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Epidemiologia e Serviços de Saúde

versão impressa ISSN 1679-4974versão On-line ISSN 2237-9622

Epidemiol. Serv. Saúde vol.29 no.3 Brasília jun. 2020  Epub 07-Jul-2020

http://dx.doi.org/10.5123/s1679-49742020000300022 

Original article

Prevalence and factors associated with respiratory diseases and diarrhea in recyclable material cooperative workers in the city of São Paulo, Brazil: a cross-sectional study, 2013*

Gisele Ferreira de Souza (orcid: 0000-0002-4734-6688)1  , Elizabeti Yuriko Muto (orcid: 0000-0003-1032-1118)2  , Felipe Parra Nascimento (orcid: 0000-0002-2184-2931)1  , Nelson Gouveia (orcid: 0000-0003-0625-0265)1 

1Universidade de São Paulo, Faculdade de Medicina, São Paulo, SP, Brazil

2Fundação Jorge Duprat Figueiredo de Segurança e Medicina do Trabalho, São Paulo, SP, Brazil.

Abstract

Objective

to analyze the prevalence of respiratory diseases and diarrhea among recyclable material cooperative workers in São Paulo City, Brazil, and associated factors.

Methods

this was a cross-sectional study conducted in three cooperatives, with data collected through structured interviews and measurement of environmental fungal concentration; Poisson regression was used to estimate prevalence ratios (PR).

Results

156 individuals were interviewed; the highest asthma, chronic obstructive pulmonary disease (COPD), and diarrhea prevalence rates occurred in cooperatives with higher total fungal concentration; highest adjusted prevalence of asthma was found in Cooperative A (PR=8.44 – 95%CI 1.09;65.37), and highest adjusted prevalence of diarrhea was found in Cooperative C (PR=2.09 – 95%CI 1.11;3.94), compared to Cooperative B; the highest COPD prevalence was found in smokers and former smokers (PR=8.66 – 95% CI 2.84;26.35).

Conclusion

fungal control measures must be adopted for disease prevention in recyclable material cooperatives.

Key words: Solid Waste Segregators; Occupational Health; Fungi; Respiratory Tract Diseases; Diarrhea; Cross-Sectional Studies

Introduction

In Brazil, 395,000 individuals are estimated to be working as solid waste sorters, garbage and recyclable material collectors, or street sweepers and related activities.1 Their daily activities include collecting, separating and compacting waste aluminum, plastic, glass, paper and cardboard which is then sold to the productive sector. This activity can result from individual initiatives or be organized in the form of recyclable material worker cooperatives. There are also people who collect recyclable materials in the street and sell it through cooperatives.2

Despite the importance of this work and the large number of people working as recyclable material operators, few studies in Brazil are dedicated to systematically identifying and quantifying the different types of agents implying health risks for those involved in this occupation. The process of collecting and separating solid waste is an occupational activity that results in risk to health, given the nature of the material and the precarious work environment and work process conditions.3

Brazilian recyclable material cooperatives have different levels of organization, availability of space, infrastructure and equipment, as well as a varied number of workers. In some places, electrical installations, lighting and ventilation are not adequate, with excessive humidity and presence of mice and cockroaches.3

Recyclable materials handled by workers are frequently contaminated with the remains of waste food, and this is propitious to the development of fungi and vectors. Under these conditions, certain symptoms and diseases are more likely to occur, as well as the possibility of worsening respiratory and dermatological problems. These workers are more prone to common illnesses such as influenza, bronchitis and ulcers.5 As such, as a result of daily handling of solid waste, exposure of these workers to bioaerosols – particles of microbial, vegetable or animal origin, also known as ‘organic dust’ – is considered to be an occupational health problem.6

In view of the growth in the number of people working with recyclable material and considering the social vulnerability and occupational risks to which they are subject, the objective of this study was to analyze prevalence of asthma, chronic obstructive pulmonary disease (COPD) and diarrhea among recyclable material cooperative workers in São Paulo City, and factors associated with the occurrence of these health conditions in their work environment and work processes.

Methods

This was a cross-sectional study conducted in three recyclable material sorting cooperatives in Greater São Paulo between August and December 2013.

Initially we visited 12 cooperatives indicated by the National Recyclable Material Workers’ Movement, in order to identify the work environment and work processes characteristics of this type of activity. The criteria used to select the cooperatives were: at least 30 employees; use of similar work processes and similar characteristics to the other cooperatives (collecting, sorting, compacting and baling); and closeness to the University of São Paulo Faculty of Medicine in order to make the field work feasible.

All the workers (adult men and women) at the three cooperatives selected took part voluntarily in the study.

The dependent variables were prevalence of asthma, COPD and diarrhea. The questionnaire included questions intended to screen for COPD and asthma. In the case of COPD, we adapted the Global Initiative for Chronic Obstructive Lung Disease questionnaire.7 In order to screen for asthma, we used the International Study of Asthma and Allergies in Childhood questionnaire, as validated by Maçãira et al.8 Occurrence of cases of diarrhea in the last six months was self-reported.

The independent variables were comprised of sociodemographic, behavioral and workplace information:

  1. age (categorized in years: 20-34; 35-50; 51-71);

  2. sex (male; female);

  3. race/skin color (white, black, brown, yellow or indigenous; the latter four categories were grouped together and described as ‘non-white’);

  4. schooling (in complete years of study: 0-8; 9 or more);

  5. tobacco smoking (non-smoker; smoker or former smoker);

  6. use of breathing protection mask (always; occasionally or never);

  7. use of gloves (always; occasionally or never);

  8. use of boots (always; occasionally or never);

  9. cooperatives (identified as A, B and C);

  10. fungus concentration (mean, expressed as colony-forming units per m3[CFU/m3] of each cooperative).

The data were collected using a structured questionnaire. Assessment of fungal microbiota present inside the cooperatives was performed in six different work environments: office, kitchen, conveyor belt, compactor, weighing scales and waste electrical and electronic equipment room. Double samples were planned for these places. The samples were collected in August, October and December 2013, at Cooperatives A, B and C, respectively.

Fungus sampling was performed using an air monitoring device (T-air Millipore), using the method based on quantifying sedimentation (per m3), using an air filter, of anemophilous fungus spores on Petri dishes containing Sabouraud dextrose agar, positioned at a height of 1.5 meters above floor level (approximate region of human breathing). When preparing the culture medium, the Sabouraud dextrose agar was dissolved in boiling water, to which chloramphenicol was added (100µg/mL); following this the mixture was placed in an autoclave at 121°C for 15 minutes. The potential for hydrogen (pH) was corrected to 5.6 and the mixture was distributed in Petri dishes, inside the device. Following exposure for 10 minutes at each of the established places, the culture dishes, fastened to the device, were closed with their own lids and sealed with Parafilm® to prevent any possible contamination. The dishes were later incubated at 25ºC for up to five days.

Analysis of the dishes was performed at the University of São Paulo Institute of Biomedical Sciences Microbiology Department. The isolated colonies were submitted to the microculture technique,9 using Sabouraud dextrose agar medium and potato dextrose agar medium. Identification of fungi10 and quantification of CFU/m3 were performed by analyzing slides of the microbiological material stained with lactophenol blue solution, using an optical microscope.

We obtained mean total fungi concentration (in CFU/m3) per collection place at each cooperative and also for the samples grouped together. Comparison of the composition of fungi genera between the cooperatives was done by grouping together the collection areas.

The data were organized on an Excel® spreadsheet. The categorical variables were compared using Pearson’s chi-square test with a 0.05 significance level. Poisson logistic regression with robust variance was used in order to identify possible factors associated with COPD, asthma and diarrhea prevalence ratios among the workers. Prevalence ratio (PR) and respective 95% confidence interval (95%CI) were calculated for each variable in univariate models. Following this, all the variables were included in a multivariate model and adjustment was analyzed as each variable was excluded, one by one, by means of the maximum likelihood ratio test. Considering that tobacco smoking is a confounding factor for respiratory diseases, this variable was included in the questionnaire and used in the analyses. All statistical analyses were performed using Stata 13.0®.

The study project was approved by the University of São Paulo Faculty of Medicine Research Project Ethics Analysis Committee: Process No. 169/13, dated May 8th 2013. All individuals who agreed to take part in the study were informed of its objectives before signing a Free and Informed Consent form.

Results

Of the 12 cooperatives visited, 9 had fewer than 30 cooperative members and a further 2 were very far from the researchers’ workplace. Three cooperatives were therefore selected, identified as A, B and C, which had 35, 58 and 63 workers, respectively, totaling 156 individuals. There were no refusals or losses.

Mean age of the workers was 44 ± 12.1 years, 28% of them were in the 20-34 age range, 35% in the 35-50 age range and 37% in the 51-71 age range. Women accounted for 60% of the interviewees, while smokers and former smokers accounted for 61% (Table 1).

Table 1 – Prevalence of asthma, chronic obstructive pulmonary disease (COPD) and diarrhea according to sociodemographic, behavioral and cooperative variables, São Paulo city, 2013 

Variable Total Asthma COPD Diarrhea

n % n % n % n %
Total 156 100 17 11 50 32 53 34

Age (years) (N=156)

20-34 44 28 5 11 10 23 14 32
35-50 54 35 6 11 24 44 20 37
51-71 58 37 6 10 16 28 19 11

Sex (N=156)

Male 62 40 4 6 17 27 18 29
Female 94 60 13 14 33 35 27 29

Race/skin color (N=154)

White 35 23 2 6 9 26 9 26
Non-white 119 77 15 13 40 33 36 30

Schooling (complete years) (N=155)

≤8 124 79 13 11 44 36 36 29
≥9 31 21 4 13 5 16 9 29

Tobacco smoking (N=156)

Non-smoker 61 39 4 7 3 5 19 31
Smoker or former smoker 95 61 13 14 47 50 26 28

Use of mask (N=153)

Always 4 3 1 25 1 25 2 50
Occasionally or never 149 97 15 10 48 32 41 28

Use of gloves (N=153)

Always 105 69 15 14 39 37 34 32
Occasionally or never 48 31 2 4 11 23 10 21

Use of boots (N=154)

Always 136 88 15 11 44 33 38 28
Occasionally or never 18 12 2 11 6 33 6 33

Cooperatives (N=156)

A 35 22 4 12 12 35 9 26
B 58 37 2 3 15 26 11 19
C 63 41 11 18 23 36 25 40

Mean time spent working as a garbage collector in the street and/or as a cooperative member was 4.4 ± 3.4 years, with no statistical difference between the cooperatives (p>0.05). Mean cigarette consumption per day was 16 ± 9 and the mean length of time that former smokers had stopped smoking was 110 months (data not shown). Out of the total number of individuals, 77% stated that they were of a race/color that was not white, and the majority had low schooling levels (79%) (Table 1).

Almost all the workers (97%) occasionally or never used breathing protection masks, 69% reported frequent use of gloves and 88% reported frequent use of boots. When screening for asthma and COPD, 11% and 32% of the individuals were identified as being positive, respectively; diarrhea prevalence was 34% (Table 1).

The greater part of the interviewees (41%) worked at Cooperative C, where prevalence of asthma (18%), COPD (36%) and diarrhea (40%) was also higher. COPD prevalence in the smoker and former smoker group was 50%, while in the 35-50 age group it was 44%. Prevalence of diarrhea among workers who always used a mask was also high (50%) (Table 1).

Mean fungi concentration per collection site varied between 116 CFU/m3 (office) to 751 CFU/m3 (conveyor belt), these two rates being found in Cooperative C (Table 2), with no significant difference between sample sites when the cooperatives were grouped together (p=0.506). When the sites were grouped together, Cooperative B (315 CFU/m3) was found to have a lower concentration than Cooperative A (531 CFU/m3) and Cooperative C (503 CFU/m3) (p=0.045).

Table 2 – Mean concentration, standard deviation (SD) and number of samples (n) of total fungi in colony-forming units (CFU/m3), in the different collection areas and different fungi genera, by cooperative (A, B, C), São Paulo city, 2013 

Variables A B C   Totala

Mean SD n Mean SD n Mean SD n p-value Mean SD n
Place

Weighing scales       280 35 2       280 35 2
Kitchen 363   1 356 11 2 288   1 341 36 4
Office 615 3 2       116   1 449 288 3
Conveyor belt 598   1 334 20 2 751 99 2 554 216 5
Compactor 457   1 289 135 2 680 158 2 479 222 5
Waste electrical and electronic equipment 540   1       378 98 2 432 116 3

Total 531 102 6 315 63 8 503 256 8 0.506 442 188 22

Fungi genera

Aspergillus spp. 137 24 6 63 30 8 120 60 8 0.009 104 51 22
Cladosporium spp. 237 80 6 51 18 8       <0.001 83 107 14
Fusarium spp. 76 43 6 70 23 8 124 103 8 0.247 91 69 22
Nigrospora spp.       30 16 8       11 17 8
Rhizopus spp.             130 95 8 47 85 8
Mucor spp.       2 2 6       1 1 6
Penicillium spp. 81 60 6 95 52 8 128 113 8 0.539 104 80 22
Non-sporogenous fungi       3 1 8       1 2 8

a) Total sample: comparison between places (p=0045).

The fungi genera identified were: Aspergillus spp., Cladosporium spp., Fusarium spp., Nigrospora spp., Rhizopus spp., Mucor spp. and Penicillium spp., as well as non-sporogenous fungi (Table 2). The genera with the highest mean concentrations in Cooperative A were Cladosporium spp. (237 CFU/m3) and Aspergillus spp. (137 CFU/m3). In Cooperative B, the highest concentrations corresponded to Penicillium spp. (95 CFU/m3) and Fusarium spp. (70 CFU/m3). In Cooperative C, mean concentrations between genera were similar, varying between 120 and 130 CFU/m3 for Aspergillus spp. and Rhizopus spp., respectively (Table 2).

The Aspergillus spp., Fusarium spp. and Penicillium spp. genera were identified in the three cooperatives analyzed. Among these genera, Aspergillus spp. had a higher concentration in Cooperative A, in comparison to the other cooperatives (p=0.009). The Fusarium spp. and Penicillium spp. genera showed no significant difference in the distribution of concentrations between the cooperatives (p=0.247 and p=0.539, respectively). Cladosporium spp. was only found in Cooperatives A and B, with higher concentrations in Cooperative A (p<0.001). Nigrospora spp., Mucor spp. and non-sporogenous fungi were only found in Cooperative B, with the latter two types having very low concentrations (≤3 CFU/m3).

In the univariate analysis, the ‘cooperative’ variable had statistically significant association with asthma and diarrhea prevalence ratios, and Cooperative C had higher prevalence ratios for both outcomes: asthma, PR=5.06 – 95%CI 1.17;22.0 (Table 3); and diarrhea, PR=2.09 – 95%CI 1.13;3.87 (Table 4). Smokers and former smokers had association with COPD (PR=10.17 – 95%CI 3.30;31.33) (Table 5). Age also had statistically significant association with COPD, although only in the intermediate age range of 35-50 years (PR=1.96 – 95%CI 1.05;3.65) (Table 5).

Table 3 – Crude and adjusted asthma prevalence ratio (PR) according to sociodemographic, behavioral and cooperative variables (n=156), São Paulo city, 2013 

Variables crudePR 95%CIa p-valueb adjustedPR 95%CIa p-valueb
Age (years)     0.990     0.706

20-34 1.00     1.00   0.706
35-50 0.98 0.32;3.02   0.77 0.21;2.91  
51-71 0.93 0.30;2.85   0.82 0.23;2.88  

Sex     0.159     0.104

Male 1.00     1.00    
Female 2.17 0.74;6.36   2.58 0.82;8.07  

Race/skin color     0.296     0.510

White 1.00     1.00    
Non-white 2.14 0.51;8.95   1.59 0.40;6.35  

Schooling (complete years)     0.710     0.515

≤8 1.00     1.00    
≥9 1.22 0.43;3.50   1.37 0.54;3.50  

Tobacco smoking     0.170     0.280

Non-smoker 1.00     1.00    
Smoker or former smoker 2.11 0.72;6.20   1.68 0.66;4.28  

Use of mask     0.317     0.857

Always 1.00     1.00    
Occasionally or never 0.41 0.07;2.38   0.83 0.10;6.65  

Use of gloves     0.099     0.032

Always 1.00     1.00    
Occasionally or never 0.3 0.71;1.26   0.18 0.04;0.86  

Use of boots     0.396     0.564

Always 1.00     1.00    
Occasionally or never 0.71 0.25;4.04   0.58 0.09;3.73  

Cooperatives     0.061     0.041

A 3.41 0.66;17.75   8.44 1.09;65.37  
B 1.00     1.00    
C 5.06 1.17;22.00   3.94 0.88;17.54  

a) 95%CI: 95% confidence interval.

b) Wald test.

Table 4 – Crude and adjusted diarrhea prevalence ratio (PR) according to sociodemographic, behavioral and cooperative variables (n=156), São Paulo city, 2013 

Variables crudePR 95%CIa p-valueb adjustedPR 95%CIa p-valueb
Age (years)     0.132     0.378

20-34 1.00     1.00    
35-50 1.16 0.67;2.03   1.35 0.69;2.62  
51-71 0.61 0.30;1.20   0.63 0.31;1.30  

Sex     0.112     0.988

Male 1.00     1.00    
Female 0.26 0.60;1.65   1.00 0.59;1.68  

Race/skin color     0.675     0.801

White 1.00     1.00    
Non-white 1.14 0.61;2.13   1.08 0.59;2.00  

Schooling (complete years)     0.979     0.859

≤8 1.00     1.00    
≥9 0.99 0.53;1.84   0.94 0.48;1.83  

Tobacco smoking     0.640     0.269

Non-smoker 1.00     1.00    
Smoker or former smoker 0.89 0.54;1.46   0.73 0.42;1.28  

Use of mask     0.255     0.229

Always 1.00     1.00    
Occasionally or never 0.55 0.20;1.53   0.58 0.23;1.42  

Use of gloves     0.182     0.306

Always 1.00     1.00    
Occasionally or never 0.66 0.35;1.22   0.69 0.34;1.41  

Use of boots     0.640     0.918

Always 1.00     1.00    
Occasionally or never 1.18 0.58;2.41   1.04 0.50;2.15  

Cooperatives     0.064     0.043

A 1.4 0.64;3.03   1.83 0.74;4.53  
B 1.00     1.00    
C 2.09 1.13;3.87   2.09 1.11;3.94  

a) 95%CI: 95% confidence interval.

b) Wald test.

Table 5 – Crude and adjusted chronic obstructive pulmonary disease (COPD) prevalence ratio (PR) according to sociodemographic, behavioral and cooperative variables (n=156), São Paulo city, 2013 

Variables crudePR 95%CIa p-valueb adjustedPR 95%CIa p-valueb
Age (years)     0.052     0.455

20-34 1.00     1.00    
35-50 1.96 1.05;3.65   1.36 0.77;2.40  
51-71 1.23 0.62;2.46   1.04 0.57;1.90  

Sex     0.303     0.092

Male 1.00     1.00    
Female 1.29 0.79;2.11   1.47 0.94;2.30  

Race/skin color     0.448     0.941

White 1.00     1.00    
Non-white 1.27 0.68;2.35   1.02 0.62;1.66  

Schooling (complete years)     0.063     0.248

≤8 1.00     1.00    
≥9 0.45 0.19;1.04   0.63 0.29;1.38  

Tobacco smoking     <0.001     <0.001

Non-smoker 1.00     1.00    
Smoker or former smoker 10.17 3.30;31.33   8.66 2.84;26.35  

Use of mask     0.767     0.561

Always 1.00     1.00    
Occasionally or never 1.3 0.23;7.24   1.62 0.32;8.33  

Use of gloves     0.116     0.229

Always 1.00     1.00    
Occasionally or never 0.63 0.35;1.12   0.65 0.32;1.32  

Use of boots     0.950     0.795

Always 1.00     1.00    
Occasionally or never 1.02 0.51;2.06   0.91 0.46;1.80  

Cooperatives     0.439     0.516

A 1.36 0.72;2.57   1.36 0.65;2.85  
B 1.00     1.00    
C 1.41 0.82;2.44   1.12 0.71;1.78  

a) 95%CI: 95% confidence interval.

b) Wald test.

The multivariate models had a better fit when all the variables studied were kept in them. In these models, higher adjusted prevalence of asthma was found in Cooperative A (PR=8.44 – 95%CI 1.09;65.37) (Table 3) and higher adjusted prevalence of diarrhea was found in Cooperative C (PR=2.09 – 95%CI 1.11;3.94) (Table 4), in relation to Cooperative B, which had lower fungi concentration. Use of gloves ‘occasionally or never’ was also found to be associated with lower prevalence of asthma (PR=0.18 – 95%CI 0.04;0.86) (Table 3). Finally, adjusted COPD prevalence was higher among smokers and former smokers (PR=8.66 – 95%CI 2.84;26.35), when compared to its prevalence among non-smokers (Table 5).

Discussion

Among recyclable material workers, this study identified a predominance of individuals aged 35 or over, females, people with low schooling levels and low use of masks as personal protective equipment (PPE), although reported frequent use of gloves and boots was high. Fungi concentration in the cooperatives varied according to workplace. Among the fungi genera identified, Aspergillus spp., Fusarium spp. and Penicillium spp. were found in all the cooperatives analyzed. Following multivariate analysis, the asthma and diarrhea prevalence ratios were higher in cooperatives that also had higher total fungi concentrations. The COPD prevalence ratio was higher among smokers and former smokers.

With regard to limitations in the development of the study, it is possible that there may have been difficulty in understanding the questions contained in the questionnaire, given the respondents’ low level of schooling. Other points worthy of note are (i) the small number of fungi samples collected in the ambient air in the cooperatives and (ii) absence of external reference groups for making comparisons. A further limitation to be considered was non-standardized diagnosis of diarrhea, which may have affected self-reported prevalence of this symptom, above all in a socially vulnerable population like this one. It was also not possible to add more precise data about tobacco smoking to the analyses, capable of providing greater robustness to the findings in relation to COPD and tobacco smoking. Finally, the small sample size (156 workers) led to estimates being imprecise, given the amplitude of the confidence intervals.

Currently no occupational exposure limits have been established for fungi and bacteria in this type of work environment, probably because the effects of microorganisms on health differ greatly between species.11 Some studies, conducted in similar environments, report relationship between exposure and development of adverse effects on health in concentrations ranging between 103 and 109 UFC/m3 for total fungi,12 although the concentrations found in our study were below these levels.

Some studies conducted in waste sorting centers point to high amplitude of fungi concentration in the air (between 650UFC/m3and 9x105 UFC/m3), varying according to the sample site, the method used and the way in which the samples were processed.(14)-(16) These values are above the mean values found in the cooperatives we studied, and the low values we found could be related to the small number of samples collected, the method used or the smaller quantity of waste handled. Values slightly above 650UFC/m3were only found in the conveyor belt and compactor areas of Cooperative C, where handling of waste is greater.

The wide variety of fungi identified in the cooperatives has also been detected in other studies of waste sorting environments.14 The results found by our study are in keeping with the studies cited, when they report dominance of the Penicillium spp. and Aspergillus spp. genera, described as producers of mycotoxins that are a potential risk to health.18 Exposure to the most prevalent fungi genera in this study can increase predisposition to allergic reactions and respiratory diseases such as asthma, for instance.19 However, no information exists as to the minimum concentration of these fungi capable of causing health problems.

A study conducted with garbage collectors demonstrated an exposure-response relation between high fungi concentration and a higher number of reports of diarrhea, with prevalence of 5.60 (95%CI 2,39;13,08).21 That data corroborates the results of this study with regard to high prevalence of diarrhea cases in cooperatives with higher fungi concentrations (Cooperative C). The hygiene conditions found in these environments – high levels of mould, heat and excess humidity – are conducive to proliferation of fungi.

Asthma is considered to be the most prevalent occupational lung disease in industrialized countries, accounting for between 26% and 52% of occupational respiratory diseases, whereby this variation is associated with type of occupation and the country studied.22 In a study conducted in Brazil in 2013, prevalence of medical diagnosis of asthma in individuals aged over 18 was 5% in the state of São Paulo, this being higher than the national average (4.4%), as well as being higher among women.23 In Latin American countries, there is evidence of a greater number of asthma cases among poor populations living in urban areas.24 These characteristics are in line with those of the group we investigated and reinforce the findings of our study. It is also important to note that diverse variables are involved in the etiology of this disease, such as environmental issues (e.g. pollution) and lifestyle (e.g. tobacco smoking).24

Prevalence of respiratory symptoms compatible with those of asthma and COPD is higher among garbage collectors when compared to office workers in garbage recycling facilities.26 Furthermore, greater asthma prevalence was found in the cooperative that had higher fungi concentration; however, we had no samples of reference groups outside the cooperatives that could have enabled comparisons. It is possible that individual exposure to fungi may have been based on fungi concentrations in the places where each individual worked. However, this approach may be subject to exposure classification bias, depending on the job activity performed, given that garbage collectors circulate in the cooperative environment and some workers carry out their duties in more than one workplace.

Tobacco smoking is the main COPD risk factor. However, even among smokers, around 15% to 20% of cases have been attributed to occupational exposure, including exposure to bioaerosols.27 In São Paulo City, COPD case prevalence varies between 6% and 16% of the population aged 40 or over, whereby cigarette use is the most commonly associated risk factor.28 In addition, risk of developing this disease has been related, above all, to individuals from lower socio-economic classes.29 Indeed, COPD prevalence among the cooperative workers was higher among smokers and former smokers, and was much higher than the rate found in the general population. No direct relationship was found between COPD and concentration of fungi in the environment, and this high prevalence may be related to the conditions of vulnerability in which these workers live, and which is reflected in their health in general.3

Frequency of PPE use (masks, gloves and boots) did not affect the prevalence of the diseases we screened for. Notwithstanding, use of breathing protection masks was found to be low;30 furthermore, the breathing protection masks available in the cooperatives we assessed are not specific for biological agents and the periodicity with which this equipment is changed may not be sufficient to protect workers, making them susceptible to exposure to bioaerosols, increased respiratory symptoms similar to those of influenza and greater risk of COPD.27 Although the results of this study showed that occasional use or non-use of gloves by workers may be related to lower prevalence of asthma, this fact may be due to chance, since there are no biological mechanisms to justify the occurrence of this. Moreover, if their hands were not sanitized correctly when putting on or taking off gloves, or if contaminated gloves were not sanitized, their use may not be an efficient protection factor.

Notwithstanding the limitations of this study, the results presented suggest that the work environment can expose these workers to fungi concentrations that are potentially harmful to their health. Such exposure, associated with low use of personal protective equipment and/or incorrect use and care thereof, precarious working conditions and high vulnerability of this population, can potentialize adverse effects on their health. Considering the growth of this occupational category, we recommend that initiatives be implemented to reduce exposure to agents having the potential to cause risk to the health of recyclable material workers.

REFERENCES

1. Centro de Estudos da Metrópole (CEM). Censo 2010: bases de dados do projeto Censo [Internet]. São Paulo: CEM/USP; 2016 [citado 2020 maio 25]. Disponível em: http://centrodametropole.fflch.usp.br/pt-brLinks ]

2. Besen GR, Fracalanza AP. Challenges for the sustainable management of municipal solid waste in Brazil. DisP - Planning Review [Internet]. 2016 Jun [cited 2020 May 25];52(2):45-52. Available from: https://doi.org/10.1080/02513625.2016.1195583Links ]

3. Gutberlet J, Baeder AM, Pontuschka NN, Felipone SMN, Santos TLF. Participatory research revealing the work and occupational health hazards of cooperative recyclers in Brazil. Int J Environ Res Public Health [Internet]. 2013 Oct [cited 2020 May 25];10(10):4607-27. Available from: https://dx.doi.org/10.3390%2Fijerph10104607Links ]

4. Elizabeti Yuriko Muto, Maria Gricia de Lourdes Grossi (orgs.). Seminário saúde, segurança e geração de renda nas centrais de triagem de materiais recicláveis [Internet]; 2014 maio 13-14; São Paulo, Brasil. São Paulo: Fundacentro; 2019 [citado 2020 mar]. Disponível em: http://www.fundacentro.gov.br/biblioteca/biblioteca-digital/download/Publicacao/280/Seminario_catadores-_altera%C3%A7%C3%A3o_26-03-2019-pdfLinks ]

5. Yang H, Ma M, Thompson JR, Flower RJ. Waste management, informal recycling, environmental pollution and public health. J Epidemiol Community Health [Internet]. 2018 Mar [cited 2020 May 25];72(3):237-43. Available from: https://doi.org/10.1136/jech-2016-208597Links ]

6. Binion E, Gutberlet J. The effects of handling solid waste on the wellbeing of informal and organized recyclers: a review of the literature. Int J Occup Environ Health [Internet]. 2012 Jan-Mar [cited 2020 May 25];18(1):43-52. Available from: https://doi.org/10.1179/1077352512z.0000000001Links ]

7. Global Initiative for Chronic Obstructive Lung Disease - GOLD. Diagnosis and assessment of COPD [Internet]. Fontana: Global Initiative for Chronic Obstructive Lung Disease; 2020 [cited 2020 May 25]. Available from: https://goldcopd.org/Links ]

8. Maçãira EF, Algranti E, Stelmach R, Ribeiro M, Nunes MPT, Mendonça EMC, et al. Determinação de escore e nota de corte do módulo de asma do International Study of Asthma and Allergies in Childhood para discriminação de adultos asmáticos em estudos epidemiológicos. J Bras Pneumol [Internet]. 2005 dez [citado 2020 maio 25];6(31):477-85. Disponível em: http://dx.doi.org/10.1590/S1806-37132005000600004Links ]

9. Riddell RW. Permanent stained mycological preparation obtained by slide culture. Mycologia [Internet]. 1950 Mar-Apr [cited 2020 May 25];42(2):265-70. Available from: https://doi.org/10.2307/3755439Links ]

10. Pitt JI, Hocking AD. Fungi and food spoilage. 2nd ed. London: Blackie Academic and Professional; 1997. [ Links ]

11. Walser SM, Gerstner DG, Brenner B, Bunger J, Eikmann T, Janssen B, et al. Evaluation of exposure-response relationships for health effects of microbial bioaerosols - a systematic review. Int J Hyg Environ Health [Internet]. 2015 Oct [cited 2020 May 25];218(7),577-89. Available from: https://doi.org/10.1016/j.ijheh.2015.07.004Links ]

12. Kuijer P, Sluiter JK, Frings-Dresen MHW. Health and safety in waste collection: towards evidence-based worker health surveillance. Am J Ind Med [Internet]. 2010 Oct [cited 2020 May 25];53(10):1040-64. Available from: https://doi.org/10.1002/ajim.20870Links ]

13. Searl A, Crawford J. Review of health risks for workers in the waste and recycling industry. Edinburgh (UK): Inst Occup Med; 2012 [cited 2020 May 25]. 149 p. Available from: https://www.bohrf.org.uk/downloads/Review_of_Health_Risks_for_workers_in_the_Waste_and_Recycling_Industry.pdfLinks ]

14. Würtz H, Breum NO. Exposure to microorganisms during manual sorting of recyclable paper of different quality. Ann Agric Environ Med [Internet]. 1997 [cited 2020 May 25];4(1):129-35. Available from: http://www.aaem.pl/Exposure-to-microorganisms-during-manual-sorting-of-recyclable-paper-of-different,90616,0,2.htmlLinks ]

15. Lehtinen J, Tolvanen O, Nivukoski U, Veijanen A, Hanninen K. Occupational hygiene in terms of volatile organic compounds (VOCs) and bioaerosol at two solid waste management plants in Finland. Waste Manag [Internet]. 2013 Apr [cited 2020 May 25];33(4):964-73. Available from: https://doi.org/10.1016/j.wasman.2012.11.010Links ]

16. Černá K, Wittlingerová Z, Zimová M, Janovský Z. Exposure to airborne fungi during sorting of recyclable plastics in waste treatment facilities. Med Pr [Internet]. 2017 Feb [cited 2020 May 25];68(1):1-9. Available from: https://doi.org/10.13075/mp.5893.00520Links ]

17. Madsen AM, Alwan T, Ørberg A, Uhrbrand K, Jørgensen MB. Waste workers’ exposure to airbone fungal and bacterial species in the truck cab and during waste collection. Ann Occup Hyg [Internet]. 2016 Jul [cited 2020 May 25];60(6):651-68. Available from: https://doi.org/10.1093/annhyg/mew021Links ]

18. Pitt JI. The current role of Aspergillus and Penicillium in human and animal health. J Med Vet Mycol [Internet]. 1994 [cited 2020 May 25];32(Suppl 1):17-32. Available from: https://pubmed.ncbi.nlm.nih.gov/7722784/Links ]

19. Fischer G, Dott W. Relevance of airborne fungi and their secondary metabolites for environmental, occupational and indoor hygiene. Arch Microbiol [Internet]. 2003 Feb [cited 2020 May 25];179:75-82. Available from: https://doi.org/10.1007/s00203-002-0495-2Links ]

20. Knutsen AP, Bush RK, Demain JG, Denning DW, Dixit A, Fairs A, et al. Fungi and allergic lower respiratory tract diseases. J Allergy Clin Immunol [Internet]. 2012 Feb [cited 2020 May 25];129(2):280-91. Available from: https://doi.org/10.1016/j.jaci.2011.12.970Links ]

21. Ivens UI, Breum NO, Ebbehoj N, Nielsen BH, Poulsen OM, Wurtz H. Exposure-response relationship between gastrointestinal problems among waste collectors and bioaerosol exposure. Scand J Work Environ Health [Internet]. 1999 Jun [cited 2020 May 25];25(3):238-45. Available from: https://doi.org/10.5271/sjweh.430Links ]

22. Galvão CES. Asma e rinite ocupacionais – visão imunoalérgica. Rev Bras Alerg Imunopatol [Internet]. 2010 [citado 2020 maio 25];33(1):1-7. Disponível em: http://www.sbai.org.br/revistas/Vol331/ART%201-10%20-%20Asma%20e%20rinite%20ocupacionais.pdfLinks ]

23. Menezes AMB, Wehrmeister FC, Horta B, Szwarcwald CL, Vieira ML, Malta DC. Prevalência de diagnóstico médico de asma em adultos brasileiros: Pesquisa Nacional de Saúde, 2013. Rev Bras Epidemiol [Internet]. 2015 dez [citado 2020 maio 25];18(suppl 2):204-13. Disponível em: http://dx.doi.org/10.1590/1980-5497201500060018Links ]

24. Cooper PJ, Rodrigues LC, Cruz AA, Barreto ML. Asthma in Latin America: a public heath challenge and research opportunity. Allergy [Internet]. 2009 Jan [cited 2020 May 25];64(1):5-17. Available from: https://doi.org/10.1111/j.1398-9995.2008.01902.xLinks ]

25. Dias-Júnior SA, Pinto RC, Angelini L, Fernandes FLA, Cukier A, Stelmach R. Prevalência de tabagismo ativo e passivo em uma população de asmáticos. J Bras Pneumol [Internet]. 2009 mar [citado 2020 maio 25];35(3):261-5. Disponível em: http://dx.doi.org/10.1590/S1806-37132009000300011Links ]

26. Athanasiou M, Makrynos G, Dounias G. Respiratory health of municipal solid waste workers. Occup Med [Internet]. 2010 Dec [cited 2020 May 25];60(8):618–23. Available from: https://doi.org/10.1093/occmed/kqq127Links ]

27. Matheson MC, Benke G, Raven J, Sim MR, Kromhout H, Vermeulen R, et al. Biological dust exposure in the workplace is a risk factor for chronic obstructive pulmonary disease. Thorax [Internet]. 2005 Aug [cited 2020 May 25];60(8):645-51. Available from: https://dx.doi.org/10.1136%2Fthx.2004.035170Links ]

28. Menezes AM, Perez-Padilla R, Jardim JR, Muino A, Lopez MV, Valdivia G, et al. Chronic obstructive pulmonary disease in five Latin American cities (the Platino study): a prevalence study. Lancet [Internet]. 2005 Nov [cited 2020 May 25];366(9500):1875-81. Available from: https://doi.org/10.1016/s0140-6736(05)67632-5 [ Links ]

29. Bagatin E, Jardim JRB, Stirbulov R. Doença pulmonar obstrutiva crônica ocupacional. J Bras Pneumol [Internet]. 2006 maio [citado 2020 maio 25];32(2):S35-40. Disponível em: https://doi.org/10.1590/S1806-37132006000800007Links ]

30. Torloni, M. Programa de proteção respiratória: recomendações, seleção e uso de respiradores [Internet]. Torloni M, Vieira AV, Aquino JD, Nicolai SHA, Algranti E (orgs.). 4. ed. São Paulo: Fundacentro; 2016 [citado 2020 maio 25]. 207 p. Disponível em: ftp://ftp.medicina.ufmg.br/osat/ebook/2016/1-ProgramadeProtecaoRespiratoria-12-08-2016.pdfLinks ]

*Article derived from the Ph.D. thesis entitled ‘Environmental assessment in recyclable material cooperatives’, defended by Gisele Ferreira de Souza at the University of São Paulo Faculty of Medicine (FM/USP) Preventive Medicine Postgraduate Program on March 12 2015. The research received financial support from the ‘SUS Research’ program, run by the Ministry of Health / Science, Technology and Strategic Supplies Secretariat / Department of Science and Technology (Decit/SCTIE/MS). The initiative was intermediated by the National Council for Scientific and Technological Development/Ministry of Science, Technology, Innovation and Communication (CNPq/MCTIC) and received support from the São Paulo State Research Support Fund (FAPESP) and from the São Paulo State Health Department (SES/SP) (Process No. 2014/50005-1). Gisele Ferreira de Souza received a Ph.D. scholarship from the Coordination for the Improvement of Higher Education Personnel (CAPES) / Ministry of Education (MEC): Funding Code 001.

Received: February 20, 2020; Accepted: May 11, 2020

CORRESPONDENCE: Gisele Ferreira de Souza – Universidade de São Paulo, Faculdade de Medicina, Departamento de Medicina Preventiva, Av. Dr. Arnaldo, no. 455, São Paulo, SP, Brazil. Postcode: 01246-903 . E-mail: giselefsouza@usp.br

Conflicts of interest: Souza GF is owner of the @semfungos company, which analyzes environmental fungi, viruses and bacteria. The remaining authors have no conflicts of interest.

Associate Editor: Taís Freire Galvão – orcid.org/0000-0003-2072-4834

Authors’ contributions

Souza GF and Gouveia N designed the study and coordinated data collection and processing. Souza GF assisted with processing air samples and analyzing the material collected. Souza GF, Muto EY, Nascimento FP and Gouveia N contributed to analysis, interpretation and discussion of the results, as well as contributing to drafting the manuscript. All the authors have approved the final version and are responsible for all aspects thereof, including the guarantee of its accuracy and integrity.

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