysts: a narrative review

Introduction

Bronchogenic cysts, first described in 1859, are rare congenital cystic malformations of the respiratory tract, with an incidence of 1 per 42,000 to 68,000 hospital admissions in one hospital series (1,2). They comprise 10–15% of mediastinal tumors and between 50–60% of mediastinal cystic lesions (3). Bronchogenic cysts arise from the abnormal budding of the tracheobronchial tree or embryonic ventral lung bud, between the 26^th–40^th day of gestation (4). Their location is usually a function of their embryological development, with central (mediastinal) cysts arising earlier in development (Figures 1,2), and more peripheral development suggesting later formation (Figure 3) (4,5). Parenchymal bronchogenic cysts are reported to comprise 20–30% of all bronchogenic cysts (5,6). Histologically, bronchogenic cysts are typically unilocular and recapitulate elements of normal bronchial structures. The cyst wall is usually lined by respiratory-type epithelium (i.e., ciliated pseudostratified columnar epithelial cells with occasional mucin-filled goblet cells) and is comprised of variable amounts of hyaline cartilage, smooth muscle, and/or seromucinous bronchial glands (Figure 4) (7,8). Occasionally, bronchogenic cysts can undergo various histologic changes related to infarction, infection, and/or prior procedure. These changes include acute and chronic inflammation with epithelial denudation, hemorrhage with hemosiderin-laden macrophages, squamous metaplasia, cholesterol clefts, and fibrosis. Bronchogenic cysts typically develop into blind ending fluid-filled structures, though fistulization to adjacent organs and fatal air emboli have been reported (3,9-12). Malignant transformation is very rare but reported in the literature (13,14). The objective of our review is to summarize the historical management of bronchogenic cysts and the impact of evolving technologies including minimally invasive excision and endoscopic drainage. The article is presented in accordance with the Narrative Review reporting checklist (available at https://med.amegroups.com/article/view/10.21037/med-22-46/rc).

Figure 1 Posterior mediastinal bronchogenic cyst. Subcarinal bronchogenic cyst detected by CT scan of chest with intravenous contrast to investigate complaints of mild dysphagia and nonspecific back pain in a 35-year-old healthy man. (A) Axial and coronal CT images demonstrates a smooth-bordered 4.5 cm cystic lesion in the subcarinal location. The cyst has high density with HU of 48 and thick proteinaceous fluid was drained at the time of robotic thoracoscopic resection. Red bordered arrow marks the cyst. (B) Coronal CT MRIs image delineates the bronchogenic cyst with the MRI image, T1-weighted image shows liquid nature of the cyst contents, demonstrating dark contents consistent with fluid. T2-weighted confirms these findings as illustrated by cyst bright finding. Complete resection was achieved by right robotic thoracoscopic approach, and the cyst was filled with thick proteinaceous fluid. Red bordered arrow marks the cyst. CT, computed tomography; HU, Houndsfield units; MRI, magnetic resonance imaging.

Figure 2 Anterior mediastinal bronchogenic cyst. (A) Incidental finding on cardiac CT scan for coronary artery calcium scoring in a 75-year-old asymptomatic woman. The cyst has low density with HU of 14 and clear fluid was found in the cyst at the time of robotic thoracoscopic resection. Red bordered arrow marks the cyst. (B) Incidental finding of anterior mediastinal cystic lesions by CT scan of the chest for investigation of non-specific chest discomfort in a 45-year-old woman. The cyst content had a high density with HU of 47 and proteinaceous fluid was drained that the time of robotic thoracoscopic resection. Red bordered arrow marks the cyst. CT, computed tomography; HU, Houndsfield units.

Figure 3 Intraparenchymal bronchogenic cyst. (A) Axial and sagittal images of a chest CT scan with intravenous contrast of a 34-year-old woman demonstrating a large peripherally located cyst in the right lower lobe, adjacent to segmental pulmonary vessels. She had a history an enlarging cystic lesion once complicated by an infection that was treated with a month-course of oral antibiotic. A complete resection was achieved by right robotic thoracoscopy and enucleation of the lung cyst separating the cyst wall from the underlying vessels and bronchus thus avoiding a pulmonary segmentectomy. Pathologic examination determined this lesion being a benign bronchogenic cyst. Red bordered arrow marks the cyst. (B) Axial and sagittal cuts of a CT scan with intravenous contrast of a 63-year-old woman admitted to the hospital with fever/chills and leukocytosis showing a cystic lesion in the right lower lobe with air-fluid level suggestive of an infected intrapulmonary bronchogenic cyst. This was her first presentation of a bronchogenic cyst. The cyst was completely resected by a right robotic thoracoscopy and wedge resection of the cyst. Final pathology report shows: Respiratory-lined cyst with fibrosis, adjacent fibrinopurulent exudate, granulation tissue and reactive mesothelial hyperplasia. Red bordered arrow marks the cyst. CT, computed tomography.

Figure 4 Histologic findings of bronchogenic cysts corresponding with imaging (hemoxylin & eosin stain). (A) Low power magnification (×12.5) reveals a thin-walled cyst with adjacent adipose and thymic tissue. (B) Higher power magnification (×400) demonstrates that the epithelial lining consists of ciliated pseudostratified columnar respiratory-type epithelium. The cyst wall lacks other features typical of a mature bronchogenic cyst. (C) Medium power magnification (×40) corresponding with images shown in Figure 2A,2B demonstrating an epithelial-lined cyst wall (upper lefthand corner) with adjacent seromucinous glands and mature hyaline cartilage (bottom righthand corner). (D) Higher power magnification (×200) demonstrates that the cyst wall is lined by an attenuated flat-to-cuboidal epithelium.

Methods

We systematically searched the available electronic literature, PubMed and Google Scholar to identify relevant case series in the adult and pediatric peer reviewed literature focusing on diagnosis and management of bronchogenic cysts. We searched the following terms ‘bronchogenic cyst’, ‘bronchogenic parenchymal cysts’, ‘bronchogenic mediastinal cysts’, ‘drainage bronchogenic cyst’, ‘pediatric bronchogenic cysts’ and ‘VATS bronchogenic cyst’ (Table 1).

Discussion

Clinical presentations

Bronchogenic cysts are frequently incidental findings on ultrasound or chest radiograph in the neonatal period (4). Symptoms in neonates are usually related to mass effect on the involved structure or infection (15). Major bronchus obstruction is rare but has been reported in the setting of a subcarinal cyst (16). More commonly, the presentation mimics centrilobular emphysema secondary to air trapping of the smaller airways (17). The presentation of bronchogenic cysts in the adult population ranges from an asymptomatic incidental finding of computed tomography (CT) of the chest to a clinical presentation of hemoptysis, pneumothorax, pneumonia (bronchogenic cyst in the lung parenchyma) or chest pain, dysphagia, central venous compression due to mass effecting the mediastinum. Imaging diagnosis is typically made using CT scan, demonstrating a smooth mass with sharp borders (occasionally lobulated), with cystic components (3,18). Masses can occasionally appear solid on CT, and in this setting, magnetic resonance imaging (MRI) can serve as an adjunctive role to highlight the cystic nature of these lesions. Fluid-filled cystic lesion demonstrates high T2 intensity without enhancement with contrast, T1 weighted imaging is variable depending upon cystic contents and their relative tissue composition (Figure 1) (3). Fiberoptic bronchoscopy with endoscopic bronchial ultrasound (EBUS) has been used to further characterize peri-bronchial cystic masses and can serve a dual therapeutic role by allowing for aspiration in cases of compressive symptoms while providing a pathologic diagnosis, albeit with an increased risk of infection secondary to bacterial contamination of the cyst content by the transbronchial needle (19-22).

Treatment

Surgical excision remains the mainstay of therapy (23-25). Surgery in the neonate can be safely delayed allowing for weight gain. Symptomatic adult patients should undergo resection after immediate stabilization (26). Aspiration is a temporizing measure only for compressive symptoms and should be shortly followed by resection as there is a significant risk of infection following biopsy/aspiration, with very high incidence of short-term recurrence of the lesion, though some series are emerging advocating for drainage as a definitive means of therapy (19-21). Mediastinal bronchogenic cysts resection must ensure complete removal of the epithelium-lined cyst wall via resection or ablation to prevent the accumulation of fluid or recurrence (27,28). In the case of intrapulmonary bronchogenic cysts within lung parenchyma, lobectomy has been the historical gold standard though more recently parenchymal sparing approaches, such as non-anatomic wedge resection or segmentectomy, have been advocated by some surgeons (29). Thoracotomy has traditionally been the standard approach given their location and inflammation of surrounding tissues, with the vast majority of older series being exclusively completed via an open approach (14,26). With the emergence of minimally invasive platforms, resection of bronchogenic cysts either mediastinal or intraparenchymal variants can frequently be performed via thoracoscopic approach (25). Our own institutional experience follows more recent trends of adopting a robotic thoracoscopic platform for resection of these lesions (30,31). There are few long-term sequelae following resection of bronchogenic cysts, although recent literature still reports a combined morbidity and mortality rate of 9.8% in a mixed series comprising bronchogenic and other cystic lesions of the lung (32).

Conclusions

Bronchogenic cysts are a relatively rare congenital malformation. Aspiration and EBUS potentially serve as useful adjuncts for compression relief and potential diagnosis but are plagued by high recurrence and risk of infection. The gold standard remains surgical excision with excellent long-term outcomes free of recurrence and low peri-operative morbidity/mortality. Video-assisted thoracoscopic resection has emerged as a viable approach and with the adoption of the robotic platform for minimally invasive thoracic surgery, thoracoscopic resection has become more feasible. The transition from open to video assisted thoracoscopic surgery (VATS) to robotic-assisted thoracoscopy has followed the authors’ experience and has been associated with few complications. Therefore, we advocate for minimally invasive resection as a diagnostic and therapeutic procedure in a single setting with relatively few complications in our own institutional experience.

Acknowledgments

Funding: None.

Footnote

Provenance and Peer Review: This article was commissioned by the Guest Editor (Nestor Villamizar) for the series “Mediastinal Cysts” published in Mediastinum. The article has undergone external peer review.

Reporting Checklist: The authors have completed the Narrative Review reporting checklist. Available at https://med.amegroups.com/article/view/10.21037/med-22-46/rc

Peer Review File: Available at https://med.amegroups.com/article/view/10.21037/med-22-46/prf

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://med.amegroups.com/article/view/10.21037/med-22-46/coif). The series “Mediastinal Cysts” was commissioned by the editorial office without any funding or sponsorship. The authors have no other conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

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