Ⅰ. INTRODUCTION
Hospital-acquired infection not only leads to secondary diseases[1], but also may serve as a cause that results in diseases fatal to patients with reduced immunity[2].
The increased medical expenses and delayed patient recovery resulting from hospital-acquired cross-infection may result in a number of social costs, and, this may lead to degrading the medical quality, it is necessary to provide periodic control to guarantee patient safety and quality medical service[2].
The department of radiology in hospital is an essential factor for providing patients with imaging examination. In particular, radiologists in charge of radiography serve as an important point where a number of bacterial cross infections, including microbial infections, may occur due to direct contact made with patients or indirect contact made through radiation generating devices. Ministry of Food and Drug Safety reported that chest x-ray imaging is an essential inspection that accounts for approximately 27.5% of all the radiological imaging examinations[3,4].
In the preceding studies, microbial observation studies were conducted in the radiology department, centered on general hospitals, and studies were conducted to observe microbes in imaging IPs and cassettes. All of them were characterized by being a cassette part of the space and close proximity of patients, and this paper attempts to proceed with microbial collection centered on the equipment.
The purpose of this study was to classify the points that make frequent contact with patients and with radiologists during such x-ray imaging, to analyze the types of microorganisms existing at those points, and to collect and analyze the data for preventing hospital-acquired cross-infection in the future.
Ⅱ. MATERIAL AND METHODS
To conduct this study, Hospitals A and B located in Daegu were selected the experiment subjects, and the microbial sampling was conducted from September 2020 to October 2020.
1. Study Subjects
General imaging equipment (DRGEM, E7239X) was used to sample microorganisms as shown in Fig. 1. In detail, the sampling was focused mainly on the tube handle serving as the main point making contact with radiologists, and on the chin supporting device, chest-contact point and patient handle serving as the main points making contact with patients during x-ray imaging.
Fig. 1. (A) X-ray tube handle, (B) Chin region, (C) Chest region, (D) Palm region.[5]
As far as the sampling process is concerned, once disinfected with Aniosurf, the patient imaging took place, and, after the imaging, sterile cotton-tipped swabs were used to sample the microorganisms from the above points each limited to an area of 10×10cm2.
According to a thesis by Jung Woo Chan et al.[5], it was confirmed that most of the bacteria became extinct after they were sterilized with Aniosurf-diluted solution. therefore, the disinfection process was conducted in advance using Aniosurf.
2. Study Methods
2.1 Disinfection Methods
The original Aniosurf (ANIOS, ANIOSURF Premium NPC) solution was diluted by a factor of 400, the disinfection took place, the disinfected objects were allowed to stand for 15 minutes, and the patient imaging took place.
2.2 Sampling Methods and Microbial Incubation
After the sampling process, to examine to microbial status, TrransystemTM(TransystemTM, Copan Diagnostics Inc., Murrieta, CA, USA) shown in Fig. 2 was used to store and transport the samples.
Fig. 2. Transystem TM.[5]
To accurately confirm the sealed samples, it was necessary to move the samples to the microbial test room as soon as possible. Therefore, the microbial analysis was initiated within 24 hours.
The test was conducted within the biosafety cabinet, the innoculation was conducted based on the horizontal stroke method using blood agar (synergy innovation), and the incubation was conducted for 48 hours within an incubator under the following conditions: 37℃ and 5% CO2.
2.3 Identification
The cultured strain parts forming a single colony were used in the identification test, and, for each single colony, the bacterial solution was manufactured by using the turbidity meter to adjust the turbidity to No. 0.5(McFarland).
The identification process was conducted using the MICROSCAN (Dade Behring, West Sacramento, CA, USA) automated device, and the results were acquired as shown in Fig. 3.
Fig. 3 Microbial identification result.
Ⅲ. RESULT
The microbial identification was conducted at the points making frequent contact with radiologists and with patients during radiological imaging examination (x-ray imaging), and the results were as follows. The collected samples were classified through the dust spot method, and the bacteria of the number of microorganisms were proposed using the colony forming unit(colony forming unit: CFU/plate).
1. Points Making Frequent Contact with Radiologists
Radiologists make direct contact with the tube handle of the radiation generating device during patient positioning and radiography. Table 1 shows the microbial identification results acquired from the handle of the radiation generating device. A total of 4 types were detected as follows and showed a value above 103 CFU: Bacillus spp., Candida spp., Proteus mirabilis, and Staphylococcus epidermidis.
Table 1. Microorganism detection by site
2. Patients
Table 2 shows the microbial identification results acquired from each point making frequent contact with patients. From the chin supporting device, proteus mirabilis, enterococcu faecium, pseudomonas aeruginosa, and NTM were detected, and, from the chest-contact point, proteus mirabilis, enterococcu faecium, and pseudomonas aeruginosa were detected, and all of them showed a value above 103 CFU (Colony Forming Unit). From the palm-contact point, NTM and candida spp. were detected and showed a value of 105 CFU (Colony Forming Unit). In total, 5 types were measured.
Table 2. Microorganism detection by site(Pt)
Ⅳ. DISCUSSION
Hospital-acquired infection refers to the infection occurring in patients within 72 hours (within 30 days for surgical patients) after admission at the hospital that was neither present nor incubating at the time of admission, and such infection includes the infection occurring in not only patients, but also hospital employees[7,8]. To prevent such infection. it seems necessary to avoid making contact with contaminated medical devices or contaminated patients to the utmost extent possible by classifying infections into endogenous infections and exogenous infections. A pre-existing study reported that approximately 50% of the hospital-acquired infections are caused by the tools used in hospital[9,10]. To prevent hospital-acquired infections, disinfecting and sterilizing medical instruments can be said to be the most important factor.
As far as radiography is concerned, Ministry of Food and Drug Safety announced that chest x-ray imaging is the most frequently executed imaging method from among various imaging methods[3.4].
Since it is the most basic examination, it is a fact that such imaging can be frequently exposed to microorganisms or bacteria. Accordingly, to prevent radiologists, related operation participants and personnel having frequent access from causing cross-contamination, close-contact points are required to be disinfected to a substantial extent[3,4].
According to a research by Jeong Woo Chan et al.[5], points having frequent contact with radiologists and with patients were selected as the research subjects, and Aniosurf (ANIOS, ANIOSURF Premium NPC) was used to conduct the pre-/post-disinfection microbial analysis. Based on the results, it was confirmed that the disinfection effect was approximately 90%, and, in some cases involving Bacillus spp., it was revealed that the microorganisms were not perfectly removed and that it was necessary to conduct an additional disinfection,
Of the detected microorganisms, Staphylococcus epidermidis is a bacterium that exists on human skin and is the most frequent hospital-acquired infectious bacterium. In the case where such bacterium is injected into veins through a prosthetic device, it is known to lead to virulence, causing septicaemia at a common frequency[12].
Pseudomonas aeruginosa detected from the patients was reported to cause pneumonia and various types of septicaemia, and was reported to develop a genetic tolerance to a number of antibiotics[13]. Enterococcu faecium is a type of enterococci that exists as commensal bacteria, and the presence of it means that the environment can be unsanitary due to actions such as not washing hands after using toilet[14]. In addition, since candida spp. injected into patients with reduced immunity through the veins or blood flow may cause abscess, thrombophlebitis, endocarditis, eye infection or other organ-related infections, it is necessary to take caution[14,15].
According to Bae et al[16], 7 kinds of bacteria were detected in the microbial measurement using the cassette and IP used for radiographic imaging. Two (ABA) sites, Bacillus sp, Coagulase-negative Staphylococci (CNS), and 1 Enterococcus sp (ENT) were detected. All except ABA were Gram positive bacilli, and only 3% reported that Gram positive bacilli were detected. In this study, micro-organisms were observed centering on the imaging device, but Bae et al. used the cassette and IP used for radiographic imaging, so it seems that more types of micro-organisms were observed as the degree of direct contact increased.
HS Shin et al[17] analyzed radiology and infection control in a general hospital, and Staphylococcus, Micrococcus, Pseudomonas stutzeri, and Pseudomonas oryzihabitans were observed. The above paper identified microbial strains in five general hospitals, suggesting that the pathogens of nosocomial infection may be different for each hospital, and at the same time, it shows that pathogens exist in all hospitals.
based on the results acquired in this study, it was confirmed that opportunistic bacteria exist at points making frequent contact with radiologists and with patients, and it was determined that it would be necessary to comply with the hand sanitation and in-hospital disinfection rules to prevent hospital-acquired infections.
The limitation of this paper is that the number of microbial collections is insufficient. In future studies, it is thought that more times of microbial collection and the method according to the collection of microorganisms should be studied differently.
Ⅴ. CONCLUSION
Based on the results acquired from the microbial measurement focused on points making frequent contact with radiologists and with patients during radiological imaging, it was confirmed that proteus mirabilis, staphylococcus epidermidis, bacillus spp., and candida spp. were detected from the points making contact with radiologists, and that proteus mirabilis, enterococcu faecium, pseudomonas aeruginosa, NTM, and candida spp. were detected from the points making contact with patients. Although most of them were revealed as microorganisms that become extinct as disinfection takes place, it is necessary to be aware that the secondary infection may occur in hospital at all times. In particular, since the types and number of microorganisms detected from the points making contact with patients were greater than those detected from the points making contact with radiologists, it is thought that it would be necessary to make stricter efforts to control infections resulting from the equipment with which patients make more frequent contact.
참고문헌
- H. S. Kim, "Effects of Hand Washing Enhancement on Improving Hand Hygiene Performance and Reducing Hospital Infection", Korean Society of Clinical Pathologists Association, 53rd Annual Meeting Abstract, 2015.
- M. S. Song, "A Study on the Awareness and Practice of the Nurce's on the Nosocomical Infection", Masters of Nurse, Dan Kook University, Korea, 2001.
- J. S. Lee, K. H. Jeong, G. H. Kim, I. C. Im, D. C. Kweon, E. H. Goo, K. R. Dong, W. K. Chung, "Radiology Department Infection Control According to Radiography Frequency and Disinfection Period", Korean Radiation Society, Vol. 5, No. 2, pp. 73-80, 2011. http://dx.doi.org/10.7742/jksr.2011.5.2.073
- G. P. Kim, "Radiation exposure of Korean population from medical diagostic examinations", Ministry of Food and Drug Safety, Vol. 11, No. 579, pp. 213-217, 2013. https://doi.org/10.23000/TRKO201400011827
- W. C. Jung, K. S. Ahn, E. J. Yang, Y. J. Kim, "Research on ANIOS Disinfection Efficiency to Prevent Infection in Radiography Room", Journal of Korean Society Radiology, Vol. 15, No. 1, pp. 55-61, 2021. https://doi.org/10.7742/jksr.2021.15.1.55
- Ministry of Health and Welfare, "Guidelines for disinfecting instruments and articles used by medical institutions", Health and Welfare Department Notification, No. 2017-101, 2017.
- M. Hasan, H. Tuckman, R. Patrick D. Kountz, J. Kohn, "Cost of hospital-acquired infection", Hospital Topics, Vol. 8, No. 3, pp. 82-89, 2010. http://dx.doi.org/10.1080/00185868.2010.507124
- B. U. Wu, R. S. Johanes, S. Kurtz, P. A. Banks, "The impact of hospital-acquired infection on outcome in acute pancreatis", Gastroenterology, Vol. 135, No. 3 pp. 816-820, 2008. http://dx.doi.org/10.1053/j.gastro.2008.05.053
- J. H. Woo, M. S. Lee, M. H. Jeong, S. O. Lee, D. R. Jeong, E. O. Kim, "National Survey on the Current Status of Nosocomial Infection Control in Korea", Korean Society for Healthcare-associated Control and Prevention, Vol. 2, No. 2, pp. 177-202, 1997.
- H. J. Jeon, D. S. Jeon, J. R Kim, J. S. Kim, J. M. Kim, "Use of Antibiotics and Environmental Survey in Nosocomial Infection", Korean Journal of Laboratory Medicine, Vol. 5, No. 2, pp. 451-462, 1985.
- S. G. Shin, H. Y. Lee, "The Pathology of Infection in the Department of Radiology", Journal of radiological science and technology, Vol. 35, No. 3, pp. 211-218, 2012.
- J. W. Lee, K. J. Oh, S. C Park, J. S. Rim, "The Clinical Features of Complicated Urinary Tract Infections by Pseudomonas aeruginosa", The Korean Journal of Urology. Vol. 49, No. 12, pp. 1149-1154, 2008. http://dx.doi.org/10.4111/kju.2008.49.12.1149
- Ahu Karaa, Ilker Devrima, Nuri Bayrama, Nagehan Katipo glub, Ezgi Kiranb, Yeliz Oruc, Nevbahar Demirayc, Hurs, Apab, Gamze Gulfidand, "Risk of vancomycin-resistant enterococci bloodstream infection among patients colonized with vancomycin-resistant enterococci ", The Brazilian Journal of Infectious diseases, Vol.19, No.1 pp.58-61, 2015 https://doi.org/10.1016/j.bjid.2014.09.010
- C. d' Enfert, B. Hube, "Candida: Comparative and Functional Genomics", Caister Academic Press, Vol. 7, No. 6, pp. 616, 2007.
- F. H. Meyers, E. Jawetz, A. Goldfien, "Review of Medical Pharmacology", Lange Medical Publications. 1978.
- SH Bae, MS Lee, CS Lim, GJ Kim, "A Study on the Measurement of the Pollution Level of Bacteria and Disinfection of Table and IP Cassette", Journal of radiological science and technology Vol. 31 No, 3, pp.229-237. 2008
- J Shin, C Park, BK Jeon, "Analysis on infection control of general hospital radiology", Journal of the Korean Society of Radiology, Vol. 6, No. 5, pp..335-342, 2012 https://doi.org/10.7742/jksr.2012.6.5.335