Effectiveness of Disinfection in Bacteriology Laboratories in Togo, 2021

Background: Laboratory personnel is at risk of biological contamination leading to laboratory-acquired infections (LAIs). The use of disinfection products is essential in the prevention of these infections. This work aimed to evaluate the effectiveness of antimicrobial agents used in disinfection in bac-teriology laboratories in Togo. Methods: This was a cross-sectional study conducted from June to December 2021 in all


Introduction
Medical laboratories are one of the professional sectors most exposed to infectious risks. Microbiology is particularly concerned since all biological agents are likely to be the subject of diagnostic examinations [1] [2]. Microorganisms from the environment or from the samples handled can contaminate surfaces (laboratory benches, equipment, floors) and the hands of operators. Infections acquired by personnel handling these pathogenic microorganisms in biological laboratories have been described in the literature since the middle of 1930 years and a study carried out in 2016 in Canada in 1352 laboratory areas, described a total number of 46 incidents of exposure to micro-organisms with an incidence of 3.4% [3]. Contaminated surfaces are an important potential source of healthcare-associated infection (HAI) transmission due to many pathogens [4]- [9].
Among the potential sources of pathogens that cause HAI, the most common are the patient's microbiota and the hands of healthcare workers [10]. Many studies have shown the role of hands in the transmission of nosocomial infections in Benin [5] [11] [12] [13]. In Togo, many studies have been conducted, but few have been published, hence the lack of available information. Hygiene, cleaning and disinfection of hands are prerequisites for hygiene management in hospitals and the food industry in order to minimize the risk of healthcare and foodborne infections [11] [13]. Making laboratory operations safe means controlling the risks at different stages of sample processing [1] [2]. One of the means used to protect oneself, the community and the environment of pathogens is disinfection. It is therefore necessary to implement procedures for cleaning and disinfecting surfaces [12]. Many commercial products are available for disinfecting and sanitizing surfaces in health care facilities and food premises such as restaurants and factories [14] [15]. Antimicrobial agents, whether disinfectants or antiseptics, were used empirically until Pasteur demonstrated the responsibility of microorganisms in infectious diseases and laid the scientific foundation for antisepsis and disinfection [16]. The use of these products aims to reduce or eliminate microorganisms. These chemicals are widely used in medicine, whether as a curative measure (wounds) or, above all, as a preventive measure for humans (body hygiene, hand hygiene, pre-operative skin preparation) or for the environment (cleaning, disinfection of premises, surfaces and equipment) [16].
The implementation of these preventive measures makes it possible to reduction of expositions frequency. These expositions can result in a failure, the absence of appropriate protection, or non-compliance with procedures.

Study Design
This was a cross-sectional and descriptive study conducted in all medical bacteriology laboratories in Togo.
Togo is located in West Africa with an area of 56.600 km 2 . Its population was estimated at 7.886.000 in 2021 [17]. This network includes the national reference laboratory, regional laboratories and district laboratories.

Study Period
The study was conducted from June to December 2021.

Sampling, Population and Study Materials
All public and private bacteriology laboratories of Togo (21) were included.
Laboratory staff was chosen by convenience (two laboratory technicians, one laboratory assistant and one secretary). The hands of this laboratory staff were sampled before and after disinfection by washing with water and mild soap. On each work surface (laboratory bench, the doors' handles, the sink, the microscopes' mechanical stage, stages controls, adjustments, the staff mobile phone, and the inside of the autoclave) a swab was taken. On the laboratory benches, samples were taken before and after disinfection. from concentrated solutions. The surfaces are disinfected before and at the end of each operation using a paper towel. The surface is first wiped to remove organic matter and dust before the 0.5% bleach solution is applied [18].

Hand Washing with Water and Mild Soap
Washing should be carried out before each handling and before wearing gloves, as well as after handling and removing gloves [18].
-Wet your hands with water and then apply the soap; -Hands are rubbed; -Rinse with water and dry.

Data Collection Technique and Tools
Data collection was done by interview, observation of practices, and laboratory measurements.
A questionnaire was designed by the investigators for this study. It was tested during a pilot survey in Greater Lomé. This questionnaire contains 5 sections with 13 items. See the questionnaire in the appendix.
Optical microscopes were used for direct examination and after Gram staining.

Sample Collection and Processing
Two types of samples were taken using sterile swabs: Sterile swabs moistened with sterile normal saline (0.9%) were used to collect samples from the palms of both hands of the staff, rotating them momentarily over the entire palm surface and between the fingers. For laboratory technicians and assistants, samples were taken before hands washing and gloves wearing, after removing gloves and washing hands at the end of the manipulation. For the secretary, swabs were taken before and after hands washing with water and mild soap.
Sterile swabs moistened with sterile normal saline (0.9%) were used to sample some at risk surfaces before and after disinfection with bleach (0.5% active chlorine). The rest of the surfaces, were swabbed only before disinfection.
In each laboratory, the swabs collected were immediately plated onto Oxoid,  [19]. Isolated colonies were counted on both blood agar and UTI medium with a magnifying glass. The results were expressed as Colony Forming Units (CFU)/swab [20].
The quality of the media was ensured by sterility and fertility tests using E. coli ATCC 25922 reference strains.

Statistical Analysis
Frequencies and mean colony numbers were calculated. The ANOVA test was used to compare the mean numbers of colonies and the prevalence ratio and 95% confidence intervals were used to compare the frequencies.

Results
The samples were collected in a total of 21 bacteriology laboratories distributed in the country.
A total of 393 samples were taken, from which 41.2% were from staff's hands.
Among them, 188 from the maritime region, 91 from kara region, 57 from central region, 38 from plateaux region and 19 from savanes region. Figure 1 shows the distribution of the different bacteriology laboratories visited throughout the country. Table 1 illustrates the proportions of contaminated sites before and after disinfection in the laboratories. Before disinfection, the most contaminated sites were sinks (66.6%), laboratory benches (61.9%), refrigerator door handles (47.6%), and technicians' mobile phones (42.8%). After disinfecting the benches with bleach, no bacterial growth was observed on their surfaces. However, the hands washed with soap and water showed persistent bacteria.

Proportion of Contaminated Sites before and after Disinfection in Laboratories
The remaining contamination after disinfection of benches and hands is 2.9% The surfaces were more contaminated than staff's hands. Table 2

Distribution of Germs Isolated before and after Disinfection in the Laboratories
Before disinfection, the proportion of Klebsiella spp was 44.3% on surfaces and that of Staphylococcus spp 75.0% on staff's hands. After hands washing, two types of strains were persistent: Staphylococcus spp 75.0% and Klebsiella spp 25%. Table 3 illustrates the distribution of germs before and after disinfection of surfaces and hands in the laboratories.
Before the disinfection the proportion of enterobacteria (Klebsiella spp. and E. coli) represented 51.8% and Staphylococcus spp. 25.0%. After the hand washing the proportion of the persistent germs was Staphylococcus spp. 75.0% and Klebsiella spp. 25.0%.

Efficacy of Antimicrobial Agents Used for Hands and Work Surfaces Disinfection
On the laboratory benches, after disinfection with 0.5% bleach solution, there was no growth on the inoculated media.
The staff's hands remained contaminated despite the washing with soap and water. Before washing, the average number of colonies was 16.7 (min: 0; max: 1000) and after washing this number was 13.6 (min: 1; max: 1050). The difference between the number of colonies observed before and after washing was not statistically significant (p = 0.8). The residual contamination was 3.7%.

Discussion
This study aimed to measure the effectiveness of hand washing of laboratory staff with water and mild soap and surfaces disinfection with sodium hypochlorite in bacteriology laboratories in Togo. The results showed that the laboratory benches and sinks were the most contaminated surfaces in the laboratories and Klebsiella spp. and Staphylococcus spp. were the most commonly identified germs. This result was not surprising since both germs are not to be distributed in the environment [21] [22]. The contamination of workers hands and mainly in microbiology laboratories was also showed by other authors [23].
The laboratory benches disinfection with a 0.5% of sodium hypochlorite solution led to an absence of bacterial growth in culture. The effect of sodium hypochlorite on bacteria growth is also well documented [24].

Microbiological Quality of Surfaces and Staff's Hands before and after Disinfection in Bacteriology Laboratories in Togo, 2021
The bacteria on the surfaces before disinfection were mainly represented by 51.8% of enterobacteria including Klebsiella spp. Strains of Klebsiella spp are commensal enterobacteria of the digestive and respiratory tracts of animals including humans. In addition enterobacterial are ubiquitous [25]. They are common in faeces and can be an indicator of faecal contamination. The high proportion of enterobacteria is due to the sampling method, according to the literature, the wet swab technique appears to be better at to detect Gram-negative bacilli [26].
This difference could be explained by the fact that our work was carried out during the COVID-19 pandemic, when disinfection measures had been reinforced following awareness-raising and training. Laboratories workers mobile phones can be a potential source of contamination for themselves, the community, their families especially their children who touch their parent's phones and without washing their hands send them to the orifices (mouth, eyes, nose and ears). In addition, these mobile phones are a potential source of nosocomial infection [10].
The hand-carried flora was predominantly represented by Staphylococci. After disinfection by washing, we noted a persistence of these germs. Our results are consistent with those obtained in Greece by Tselebonis et al. in 2016 [30] and by Ravaoarisaina et al. (2019) in Madagascar [31] who found the same trend where Staphylococci represented more than 50% of the germs. This predomin-Open Journal of Preventive Medicine ance of Staphylococci on the hands could be explained by the fact that they are commensal bacteria of the epithelia of humans and animals [32]. Furthermore, Staphylococcus epidermidis is a skin commensal in almost 100% of humans.

Effectiveness of Antimicrobial Agents Used for Hands and Work Surfaces Disinfection in Bacteriology Laboratories in Togo, 2021
During this study, it was noted that all the laboratory benches disinfected with the 0.5% bleach solution did not show any bacterial growth. These results confirm the effectiveness of this biocide or disinfectant, especially when used under the proper conditions as indicated by the manufacturer [12]. showed a significant reduction of germs (p < 0.001) [34]. These results may be explained by the fact that hand washing and drying techniques were not followed by all staff in our study. For more than twenty years, most studies have consistently shown poor compliance with hand washing in all healthcare sectors, including sectors considered at risk of nosocomial infections such as intensive care units [32]. Overall, compliance calculated in these studies varies between 20% and 50%. Out of the 50% of people who wash their hands frequently, only 25% do so in accordance with the rules of the art by respecting the techniques [30].

Limitations of the Study
Laboratory surfaces (door handles, fridges, sinks, microscope coarse adjustment knobs and stages, and staff mobile phones) were not sampled after disinfection, as these surfaces are not routinely disinfected. Nevertheless, this study showed that the 0.5% sodium hypochlorite (bleach) solution was totally effective in disinfecting benches.

Conclusion
In this study, which assessed the effectiveness of disinfectants used in medical bacteriology laboratories in Togo, it emerged that sinks and benches were the most contaminated surfaces, with Klebsiella spp. and Staphylococcus spp. predominating. The use of 0.5% sodium hypochlorite solution to disinfect benches was effective. However, the risk of contamination by pathogenic bacteria persists because hand washing with water and mild soap is not sufficiently effective. It is therefore necessary to raise staff awareness of the need to comply with good mi-