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HOME > J Prev Med Public Health > Volume 51(4); 2018 > Article
Original Article
Urinary Mercury Levels Among Workers in E-waste Shops in Nakhon Si Thammarat Province, Thailand
Somsiri Decharatorcid
Journal of Preventive Medicine and Public Health 2018;51(4):196-204.
DOI: https://doi.org/10.3961/jpmph.18.049
Published online: June 19, 2018
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Department of Occupational Health and Safety, Faculty of Health and Sports Science, Thaksin University, Phatthalung, Thailand

Corresponding author: Somsiri Decharat, PhD Department of Occupational Health and Safety, Faculty of Health and Sports Science, Thaksin University, 222 Moo 2 Papayom District, Phatthalung 93210, Thailand E-mail: somsiri_9@hotmail.com
• Received: February 21, 2018   • Accepted: June 8, 2018

Copyright © 2018 The Korean Society for Preventive Medicine

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

  • Objectives
    To determine urinary mercury levels in e-waste workers in Southern Thailand and the airborne mercury levels in the e-waste shops where they worked, to describe the associations between urinary and airborne mercury levels, and to evaluate the prevalence of mercury exposure-related health effects among e-waste workers.
  • Methods
    A cross-sectional study was conducted by interviewing 79 workers in 25 e-waste shops who lived in Nakhon Si Thammarat Province, Thailand. Information on general and occupational characteristics, personal protective equipment use, and personal hygiene was collected by questionnaire. Urine samples were collected to determine mercury levels using a cold-vapor atomic absorption spectrometer mercury analyzer.
  • Results
    The e-waste workers’ urinary mercury levels were 11.60±5.23 μg/g creatinine (range, 2.00 to 26.00 μg/g creatinine) and the mean airborne mercury levels were 17.00±0.50 μg/m3 (range, 3.00 to 29.00 μg/m3). The urinary and airborne mercury levels were significantly correlated (r=0.552, p<0.001). The prevalence of self-reported symptoms was 46.8% for insomnia, 36.7% for muscle atrophy, 24.1% for weakness, and 20.3% for headaches.
  • Conclusions
    Personal hygiene was found to be an important protective factor, and should therefore be stressed in educational programs. Employers should implement engineering measures to reduce urinary mercury levels and the prevalence of associated health symptoms among e-waste workers.
Electronic waste, or e-waste, can be defined as discarded computers, electronic office equipment, electronic entertainment devices, mobile phones, television sets, and refrigerators [1]. An estimated 50 million tons of e-waste are produced each year [2]. In the US, 30 million computers are discarded each year, and 100 million phones are disposed of in Europe annually. The Environmental Protection Agency has estimated that only 15-20% of e-waste is recycled, while the rest of these electronics go directly into landfills and incinerators [3]. Thailand is a developing country that faces e-waste problems due to a lack of appropriate technologies, facilities, and resources, as well as gaps in e-waste regulations causing the illegal importation of e-waste for dismantling and recycling purposes [4-8]. Substances found in e-waste include epoxy resins, fiberglass, polychlorinated biphenyls, polyvinyl chlorides, thermosetting plastics, lead, tin, copper, silicon, beryllium, carbon, iron, aluminum, cadmium, mercury, and thallium [8]. Mercury can be found in fluorescent tubes (numerous applications), tilt switches (mechanical doorbells, thermostats) [3], and flat-screen monitors. Toxic substances in e-waste can be released into the environment, ending up in bodies of water, groundwater, soil, and air. This can impact the health of land and sea animals, including humans [9-12]. Mercury exposure can lead to several adverse health effects, including sensory impairment, dermatitis, memory loss, and muscle weakness. Exposure in utero causes fetal deficits in motor function, attention, and verbal domains [13].
For the purposes of this study, an e-waste shop was defined as a facility that engages in the refurbishment, dismantling, or recycling of e-waste. The objectives of this study were to determine urinary mercury levels in e-waste workers and the airborne mercury levels in the e-waste shops where they worked, to assess associations between urinary and airborne mercury levels, and to evaluate the prevalence of mercury exposure-related health effects among e-waste workers.
In this cross-sectional study, urinary mercury samples were collected from 79 e-waste workers who worked in 25 e-waste shops in Nakhon Si Thammarat Province, southern Thailand, from May to August 2016. This research was approved by the ethics committee of the Institute of Research and Development, Thaksin University (no. E001/2557).
Study Population
This study enrolled workers at e-waste shops with records of high levels of exposures; in total, 79 e-waste workers (25 office workers refer to the workers who worked in office area that low levels of exposure; and 54 worker in e-waste processes refer to the workers who worked in e-waste processes area that high levels exposure) were recruited from 25 e-waste shops in Nakhon Si Thammarat Province in southern Thailand. The inclusion criteria for the exposed group were: e-waste workers, aged 18-57 years, in occupational contact with e-waste, who had maintained that occupational contact for at least 1 year. Participants who agreed to take part in the study provided written informed consent. Of the 79 exposed subjects recruited, 47 were male and 32 were female.
Questionnaires and Urine Sample Collection
General information on the e-waste workers was collected by face-to-face interviews using a survey form, by a walk-through survey, and through on-site observations. The 79 ewaste workers were interviewed using a questionnaire. Detailed information was collected, including general and occupational characteristics, personal protective equipment (PPE) use, and personal hygiene. At the end of each shift, the subjects were interviewed about their general characteristics, including work-related factors. Spot urine samples (30 mL) were collected from the first urination in the morning, then kept in polypropylene sample vessels and stored at -20°C for analysis.
Airborne Mercury Collection
The dosimeter and hopcalite sampling devices were exposed side-by-side following step-by-step experimental procedures that have been previously described [14]. All samples were collected in the e-waste workers’ breathing zone according to the Occupational Safety and Health Administration analytical method. Each personal sampling pump was calibrated with a representative sampler, and the end of the sampler was broken off immediately prior to sampling. Samplers were attached to pumps with flexible tubing and air was collected at a rate of 0.15 to 0.25 L/min. Samplers were capped and packed securely for shipment. Hopcalite sorbent and the front glass wool plug from each sampler were placed in separate 50 mL volumetric flasks, and 2.5 mL of concentrated nitric acid followed by 2.5 mL of concentrated hydrogen chloride was added. The hopcalite sorbent was dissolved, diluted to 50 mL with deionized water, and the mercury concentration was then determined with cold-vapor atomic absorption spectroscopy.
Laboratory Analysis

Measurement of urinary creatinine levels

Creatinine levels in urine were determined using the Jaffe’s reaction, in which creatinine produces an orange color after reaction with picric acid in alkaline medium [15]. After allowing an incubation time of 15 minutes at room temperature for color development, optical absorbance was measured at 520 nm.

Measurement of urinary mercury levels

The method of measuring urinary mercury levels was modified from that of Ham [16]. A CETAC M6000A cold-vapor atomic absorption spectrometer (CETAC, Omaha, NE, USA) was used to measure urinary mercury levels. The instrumental parameters were a slit width of 0.5 μm, wavelength of 253.7 nm, photo multiplier tube of 4 mA, no background correction, and a delay time before reading of 55 or 70 seconds.

Validation of urinary mercury analyses

Field water blank samples (10% of urine specimens) were frozen and shipped on dry ice as quality control for all analyses. These field blanks were analyzed for mercury using the same method. A series of standard additions containing 0, 10, 20, and 40 mg/dL were prepared. The correlation coefficient (r) between the mercury concentration in the authentic mercury solution and absorption was 0.9995. The overall limit of detection was 5 mg/g creatinine. External quality control (Lyphochek While Blood Metals Control; Bio-Rad, Hercules, CA, USA) and a 5 mg/L calibration range standard check were performed at the start and end of the analysis, and after every 10 samples. The accuracy of the overall method ranged from 96.8 and 98.8%, and the calculated precision was within an 8.0% relative standard deviation. The detection limit for mercury was 0.15 μg/L. The urinary mercury analysis required 0.2 mL of urine.
Statistical Analysis
Descriptive statistics were used to present the results of the urinary mercury tests. The means of normally distributed data groups were compared using the Student t-test. The Pearson test was used to investigate the association between airborne mercury levels and urinary mercury levels. Statistical significance was defined as p<0.05 and statistical analyses were performed using SPSS version 17 (SPSS Inc., Chicago, IL, USA).
Demographic Characteristics of the Subjects
The subjects of this study consisted of 79 e-waste workers in e-waste shops in Nakhon Si Thammarat Province, southern Thailand. The age range of the e-waste workers was 18-57 years (mean, 34.27 years). All workers were Buddhist. The majority had a secondary-school education or lower (67.1%), and nearly half were married (48.1%). The subjects consisted of 27 smokers (34.2%) and 52 non-smokers (65.8%), while 53.2% reported that they consumed alcohol. In this study, 59.5% of subjects consumed fish and seafood ≤3 times/mo, while 40.5% consumed fish and seafood >3 times/mo.
Of all subjects, 57.0% worked more than 8 hours per day and 81.0% had a work duration of more than 6 years. Most subjects (73.4%) did not used cotton masks and 51.9% did not used gloves when contacting e-waste. Only 25.3% of them washed their hands before lunch, while 74.7% did not do so.
The average urinary mercury levels of the e-waste workers were significantly different from those of 25 office workers refer to the workers who worked in office area that low levels of exposure; and 54 worker in e-waste processes refer to the workers who worked in e-waste processes area that high levels exposure that shown in study population (p<0.001). It was found that mean urinary mercury levels were significantly affected by characteristics such as smoking cigarettes, hours worked per day, duration of work, not using PPE, and not washing one’s hands before lunch (p<0.001) (Table 1).
Non-smoking workers’ urinary mercury concentrations were significantly lower (β=-0.004, p<0.001) than those of their smoking counterparts. Those who consumed fish ≤3 times/mo had significantly lower urinary mercury concentrations than those who consumed fish >3 times/mo (β=0.024, p=0.016). Age and gender were not significant risk factors for urinary mercury concentrations (β=-0.008, p=0.875; β=-0.004, p=0.987, respectively). Smoking status appeared to be a confounder for age. Urinary mercury concentrations were positively correlated with the amount of fish consumed per month. Among the non-smokers, the office workers had lower urinary mercury concentrations than those who worked directly in ewaste processing (p<0.001).
In the multivariate regression analysis, smoking cigarettes, hours worked per day, duration of work (years), not using a cotton mask, not washing one’s hands before lunch, and fish consumption were significant predictors of urinary mercury concentrations (Table 2).
Correlation Between Air Mercury Levels and Urinary Mercury Levels
The mean airborne mercury level was 17.00±0.50 μg/m3 (range, 3.00 to 29.00 μg/m3). The occupational exposure standard for mercury in the workplace atmosphere is 50 μg/m3 for 8 hr/d and 40 hr/wk, using time-weight averages [17]; none of the air samples exceeded this level. However, the mean airborne mercury levels were significantly lower in the office areas (10.82±0.34 μg/m3; range, 3.00 to 15.00 μg/m3) than in the working areas (25.24±0.21 μg/m3; range, 15.00 to 29.00 μg/m3). The mean urinary mercury concentration was 11.60±5.23 μg/g creatinine (range, 2.00 to 26.00 μg/g creatinine). In this study, the workers who worked in office areas (9.84±1.02 μg/g creatinine; range, 3.00 to 15.30 μg/g creatinine) had significantly lower urinary mercury concentrations than those who did not (19.26±3.02 μg/g creatinine; range, 15.00 to 29.00 μg/g creatinine). A significant correlation was found between the sampled airborne mercury levels and urinary mercury levels (r=0.552, p<0.001) (Figure 1).

Prevalence of health symptoms among the subjects

The prevalence of self-reported symptoms in the past 3 months is shown in Table 3. The most common symptom was insomnia (46.8%), followed by muscle atrophy (36.7%), weakness (24.1%), and headaches (20.3%).
The relationships between position worked, gender, age, educational level, smoking, alcohol consumption, hours worked per day, duration of work, use of PPE, and personal hygiene (as independent variables) with the symptom rates for 4 selected symptoms (insomnia, muscle atrophy, weakness, and headaches) are shown in Table 4.
The prevalence of insomnia was statistically significantly higher among subjects who worked in e-waste processing than among subjects who worked in an office environment (p<0.001). The education, gender, age, smoking, alcohol consumption, duration of work, mask use, and glove use were all significantly associated with increased insomnia at the level of p<0.001.
The prevalence of muscle atrophy was statistically significantly higher among workers who worked in e-waste processing than among office workers (p<0.001). The following variables (gender, age, education, hours worked per day, mask use, glove use, and washing one’s hands before lunch) were also significantly associated with increased muscle atrophy at the level of p<0.001.
The prevalence of weakness was statistically significantly higher among workers who worked in e-waste processing than among subjects who worked in the office (p<0.001). In addition, gender, age, education, and hours worked per day were significantly associated with weakness at the level of p<0.001.
In addition, the prevalence of headaches was statistically significantly higher among workers who worked in e-waste processing than among office workers (p<0.001). The following variables (education, hours worked per day, duration of work, mask use, and washing one’s hands before lunch) were also significantly associated with headaches at the p<0.001 level.
Urinary mercury levels are commonly used as diagnostic measures and indicators of mercury exposure in humans [18]. The urinary mercury levels of the subject workers were all below the 35 μg/g creatinine biological exposure index recommended by the American Conference of Governmental Industrial Hygienists (ACGIH) [18]. Overall, 16.5% of the airborne mercury samples (13 of 79) exceeded the 25 μg/m3 threshold recommended by the ACGIH [18]. However, all samples were below the 50 μg/m3 time-weight average exposure index recommended by the Department of Labor Protection and Welfare of Thailand [17].
This study agrees with the results of Babu et al. [19], who reported that the recycling process of e-waste may release mercury in its elemental vapor form into the environment. Workers who live at e-waste recycling sites may be exposed to both inorganic and organic mercury. The results of this study are also similar to those reported by Decharat [20] and Julander et al. [21], who found that garbage workers who had contact with solid waste were at a greater risk of exposure to mercury than those who were in other positions. This result is also consistent with the study of Needhidasan et al. [22], who reported that levels of hexavalent chromium, manganese, lead, and tin were significantly higher in workers at an e-waste recycling facility than in e-waste workers in a slum community. In contrast, the levels of cobalt, silver, cadmium, and mercury were significantly higher in the slum community workers than in the facility workers.
Workers who worked more than 8 hours per day and had worked at the facilities for more than 6 years had significantly higher urinary mercury levels than their counterparts. This result is supported by the findings of Hansen and Danscher [23], who reported that long-term exposure to mercury and a lack of appropriate prevention may lead to an accumulation of mercury in workers’ bodies. The author noted that the e-waste workers were working in a poorly-ventilated, enclosed area without a mask and technical expertise, resulting in dangerous levels of exposure. This result is further supported by Jafari et al. [24], who also showed that when local and general ventilation systems were both on, the occupational exposure to oxide chemicals was below the threshold limit values (TLVs), but that exposure to respiratory dust at 2 welding stations and ozone levels at 3 welding stations were higher than the respective TLVs.
Workers who used a mask and/or gloves had significantly lower urinary mercury levels than those who did not, and those who always washed their hands before lunch had significantly lower urinary mercury levels than those who sometimes did so. This highlights the benefits of good hygiene practices after handling e-waste. Workers must adhere to good personal hygiene, especially before eating, smoking, and when leaving the workplace, so that microorganisms and harmful chemicals are unable to be absorbed into their bodies or transmitted to another environment on the clothes of contaminated workers [25].
Seafood was probably also a cause of elevated urinary mercury levels, which were significantly different in recycling workers and office workers [26].
This study assessed health symptoms among e-waste workers. Health symptoms, including insomnia, muscle atrophy, weakness, and headaches, were significantly more prevalent among workers who were directly involved in e-waste processing than among other workers. The prevalence of insomnia in this study was consistent with the findings of Wilson [27], which reported the occurrence of certain symptoms, including insomnia, headaches, disturbances in sensations, and tremors among workers who had contact with e-waste. The health symptoms found in this study are similar to those described by Huo et al. [28], who reported that the prevalence rates of headache/vertigo (47.7%), itching (15.0%), nausea (11.1%), insomnia (9.7%), hypomnesia (5.3%), nasal obstruction (5.3%), and conjunctiva congestion (4.8%) in e-waste dismantlement workers were significantly higher than those in the control group. The period of time worked in an e-waste shop was statistically significantly associated with the prevalence of health symptoms among e-waste workers. This finding is also supported by the findings of Grant et al. [29], who showed that increases in spontaneous abortions, stillbirths, premature births, and reduced birth weight and birth length were associated with the length of exposure to e-waste.
The use of PPE at work was also statistically significantly associated with the prevalence of health symptoms among ewaste workers. This finding is also supported by the results of Monika and Kishore [30], who reported that the majority of informal e-waste recyclers did not use any PPE to protect themselves from the dangerous toxins released by processing ewaste. This is also consistent with a study by the International Labor Organization [31], which reported that when the recycling process (cleaning, crushing, or heating parts) was carried out using bare hands and without the use of masks, the adverse health effects included sensory impairment, dermatitis, memory loss, and muscle weakness [10]. In the present study, the author noted that the types of PPE in use in these shops were inappropriate for this type of work. Mercury can accumulate on the surfaces of the PPE used by the e-waste workers. In addition, mercury can penetrate a cotton mask and enter a worker’s airway. E-waste workers using these inappropriate protective devices may mistakenly believe that they are protected.
A limitation of this study is that our data did not contain information on amalgam restorations, although previous studies have shown significant associations between amalgam fillings and oral lesions, autoimmune disorders, multiple sclerosis [32], central nervous symptoms [33], and subfertility in females [34].
In conclusion, personal hygiene is an important protective factor that should be stressed in educational programs. Employers should implement engineering measures to reduce urinary mercury levels and the prevalence of related health symptoms among e-waste workers.
The author thanks the workers in the e-waste shops in Nakhon Si Thammarat Province, Thailand, for giving permission to collect urinary mercury samples. Sincere appreciation is extended to all staff in the laboratory at the Faculty of Medical Technology, Mahidol University.

CONFLICT OF INTEREST

The author has no conflicts of interest associated with the material presented in this paper.

Figure. 1.
The correlation plot of airborne mercury levels versus e-waste workers’ urinary mercury levels.
jpmph-51-4-196f1.jpg
Table 1.
Subject characteristics
Characteristics n (%) Urinary mercury levels (mean±SD, µg/g creatinine) p-value
Work position <0.001
 Worked in e-waste processes 54 (68.4) 18.98±5.89
 Office workers 25 (31.6) 9.15±3.28
Socio-demographic
 Gender 0.06
  Men 47 (59.5) 11.05±3.58
  Women 32 (40.5) 9.98±2.35
 Age (y) 0.16
  ≤34 46 (58.2) 9.55±3.08
  >34 33 (41.8) 10.98±5.80
 Education 0.07
  ≤Secondary school/vocational certificate or equivalent 53 (67.1) 12.90±5.12
  >Secondary school/vocational certificate or equivalent 26 (32.9) 10.51±4.08
Behavioral
 Smokes cigarettes <0.001
  Yes 27 (34.2) 16.55±4.25
  No 52 (65.8) 8.90±3.12
 Drink alcohol 0.07
  Yes 42 (53.2) 12.25±5.01
  No 37 (46.8) 10.59±5.89
 Hours worked per day <0.001
  8 34 (43.0) 8.65±3.28
  ≥8 45 (57.0) 19.07±5.12
 Duration of work (y) <0.001
  6 15 (19.0) 9.65±3.18
  ≥6 64 (81.0) 17.07±5.16
Personal protective equipment
 Cotton mask <0.001
  Yes 21 (26.6) 9.00±3.24
  No 58 (73.4) 15.77±5.36
 Gloves <0.001
  Yes 38 (48.1) 9.15±3.08
  No 41 (51.9) 16.87±4.15
Personal hygiene
 Washed hands before lunch <0.001
  Yes 20 (25.3) 8.95±3.56
  No 59 (74.7) 16.90±3.58
 Consumed fish (times/mo) <0.001
  ≤3 47 (59.5) 7.99±3.17
  >3 32 (40.5) 16.05±3.25

SD, standard deviation.

Table 2.
Univariate analysis for factors associated with work positions
Characteristics Work positions (n)
p-value OR (95% CI)
E-waste (n = 54) Office (n = 25)
Socio-demographic
 Gender 0.09
  Men 35 12 0.81 (0.61,1.05)
  Women 19 13 1.00 (reference)
 Age (y) 0.56
  ≤34 34 12 1.11 (0.72, 159)
  >34 20 13 1.00 (reference)
 Education 0.05
  ≤Secondary school/vocational certificate or equivalent 47 6 1.00 (reference)
  >Secondary school/ vocational certificate or equivalent 7 19 1.45 (106, 1.98)
Behavioral
 Smokes cigarettes 0.003
  Yes 24 3 1.00 (reference)
  No 30 22 1.34 (1.02, 1.72)
 Drink alcohol 0.05
  Yes 28 14 1.00 (reference)
  No 26 11 1.46 (1.05, 1.87)
 Hours worked per day 0.02
  8 22 12 0.15 (0.00, 0.48)
  ≥8 32 13 1.00 (reference)
 Duration of work (y) 0.01
  6 9 6 1.43 (1.11, 1.87)
  ≥6 45 19 1.00 (reference)
Personal protective equipment
 Cotton mask 0.008
  Yes 2 19 1.00 (reference)
  No 52 6 1.33 (1.15, 1.98)
 Gloves 0.12
  Yes 16 22 1.00 (reference)
  No 38 3 1.25 (0.86, 1.68)
Personal hygiene
 Washed hands before lunch 0.02
  Yes 2 18 0.57 (0.37, 0.98)
  No 52 7 1.00 (reference)
 Consumed fish (times/mo) 0.02
  ≤3 29 18 0.69 (0.97, 1.67)
  >3 25 7 1.00 (reference)

OR, odds ratio; CI, confidence interval.

Table 3.
Prevalence of health symptoms during the preceding 3 months
Variables n Prevalence (%)
Emotional changes
 Mood swings 12 15.2
 Irritability 23 29.1
 Nervousness 9 11.4
 Excessive shyness 8 10.2
Insomnia 37 46.8
Neuromuscular changes
 Weakness 19 24.1
 Muscle atrophy 29 36.7
 Twitching 14 17.7
Headaches 16 20.3
Disturbances in sensations 7 8.9
Changes in nerve responses 12 15.2
Table 4.
Prevalence of symptoms in the preceding 3 months
Characteristics Total (n) Insomnia
Muscle atrophy
Weakness
Headaches
Count (n) Prevalence (%) p-value Count (n) Prevalence (%) p-value Count (n) Prevalence (%) p-value Count (n) Prevalence (%) p-value
Total (n) 37 46.8 29 36.7 19 24.1 16 20.3
Work position <0.001 <0.001 <0.001 <0.001
 Worked in e-waste processes 54 34 63.0 26 48.1 15 27.8 14 25.9
 Office workers 25 3 12.0 3 12.0 4 16.0 2 8.0
Socio-demographic
 Gender <0.001 0.06 <0.001 0.06
  Men 47 31 66.0 12 25.5 16 34.0 7 14.9
  Women 32 6 18.8 17 53.1 3 9.4 9 28.1
 Age (y) <0.001 <0.001 <0.001 <0.001
  ≤34 46 5 10.9 8 17.4 2 4.3 3 6.5
  >34 33 32 97.0 21 63.6 17 51.5 13 39.4
 Education <0.001 <0.001 <0.001 <0.001
  ≤Secondary school/vocational certificate or equivalent 53 15 28.3 15 28.3 9 17.0 8 15.1
  >Secondary school/ vocational certificate or equivalent 26 22 84.6 14 53.8 10 38.5 8 30.8
Behavioral
 Smokes cigarettes <0.001 0.06 0.05 0.05
  Yes 27 25 92.6 12 44.4 8 29.6 9 33.3
  No 52 12 23.1 17 32.7 11 21.2 7 13.5
 Drink alcohol <0.001 0.06 0.05 0.60
  Yes 42 26 61.9 15 35.7 9 21.4 7 16.7
  No 37 11 29.7 14 37.8 10 27.0 9 24.3
 Hours worked per day 0.05 <0.001 <0.001 <0.001
  8 34 14 41.2 8 23.5 4 11.8 3 8.8
  ≥8 45 23 51.1 21 46.7 15 33.3 13 28.9
 Duration of work (y) <0.001 0.24 0.50 <0.001
  6 15 5 33.3 5 33.3 4 26.7 2 13.3
  ≥6 64 32 50.0 24 37.5 15 23.4 14 21.9
Personal protective equipment
 Cotton mask <0.001 <0.001 0.05 <0.001
  Yes 21 1 4.8 1 4.8 4 19.1 3 14.3
  No 58 36 62.1 28 48.3 15 25.9 13 22.4 0.60
 Gloves <0.001 0.03 0.06
  Yes 38 15 39.5 12 31.6 9 23.7 7 18.4
  No 41 22 53.7 17 41.5 10 24.4 9 22.0
Personal hygiene
 Washed hands before lunch 0.06 <0.001 0.05 <0.001
  Yes 20 10 50.0 5 25.0 4 20.0 3 15.0
  No 59 27 45.8 24 40.7 15 25.4 13 22.0
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Figure & Data

References

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    Figure

    JPMPH : Journal of Preventive Medicine and Public Health