Fungal contamination of the respiratory tract and associated respiratory impairment among sawmill workers in India

Study design and study population

The wood processing facilities studied were all primary mills where logs were stripped, trimmed and sawn into lumber boards primarily used for furniture making. Prior to milling, the logs are stored in an outdoor holding area that is subject to ambient environmental conditions, including drenching precipitation during the rainy season. The major species processed were predominantly hardwoods such as margosa (Azadirachta indica), mango (Mangifera indica), sal (Shorea robusta), teak (Tectona grandis) and mahogany (Toona ciliata). The four wood mills were chosen as a convenience sample based on their proximity to the laboratory at which the sputum the samples were analysed.

We carried out this study in Kalyani (population ∼450 000) in West Bengal, India. We identified four small wood working mills employing, in total, 79 workers. We attempted to recruit the entire workforce. The final study group included those who consented to participation, completed the study question, performed adequate spirometry and were able to produce an adequate sample of expectorated sputum for analysis.

Although airborne dust sampling was not carried out to quantify exposure levels, grossly, the work process was extremely dusty, generating visible piles of settled saw dust several feet high near the production lines. There were no specific dust suction collection systems in place at any of the sites and nothing beyond makeshift personal respiratory protection (e.g. mouth-covering scarves) was employed. The study was carried out over a 2–3-week period in the dry season. Lung function studies and sputum collections were carried out on site at each mill. Routine work operations continued during study times. The study was approved by the Departmental Research Committee of the Dept of Physiology, University of Kalyani, and we obtained signed informed consent from the participants before participation.

Respiratory questionnaire

We used an English–Bengali back-translated version of European Community Respiratory Health Survey (ECRHS-II) questionnaire to inquire about respiratory health, occupational exposure and lifestyle factors of the participants. Although the translated version of this questionnaire has not been validated by formal assessment, we have employed this questionnaire in our previous studies [24–26]. Subjective respiratory complaints in the previous 12 months included: 1) acute or chronic wheezing or whistling of the chest; 2) production of phlegm; 3) acute or chronic cough; 4) breathing trouble; 5) appearance of blood in sputum (haemoptysis); and 6) skin symptoms such as dryness, rash or irritation.

Lung function testing

We measured lung function using a computerised spirometer (Maestros Mediline Systems Limited, Mumbai, India) according to the American Thoracic Society (ATS)/European Respiratory Society (ERS) guidelines for spirometry [27]. We calibrated the spirometer prior each testing day with a 3-L fixed-volume calibration syringe. We calculated the predicted values of lung function variables using prediction equations for the Indian population [28]. The quality of each spirogram was evaluated for acceptability and repeatability in accordance with the ATS/ERS criteria [27]. To achieve accurate and replicable spirograms, each participant completed between three and eight spirometry manoeuvres. Spirometry was performed at a distance sufficiently removed from the mills to avoid any marked interference from workplace contaminants.

Assessment of sputum

We collected spontaneously expectorated sputum samples by asking each participant to expectorate into a sterile polypropylene tube (Tarsons Ltd, Kolkata, India). Sputum samples were processed using the method of Popov et al. [29] as modified and previously reported in detail elsewhere [30]. In brief, the sputum samples were poured into a Petri dish and all visible white cloudlets with no squamous cell contamination were carefully picked out and processed with freshly prepared 0.1% dithiothreitol (DTT) (Sisco Research Laboratories, Mumbai, India). The suspension was filtered through a 25-μm nylon filter, as described previously [30], to remove all squamous or epithelial cell contamination. Cell viability was assessed by trypan blue staining. Cytospin slides were prepared and Leishman stained according to the method of Saraiva-Romanholo et al. [31]. We performed differential cell counts of the sputum samples after achieving ≥80% intact nonsquamous cells, irrespective of the degree of cell viability or squamous cell contamination during viability determination.

Fungal characterisation

In order to characterise fungal contamination of the expectorated sputum, an aliquot of each crude sputum sample (without adding DTT) was placed in a clean polypropylene tube and mixed with PBS (pH 7.4). The ratio of PBS to sputum was kept at 1:1. A 100-µL aliquot of thoroughly mixed sputum sample was incubated in potato dextrose agar medium for 24 h at 37°C. All the fungal colonies on the agar plates were similar in morphology; one of the colonies was selected from the plate and grown in potato dextrose liquid broth under the same incubation conditions as noted above. We also collected saliva as a control from each of the workers to test for the presence of fungus in the oral cavity that might account for the sputum finding. We collected the saliva samples from the cheek, gum and sublingual areas using a sterile cotton swab (Himedia, Mumbai, India) prior to sputum expectoration. We directly examined sputum samples for the presence of fungus and cultured these samples using the same methods as for sputum.

To confirm whether the colonies represented homogenous species, we sequenced additional colonies from the agar plates randomly. For identification of the isolated culture, sequencing of the conserved genomic region was carried out using standard primer pair for the amplification (sequencing service was provided by Amnion Biosciences Pvt Ltd, Bengaluru, India). The amplicon used for the identification was 18S ribosomal RNA gene, partial sequence; internal transcribed spacer 1 and 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence. The 488-base pair amplicon sequence was then searched for the similarity in US National Center for Biotechnology Information (NCBI) nucleotide collection database using the Nucleotide Basic Local Alignment Search Tool (BLASTN) using standard search parameters [32]. A phylogenetic tree was constructed later using first 10 hits from NCBI BLASTN search results and the query sequence using Molecular Evolutionary Genetics Analysis version 4.1 [33]. The evolutionary history was inferred using the neighbour-joining method. The bootstrap consensus tree inferred from 500 replicates was taken to represent the evolutionary history of the taxa analysed. Branches corresponding to partitions reproduced in <50% bootstrap replicates were collapsed. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (500 replicates) is shown next to the branches. The tree was drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The evolutionary distances were computed using the Maximum Composite Likelihood method and are in the units of the number of base substitutions per site. All positions containing gaps and missing data were eliminated from the dataset (Complete Deletion option). There were a total of 365 positions in the final dataset.

Statistical analyses

Participants were dichotomised into those who had or did not have detectable fungus in their sputum. We used the Chi-squared or Fisher's exact test to compare categorical variables and the t-test or Wilcoxon rank sum test to compare continuous variables (the latter for body mass index and employment duration, which were not normally distributed). We used ANOVA to test the overall difference in the distributions of sputum leukocyte cell types in fungal positive versus fungal negative samples. We assessed colinearity among the sputum cell type percentages for the entire study group using Pearson correlations.

We used linear regression analysis to test the associations between selected independent variables (fungal status, and eosinophil and lymphocyte percentages) and forced midexpiratory flow (FEF_25–75%) % predicted as the dependent variable. All linear regression models also took into account the covariates age, smoking status (current versus former or never) and duration of employment. In addition to testing models in which only one of the independent predictors of interest was included along with the adjusting covariates, we also tested models including both fungal status and either eosinophil or lymphocyte percentage in the same model. We did so in order to assess the potential mediation of any fungal association with lung function by the presence of sputum eosinophils or lymphocytes. Because sputum eosinophil and lymphocyte percentages were strongly correlated with one another (r=0.72, p<0.01) and both inversely correlated with the percent of macrophages (r= −0.63 and r= −0.55, respectively; both p<0.01), we did not include any of these in multivariate models. Eosinophil and lymphocyte percentages, however, were only weakly negatively correlated with the percent neutrophils (r= −0.22 (p<0.05) and r= −0.24 (p<0.10), respectively), allowing us to test whether inclusion of that variable had a substantive impact on the mediation by eosinophils of the association of fungal contamination with lung function. All analyses were performed using SPSS version 20 (IBM Corp., Armonk, NY, USA).