A R T I C L E  I N F O		ABSTRACT
ORIGINAL ARTICLE		Introduction: Today, disinfection of surfaces by using antimicrobial agents is critical for the prevention and control of pathogens and reduction of infection in hospital. The aim of this study was to investigate and compare the effects of two disinfectants against Staphylococcus aureus isolated from the NICU of Shahid Sadoughi Hospital of Yazd in 2017. Materials and Methods: In this descriptive cross sectional study, bacterial culture of samples collected from different surfaces of the NICU and S. aureus isolates were identified using conventional biochemical tests. Peracetic acid and chlorine dioxide various concentrations were used as disinfectants. Their effects against Staphylococcus aureus were determined by Standard disc diffusion method. Data were analyzed by linear mixed models in SPSS version 23. Results: 39.39% of samples were found to be S. aureus infected. The mean diameter of growth inhibition zone for peracetic acid 0.1% was significantly lower than that for peracetic acid 0.2%, and peracetic acid 0.1% was significantly higher than that for chlorine dioxide (P < 0.001). The comparison of growth inhibition zone diameters for peracetic acid 0.1% and chlorine dioxide disinfectants showed that the average diameter of the inhibition zone created by peracetic acid 0.1% was significantly higher than that created by chlorine dioxide. The most effective disinfectant on S. aureus strains isolated was peracetic acid 0.2% and the least effective disinfectant was chlorine dioxide. Conclusion: In health care facilities with S. aureus infection, peracetic acid 0.2% can be used effectively to reduce nosocomial infection rate.
Article History: Received: 05 February 2019 Accepted: 20 April 2019
*Corresponding Author: Mehdi Mokhtari Email: mokhtari@ssu.ac.ir Tel: +989133559789
Keywords: Disinfectants, Nosocomial infections, Neonatal Intensive Care Units, Peracetic acid, Chlorine Dioxide, Staphylococcus aureus.

Introduction
Contaminated surfaces have always been considered as one of the ways of transmission of diseases in health care facilities. Proper disinfection and sterilization can be an effective way to control hospital infections¹. Nosocomial infections are one of the common problems of hospitals that increase the burden of diseases in the community and mortality in hospitalized patients ².  The incidence rate of these infections in NICUs has been reported from 5.9% to 31.8% ^{3, 4}. Factors such as prematurity, low weight, long hospital stay, use of invasive methods such as tracheal tube, ventricular shunt, vascular catheter, and intravenous feeding with fat emulsions play an important role in the development of these infections and the difference in their incidence rates in neonates ^{5, 6}. One of the most distinct and most frequently occurring bacterial infections in the hospitals around the world is Staphylococcus aureus infection ⁷. This bacterium is a gram-positive, catalase-positive, obligate anaerobic and sporeless coccus ^{8, 9}. Many factors can contribute to the transmission of Staphylococcus aureus . One of the most important factors for the spread of nosocomial infections is inappropriate use of antimicrobial agents ¹⁰. Proper use of disinfectants and antiseptic agents for medical equipment and surfaces can be very effective way to reduce exposure population ¹¹. Having enough knowledge about the principles of disinfection, antisepsis and sterilization is a key factor. Unfortunately, due to inappropriate selection of disinfectants, inappropriate physical conditions of the setting and lack of relevant knowledge and training among the staff, the effects of these substances have been declining, leading to unhealthy condition and consequently increased of Nosocomial infections ¹². Peracetic acid (PA), with the chemical formula C₂H₄O₃, is a combination of acetic acid and peroxyhydroxide that is called with different commercial names around the world. Peracetic acid with oxidizing the outer membrane can kill bacterias, endospores, yeasts, and fungal spores.
 PA belongs to the organic peroxides family and is produced by combination of acetic acid and hydrogen peroxide in aqueous environment, and exhibits high antimicrobial properties because of its high oxidation potential ¹³. Chlorine dioxide (ClO₂) is a strong oxidizing substance and serves as a highly effective disinfectant for hospital equipment ¹⁴. The prevention and control of hospital infection in infants is very important, because their immune system has not yet been fully activated and therefore microbial agents may develop severe and fatal infections in them. Also premature and low birth weight infants with acute medical problems stay for weeks to months in the NICU, during which they may contact with medical equipment, antibiotic-resistant hospital flora, and invasive procedures.Therefore NICU should be more studied to ensure that disinfection process is safe for infants and staffs. ¹⁵.
Materials and Methods
Studied disinfectants
Peracetic acid at concentrations 0.1% and 0.2% (Merck Co., Germany) and Chlorine dioxide 1% (Dorna Daroye, Yazd, Iran) were used as disinfectants.  
Sample collection
This descriptive cross sectional study was performed on samples from the NICU of Shahid Sadoughi Hospital in Yazd in 2017. First, 93 samples was calculated by using the G-Power software version 3192 given the effect size of 0.3, the significance level of 0.5 and the power of 80%.
Sampling procedure  was performed within three months (from November to February 2017) in three randomly selected days at 1-month intervals (to be repeated).
. 33 places in different parts of the NICU with the highest exposure to patients and staff were selected. Then, surfaces of 10 cm x 10 cm were marked with tape strips. At 11-12 o'clock, a sterile swab was moisturized with sterilized physiological serum, and all marked surfaces were sampled ¹⁶. Then, samples were poured into a tube containing 3 ml of the prepared and labelled tryptic soy broth (TSB) culture medium (Darvash Company, Iran), and then were immediately transferred to the Microbiology Laboratory of Shahid Sadoughi University of Medical Sciences.
All sampling steps were carried out near an alcohol light. Sampling from all selected places was carried out according to the above method. Sampling was performed in triplicate at 1-month intervals and without any prior coordination with the staff of the NICU.
Sample culture and identification of Staphylococcus aureus isolates
100 μl of each sample was transferred to the already prepared culture media blood agar- Eosin Methylene Blue Agar (EMB) (Darvash Company, Iran) and cultured linearly by using a sterile loop near the flame. Plates were incubated at 37 °C for 24 hours. The colonies present in the culture media were gram stained. In the case that clustered gram-positive cocci were observed, the colonies were identified using conventional biochemical tests such as catalase, coagulase, and Mannitol fermentation in Mannitol salt agar (Darvash Company, Iran) ¹⁷.
Antimicrobial effect of disinfectants
Susceptibility of bacterial isolates against disinfectants was measured by the Kirby-Bauer method and according to the CLSI protocol ¹⁸. In brief, sterilized blank disks were dipped with 20 μl of the disinfectant and after complete absorption, disks were left at 37 °C to dry completely. A bacterial suspension of the fresh (24-h) culture of S. aureus isolates, equivalent to 0.5 McFarland opacity (1.5×10⁸ CFU/ml), was prepared and cultured on the Mueller-Hinton agar (Darvash Company, Iran) by using a sterile swab. Then, disks containing disinfectants were placed on the culture media at a distance of 24 mm from each other by means of sterile pins, and stored at 37 °C for 18-24 h. After incubation, the bacterial growth inhibition zone around the disk was measured in mm. The susceptibility measurement was conducted in triplicate with the three disinfectants for all isolates and the mean diameter of the growth inhibition zone was calculated after each test ². In this study, the growth inhibition zone diameter of 6 mm was considered to represent no effect, 7-10 mm low effect, 11-15 mm average effect and more than 15 mm strong effect ². To control the test, a disk containing physiological serum was used, and to control the sterility, a blank disk without any additive was used. Finally, the data were tabulated and analyzed using the mixed linear model and descriptive tables in the SPSS version 23.
Ethical issues
This study was conducted after its protocol was approved by the Medical Ethics Committee of Shahid Sadoughi University of Medical Sciences and Health Services (IR.SSU.SPH.REC.1395.9)
Results
39 isolates (39.39%) if all samples (99 samples) were found S. aureus positive in three steps of sampling. 11 samples (28.20%) were found in the first sampling, 15 (38.46%) in the second sampling and 13 (33.33%) in the third sampling. Comparison of the inhibition zone diameters of the three disinfectants was performed using a linear mixed model. The mean (± standard deviation) values of the inhibition zone diameters for the three disinfectants are shown in Table 1. The mean inhibition zone diameters obtained for the peracetic acid 0.1% and 0.2% and chlorine dioxide 0.1%  were 36.228 (mm), 45.319(mm) and 4.424(mm) respectively.

Disinfectant	Mean(mm)	SD
Peracetic acid 0.1%	36.228	1.625
Peracetic acid 0.2%	45.319	1.659
Chlorine dioxide 1%	4.424	1.625

The paired comparison of the effect of disinfectants on the inhibition zone showed that the mean diameter of the inhibition zone created by the peracetic acid 0.1% was significantly lower than that created by the peracetic acid 0.2% (P = 0.000), and this variable for peracetic acid 0.2% was significantly higher than that for chlorine dioxide 1% (P = 0.000) (Table 2).
The comparison of the diameters of growth inhibition zones created by the peracetic acid 0.1% and 0.2% and chlorine dioxide 1%, showed that the mean diameter of the growth inhibition zones created by peracetic acid 0.1% were significantly higher than that created by the chlorine dioxide 1% (P = 0.000).

Disinfectant(I)	Disinfectant(J)	Mean (I-J)	SD	df	P-value	95% CI
						Lower limit	Upper limit
Peracetic acid 0.1%	Peracetic acid 0.2%	-9.091*	1.371	72.531	0.000	-12.452	-5.730
	Chlorine dioxide 1%	31.804*	1.588	86.291	0.000	27.927	35.681
Peracetic acid 0.2%	Peracetic acid 0.1%	9.091*	1.371	72.531	0.000	5.730	12.452
	Chlorine dioxide 1%	40.895*	1.371	72.531	0.000	37.534	44.256
Chlorine dioxide 1%	Peracetic acid 0.1%	-31.804*	1.588	86.291	0.000	-35.681	-27.927
	Peracetic acid 0.2%	-40.895*	1.371	72.531	0.000	-44.256	-37.534
* Adjustment for multiple comparisons: Bonferroni.

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