Prevalence of methicillin resistant Staphylococcus aureus in Lumbini Medical College and Teaching Hospital, Palpa, Western Nepal

Background

Multidrug resistant Staphylococcus aureus is common in both tertiary and primary health care settings. Emergence of methicillin resistance in S. aureus (MRSA) along with macrolide, lincosamide, streptogramin B (MLSB) has made treatment of Staphylococcal infection more challenging. The main objective of this study was to detect MRSA, MLSB (inducible; MLSBi and constitutive; MLSBc) resistant S. aureus using phenotypic methods and to determine their antibiogram.

Methods

Various samples were collected from 1981 patients who attended Lumbini Medical College and Teaching Hospital (LMCTH) during the period of 6 months from September 2015 to February 2016. Out of a total of 1981 samples, 133 S. aureus were isolated. Cefoxitin was used to detect MRSA by the disk diffusion test. Inducible clindamycin resistance (MLSBi) was detected by the D-zone test. The antibiotic profile of all isolates was tested by a modified Kirby Bauer disk diffusion method.

Results

Among 133 S. aureus, there were 58 (43.6%) MRSA, 34 (25.6%) MLSBi and 30 (22.6%) MLSBc. Of a total of 64 MLSB, a significant proportion (62.5%) was MRSA (p < 0.001). Among 11 different antibiotics that were tested for S. aureus, MRSA showed significant resistance to 9 (p < 0.05) with the exception of vancomycin and linezolid. All the isolates were 100% sensitive to linezolid. MLSBi organisms were 100% sensitive to vancomycin and linezolid. Both MLSBi and MLSBc showed a higher degree of resistance to multiple antibiotics (p < 0.05).

Conclusions

Isolation of MRSA, MLSBi and MLSBc were remarkably high. Routine use of simple and cost effective methods such as the disk diffusion test by cefoxitin for MRSA and the D-zone test for MLSBi organisms can easily identify these isolates. Antibiotic resistance profiles from this study can optimize the treatment of multi-drug resistant S. aureus.

Staphylococcus aureus is one of the common pathogens isolated in most microbiological laboratories [1]. It is responsible for a wide range of infections including superficial skin infections, food poisoning, osteomyelitis and septicemia [2]. Treatment of infections caused by MRSA is challenging as these organisms are resistant to currently available antibiotics [3]. A lack of newer drugs to keep pace with these superbugs has impelled the precise identification of the organisms and use of the available antibiotics on the basis of antibiotic susceptibility tests. Thus the cautious use of available antibiotics and the addition of newer effective drugs is recommended to treat the multi-drug resistant strains [4].

In Nepal, various laboratories have reported the emergence of multidrug resistant organisms such as extended spectrum beta lactamase producing organisms (ESBL) [5], vancomycin resistant enterococcus (VRE) [6], penicillin resistant Streptococcus pneumoniae [7] and MRSA [1, 3, 8].

MRSA is an important group of multidrug resistant organisms responsible for increasing the rate of morbidity and mortality [9]. These organisms are most commonly found in nosocomial infections, however, community-associated MRSA have been detected in recent years in laboratories which are additionally virulent and transmissible [10]. The macrolide group of drugs is generally chosen for oral treatment of these infections which are also the alternative drugs for patients allergic to penicillin. Macrolides such as clindamycin are useful for treating skin and soft tissue infections caused by MRSA [11]. However, emergence of MLSB resistant S. aureus has jeopardized the treatment of such cases [12].

The presence of mecA gene located on cassette chromosome in S. aureus (SCCmec) is responsible for methicillin resistance [9]. This gene encodes penicillin binding protein 2A (PBP2A) which has a low affinity for methicillin. The Cefoxitin (30 µg) disk is used to detect MRSA by the disk diffusion method. S. aureus that are mecA positive should be reported as resistant to oxacillin and other β-lactam antibiotics [13].

There are various methods for detection of MRSA in a microbiology laboratory. Screening of MRSA is commonly performed by molecular and culture methods. In resource limited laboratories, culture is still the efficient method for MRSA identification. The culture method has also been used in Europe as a cost-effective method to detect MRSA [14].

MRSA commonly exhibit resistance to MLSB in addition to many other antibiotics. MLSB resistance is due to methylation of 23S rRNA-binding which is encoded by an erm gene. Inducible MLSB resistance (MLSBi) is detected by the D-zone test [12].

To date there have been no studies, particularly in the western region of Nepal to detect MRSA and MLSB. Use of simple and cost effective methods in this study can enhance the identification of these organisms and direct the appropriate treatment. We hypothesized that MRSA and MLSB organisms are prevalent in tertiary level hospitals and are resistant to multiple antibiotics. Thus the specific objective of this study was to determine the prevalence of these organisms and to explore their antibiotic profile.

We report a cross-sectional study conducted from September 2015 to February 2016 at Lumbini Medical College and Teaching Hospital (LMCTH), Palpa, Nepal. LMCTH is a tertiary care teaching hospital affiliated with Kathmandu University in Palpa district in the western region of Nepal. This hospital has 600 beds and 20–30 patients get admitted to different departments every day. The hospital serves patients from Palpa and the surrounding districts. The microbiology laboratory in this teaching hospital receives up to 20 samples of culture daily from Out Patient Department (OPD) and wards/In Patient Department (IPD).

Sample collection

All samples (blood, sputum, urine, pus and body fluids) of patients who attended the hospital for treatment were collected from various departments for culture after the treating clinician requested them. Collected samples were received at the microbiology laboratory for microbiological tests. Sterile containers were used for sample collection using the aseptic technique. The clinicians responsible for the treatment of patients requested all received samples.

Culture and bacterial identification

Samples were inoculated into McConkey’s agar and blood agar, however, selective media for S. aureus was not used. The gram stained smear of the suspected colonies was observed under an oil immersion lens. Gram positive cocci in clusters were subjected to further biochemical tests. S. aureus was identified by standard microbiological techniques [2]. Different biochemical tests such as catalase, coagulase and mannitol fermentation tests were performed. Gram positive cocci (GPC) in clusters, which were also catalase positive, were subjected to a slide coagulase test. GPC, which were both catalase and coagulase positive, were considered as S. aureus. Those which were negative by the slide coagulase test were further subjected to a tube coagulase test and were considered S. aureus if were positive for both the catalase and tube coagulase tests. Finally, all S. aureus were confirmed by a mannitol fermentation test.

All S. aureus isolated from different samples during the study period were included in the study. However, only first isolate was included in the study if the same patient had other samples (blood, pus, body fluid and sputum) positive for S. aureus with same antibiogram. Organisms other than S. aureus, including coagulase negative Staphylococcus, were excluded from the study. In addition, various characteristics of patients which included patient’s history, clinical conditions; such as patients with a ventilator, urinary catheter, central line; and patients from different departments such as Intensive Care Unit (ICU) and wards were analyzed for their association with the MRSA infection.

Antibiotic susceptibility testing of S. aureus

Antibiotic susceptibility tests of the S. aureus were performed by a modified Kirby–Bauer disk diffusion method according to the guidelines of the Clinical and Laboratory Standards Institute (CLSI 2012) on Mueller–Hinton agar (MHA) [13]. Antibiotic disks (HiMedia Laboratories, Pvt. Limited, India) such as oxacillin (1 μg), cefoxitin (30 μg), penicillin G (10 U), cefazolin (30 μg), cephalexin (30 μg), ceftriaxone (30 μg), ciprofloxacin (5 μg), amoxiclav (20 + 10 μg), tetracycline (30 μg), erythromycin (15 μg), co-trimoxazole (25 μg), gentamicin (10 μg), amikacin (30 μg), clindamycin (2 μg), vancomycin (30 μg), and linezolid (30 µg) were used for antibiotic susceptibility tests.

Identification of MRSA

Both oxacillin (1 μg) and cefoxitin (30 µg) are used for identification of MRSA. Cefoxitin is considered more accurate than oxacillin. The sensitivity and specificity of the cefoxitin disk to detect MRSA is in concordance with that of mecA gene detection by polymerase chain reaction (PCR) [15]. S. aureus, which showed a zone of inhibition ≤21 mm with cefoxitin (30 µg) on MHA after overnight incubation at 35 °C, were considered as MRSA [13].

Identification of MLSB resistant strains

Staphylococcus aureus resistant to macrolide, lincosamides and streptogramin B are known as MLSB. Similarly, MLSBi are inducible clindamycin resistant strains which were detected by a disk approximation test. A lawn culture was prepared on MHA with the bacterial suspension equivalent to the turbidity of 0.5 McFarland’s standard. A clindamycin disk (2 μg) was placed 15 mm away from the edge of an erythromycin disk (15 μg) on a MHA plate [13]. After 18–24 h of incubation, organisms that showed flattening of the clindamycin zone of inhibition adjacent to the erythromycin disk (“D” zone) were considered to be MLSBi. A zone size of ≤13 mm around erythromycin and ≤21 mm around clindamycin were considered as resistant. Organisms which were resistant to both antibiotic disks were taken as MLSBc. Organisms were considered as MS (macrolide streptogramin) phenotype when they were resistant to erythromycin and sensitive to clindamycin with a negative D test. Isolates which are sensitive to both erythromycin and clindamycin were reported as erythromycin and clindamycin (ERY, CL) sensitive phenotype [16]. S. aureus ATCC 25923 was used as a standard control strain.

Statistical analysis

Data were analyzed by IBM SPSS statistics 21 software. Frequency and percentage for descriptive and Chi Square test with cross tab for inferential statistics were used.

A total of 1981 samples (blood 647, pus 188, swab 321, body fluid 354 and urine 471) from patients attending the hospital for treatment were collected and analyzed. From the total of 1981 samples, 133 were confirmed as S. aureus and were further tested for MRSA and MLSB. The drug profile of isolates was tested for 11 different antibiotics.

The maximum number of S. aureus were found in children <10 years (49.1%) and higher incidence of MRSA infections were found in males (52.4%). However, both failed to elicit a statistically significant difference. High proportion of blood samples contained MRSA (49.2%). A higher proportion (54.2%) of MRSA was derived from ICU. Blood culture is more common among younger patients and children owing to the higher attendance and morbidity (Table 1).

The cefoxitin disk detected 58 (43.6%) MRSA while oxacillin detected only 43 (32.3%) which was statistically significant (p < 0.001) on post hoc analysis (not shown in the table). MRSA showed a higher degree of resistance to many antibiotics such as erythromycin (62.5%), ciprofloxacin (68.2%), cotrimoxazole (71.4%), gentamicin (73.5%), clindamycin (70.0%) and amikacin (100%) in this study. All the organisms were sensitive to linezolid (Table 2).

None of the characteristics of the patients (socio-demographic, urinary catheter, ventilator, central line, ICU stay, hospital stay and prior antibiotic use) were found to be associated with isolation of MRSA. MRSA infection was proportionally higher in patients with a central line and urinary catheter, however, the association was not statistically significant.

Out of a total of 64 isolates that showed resistance to erythromycin, 34 were identified as MLSBi by the D-zone test. MLSBi organisms were 100% sensitive to vancomycin and linezolid. Both MLSBi and MLSBc showed higher degree of resistance to multiple antibiotics. Consistently, the same three S. aureus were MLSBc as well, showing reduced susceptibility to vancomycin by disc diffusion method (Table 3).

MLSBi, MLSBc and Sensitive phenotype were 25.6, 22.6 and 51.9% of the total respectively. A higher number of MLSB resistant organisms (40/133; 62.5%) were resistant to methicillin (p < 0.001) (Table 4).

This study determined the prevalence of MRSA, MLSBi and MLSBc in LMCTH with their antibiogram. The cefoxitin disc (30 µg) was used to detect MRSA by the disk diffusion method. More than 2 in 5 isolated S. aureus were MRSA (43.6%). Findings in our study are consistent with the previous studies conducted in Nepal (Chitwan, 43.1% [1], Kathmandu, 42.4% [3]) and in India (40.2%) [12]. However, varying prevalence of MRSA has been reported from different parts of Nepal such as 26.1% in Dharan [8], 68% in Chitwan [17] and 57.1% in Birgunj [18]. The prevalence of MRSA in this study can alarm the majority of clinical settings, where the beta-lactam group of drugs are extensively used to treat bacterial infections. The development of proportionally high MRSA in these settings might have been due to the wide use of antibiotics available over the counter without specific laboratory tests.

Multidrug resistance patterns were more common in MRSA than MSSA. MRSA was more than 50% resistant to erythromycin, ciprofloxacin and cotrimoxazole. Similarly, a higher degree of resistance to other antibiotics was found in MRSA compared to MSSA. The findings in this study have been consistent with the findings from studies conducted in other parts of Nepal [3, 8].

For MRSA; beta-lactam drugs, beta-lactam/beta-lactamase inhibitor combinations, cephems and carbapenems; should be reported as resistant despite of in vitro susceptibility. However, all cephalosporins except anti-MRSA such as ceftaroline should be reported as resistant irrespective of their zone of inhibition once they are confirmed as MRSA.

On the other hand, methicillin-susceptible S. aureus (MSSA) are susceptible to other penicillins, beta-lactam/beta-lactamase inhibitor combinations. Thus routine testing of many beta-lactam drugs can be deduced by testing only penicillin and cefoxitin.

The burden of infections and overuse of antibiotics, (in Nepal all antibiotics are easily available “over the counter”) often without an antibiotic susceptibility test, can easily spread antibiotic resistance across the border, and therefore is a serious threat to the entire world [5, 19, 20]. Immediate strategies against “over the counter antibiotics” through amendment in policy, health education, mandatory antibiotic susceptibility tests before antibiotic prescription, increased funding for antimicrobial resistance through joint collaboration between national, regional and global partners are urgently required.

In this study, socio-demographic and clinical characteristics of patients were analyzed to explore the association with MRSA infection. However, none of these characteristics were found associated with MRSA. Findings in this study are not unique. In recent years, community-associated MRSA infections without any association with the characteristics of patients have been reported [21].

Resistance to the macrolide group of drugs in S. aureus has been reported from various parts of the world [11, 12]. In this study, more than 1 in 4 (25.6%) were found as MLSBi among 133 S. aureus, which is higher than in the previous study (10.8%) conducted in India [12]. Once the isolate is confirmed as MLSBi, clindamycin is reported as resistant. However, clindamycin could show a good zone of inhibition on MHA when tested independently in the absence of erythromycin. Most of the isolates, which showed MLSBi and MLSBc, were MRSA in this study which is consistent with a study conducted in Libya [22]. Combined resistance patterns (both MLSB and methicillin resistance) is common in S. aureus and bears limited treatment options such as oral cotrimoxazole and intravenous vancomycin. Precise identification, timely intervention with the appropriate antibiotic and prevention of transmission can decrease morbidity and mortality of patients in multidrug resistant Staphylococcal infections.

The current study was conducted in one single setting in the western region of Nepal. A multi-setting study within the region and beyond the region could have strengthened the findings. Findings from this study could have been strengthened if MRSA were classified as hospital acquired and community acquired. Nevertheless, the findings in this study can direct the appropriate treatment for a wide variety of infections caused by staphylococcus. The duration of 6 months was chosen arbitrarily to determine the prevalence of MRSA and MLSB resistant organisms in this study. A longer duration of study could have bolstered the findings. Advanced molecular techniques such as PCR could have added to the findings in this study, however, this was beyond the scope of this study.

This study showed high prevalence of MRSA, MLSBi and MLSBc in a tertiary care hospital in the western region of Nepal. The disk diffusion test by cefoxitin for MRSA and the D-zone test for MLSBi organisms are simple and cost effective methods and can be routinely utilized in resource limited settings to identify these isolates. Antibiotic resistance profiles in this study can direct the optimal treatment for multidrug resistant S. aureus infections. Similarly, S. aureus showed combined or isolated resistance patterns to methicillin and MLSB. MRSA were resistant to multiple antibiotics except vancomycin and linezolid. This warrants an urgent need of attention to the rational use of vancomycin as a last resort for MRSA. MLSBi detection in this study has demonstrated the limitation of clindamycin use. Further research on these organisms across various settings can explore the level and pattern of resistance over time.

MRSA:

methicillin resistant Staphylococcus aureus

MLSBi:

inducible macrolide, lincosamide, streptogramin B resistance

MLCBc:

constitutive macrolide, lincosamide, streptogramin B resistance

MS phenotype:

macrolide streptogramin phenotype

LMCTH:

Lumbini Medical College and Teaching Hospital

CLSI:

Clinical and Laboratory Standards Institute

MHA:

Mueller–Hinton agar

PCR:

polymerase chain reaction

VISA:

vancomycin intermediate Staphylococcus aureus

VRSA:

vancomycin resistant Staphylococcus aureus

SR, SSP and BA designed the concept of the study. SR, KB and JA performed the laboratory works. SR and BA drafted the manuscript. All authors read and approved the final manuscript.

Acknowledgements

We are grateful to Mrs. Kate Ale for her revisions and inputs in improving this manuscript. We express our gratitude to Mr. Gordon Tambellini for the suggestions on the final proof of the manuscript. We would like to appreciate reviewers’ contribution in improving the manuscript. We would also like to thank all the staff in the microbiology department of LMCTH for their kind cooperation and support.

Competing interests

The authors declare that they have no competing interests.

Availability of data and materials

All the data pertinent to this study are presented in the manuscript.

Consent for publication

Not applicable.

Ethics approval and consent to participate

Ethical approval was received from the Ethical board of Lumbini Medical College and Teaching Hospital, Prabas, Nepal. Informed consent was obtained from each patient before taking samples. In case of neonates and infants, informed consents were obtained from one of their parents.

Funding

No research fund was available for this study.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Authors and Affiliations

1. Department of Microbiology, Lumbini Medical College, Palpa, Nepal

   Shristi Raut, Kishor Bajracharya & Sushama Suresh Pant

2. B.P. Koirala Institute of Health Sciences, Dharan, Nepal

   Janak Adhikari

3. Mahidol-Oxford Tropical Medicine Research Unit, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand

   Bipin Adhikari

Corresponding author

Correspondence to Shristi Raut.

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions