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An Eleven-Year Review of Congenital Pulmonary Lesions in a Referral Children’s Hospital in Tehran

AUTHORS

Lobat Shahkar 1 , Sara Sanii 2 , * , Habibe Nejad Biglari 3 , Elham Pourbakhtyaran 2 , Seyyed Ahmad Tabatabai 1 , Seyyed Hossein Fakhraee 2

1 Pulmonology Department, Shahid Beheshti University of Medical Sciences, Tehran, Iran

2 Neonatal Health Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran

3 Pediatric Neurology Department, Shahid Beheshti University of Medical Sciences, Tehran, Iran

How to Cite: Shahkar L, Sanii S, Nejad Biglari H, Pourbakhtyaran E, Tabatabai S A, et al. An Eleven-Year Review of Congenital Pulmonary Lesions in a Referral Children’s Hospital in Tehran, Arch Pediatr Infect Dis. 2016 ; 4(4):e59866. doi: 10.5812/pedinfect.32792.

ARTICLE INFORMATION

Archives of Pediatric Infectious Diseases: 4 (4); e59866
Published Online: September 3, 2016
Article Type: Research Article
Received: August 29, 2015
Revised: July 27, 2016
Accepted: August 7, 2016
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Abstract

Background: Congenital pulmonary lesions may be diagnosed through ultrasonographic screenings or be revealed as causes of respiratory distress in the neonatal period and infancy. Less commonly, they are detected as incidental features.

Objectives: Our study represents the diversity of congenital pulmonary lesions and their characteristics during an 11-year period in a referral teaching children’s hospital in Tehran, the capital city of Iran.

Methods: Data from an 11-year period of patients with the final diagnosis of congenital pulmonary lesions in Mofid Children’s hospital were reviewed. The data included the prenatal ultrasonographic, postnatal radiographic, and pathologic diagnoses, along with the patient’s age, way of presentation, length of hospitalization, and accompanying features and morbidities.

Results: Of 37 cases of congenital pulmonary lesions, 28 cases (75%) were boys. Thirty-six cases (97.2%) presented with pure pulmonary signs and symptoms. Of these cases, 16 (43.2%) were neonates, 17 (46%) were infants, and 4 (10.8%) were children. Twenty-seven (73%) patients missed the opportunity for early diagnosis. In order of frequency, cases were diagnosed as congenital lobar emphysema (43.5%), congenital cystic adenomatoid malformation (32.5%), pulmonary sequestration (19%), hybrid lesion (2.5%), or bronchogenic cyst (2.5%).

Conclusions: In an analysis of retrospective data of 37 congenital pulmonary lesions, male predominance was obvious, as has been found in previous studies.

Keywords

Pulmonary Emphysema Congenital Bronchopulmonary Sequestration Cystic Adenomatoid Malformation of Lung Congenital

Copyright © 2016, Pediartric Infections Research Center. This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International License (http://creativecommons.org/licenses/by-nc/4.0/) which permits copy and redistribute the material just in noncommercial usages, provided the original work is properly cited.

1. Background

Congenital pulmonary lesions in children may present diversely in different age groups. Annual incidence of congenital thoracic malformation is 4.4/10,000 (1). A subdivision of these is categorized as cystic lesions (2). There have always been controversies about their origin, nomenclature, pathology, and even therapeutic approaches (1, 2). Congenital pulmonary airway malformation (CPAM), previously called congenital cystic adenomatoid malformation (CCAM), with the incidence of 1/11,000 to 1/35,000, is subdivided into five types (1-3). It is known that this lesion has the potential for prenatal regression and that it may retain its primary size or grow and bring about pulmonary hypoplasia and hydrops (2, 3). Early diagnosis by gestational routine ultrasonography, with positive predictive value and the sensitivity of ranges between 45% - 57% and 70% - 81%, respectively, is of great value in many ways (4). First, if indicated, by fetal interventions, growth and normal development of pulmonary tissue will be guaranteed. Second, the consequences of a maladapted newborn, such as respiratory distress, long hospitalizations, frequent infectious complications, and malignancy transformation will be prevented. Third, by serial ultrasonographic monitoring, the natural course of the lesions (e.g., regressing, progressing, reaching a plateau, or even disappearing) can be followed.

Bronchopulmonary Sequestrations (BPSs), as non-functional pulmonary tissues, comprise up to 14% to 30% of congenital lung lesions (1-3). They are classified as extra lobar sequestration (ELS) and intra lobar sequestration (ILS). ILS is often located in the posterior basal segment of the left lower lobe. ELS, in almost 50% of cases, has associated malformations, such as congenital diaphragmatic hernia (1-3). ELS is found more often in the left lower lobe and is more prevalent in males (3). These two groups differ regarding venous drainage; ILS is drained into the pulmonary, but ELS is drained into the systemic (e.g., azygos or portal vein) venous system (1, 3). Detection of vascular supply is important for surgical excisional planning. There may be found a prenatal history of polyhydramnios (1-3). Moreover, some of these lesions seem to disappear postnatally. These lesions have a more favorable outcome than CCAMs (2, 3). The combination of an aberrant systemic blood supply and an echogenic lung mass in prenatal ultrasonography is pathognomonically in favor of sequestration (2).

Congenital Lobar Emphysema (CLE) is mostly seen in males and affects the left upper lobe (42%), right middle lobe (35%), right upper lobe (21%), and lower lobes (2%), in sequence of prevalence (2, 3). Spontaneous regression in the third trimester is not unusual in CLEs. Asymptomatic lesions, or ones with minimal symptoms, may be followed conservatively, contrary to CCAMs and PSs, which hold the risk of later infection and malignancy transformation. CLE is rarely documented in prenatal ultrasonographies (2, 3).

Bronchogenic cysts (BCs) are found in the mediastinum in up to two-thirds of cases, with the remainder found within the lung parenchyma (1-3). Most cases present postnatally, usually with pulmonary infection. Malignant transformation has not been reported in relation to these lesions. Some clinicians choose to manage them conservatively, while others prefer surgery, based on the patient’s symptoms or the mass’s complications (1-3).

2. Objectives

The aim of this study was to demonstrate the diversity of congenital pulmonary masses, define the applied diagnostic modalities of each, and report an analysis of demographic data and patients’ various presenting features.

3. Methods

This retrospective study was conducted in Mofid children’s hospital, as the most crowded referral pediatric surgery center, to provide readers with comprehensive data about each congenital mass group’s characteristics and make comparisons with similar studies. All patients included in this study were diagnosed prenatally or postnatally as congenital pulmonary mass, incidentally detected during hospital course as congenital pulmonary mass, or referred for further investigation between the years of 2004 and 2015. After obtaining approval from the ethical committee of Shahid Beheshti University of Medical Sciences, data pertaining to all patients presenting with congenital lung mass during the 11-year period was obtained from the hospital medical records department. Patients’ surgeries were performed by board-certified pediatric surgeons, via the trans-thoracic approach. Imaging studies, including chest radiography, ultrasonography, and CT scans were all performed at Mofid children’s hospital, with the exception of prenatal ultrasonographies and fetal MRIs.

The following data was retrospectively studied, based on the medical records: sex, gestational age, age at surgery, patient’s first presenting symptom, length of hospitalization, and accompanying features. The prenatal ultrasonographic diagnosis, postnatal radiographic diagnosis, and pathologic diagnosis of each patient was identified, if available.

4. Results

Between the years 2004 and 2015, 47 cases were definitely diagnosed as congenital lung mass in Mofid Children’s Hospital. Cases of pulmonary cystic lesions were separately analyzed in this study. Of these 37, 28 cases (75%) were boys, and 9 (25%) were girls. The mean hospital stay of the patients was 13.3 days (SD: 10.21). Thirty-six (97.2%) cases presented with pure pulmonary signs and symptoms, whereas only one (2.8%) case was accidentally diagnosed and one presented with non-respiratory features (e.g., fever, vomiting, restlessness, and poor weight gain). Cases were subdivided into three distinct age groups, as follows: group 1 included cases with the age of 28 days and younger; group 2 consisted of patients aged 29 days to 24 months; group 3 was composed of cases with a patient age two years and older. The frequency of cases in each age group was 16 (43.2%), 17 (46%), and 4 (10.8%), respectively.

In terms of prenatal evaluations, unfortunately, 27 (73%) patients missed the opportunity for early diagnosis. Most of the cases without prenatal diagnosis were later found to be CLE. Ten (27%) pathologically diagnosed patients had the same radiologic diagnosis.

Of 37 cases, 16 (43.5%), 12 (32.5%), 7 (19%), 1 (2.5%), and 1 (2.5%) were diagnosed as CLE, CPAM, pulmonary sequestration, hybrid lesion, or bronchogenic cyst, respectively. Lesions were mostly located in the left side of the thorax (21, or 57%) versus the right side (16, or 43%). Echocardiography was routinely done during the hospital course, but the GI contrast study for detecting any possible gastrointestinal communication was performed in none of the cases. Accompanying features, with the exception of icterus as a common neonatal complaint and pneumothorax and pleural effusion as frequent complications of thoracotomy, were considered as follows: three cases with cardiovascular morbidities (patent ductus arteriosus and atrial septal defect), two cases with hematologic accompanying feature (thrombocytopenia), two cases with central nervous system abnormality (leukomalacia and brain cyst), and one case with hypospadiasis. Of these nine accompanying co-morbidities, four were seen with pulmonary sequestration, three were seen in CCAM, and two were among the CLE cases.

Table 1. Distribution and Characteristics of Congenital Pulmonary Lesions
LesionNo.RightLeftBilateralAge RangeMedian Gestational Age, WeekM: FPrenatal Diagnosis+/-
CCAM125611 - 124 days37.610: 24/8
Pulmonary Sequestration743019 days - 8 years37.44: 33/4
CLE1651106 days - 5 years39.813: 31/15
Hybrid lesiona10103 days380: 11
Bronchogenic Cyst11006 days381: 01 (wrong diagnosis)
Total37152111 day - 8 years39.528: 910/27

aHybrid lesion refers to the simultaneous presence of CPAM and sequestration in an individual pulmonary lesion.

5. Discussion

In a study conducted by Langston in Texas children’s hospital, 42 cases had the same pathologies as our study. In contrast to the frequency of our cases, their cases included pulmonary sequestration (40%), CLE (24%), CCAM (21%), and bronchogenic cyst (15%) (5). In the Langston study, male predominance was apparent in all the masses except for CLE, in which the sexes had the same frequency. However, in our study, the male-to-female ratio of CLE cases was 13 to 1 (5).

In another study in Saudi Arabia, of 57 cases, 65% were CLE, 12% were CCAM, 14% were bronchogenic cyst, and 9% were sequestration. The prevalence of cystic lesions in the Saudi Arabia study was somewhat comparable to ours regarding the high prevalence of CLE cases (6). Most of our cases with undefined prenatal diagnosis were postnatally diagnosed as CLE (55%). Although missing some of these screening prenatal diagnoses is inevitable, even in expert hands, paying attention to controversial clues and ambiguous hints should prompt radiologists to apply further modalities, such as ultra-fast magnetic resonance imaging (7, 8). Unfortunately, all of the pathology reports neglected to include Immune-Histo-Chemical staining, which is necessary for prediction of probable future malignant transformation (9, 10).

CCAM sub-typing in our study was as follows: five cases were type 1, which is considered the most common and has the best prognosis; two cases were classified as type 2 (one of them was the only hybrid lesion); one case was type 3 and, unfortunately, five cases did not specify typing (1-3). In the study of Adzick et al., excluding type 0, which is incompatible with life (less than 2%), most of the CCAM cases belonged to the type 1 category (60% - 70%), whereas the least common cases were included in the type 3 group (10). Classification of CCAM lesions into macro-cystic and micro-cystic was not mentioned in our pathologies.

Male gender was significantly (five times) more prevalent in these lesions. In our survey, three cases were diagnosed as ELS, two BPS were not defined regarding their sub-category, one case was a hybrid of ELS and CPAM (type 2), and only one case was an ILS. In the study of Langston in Texas, ELSs were almost two times more frequent than ILSs, whereas in the study conducted in Saudi Arabia, such classification was not mentioned (5, 6). These lesions equally involved the two hemi-thoraces. None of the PSs had the accompaniment of polyhydramnios, hydrops, or diaphragmatic hernia. In spite of the significance of vascular drainage of such lesions, the vascularity of the only hybrid lesion was specified in the surgery notes (i.e., vein drained to azygos and artery derived from the descending aorta).

In our investigation, among 16 cases of CLEs, only one case had prenatal diagnosis; 13 cases were males, and 11 cases were located in the left upper lobe. In this study, none of the CLE cases was diagnosed to have congenital heart disease, although that is expected in 20% of cases, according to the previous studies (2, 3). Polyhydramnios, mediastinal shift, bilateral lesions, existence of hydrops, and larger cysts have been proposed as poor prognostic features (1-3, 10-12).

Our only case of right BC was a six-day old male with associated findings of prenatal polyhydramnios, congenital diaphragmatic hernia, and jejunal atresia. Although he could have benefited from fetal interventions, such as simple amniotic fluid centesis to alleviate polyhydramnios, open fetal surgical resection, thoracoamniotic shunt placement, and percutaneous laser ablation, surgeons decided to postnatally resect the lesions through lobectomy (13, 14).

In our study, polyhydramnios was documented in three cases: in a case of CCAM (type 1), in a newborn with bronchogenic cyst, and in a patient diagnosed with congenital lobar emphysema. We found just one bilateral case of CCAM. She was a three-day old female, who underwent bilateral segmentectomy and was discharged in good condition after 25 days of hospitalization. Hydrops was not indicated in any cases. History of prematurity was present in three cases (two CCAM and one pulmonary sequestration). The cases with the oldest patients included an 8-year-old female with sequestration, two 5-year-old females with sequestration, and a 3.5-year-old female with CLE.

5.1. Conclusion

Regarding the diversity and significance of congenital pulmonary masses detected in children, in this study, we aimed to identify the characteristics of cystic lesions during an 11-year period in a referral children’s hospital in Tehran, Iran. Male predominance was obvious among the cases, as had been found in previous studies.

Acknowledgements

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