Background
Nosocomial infections have become increasingly a major health concern in many hospitals worldwide [
1,
2]. Nosocomial infections account for about 1.4 million infections every year [
3].
Acinetobacter infections have frequently been reported as a major of nosocomial infections [
1,
4,
5].
Acinetobacter species, ubiquitous gram-negative coccobacilli, are widespread in nature, water and soil [
5,
6]. More than 20 species of
Acinetobacter have been characterized but only few species including
Acinetobacter baumannii,
A. calcoaceticus and
A. lwoffii play a significant role in nosocomial infections [
6]. However,
A. baumannii has the greatest clinical significance and identified as the causative agent of the majority of nosocomial infections especially in intensive care units (ICU) [
6‐
8].
A. baumannii can cause a wide range of infections including bacteremia, meningitis, urinary tract, bloodstream or surgical wound infections and ventilator associated pneumonia [
5,
6].
However, the emergence of antibiotics-resistant
A. baumannii especially, multiresistant strains seriously challenges the treatment of these infections [
9]. This is of special concern in developing countries, since antibiotic prescription rates and intake without prescription is markedly higher [
9]. Antibiotic resistance causing increased morbidity, mortality, and economic impacts on health services [
2]. Vulnerable groups of inpatients such as people with impaired host defenses are especially at high risk [
4,
10].
A. baumannii has the ability to survive for long periods and could easily spread in hospital environments [
5]. These traits could define its propensity for causing extended outbreaks [
5,
6].
A. baumannii is mainly transmitted by direct contact with infected persons or indirect contact with contaminated environments. However, airborne route also plays an important role in transmission of
A. baumannii infections in hospitals [
2,
11]. Although, airborne transmission was considered as a route for acquisition of
A. baumannii infections; there are very few studies in the field [
11‐
14].
Prevention and control of hospital infections require knowledge about the sources and reservoirs of nosocomial infection agents [
5]. In other words, identification of
A. baumannii sources in hospital environments improves the knowledge of potential routes of
A. baumannii transmission. Such information would also allow implementing more appropriate control policies against the spreading of
A. baumannii infections.
Based on these premises, the present study was carried out in order to 1) determine the occurrence of A. baumannii in air, water and inanimate surface samples in different wards of four educational hospitals 2) evaluate the antibiotic resistance of isolated A. baumannii 3) Evaluate the frequency of three common OXA-type carbapenemase-encoding genes in isolated resistant bacteria 4) analyze the molecular diversity of A. baumannii isolates by repetitive extragenic palindromic sequence PCR (REP-PCR).
Methods
The study was carried out from April 2014 to April 2015 in four educational hospitals of Isfahan University of Medical Sciences, Isfahan, Iran. Air, water and surface samples were taken in four locations in each hospital including operating theatres (OT), intensive care units (ICU), surgery wards (SW), and internal medicine wards (IM). Each hospital was visited 4 times and samples from various locations were taken on one single day after routine cleaning. A similar disinfection procedure was used for all hospitals. During the study period, patients, staffs, and patient attendants were present, but visitors were limited.
Air samples
A total of 64 air samples were collected at a calibrated flow rate of 10 l/min using an all-glass impinger (AGI), containing phosphate buffer solution. Air sampling was performed at a height of 1.5 m above the ground level to simulate the breathing zone and approximately 2400 L of air was collected using portable pump from each site. Temperature and relative humidity were recorded by use of a portable weather station (Kimo) throughout the sampling periods and were about 26 ± 2.3 °C and 28% ± 5.6%, respectively.
Surface samples
A total of 42 surface samples were taken from patient beds in SW, IM and ICU of four hospitals. Surface samples were obtained by swabbing of beds surface with a saline solution moistened cotton swab. After sampling, swab was placed into a sterile tube containing 2 mL of 0.8% salt water and was transferred to the laboratory.
Water samples
Sampling of tap water was done in 250 ml bottles containing thiosulfate from SW, IM and ICU of four hospitals.
All samples were transferred to the laboratory in an insulated box with cooling packs and processed immediately upon arrival in the laboratory.
Detection of A. baumannii
For detection of A. baumannii in air samples, aliquots of each impinger collection medium were plated onto blood agar and MacConkey agar after a vigorous shaking.
The saline suspension of surface samples was enriched overnight at 37 °C in brain heart infusion broth. Then, 0.3 ml of liquid broth transferred to each of the blood agar and MacConkey agar.
Water samples were filtered by membrane filtration (0.22 μm, 47 mm in diameter, Millipore) and then filters were placed on MacConkey agar plates.
All MacConkey and blood agar plates were incubated at 37 °C for 72 h. After incubation time non-repetitive colonies were isolated and confirmatory procedures by using conventional biochemical tests was performed [
1]. Suspected colonies were also further verified using the
Acinetobacter specific primer set Ac436F and Ac676r (Table
1), and
A. baumannii identification was further confirmed by polymerase chain reaction (PCR) amplification of the inherent blaOXA-51 gene (Table
1) [
12]. Confirmed
A. baumannii isolates were analyzed for antimicrobial susceptibility and also screened for the presence of three most common OXA- type carbapenemase-encoding genes.
Table 1
Primers used in the study
Ac436 Ac676 | TTTAAGCGAGGAGGAGG ATTCTACCATCCTCTCCC | 240 | 56 | |
OXA-51 | F: TAATGCTTTGATCGGCCTTG R: TGGATTGCACTTCATCTTGG | 353 | 57 | |
OXA-23 | F: GATCGGATTGGAGAACCAGA R: ATTTCTGACCGCATTTCCAT | 501 | 54 | |
OXA-24 | F: GGTTAGTTGGCCCCCTTAAA R: AGTTGAGCGAAAAGGGGATT | 246 | 54 | |
OXA-58 | F: AAGTATTGGGGCTTGTGCTG R: CCCCTCTGCGCTCTACATAC | 599 | 54 | |
REP | REP1: IIIGCGCCGICATCAGGC REP 2: ACGTCTTATCAGGCCTAC | - | 43 | |
Antimicrobial susceptibility testing
Antimicrobial susceptibility analysis of the isolates was performed by disc diffusion method on Mueller–Hinton agar using ceftazidime (30 μg), imipenem (10 μg) and gentamicin (10 μg) according to the recommendations of the Clinical and Laboratory Standards Institute (CLSI) [
15]. For quality control, standard strain of
E. coli (ATCC 25922) was used.
Detection of OXA-type carbapenemase-encoding genes
A. baumannii isolates were screened for 3 common OXA-type carbapenemase-encoding genes including blaOXA-23, blaOXA-58 and blaOXA-24 by PCR amplification with specific three sets of primers (Table
1).
PCR amplification
A loopful of each isolate was put into 100 μl of deionized water. Then the suspension was vortexed and DNA was extracted by boiling for 15 min and centrifugation at 13,000 rpm for 10 min. Supernatant was used for PCR amplification. All PCR reactions were performed in a final volume of 25 μl containing 2.5 μl of 10x PCR buffer (2 mM MgCl
2), 0.2 μM of each primer, 0.2 mM of each of the dNTPs, 2 units of Taq DNA polymerase, and 2 μl template DNA. The PCR cycling conditions were as follows: initial denaturation at 94 °C for 5 min, followed by 35 cycles of 45 s at 94 °C, primer annealing at varied temperatures (Table
1) for 45 s, primer extension at 72 °C for 45 s, and final extension at 72 °C for 10 min. All PCR assays included positive (
A. baumannii, ATCC 19606) and negative controls. PCR products were analyzed by electrophoresis using 1.5% (w/v) agarose gel. Gels were analyzed using an ultraviolet (UV) transilluminator (UV Tech, France).
REP- PCR
Genotype comparison was carried out for evaluating clonality of the isolates. The primers REP1 and REP2 (Table
1) were used and PCR amplification of the isolates was performed as described previously [
16].
Discussion
Over the past two decades, antibiotic resistant
A. baumannii has emerged as one of the most problematic hospital acquired pathogens [
4,
17,
18].
The results of this study showed the presence of
A. baumannii in various hospital environments including air, inanimate surface and water.
A. baumannii was isolated from 11% (7/64) of air samples. Other investigations on hospital air also reported the presence of
Acinetobacter species and
A. baumannii [
12‐
14,
19]. In the study of Gao et al. [
12] on air samples from burn wards of a general hospital in China, 16 samples were found positive for
A. baumannii. However, the majority of air samples were negative. Munoz-Price et al. [
14] also reported the presence of
A. baumannii in 22.6% (12/53) of air samples in a trauma ICU. Our results showed that the highest detection was related to ICUs. It has been demonstrated that
A. baumannii is responsible for a high percentage of ventilator-associated pneumonia which occurs predominantly in ICU patients with mechanical ventilation [
1,
4]. There is some evidence that hospital air plays a significant role in the transmission of
A. baumannii infections [
2,
11]. Bernards et al. [
20] reported the airborne route of
A. baumannii outbreaks in two Dutch hospitals.
A. baumannii aerosols could be released from various sources including respiratory droplets produced by patients, ventilation and air conditioning systems and also ward activities such as those generated by bed making and mechanical floor cleaning [
2,
13,
21].
Analysis of water samples revealed the presence of
A. baumannii in one sample of SW. Hospital water systems were known to be colonized by some nosocomial pathogens such as
Legionella pneumophila and
Pseudomonas aeruginosa and could act as a potential source for aerosolized nosocomial pathogens [
22,
23].
It is also possible that airborne bacteria deposited on inanimate surfaces [
2]. Our results showed that 17% (7/42) of patient beds were contaminated with
A. baumannii and ICUs had the highest rate of contamination. Study of Custovic et al. [
4] showed that 17.7% (31/175) swabs were taken from hospital surfaces, medical equipment and hands of medical staffs were positive for some nosocomial pathogens with the highest isolation rate of
A. baumannii (51.6%).
Detection of
A. baumannii in air, water and inanimate surface samples revealed that hospital environments could act as a potential route for transmission of
A. baumannii infections especially in ICUs. Several studies demonstrated the relation between
A. baumannii outbreaks and environmental sources such as patient beds, air conditioners and ventilation equipment. In the study of Aygun et al. [
24]
A. baumannii was isolated from 39.3% (22/59) environmental samples obtained by swabbing in ICU. They concluded that environmental contamination has an important reservoir role in outbreaks of
A. baumannii in ICUs. Results of Tena et al. [
25] showed that all five clinical isolates and one environmental isolate belonged to a single clone. Based on the clonal relationship of the isolates by pulsed-field gel electrophoresis (PFGE), they concluded that the infection source has probably been the hands of the healthcare workers [
25]. Similarly, Cicek et al. [
7] suggested that all the patients and environmental isolates were derived from a common source.
A. baumannii isolates showed the highest resistance towards ceftazidime (92.5%, 37/40). It has been reported that a high portion of clinically isolated
A. baumannii are resistant to cephalosporins such as ceftazidime [
18]. Our results also showed that a high percentage of
A. baumannii isolates were resistant to imipenem (85%, 34/40) and all air isolates were multidrug resistant [
6]. In consistent with our results, Gao et al. [
12] reported that 93.75% (15/16)
A. baumannii isolates from air samples were resistant to imipenem. Carbapenems resistant strains of
A. baumannii have been associated with considerable mortality and hospital costs [
26,
27]. Crude mortality of infections caused by these strains ranges from 16 to 76% [
27]. High resistance rate of
A. baumannii to carbapenems has been frequently observed in clinical isolates [
4,
28]. However, some European studies reported much lower resistance to carbapenems [
28]. Antimicrobial susceptibility analysis revealed the lowest resistance towards gentamicin.
However, 67.5% (27/40) of
A. baumannii isolates were multidrug resistant [
6]. Multidrug resistant
A. baumannii, in particular carbapenem resistant has a propensity to cause hospital infections [
18].
The results showed that OXA-23 was the most frequent gene (77.5%, 31/40) detected in
A. baumannii isolates. The OXA-23 gene was detected in all of air isolates except one isolate. This result suggests that the OXA-23 was the main cause of the resistance of
A. baumannii isolates from air, water and surface samples in our hospitals. Other investigations also reported OXA-23 group as the most prevalent carbapenemase-encoding gene [
18]. Gao et al. [
12] also found 15/16 strains from air samples were positive for OXA-23 gene. Pajand et al. [
10] reported a high prevalence of blaOXA-23 (68%) in carbapenems resistant
A. baumannii isolates. However, we could not detect any OXA-58 gene and OXA-24 was found only in two isolates of air samples. In the study of Gao et al. [
12], OXA-24 and −58 were not detected in any air isolates. Tena et al. [
25] detected OXA-24 carbapenemase in all five isolates from patients and one isolate from surface of a serum container. Conversely, studies in Italy reported the frequent isolation of OXA-58 producing
A. baumannii [
29].
Genotype comparison of the 40 isolates showed 10 distinct patterns. REP-PCR results analysis showed no high similarity between air, surface and water isolates from various wards. A unique REP-PCR profile was only observed in isolates from a surface sample of SW in hospital A and air sample isolate of ICU in hospital C. These results demonstrated that A. baumannii isolates were derived from various sources in hospital environments.