Background
Infectious diseases are the most common cause of death worldwide [
1]. Pulmonary infections result in more deaths each year than any other type of infectious disease [
2]. Delayed identification of the causative pathogen is the major cause of treatment failure and death in cases of pulmonary infection. Current microbiological tests such as culture-based methods have limitations in terms of sensitivity [
3,
4], speed, and the spectrum of available assay targets [
5]. Failure to identify the etiologic agent can lead to nonspecific and ineffective antibiotic therapy, resulting in adverse outcomes [
5,
6]. Timely identification of infectious pathogens allows tailoring of antimicrobial regimens, which can improve the prognosis of pulmonary infections.
Advances in genomic sequencing technologies and bioinformatics approaches have provided useful tools for clinical diagnostics such as metagenomic next-generation sequencing (mNGS) [
7‐
9]. mNGS is an unbiased approach that can in theory detect any microorganism in a clinical sample [
10], and can distinguish etiologic microorganisms from background commensals [
11]. Several studies have used mNGS to detect pathogens in infections of the central nervous system [
12‐
14], digestive tract [
15,
16], systemic circulation [
17,
18], and lungs [
19‐
23]. However, there have been few reports on the use of mNGS for diagnosing pulmonary infections, and the types of sample tested were mainly limited to percutaneous lung biopsy [
19] and bronchoalveolar lavage fluid (BALF) [
20‐
23] specimens.
Peripheral pulmonary lesions (PPLs), which are lesions surrounded by normal lung parenchyma, are difficult to visualize by bronchoscopy and thus pose a challenge for diagnosis. Computed tomography (CT)-guided percutaneous needle biopsy has a high diagnostic yield for PPLs, but is invasive and has a relatively high incidence of complications such as bleeding or pneumothorax [
24,
25]. Bronchoscopy is appropriate for initial investigation of PPLs because of the lower complication rate [
26]. Most previous studies have focused on the use of bronchoscopy in diagnosing malignancies, and there is little information on its application to the diagnosis of infectious PPLs.
The present study comprised 2 parts. We first retrospectively evaluated the performance of mNGS for detecting pathogenic microorganisms in infectious PPL samples obtained by ultrathin bronchoscopy in conjunction with virtual bronchoscopic navigation (VBN) and rapid on-site cytological evaluation (ROSE), and compared the diagnostic accuracy of mNGS with that of the conventional culture method. We also analyzed the microbial composition of transbronchial lung biopsy (TBLB), bronchial needle brushing (BB), and BALF specimens and compared the diagnostic accuracy of mNGS for the 3 specimen types.
Methods
Patient selection
We retrospectively analyzed the medical records of consecutive patients who were clinically and radiologically suspected of having infectious PPLs and underwent VBN-assisted ultrathin bronchoscopy at our hospital between July 2018 and July 2019. Patients for whom TBLB, BB, and BALF samples were not simultaneously available for mNGS as well as those with incomplete clinical data were excluded. Ultimately, 39 patients were included in the analysis.
Specimen collection and processing
All bronchoscopies were performed by the same experienced bronchoscopist. The patient was locally anesthetized with 2% lidocaine, and an ultrathin bronchoscope (BF-typ XP260F; Olympus, Tokyo, Japan) with an external diameter of 2.8 mm and channel diameter of 1.2 mm was navigated to the target bronchus as far as possible using a VBN system (Direct Path 1.0). TBLB, BB, and BALF were sequentially collected from peripheral lesions in each subject. TBLB was performed first, while ROSE was performed during the examination to determine whether the amount of sample was sufficient for analysis. BB was then performed using a protective needle brush, and BALF specimens were obtained after brushing the samples.
BALF specimens were separately sent to the clinical microbiology laboratory for culture and to a commercial laboratory for mNGS. TBLB specimens and sterile saline soaked with protective needle tip were sent to a commercial laboratory for mNGS. In addition to culture, other traditional pathogen detection methods based on invasive respiratory specimens obtained through bronchoscopy were described in detail in a previously published study in our center [
27]. Gram staining, acid-fast staining, hexamine silver staining, the galactomannan antigen detection test (GM test) with BALF samples, and
Mycobacterium tuberculosis / rifampicin resistance test (X-pert) with BALF samples were performed to identify bacteria including
M. tuberculosis and fungi including
Pneumocystis carinii.
Rose
Biopsy specimens were smeared onto labeled glass slides and rapid staining was performed using Diff-Quik stain. The specimens were immediately evaluated under a light microscope by a cytotechnologist to determine whether the sample was sufficient for a provisional diagnosis and subsequent laboratory analyses. The assessment was communicated to the bronchoscopist, who terminated or modified the sampling process accordingly.
mNGS
Sample processing and nucleic acid extraction
Lung biopsy specimens were cut into small pieces. BALF samples (0.5–3 ml) and the soaking solution of brush tips were collected according to standard procedures. DNA was extracted from the samples using the TIANamp Micro DNA Kit (DP316; Tiangen Biotech, Beijing, China) according to the manufacturer’s protocol.
Construction of DNA libraries
Single-stranded (ss) DNA libraries were constructed after DNA fragmentation, end repair, adapter ligation, denaturation into single strands, and circularization. DNA nanoballs were generated from the ssDNA by rolling circle amplification and loaded into the flow cell and sequenced on a BGISEQ-50 platform (BGI, Beijing, China).
High-quality sequencing data were generated by removing low-quality and short-length (< 35 bp) reads, followed by a computational subtraction of human sequences mapped to the human reference genome (hg19) by Burrows–Wheeler alignment. After removing low-complexity reads, the remaining data were classified by simultaneous alignment to 4 NCBI microbial genome databases (
ftp://ftp.ncbi.nlm.nih.gov/genomes/) comprising whole genome sequences of 4061 viral taxa, 2473 bacterial genomes or scaffolds, and genomic sequences for 199 fungi related to human infection and 135 parasites associated with human diseases.
Diagnosis of pulmonary infection
The final diagnosis was made based on clinical manifestations, imaging findings, pathogen detection by culture methods and mNGS, serologic examination results, ROSE, and histopathologic analysis, expert opinion, and treatment effect observations. Serologic examination included nucleic acid detection by PCR-based testing for common respiratory viruses (Epstein–Barr virus, human cytomegalovirus, respiratory syncytial virus, parainfluenza virus, and adenovirus), serum cryptococcal capsular polysaccharide antigen test for Cryptococcus neoformans detection, and Mycoplasma pneumoniae antibody detection.
Statistical analysis
The sensitivity and specificity of mNGS for the diagnosis of pulmonary infections were evaluated based on the final diagnosis as the gold standard. SPSS v25.0 software (SPSS Inc., Chicago, IL, USA) was used for statistical analysis, and Prism v8 software (GraphPad, La Jolla, CA, USA) was used to plot the data. The chi-squared test was used to compare rates and analysis of variance was used to compare measurement data between groups. P < 0.05 was considered statistically significant.
Discussion
Conventional culture-based techniques that are employed to isolate pulmonary pathogens typically use selective culture media designed for specific types of microorganism and are thus biased towards those that are known; novel and rare microorganisms may therefore be missed, which explains the typically low detection rates. One study reported a sensitivity of 35.2% by the culture method in the diagnosis of infectious diseases [
22]. However, another group reported that no bacterial pathogen was isolated by culture in up to 75% of pneumonia cases [
4], which is similar to the culture-negative rate in another study [
3]. In the present work, the culture-positive rate for the diagnosis of lung infections was 16.3%. This low rate may be explained by the fact that the patients were treated with broad-spectrum antibiotics prior to sample collection, which could affect culture results without eradicating the infection [
23,
28]. Additionally, 74% of patients in our cohort were immune-impaired, and may therefore have harbored microorganisms that were fastidious or non-cultivable [
3,
29,
30].
mNGS allows for unbiased detection of virtually any pathogen present in a sample through direct sequencing of extracted DNA [
31,
32]. Several studies have reported the application of mNGS to the diagnosis of pulmonary infections. Different standards were used to calculate the sensitivity of mNGS for detecting pathogens in these studies, with some based on traditional methods [
19‐
21] and others based on the final diagnosis [
22,
23]. However, all of the studies concluded that mNGS has greater sensitivity and hence, an advantage over traditional culture-based methods in the identification of pathogens. mNGS has been used to detect pathogens in CT-guided lung tissue puncture biopsies; the sensitivity and specificity were 100.0% and 76.5%, respectively, for bacteria and 57.1% and 61.5%, respectively, for fungi, which were higher than the culture method [
19]. The sensitivity of mNGS for detecting respiratory microbes (human metapneumovirus, respiratory syncytial virus,
Stenotrophomonas maltophilia, human herpesvirus 6, and cytomegalovirus) in BALF from hematopoietic cell transplant patients with acute respiratory illnesses was reported to be 100%, which is higher than the rate by culture-based methods [
20]. In 13 cases of pneumocystis pneumonia,
P. jirovecii was detected in all BALF, sputum, and blood samples by mNGS and in 5/13 samples by conventional methods, demonstrating the superior sensitivity of the former approach [
21]. mNGS of BALF was used to diagnose community-acquired pneumonia in immune-impaired patients; pathogens were identified in 6/13 samples by standard procedures and in 12/13 samples by mNGS [
33]. Another study reported a sensitivity of 50.7% for the diagnosis of infectious disease by mNGS; however, the analyzed samples were not limited to lung specimens as they were obtained from patients with various types of infectious disease [
22]. In the present study, the final diagnosis of each case was used to evaluate the sensitivity and specificity of the diagnostic method. We found that mNGS had higher sensitivity for detecting pathogens in BALF than standard cultures regardless of the type of pathogen (bacteria, 85.7% vs 42.9%; fungi, 71.4 % vs 4.8%; uncategorized pulmonary pathogens, 81.4% vs 16.3%).
mNGS was especially useful for detecting fungi in our study: fungal pneumonia was identified in only 1/21 samples by the culture method but in 19/21 samples by mNGS. The 2 patients missed by mNGS included one with cryptococcal pneumonia and one with aspergillus pneumonia; in the latter, the culture and GM test yielded positive results. These results suggest that although the culture-positive rate is low, it is important to combine culture, GM test, and mNGS for the diagnosis of fungal pneumonia to avoid missing a positive sample. Moreover, it should be noted that mNGS is not infallible; for example, it has no advantage for the diagnosis of cryptococcal pneumonia. As demonstrated in the present study, all 4 cases of cryptococcal pneumonia were positive for capsular polysaccharide antigen, but 1 case was missed by mNGS. ROSE also played an important role in the diagnosis of cryptococcal pneumonia: granulomas were found in TBLB specimens from all 4 patients and Cryptococcus was detected in TBLB specimens from 3 of the 4 patients. Therefore, our recommendation for the diagnosis of cryptococcal pneumonia is to test for capsular polysaccharide antigen, while mNGS is unnecessary if cryptococcal pneumonia is highly suspected based on the patient’s exposure history, clinical manifestations, imaging findings, and ROSE results.
In terms of detecting bacteria, mNGS still has advantages over culture, although this advantage is not as prominent in fungal detection.
P. aeruginosa,
K. pneumoniae, and
E. coli were readily detected by culture.; however, some pathogenic bacterial pathogens detected by mNGS, including
Nocardia,
M. tuberculosis,
P. jirovecii,
H. parainfluenzae,
P. piscolens, and
Prevotellacan’t be easily detected by culture, which are either fastidious microbes (eg, anaerobes) or require long incubation times (eg,
M. tuberculosis). In patient 4, 2 obligate anaerobic bacteria (
P. piscolens and
Prevotella) were identified and in patient 25,
P. piscolens was detected.
P. piscolens and
Prevotella are usually isolated from the oral cavity of patients with dental pulp disease, periodontal infection, or alveolar abscess as well as from healthy individuals, and are potential causative pathogens of pulp and periodontal diseases [
34,
35]; for instance,
Prevotella was shown to induce severe bacteremic pneumococcal pneumonia in mice [
36].
In the present study, 74% patients were immune-impaired and 23% were confirmed to have mixed pulmonary infections by mNGS. In contrast, conventional culture cannot be used to identify microorganisms in cases of infection caused by a mixture of pathogens. Thus, mNGS is a more useful diagnostic tool for immune-impaired patients who are susceptible to various pathogens.
We examined flora composition in the 3 types of lung specimen (including the relative abundance of pathogens and relative abundance and richness of common LRT commensals) by mNGS. Surprisingly, we found that TBLB and BB samples had similar flora compositions except in terms of the richness of common LRT commensals, while the relative abundance and richness of common LRT commensals were higher in BALF than in TBLB specimens.
BB specimens had a higher number of true positives by mNGS than TBLB and BALF specimens and fewer false positive and false negatives than TBLB specimens, indicating that BB is more useful than TBLB for diagnosing infective PPLs irrespective of diagnostic efficacy, relative abundance of pathogenic microorganisms, and interference from common LRT commensals. The superior diagnostic performance of BB was likely due to the fact that it contained cells and microorganisms from a larger area. Thus, high-throughput sequencing of BB is an alternative sampling method in patients with infectious PPLs that are unable to tolerate the more invasive TBLB procedure, such as those with hematologic diseases characterized by thrombocytopenia or poor platelet function.
It should be emphasized that we performed bronchoscopy in strict accordance with the accepted standards and took appropriate measures to avoid contamination: for example, the bronchoscope was introduced transnasally and passed through the vocal cords without aspiration to avoid oral contamination, and protected specimen brushes were used to obtain BB specimens while the bronchoscope was navigated to the target bronchus as far as possible using the VBN system to avoid interference by bacteria from sites other than the target. Research by other investigators [
22] and our own experience of using mNGS to diagnose patients who did not receive any antibiotic treatment have shown that regardless of whether broad-spectrum antibiotics are used, the detected microorganisms are usually a mixture of pathogenic microorganisms and LRT commensals. This is likely because the sequencing procedure is highly sensitive and does not depend on bacterial viability.
mNGS can provide detailed information about lung microbiota. The following criteria have been established for a positive mNGS result: 1) the relative abundance of bacteria (excluding
M. tuberculosis) and fungi exceeds a certain value (30%) [
19]; 2) the sample is positive for
M. tuberculosis if at least one read is detected at the species or genus level [
22]; and 3) if a pathogen is detected by traditional methods and the number of reads by mNGS is >50, the sample is also considered as being positive by mNGS [
19]. Correctly interpreting mNGS results remains challenging; moreover, determining which microorganism is the etiologic agent in cases of infection can be difficult as there is no clear threshold for pathogenicity. Thus, mNGS must be combined with a review of clinical information to accurately diagnose infectious diseases.
This study had some limitations. Firstly, it did not include patients who had not been treated with antibiotic agents. Because those who need to be obtained three specimens (TBLB, BALF and BB) for mNGS are often complex cases with poor response to initial empirical antibiotic agents. For economic reasons, consequently, we couldn’t assess the effect of antibiotic exposure on mNGS results. Secondly, the number of patients who had mNGS in all three samples is limited due to the relatively expensive cost of mNGS sequencing. Thirdly, the study was retrospective and we did not perform statistical comparisons of the specificity of mNGS for different sample types. This is because specimens for mNGS were collected only if the clinical information, CT findings, and ROSE results suggested the presence of infectious lesions; therefore, there were few negative cases, making the calculated specificity unreliable.
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