Surgical lung biopsy (SLB) is an invasive procedure performed to assist in treatment efforts when other noninvasive or minimally invasive procedures have failed to provide an urgent and specific diagnosis.1,2 Surgical lung biopsy is performed through a limited thoracotomy, without costal arc resection, allowing tissue samples to be obtained from 1 or more involved lobe(s)1 for adequate histological, histochemical, and molecular analysis. However, there may be reluctance to perform SLB in critically ill patients with diffuse pulmonary infiltrates, who are frequently suffering from acute respiratory failure, often undergoing mechanical ventilation, and hemodynamically unstable. The progression of the disease and the need of a specific diagnosis are decisive factors. The purpose of this study was to evaluate diagnostic accuracy, changes in therapy, and survival of patients with diffuse lung infiltrates, mostly presenting acute respiratory failure, who underwent SLB.

Patients. We examined the medical records of all patients who underwent SLB at our institutions from January 1982 to December 2003. From these we selected patients older than 18 years of age with diffuse infiltrates on chest roentgenogram and respiratory failure. Respiratory failure was defined as a PaO2 of less than 60 mmHg (hypoxemic ARF), or a SpO2 less than 90% of arterial blood, or PaCO2 more than 50 mm Hg (hypercapnic acute respiratory failure) while breathing room air. Acute was defined as onset of symptoms of respiratory distress less than 10 days prior to SLB, in order to exclude those patients with a steady deterioration of a chronic process. Surgical lung biopsy was performed at the discretion of the attending physician under general anesthesia; progressive hypoxemia was the usual indication. Through a limited thoracotomy, tissue samples were removed with a cutting stapler. A specific protocol for specimen processing was followed. A portion of the surgical specimen was sent to surgical pathology, and permanent sections were examined after appropriate staining. The remaining specimen was sent to the microbiology laboratory where smears were prepared and part of the tissue was homogenized. Cultures were prepared for aerobic and anaerobic bacteria, fungi, mycobacteria, Legionella, Nocardia, Chlamydia, and viruses. Stains were performed with Gram stain for bacteria, Grocott for fungi and Pneumocystis carinii, and Ziehl-Neelsen for mycobacteria and Nocardia. Results of stains were usually available within 3 hours after specimen arrival in the laboratory.

Statistical Analysis. Comparisons between groups were made using chi-square analysis and unpaired t test when appropriate; P < 0.05 was taken as significant. Every analysis was performed with the SPSS for Windows 10.0 statistical software.

Patient Characteristics. Over the period examined, 303 surgical lung biopsies were performed, and 63 cases (20.8%) met our study criteria. Thirty-one patients (49%) were women and 32 (51%) were men, with a median age of 51 years (range, 18 to 92 years). Arterial blood samples for gas analysis taken during inspiration of room air in the 24 hours preceding SLB were obtained from 56 patients (89%). Forty-four patients were in acute respiratory failure as indicated by the following: 38 of them had a PaO2 < 60 mm Hg; 4 had a PaCO2 > 50 mm Hg; and in 2 patients, both PaO2 and PaCO2 indices were altered. Eleven cases had only SpO2 values (under 90%) available. Tables 1 and 2 list respectively the gasometric data and preexisting medical conditions in the study population. Thirty-three patients (52%) were immunocompromised, and 48 (66%) had preexisting medical conditions. The mean time from admission to SLB was 18 days (range, 0 to 61 days), the mean interval from SLB to hospital discharge or death was 21 days (range, 1 to 143 days) and the mean total hospitalization time was 39 days (range, 4 to 184 days).

Diagnostic Results. The diagnostic results of SLB are shown in Table 3. All biopsy specimens exhibited abnormalities. Forty-eight patients (76%) had benign/inflammatory etiologies; 14% had infectious causes, and 10% had infiltrates directly or indirectly due to neoplastic process. Among the main benign/inflammatory etiologies, 26 patients (41.3%) had diffuse alveolar damage (DAD)—as the only histopathological diagnosis in 7 patients, or associated with the main process in 19 patients. Twenty one of these were in the exudative stage and 5 in the proliferative stage. Acute lung injury was observed in 6 cases. At least 15 patients received steroid treatment, but in only 3 cases was corticotherapy started after the histopathological result (Table 4). Only 1 patient was in acute respiratory distress clinically. Seven patients (11%) had usual interstitial pneumonia (UIP), and 7 patients had chronic bronchiolitis, both in acute exacerbation and discordant radiology vs histopathology. Seven patients (11%) had a granulomatous process (2 sarcoidosis and 5 tuberculosis); 5 patients (8%) had pulmonary thromboembolism, and 4 patients (6.3%) had passive congestion. For 15 patients (23%) an etiologic factor was determined through the biopsy as follows: acute and chronic broncho-aspiration in 4 patients (6.3%) and infectious etiologic factor in 11 patients (17%). The most common cause found was tuberculosis, occurring in 5 patients (8%), followed by cytomegalovirus in 2 patients (3%), Pneumocystis carinii in 2 patients (3%), Strongyloides sp. in 1 patient (1%), and Aspergillus sp. in 1 patient (1%). Clinical, biopsy, and necropsy diagnoses were compared (Table 3). In this situation, the preoperative diagnosis of the cause of respiratory failure or diffuse pulmonary infiltrate was changed in 37 patients (59%). Autopsies were obtained in 25 patients who died in hospital and confirmed SLB results in 18 cases (72%). Therapy was changed in 31 patients (65%) based on SLB results. Change in therapy was defined as the as the addition or subtraction of 1 or more drugs or the early discontinuation of aggressive life support. Drug changes usually involved antibiotics and/or corticosteroids, but also included heparinization and the initiation or discontinuation of antineoplastic agents for malignancy or drug-induced toxicity, respectively. Surgical complication data was obtained in 32 patients; surgical complications were present in 5 patients (1 infection of the surgical wound, 1 pneumothorax, and 3 subcutaneous emphysema, Table 4).

Survival. Thirty-one patients (49%) survived to be discharged from the hospital.. For the 34 patients who died in hospital, survival time after SLB was 20 ± 29 days. Although not statistically significant, alterations in therapy resulting from SLB modified the survival rate in 7 patients (22%) out of 32 patients who had the information available (X2 = 0.14, P = 0.4). A marginal significance was found between mortality and the presence of surgical complications (X2 = 3.80, P = 0.05). In addition, neither the availability of a specific diagnosis nor changes in diagnosis, as well as infectious agent or immunocompromised status affected survival rates (X2 = 0.44, P = 0.24; X2 = 0.51, P = 0.27; and X2 = 0.13, P = 0.08, respectively).

Preoperative characteristics that did not differ between survivors and nonsurvivors included age (X2 = 2.42; P = 0.9.), PaO2, (X2 = 5.07; P = 0.1) PCO2, (X2 = 4.02; P = 0.1) and breathing frequency at the time of SLB ((X2 = 1.37; P = 0.6). There was no difference between the preoperative primary diagnosis and the diagnosis found at SLB in survivors versus nonsurvivors. Characteristics that differed significantly between survivors and nonsurvivors included sex (X2 = 3.56; P = 0.05), comorbidity (X2 = 3.56; P = 0.05), SpO2 (X2 = 3.98; P = 0.05), and presence of DAD in the SLB (X2 = 8.38; P = 0.004). Eight out of 26 patients (31%) with DAD and only 3 out of 11 patients (27 %) with infectious etiology survived, in contrast to the case with acute exacerbation of UIP, in which 4 of 7 patients (57%) survived. A marginal significance was obtained for the clinical and gasometric pattern of acute respiratory failure (X2 =3.1; P = 0.07)

Although SLB did provide a specific diagnosis in many patients with diffuse pulmonary infiltrates and acute respiratory failure, the hospital mortality rate of 51% was high in this hypoxic patient population. Hospital mortality rates from similar but smaller series of hypoxic patients undergoing SLB are consistent with our experience, ranging from 50% to 70%.3–7 In contrast, reported mortality rates for all patients (hypoxic and nonhypoxic) undergoing SLB tend to be lower.4,8–10 Greenman and coworkers11 found a 73% mortality rate in hypoxic (PaO2 < 55 mm Hg) immunosuppressed patients and a 39% mortality rate in nonhypoxic patients. In immunosuppressed patients, Jaffe and Maki12 found a significantly higher PaO2 in survivors of SLB, as compared to nonsurvivors. While our study was not designed to evaluate hypoxia as a predictor of mortality in patients undergoing SLB, probably our hypoxic patients ultimately did not fare well.

Given the high mortality rate, it would be helpful to be able to predict outcome. Poe and coworkers13 in a retrospective review attempted to predict mortality in immunocompromised patients with pulmonary infiltrates undergoing either transbronchial biopsy or SLB. They found that early mechanical ventilation (within the first 72 hours of admission, either preoperatively or for more than 24 hours postoperatively), the initial room-air PaO2, and corticosteroid therapy at the onset of symptoms were significant predictors of mortality. None of the 51 patients who simultaneously had a PaO2 of < 50 mm Hg on room air, was receiving corticosteroids, and required early mechanical ventilation survived.

Most investigators feel that mortality in patients undergoing SLB is due to the severity of the underlying disease and not to complications of the surgical procedure.3,4,14–16 With the exception of a mortality percentage of 21.4% reported by Ferson et al,17 more recent series refer indices lower than 8% directly related to the biopsy procedure.18–21 While this assertion is difficult to prove, the complications in our series did not appear to directly cause death. However, the mortality rate in the patients suffering complications, while marginally significant, suggests that such complications requires more complex patient care. Studies evaluating the impact of SLB complications on outcome should include a nonoperative control group. In a prospective, randomized study comparing SLB and empiric antibiotic therapy for acute pneumonitis in 22 non-neutropenic cancer patients, Potter and coworkers22 did not find a significant difference in mortality rates between the 2 groups. The investigators did feel that 3 patients (21% of those undergoing SLB) experienced complications of SLB that contributed directly to their deaths. Although our patients did not suffer this high rate of catastrophic complications, any complication of a procedure of uncertain benefit is of concern.

Intrathoracic surgery, especially in the hypoxic patient, carries with it the risk of prolonged postoperative mechanical ventilation. Although it became possible to extubate half of our patients postoperatively, 6 patients (50%) were mechanically ventilated until death. It is not known how many of these patients would have eventually required ventilatory support had SLB not been performed, although only 1 of the patients presented a serious complication (air leak) related to the biopsy.

In the last decades, advances in technology such as computerized tomography, acquisition of knowledge in lung pathology produced by indications of surgical lung biopsy, the new ATS/ERS Classification of the Interstitial Lung Diseases may be an explanation for our 100% of specificity in diagnosis, in contrast to those found in previous series of SLB in immunosuppressed patients, ranging from 40% to 83%.11,12,23–27 Autopsy results in 18 (72%) patients verified the accuracy of SLB in all but 7 cases; the additional diagnosis (4 infectious pneumonias, 5 diffuse alveolar damages, and 1 bronchiolitis) may represent infections or complications resulting from them, which occurred between SLB and death. In many patients, the preoperative diagnosis was either erroneous or incomplete. The impact of SLB on changes in diagnoses, the presence of a specific diagnosis, and subsequent alterations in therapy on survival were very encouraging, and mirrored the experience of many others investigators.7,14,16,28,29 Delays in diagnosis can account for the high mortality rate reported in the literature,25,28,30 because the study population included many patients undergoing SLB relatively late in the course of their acute respiratory failure. Mortality might have been even greater in the diagnostic group, had a diagnosis not been made, this being a speculation that can be evaluated using our data. Also, patients without a specific diagnosis may have had less severe disease and may have thus been preselected for lower mortality. Nevertheless, while SLB is undoubtedly of value in securing or confirming diagnoses, our results suggest that SLB may influence patient survival rates through the direction of treatment strategy.

If patient benefit is defined by survival, the 6 patients (50% of total) who both survived and in whom SLB results were judged to be useful in guiding therapy can definitely be described as having benefited from SLB.

In conclusion, SLB provided a specific, accurate etiologic diagnosis in many patients with diffuse pulmonary infiltrates and acute respiratory failure when clinical improvement did not occur after standard treatment. Surgical lung biopsy may produce a specific diagnosis that indicates a distinct treatment, lowering patient mortality.