|
|
ORIGINAL ARTICLE |
|
Year : 2022 | Volume
: 13
| Issue : 1 | Page : 77 |
|
Bacteriological quality of drinking water and hygienic assessment of water cooler dispensers in higher education institution
Nopadol Precha, Chayada Rattanaphan, Tanyaporn Galiga, Presert Makkaew, Nutcha Narom, Siriuma Jawjit
Department of Environmental Health, School of Public Health, Walailak University, Nakhon Si Thammarat, Thailand
Date of Submission | 22-Oct-2020 |
Date of Acceptance | 17-Mar-2021 |
Date of Web Publication | 27-Apr-2022 |
Correspondence Address: Siriuma Jawjit Department of Environmental Health and Technology, School of Public Health, Walailak University, Thai Buri, Tha Sala District, Nakhon Si Thammarat Thailand
 Source of Support: None, Conflict of Interest: None  | Check |
DOI: 10.4103/ijpvm.IJPVM_644_20
Background: The bacteriological quality of drinking water has become a public health concern according to its association with water-borne diseases. Nowadays, there are several different types of drinking water, including water cooler dispensers (WCDs), which are becoming a popular device in educational institutions. Therefore, this study aims to determine the bacteriological quality of drinking water from WCDs, and inspect their hygienic conditions in students' dormitories at a university in Nakhon Si Thammarat, Thailand. Methods: Water samples from 53 WCDs installed in 13 dormitories were collected and analyzed coliform bacteria by using the multiple-tube fermentation technique. The hygienic inspection form from the Department of Health, Ministry of Public Health, was used for inspection of the sanitary conditions. The hygienic factors of water cooler sanitation were analyzed using the generalized linear model. Results: Coliform bacteria were found in 10 out of 53 samples; moreover, Escherichia coli was recovered in three samples. Maintenance/cleaning and monitoring were the most two sanitary issues found in 100% (53/53) of the WCDs. Location and features of machine were found the correlation with the prevalence of coliform bacteria in drinking water. Conclusions: The findings of this study suggest regular monitoring of water quality in educational institutions. Also, the Sanitary Standard and Operational Procedures (S.S.O.P.) should be developed to improve the hygienic conditions of the water cooler dispensers.
Keywords: Drinking water, environmental monitoring, hygiene, water quality
How to cite this article: Precha N, Rattanaphan C, Galiga T, Makkaew P, Narom N, Jawjit S. Bacteriological quality of drinking water and hygienic assessment of water cooler dispensers in higher education institution. Int J Prev Med 2022;13:77 |
How to cite this URL: Precha N, Rattanaphan C, Galiga T, Makkaew P, Narom N, Jawjit S. Bacteriological quality of drinking water and hygienic assessment of water cooler dispensers in higher education institution. Int J Prev Med [serial online] 2022 [cited 2023 Jan 27];13:77. Available from: https://www.ijpvmjournal.net/text.asp?2022/13/1/77/344227 |
Introduction | |  |
The quality of drinking water has become a significant concern for public health issues, which are associated factors of water-borne diseases.[1],[2] World Health Organization (WHO) has reported that inadequate water contributed to at least 2 billion people use a fecal contamination of drinking water source.[3] Moreover, unsafe drinking water and hand hygiene caused 829,000 people to die each year from diarrhea. However, water-borne disease could be reduced by providing adequate water supply and facilities.[4] Therefore, safe drinking water and water supply systems can contribute to the public health resolution goal.
Nowadays, water cooler dispenser (WCD) has become a popular device of drinking water sources in tropical countries, particularly in public institutions and workplaces. However, the dispenser machines can contain various microbial pathogens.[5] The significant findings showed that the bacterial contamination in WCDs tank were higher than water supplied to them.[6] The hygienic conditions, machine characters, and maintenance services could affect the bacteriological quality of drinking water.[7] According to the WHO guideline, the quality of drinking water should be considered for turbidity, pH, residual free chlorine, coliform bacteria, and other microbial pathogens.[3] All of these, the crucial concern is microbial contamination that can contribute the severe health problems as water-borne diseases. Coliform bacteria have commonly been used for microbiological investigation of fecal contamination in drinking water.[8]
Due to the extension of the dormitory and a higher number of students, university has to provide safe drinking water to them. WCDs are essential equipment that can facilitate in the daily life of students. To our knowledge, several studies have performed on the bacteriological quality of drinking water in household and office building, while there are few studies on WCDs in educational places.[6],[7],[9],[10],[11],[12] Regarding the essential of safe drinking water supply for the student, this study aims to investigate the hygienic conditions of WCDs and bacteriological quality of drinking water distributed through WCDs located in a student dormitory at the university campus in Nakhon Si Thammarat, Thailand.
Methods | |  |
Water samples collection
A total of 53 drinking-water samples were collected from 53 WCDs that located in all 13 dormitories of Walailak University, during August–October 2017. A 100-mL water sample was collected from each device by using sterile sample bottles containing sodium thiosulfate to neutralize the effect of chlorine.[13] Collected samples were kept in the icebox and transported to the laboratory for bacteriological analysis within 6 h. The procedures had been performed under aseptic technique.
Bacteriological analysis
The microbial indicator of fecal contamination, coliform bacteria namely total coliform bacteria, fecal coliform bacteria, and Escherichia coli (E. coli) in water samples were identified in this study. Total coliform bacteria in the water sample were measured using the most probable number (MPN) test method. To investigate the coliform bacteria in drinking water based on MPN, single- and double-strength concentrations of Lauryl Tryptose Broth (LTB) medium (HiMedia Laboratories, India) were used for the presumptive test. Brilliant Green Lactose Bile Broth (BGLB) medium (HiMedia Laboratories, India) was used to confirm the total coliform bacteria at 35–37°C for 24–48 h, while EC broth medium (HiMedia Laboratories, India) was applied for selective enumeration of fecal coliform bacteria at of 44.5–45.5°C for 24 h. The number of positive tubes were recorded from each set and compare with the MPN table to give the amount of total coliform bacteria and fecal coliform bacteria, respectively. For E. coli identification, all positive EC broth was inoculated and cultured in Eosin Methylene Blue (EMB) medium (HiMedia Laboratories, India) was used to differentiate E. coli from other gram-negative coliform bacteria by specific colony morphology. The metallic green sheen colony on EMB were selected to identify using biochemical tests of Indole, Methyl red, Voges-Proskauer, and Citrate utilization (IMViC).[14]
WCD hygiene assessment
To perform the survey, 53 WCDs in dormitories were assessed using hygienic management of WCDs form. The hygienic assessment form was applied from the Handbook of Drinking Water Vending Machines and a previous study.[15],[16] The information was divided into six requirements with 18 items in total listed: (1) location, (2) feature of water dispenser, (3) water source and water quality improvement, (4) water quality control, (5) maintenance and cleaning, and (6) monitoring. The WCDs hygiene assessment results were categorized as “satisfactory” and “unsatisfactory” by applying criteria from the Department of Health, Ministry of Public Health.[15]
Ethical considerations
The data collection was conducted after ethical approval from the Human Research Ethics Committee of Walailak University, Thailand (WUEC-16-076-01).
Statistical analysis
The association between hygienic conditions (18 items) and fecal coliform bacteria was statistically analyzed using the generalized linear model. The associations are shown as correlation coefficients using STATA version 13. P value <0.05 was considered as the significant level.
Results | |  |
Total coliform and fecal coliform bacteria were detected in 10 of 53 (18.87%) WCDs, which has distributed among 6 of 13 dormitories. The bacteriological analysis of 10 WCDs were higher than the drinking water standard for total coliform and fecal coliform bacteria (<2.2 MPN/100 mL) according to Thai Industrial Standards Institute, 2006. The range of MPN value of total coliform and fecal coliform bacteria measured in 10 water samples from unsatisfactory WCDs were shown in [Table 1]. Moreover, E. coli was detected 1.59% (3/10) from those 10 WCDs. | Table 1: The results of bacteriological analysis of drinking water from WCDs
Click here to view |
Hygienic assessment results of 53 WCDs in 13 student dormitories, Walailak University, were shown in [Table 2]. A total of 53 WCDs showed unsatisfactory assessments, which were mostly found in 4 of 6 hygienic requirements. The WCDs showed the most unsatisfactory issue in terms of location part particularly, improper machine installation sites and feature part, only clean without any dirt on the machine (parts exposed directly to the water were not presented thallophytic plants or any unsanitary). However, the hygienic assessment of all WCDs was satisfactory for the water sources and improvement and drinking water standard quality control, while the maintenance/cleaning and monitoring parts showed unsatisfactory.
Eighteen items of hygienic conditions were statistically tested for the correlation with fecal coliform bacteria. The results found that only three items were correlated with fecal coliform bacteria. The correlation coefficient of the three hygienic items and the prevalence of fecal coliform bacteria were shown in [Table 3]. | Table 2: Assessment of hygienic conditions of the drinking water dispenser machines (n=53)
Click here to view |
 | Table 3: The correlation analysis of hygienic condition and fecal coliform
Click here to view |
Discussion | |  |
The coliform and E. coli are the common indicators of fecal contamination in drinking water, which are used as microbiological parameters to be regulated by Thai legislation for drinking water quality investigation.[17] Bacteriological quality of drinking water from WCDs was analyzed using the standard method of MPN, which is widely used for drinking water quality measurement.[18],[19],[20] According to Thailand standard of drinking water, the recommended coliform bacteria should be at least 2.2 MPN/100 ml, while the 10 of 53 WCDs exceeded the standard. These data are comparable with research by Rakkamon et al. (2012) where coliform bacteria were found in all WCDs at a university in Thailand.[21] Although it was not the most approach of the actual number of bacteria present in the sample, MPN was the index of bacterial indicator number.[22] In this study, a few number of E. coli were detected in drinking water from WCDs as well as the previous studies in- and around the educational institutions in Thailand.[7],[16],[23] The low level of E. coli in this study might show the low risk of illness from E. coli exposure as described in the previous quantitative microbial risk assessment (QMRA) of drinking water in Mahasarakham province of Thailand.[23] In addition, E. coli detected in drinking water can be implied that pathogenic bacteria, viruses, and parasites may also be contaminated.
The quality of drinking water and hygienic conditions of WCDs should be routinely investigated. However, various studies in Thailand had indicated that dispenser machines were lack of proper hygienic management.[7],[16],[23] The hygienic assessment of WCDs showed unsatisfactory results for all dispenser machines, which were due to a lack of monitoring evidence and its consequential effect in the maintenance and cleaning section. These two sections have not found the evidence from any documents or dormitory manager. The irregular maintenance and cleaning are the critical issue of bacterial contamination in WCDs, which should change the membrane filter every 6 months and circulate water within dispensers.[6],[7],[15],[24] Although the results showed that the improper condition of WCDs locations and unclean dispenser surface are associated with the number of fecal coliform bacteria, only machines location are the significant factor of this issue. These may be described as the poor hygiene of dispensers machines are located nearby the garbage or dust generating sources and the unclean of the faucets and dispenser surfaces, which are the suitable point of bacterial growth and biofilm formation.[9],[19]
The results of this study had indicated that the irregular cleaning and improper installation sites can influence the abundance of bacteria on faucets and dispenser body that probably distribute pathogens through drinking water consumption from WCDs.[25] Furthermore, physicochemical parameters are also essential factors for drinking water quality analysis and bacterial contamination in WCDs.[26],[27] These parameters should be more investigated to combine with bacteriological results for more clarification of bacterial contamination in WCDs.
Conclusions | |  |
Drinking water quality in an educational institution is essential for student health due to its necessity for daily life consumption. This study had revealed the fundamental problem of drinking water in an educational institution, which can indicate the sanitation issue of water supply systems for drinking water and may encourage the threat to student health. Therefore, the awareness and knowledge on basic of Sanitary Standard and Operational Procedures (S.S.O.P.) should be raised for safe drinking water, and the correlation between bacteriological water quality from WCDs and gastrointestinal disease hospital admission should be done for further studies.
Acknowledgments
The authors would like to thank the Environmental Health laboratory staff of Walailak University for their help in this study.
Financial support and sponsorship
This research project is supported by Undergraduate Research Grants, Walailak University.
Conflicts of interest
There are no conflicts of interest.
References | |  |
1. | Reynolds KA, Mena KD, Gerba CP. Risk of waterborne illness via drinking water in the United States. Rev Environ Contam Toxicol 2007;192:117-58. |
2. | Fiebelkorn AP, Person B, Quick RE, Vindigni SM, Jhung M, Bowen A, et al. Systematic review of behavior change research on point-of-use water treatment interventions in countries categorized as low-to medium development on the human development index. Soc Sci Med 2012;75:622-33. |
3. | World Health Organization. Guidelines For Drinking-Water Quality. Geneva: World Health Organization; 2011. |
4. | Hunter PR, Zmirou-Navier D, Hartemann P. Estimating the impact on health of poor reliability of drinking water interventions in developing countries. Sci Total Environ 2009:407:2621-4. |
5. | Sacchetti R, De Luca G, Dormi A, Guberti E, Zanetti F. Microbial quality of drinking water from microfiltered water dispensers. Int J Hyg Environ Health 2014;217:255-9. |
6. | Park S, Farooq A, Jo H, Kim J, Yang M, Ko Y, et al. Investigation of microbial communities in water dispensers. Appl Biol Chem 2017;60:667-72. |
7. | Pratum C, Khananthai N. Assessment of factors affecting drinking water quality from free water dispensers in the higher education institution. Int J Environ Sci Educ 2017;12:787-97. |
8. | Saxena G, Bharagava RN, Kaithwas G, Raj A. Microbial indicators, pathogens and methods for their monitoring in water environment. J Water Health 2014;13:319-39. |
9. | Liguori G, Cavallotti I, Arnese A, Amiranda C, Anastasi D, Angelillo IF. Microbiological quality of drinking water from dispensers in Italy. BMC Microbiol 2010;10:19. |
10. | Furuhata K, Ishizaki N, Fukuyama M. Bacterial contamination in cold water samples obtained from water dispensers. Biocontrol Sci 2015;20:147-51. |
11. | Semerjian L, Ibrahim MM, Alkhateri BM. A comparative study of microbial contamination between public institutional and private residential bottled water dispensers. Environ Monit Assess 2020;192:259. |
12. | Ghorbanzadeh A, Peivasteh Roudsari L, Afshar Kohan N, Zangi R, Moradi F. A survey on coliform contamination and chemical parameters of potable water from water dispensers in faculties of Mashhad University of medical sciences. J Food Safe Hyg 2019;4:63-8. |
13. | Rice EW, Baird RB, Eaton AD. Standard Methods for the Examination of Water and Wastewater. 23 rd ed. Washington DC, USA: American Public Health Association; 2017. |
14. | Bergey DH, Noel RK, John GH. Bergey's Manual of Systematic Bacteriology. Baltimore, MD: Williams & Wilkins; 1984. |
15. | Handbook of Drinking Water Vending Machines. Business Detrimental to Health, in Public Health Act 1992 and the Ministry of Public Health. Bangkok; 2013. |
16. | Yongyod R. Drinking water quality and evaluation of environmental conditions of water vending machines. Asia Pac J Sci Technol 2018;23:1-5. |
17. | Thai Industrial Standards Institute. Drinking Water (TIS 257-2006).Thailand: Ministry of Industrial; 2006. |
18. | Nkere C, Ibe N, Iroegbu C. Bacteriological quality of foods and water sold by vendors and in restaurants in Nsukka, Enugu State, Nigeria: A comparative study of three microbiological methods. J Health Popul Nutr 2011;29:560-6. |
19. | Moosa M, Khan M, Alalami U, Hussain A. Microbiological quality of drinking water from water dispenser machines. Int J Environ Sci Dev 2015;6:710-3. |
20. | Rubino F, Corona Y, Pérez JGJ, Smith C. Bacterial contamination of drinking water in Guadalajara, Mexico. Int J Environ Res Public Health 2018;16:67. |
21. | Rakkamon T, Chaimay B, Inraksa S, Rachasong W. Quality of drinking water from water cooler at Thaksin University, Phatthalung Campus. Thaksin University J 2012;15:18-26. |
22. | Bartram J, Pedley S. Microbiological analyses. In: Bartram J, Ballance R. editos. Water Quality Monitoring: A Practical Guide to the Design and Implementation of Freshwater Quality Studies and Monitoring Programmes. London, U.K.: E&FN Spon; 1996. p. 383. |
23. | Wibuloutai J, Thanomsangad P, Benjawanit K, Mahaweerawat U. Microbial risk assessment of drinking water filtration dispenser toll machines (DFTMs) in Mahasarakham province of Thailand. Water Supply 2019;19:1438-45. |
24. | Malik A, Yasar A, Tabinda A, Abubakar M. Water-borne diseases, cost of illness and willingness to pay for diseases interventions in rural communities of developing countries. Iran J Public Health 2012;41:39-49. |
25. | Jeena MI, Deepa P, Mujeeb Rahiman KM, Shanthi RT, Hatha AAM. Risk assessment of heterotrophic bacteria from bottled drinking water sold in Indian markets. Int J Hyg Environ Health 2006;209:191-6. |
26. | Malakootian M, Mansoorian HJ, Moosazadeh M. Performance evaluation of electrocoagulation process using iron-rod electrodes for removing hardness from drinking water. Desalination 2010;255:67-71. |
27. | Gibert O, Lefèvre B, Fernández M, Bernat X, Paraira M, Calderer M, et al. Characterising biofilm development on granular activated carbon used for drinking water production. Water Res 2013;47:1101-10. |
[Table 1], [Table 2], [Table 3]
|