Radiol Oncol 2019; 53(3): 357-361. doi: 10.2478/raon-2019-0032 357 research article Idiopathic pulmonary fibrosis in patients with early-stage non-small-cell lung cancer after surgical resection Nezka Hribernik1, Igor Pozek2, Izidor Kern2 1 Institute of Oncology Ljubljana, Ljubljana, Slovenia 2 University Clinic of Respiratory and Allergic Diseases Golnik, Golnik, Slovenia Radiol Oncol 2019; 53(3): 357-361. Received 22 January 2019 Accepted 26 June 2019 Correspondence to: Izidor Kern, M.D., Department of Pathology, University Clinic of Respiratory and Allergic Diseases Golnik, Golnik 36, 4204 Golnik, Slovenia. Phone: +386 4 25 69 415; E-mail: izidor.kern@klinika-golnik.si Disclosure: No potential conflicts of interest were disclosed. Background. The outcomes of patients with both lung cancer and idiopathic pulmonary fibrosis (IPF) are unfavora- ble. Therapeutic interventions for lung cancer such as surgery can cause acute exacerbation of IPF (aeIPF). This study aimed to assess the frequency of IPF in a group of patients with early-stage non-small-cell lung cancer (NSCLC) and to report clinical characteristics and outcomes of this cohort of patients. Patients and methods. This observational cohort retrospective study analyzed 641 pathological records of patients after surgical resection of early-stage non-small-cell lung cancer (NSCLC) at University Clinic Golnik from May 2010 to April 2017. Pathological records of NSCLC with coexisting IPF were reviewed. CT scans and biopsy specimens for this group of patients were analyzed by a thoracic radiologist and pathologist, independently. We searched radiological and pathological features of usual interstitial pneumonia (UIP) pattern in this group of patients. We report the clinical characteristics and outcome of this cohort of patients. Results. Out of 641 patients with early-stage NSCLC, only 13 (2.0%) had histologically and radiologically proven co- existing UIP/IPF. Squamous cell carcinoma was the most common type of lung cancer (7/13 patients). The majority of tumors were small size (all being pT1 or pT2), stage I–II (11/13 patients), located in the lower lung lobes (11/13 patients). Almost all patients were current or ex-smokers (11/13 patients). There were two pathologically confirmed fatal cases (15.4%) due to aeIPF in the first two months after radical treatment, one after adjuvant radiotherapy and the other after surgery. Out of 13 patients, one patient had a lung cancer relapse. Conclusions. Frequency of UIP/IPF in surgically treated early stage NSCLC is rather low. Our observational study shows that radical treatment of lung cancer can cause aeIPF with dismal outcome in this group of patients. The standard of care in these mostly elderly patients still remains unresolved. Key words: early-stage non-small-cell lung cancer; idiopathic pulmonary fibrosis; acute exacerbation; surgery; radio- therapy Introduction In Slovenia, lung cancer is still the leading cause of cancer mortality in men and the third cause of can- cer mortality in women.1 Non-small-cell lung can- cer (NSCLC) represents about 85% of all lung can- cers.2 For 20–25% of all lung cancer patients, who are diagnosed at an early stage (stage IA–IIIA), surgery remains the best chance of cure.3 Patients at very high risk for surgery-related complications can be treated with curative radiotherapy (RT), ei- ther hypofractioned high-dose RT or stereotactic body radiation therapy (SBRT) in stage I NSCLC.3 Reported local control after SBRT reaches around 80%–90% at 5 years.4,5 Idiopathic pulmonary fibrosis (IPF) is a devas- tating lung disease that affects mostly smokers. It is a specific form of a progressive fibrotic interstitial Radiol Oncol 2019; 53(3): 357-361. Hribernk N et al. / Idiopathic pulmonary fibrosis in NSCLC358 lung disease of unknown cause, occurring primar- ily in older adults. It shows histopathologic and radiologic pattern of usual interstitial pneumonia (UIP).6 Long-term survival of IPF patients still re- mains poor with median survival rate from 2 to 3 years from time of diagnosis.7 Data suggest an increased risk of lung cancer among patients with IPF.8 Treating patients with early-stage lung cancer and coexisting IPF can be demanding as IPF is independently associated with poorer overall survival in patients with lung can- cer who undergo pulmonary resection.9-11 Surgical procedures can lead to an acute exacerbation of IPF or other respiratory complications.12 And as re- ported, pre-existing interstitial lung disease, such as IPF, is a significant risk factor for developing se- vere radiation pneumonitis after RT.13-16 This study aimed to assess the frequency of IPF in a group of patients who had radical surgical re- section for an early-stage NSCLC, to describe mor- phological and clinical characteristics and report outcomes of this cohort of patients. Patients and methods We conducted an observational cohort retrospec- tive study analyzing 641 consecutive pathological records of patients who underwent lung surgery because of an early-stage NSCLC at University Clinic Golnik from May 2010 to April 2017. Patients with metastatic NSCLC or neuroendocrine carci- noma were excluded from the analysis. The study was conducted in accordance with the ethical standards laid down in an appropriate version of the 1964 Declaration of Helsinki. The study was conducted with the understanding and the consent of the subjects. Prior to intervention for the acquisition of bioptic material, patients have signed an informed consent for intervention and that their data can be used for scientific purposes. All pathological records with an early-stage NSCLC and interstitial fibrosis with UIP pattern were selected for more detailed analysis. CT scans and pathological specimens for this group of pa- tients were reviewed again by a thoracic radiolo- gist and pathologist, independently. The UIP/IPF patient cohort included patients who were given a diagnosis of definite UIP/IPF, probable UIP/IPF, or possible UIP/IPF in according with the American Thoracic Society, European Respiratory Society, Japanese Respiratory society, and Latin American Thoracic association (ATS/ESR/JRS/ALAT) 2011 statement.6 All other patients were excluded from further analysis. The clinical data of patients with coexisting early-stage NSCLC and UIP/IPF were thoroughly reviewed. Demographic data (age, gender, smok- ing status), pulmonary function test results (forced expiratory volume in 1 s (FEV1), forced vital capac- ity (FVC), diffusing capacity of the lung for carbon monoxide (DLCO)), as well as data on postopera- tive morbidity, mortality and adjuvant therapy TABLE 1. Baseline clinical, radiological and pathological characteristics of patients with early-stage non-small cell lung cancer and idiopathic interstitial pneumonia Characteristics N = 13 (%) Gender Male 11 (84.6) Female 2 (15.4) Age, years 73.3 ± 4 Smoking status Current smoker 3 (23.1) Former-smoker 8 (61.5) Never-smoker 2 (15.4) FEV1/FVC before operation 0.71 ± 0.08 FEV1 before operation ml 2769 ± 690 % 101.6 ± 20 FVC before operation ml 3910 ± 818 % 105 ±19 DLCO before operation % 74.2 ±21 Histological subtype Squamous cell carcinoma 7 (53.8) Adenocarcinoma 5 (38.5) Adenosquamous cell carcinoma 1 (7.7) Pathologic TNM stage (8th edition) pT1a 3 (23.0) pT2a 6 (46.2) pT2b 4 (30.8) IA 2 (15.4) IB 2 (15.4) IIA 3 (23.0) IIB 4 (30.8) IIIA 2 (15.4) Lobe distribution Left lower lobe 7 (53.8) Right lower lobe 4 (30.8) Right middle lobe 2 (15.4) Type of operation Lobectomy 11 (84.6) Bilobectomy 2 (15.4) Adjuvant therapy Adjuvant chemotherapy 4 (30.8) Adjuvant radiotherapy 1 (7.7) Data are presented by mean ± SD or number (N, %). DLCO = diffusing capacity of the lung for carbon monoxide; FEV1 = forced expiratory volume in 1 s; FVC = forced vital capacity Radiol Oncol 2019; 53(3): 357-361. Hribernk N et al. / Idiopathic pulmonary fibrosis in NSCLC 359 (chemotherapy or RT) for lung cancer or further therapy for UIP/IPF were collected from our hospi- tal data base. Most of the patients were followed- up in other institutions, therefore data on pulmo- nary function tests after radical treatment are miss- ing and not presented in this paper. The period of data collection was from May 2010 to April 2018. Results Out of 641 patients with an early-stage NSCLC on- ly 13 (2.0%) had histologically and radiologically proven coexisting UIP/IPF. In this group of patients, 11/13 (84.6%) were men, 11/13 (84.6%) were current or former smok- ers. Mean age at time of diagnosis was 73.3 years. Pulmonary function test results before resection (FEV1, FVC, DLCO) are described in Table 1. Squamous cell carcinoma was diagnosed in 7/13 (53.8%) patients and adenocarcinoma in 5/13 (38.5%) patients. Pathological stage I was present in 4/13 (30.8%) patients, stage II in 7/13 (53.8%) pa- tients and stage III in 2/13 (15.4%) patients. In 11/13 (84.6%) of patients the tumor was located in the lower lobes. Lobectomy was performed in 11/13 (84.6%) of patients, other 2/13 (15.4%) patients had bilobectomy. After radical surgery, 4/13 (30.8%) patients received adjuvant chemotherapy and 1/13 (7.7%) patient received adjuvant radiotherapy be- cause of pN2 stage. TABLE 2. Baseline clinical, radiological and pathological characteristics of the two patients who died in two months time after radical treatment of early-stage non-small cell lung cancer due to acute exacerbation of idiopathic pulmonary fibrosis (IPF) Characteristics Patient No. 1 Patient No. 2 Gender Male Male Age, years 73 81 Smoking status Former-smoker Former-smoker FEV1/FVC before operation 72% 70% FEV1 before operation 2800 ml (93%) 3110 ml (121%) FVC before operation 3900 ml (94%) 4570 ml (122%) DLCO before operation 57% 47% Histological subtype Squamous cell carcinoma Squamous cell carcinoma Pathologic TNM stage (8th edition) IIIA IA Lobe distribution Left lower lobe Left lower lobe Type of operation Lobectomy Lobectomy Adjuvant therapy Chemotherapy and radiotherapy No Time from the end of radical treatment till death 54 days after finishing radiotherapy 14 days after surgical resection DLCO = diffusing capacity of the lung for carbon monoxide; FEV1 = forced expiratory volume in 1 s; FVC = forced vital capacity FIGURE 1. Radiological images and images of pathological specimens for Patient No.1. (A) CT scan before lung resection demonstrating honeycomb cystic changes in the subpleural regions of the lung characteristic for typical UIP pattern and tumor in left lower lobe. (B) CT scan after (radical treatment) lobectomy showing extensive bilateral ground glass opacities which are consistant with acute exacerbation of UIP and progressive reticular fibrotic changes. (C) Surgical specimen showing subpleural honeycombing with fibroblastic focus. (D) Autopsy specimen showing acute lung injury with hyaline membranes. A B C D Radiol Oncol 2019; 53(3): 357-361. Hribernk N et al. / Idiopathic pulmonary fibrosis in NSCLC360 Baseline clinical, pathological and radiological characteristics of patients are shown in Table 1. There were 2/13 pathologically confirmed fa- tal cases (15.4%) due to acute exacerbation of IPF (aeIPF). Characteristics of these two patients are presented in Table 2. Autopsy was performed in both cases to determine the cause of death. Patient No. 1 started to clinically deteriorate with respira- tory insufficiency and dry cough four weeks after finishing postoperative adjuvant RT, and died 54 days after finishing it. In patient No. 2 acute res- piratory deterioration developed on the second postoperative day, leading to death on day 14 af- ter surgery. Both patients were treated with high dose corticosteroids and oxygen. Figure 1 and 2 are showing radiological images and images of patho- logical specimens for these two patients. Another patient died in the first month after surgery, data on the cause of death is missing. Three patients (23.1%) had documented UIP/IPF progression during follow-up in the period of the data collection. They were all regularly seen by an interstitial lung diseases specialist and received pharmacologic therapy for UIP/IPF, one patient was treated with corticosteroid monotherapy and two were treated with pirfenidone. Out of 13 patients only one (7.7%) had a lung cancer relapse during data collection period and died because of this. Discussion Based on our one-center retrospective analysis, only 13/641 (2.0%) of patents with early NSCLC had concomitant IUP/IPF. To our knowledge, this is the lowest percentage to be reported till now, as earlier reports found incidence from 2.4–24.3%.17-19 The reason is probably the use of more strict inclu- sion criteria in our study. We followed both histo- logical and radiological criteria for UIP/IPF and not only histological analysis. Another reason could be that surgical resection was performed in fewer pa- tients compared to other studies due to more strict criteria for surgery. Anyhow, looking closely only at the characteristics of the two patients that died because of aeUIP, our criteria for surgery were not strict. They were elderly and had quiet low DLCO. Due to a small number of patients it is difficult to make a general conclusion. Tumors were mostly small, located in the lower lobes, with squamous histology being more fre- quent. We noticed male predominance and highly positive smoking status. All this is in accordance with earlier reports.19,20 Two patients (15.4%) had an aeIPF with fatal outcome after radical therapy, one after surgery and one after postoperative radiotherapy. It is known, that patients with IPF are at very high risk for adverse pulmonary events after lung resection surgery and that the greater the extent of lung re- section, the higher incidence of not only aeIPF, but also pneumonia, prolonged air leakage, bronchop- leural fistula, empyema in the postoperative pe- riod.21,22 There are now reports that limited resec- tions are acceptable if the resection can be achieved with an adequate margin.23 New treatment options such as SBRT, which deliver highly conformal, high doses of radiotherapy to clinical target and spare the surrounding tissue, were tested as an al- ternative to surgery. Yet, also after SBRT there are cases of severe radiation pneumonitis published in the literature.20 Regarding which is the standard of A B C D E FIGURE 2. Radiological images and images of pathological specimens for Patient No.2. (A) Chest X ray before surgical resection shows some reticular changes in the periphery of the lower lobes. CT shows reticular fibrotic changes with multiple calcifications in the periphery of the lung in combination with paraseptal emphsema and small tumor in the left lower lobe. (B) Chest X ray after left sided lobectomy shows new bilateral alveolar opacities. (C) Surgical resection specimen demonstrating microcystic changes with fibroblastic focus. (D) Autopsy specimen showing acute lung injury with hyaline membranes Radiol Oncol 2019; 53(3): 357-361. Hribernk N et al. / Idiopathic pulmonary fibrosis in NSCLC 361 care in these mostly elderly patients still remains unresolved. There is a great need to conduct a randomized controlled trial to compare survival and quality of life after surgical treatment, either radical or limited resection, versus nonsurgical treatment and to determine predictive factors that would help to guide the decision. Clinical registries could also prospectively collect data on this group of patients, helping to gain more real-life data. Until we get more of this hard data on which oncological-surgical treatment is most appropriate, it is worthwhile to discuss such clinical cases in an individual manner at a multidisciplinary tumor board, with an interstitial lung disease specialist being part of it. At the same time, these patients should be followed by interstitial lung diseases specialist after completing radical treatment for lung cancer, receiving the appropriate therapy for IPF, if needed. Intensive surveillance is a must in this group of patients. Our retrospective observational study has many limitations. 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