Methicillin-Resistant Staphylococcus aureus (MRSA)

Methicillin-Resistant Staphylococcus aureus (MRSA) is a pathogen that causes many complicated infections in humans. MRSA is a type of S. aureus that has produced by process of resistance to beta-lactam antibiotics, which include the penicillins (methicillin, dicloxacillin, nafcillin, Oxacillin, etc.) and the cephalosporins. In this study isolation of Methicillin-Resistant Staphylococcus aureus (MRSA) strains was done from various surgical and accidental wounds. A total of 150 Clinical specimens from surgical and accidental wounds were collected from different hospitals of Faisalabad and processed for isolation into Oxacillin broth and sub-cultured on CHROMagar’ MRSA. The isolates through ��-hemolysis on blood agar, clot formation by coagulase test. MRSA isolates were confirmed by latex agglutination test for the presence of Penicillin-Binding Protein 2a (PBP2a). All positive MRSA were molecularly characterize using PCR. The rate of prevalence of MRSA was found to be 91.7%, higher prevalence of MRSA was found in human males and in 21-40yrs age group. All MRSA isolates showed 100% resistance against Amoxicillin-Clavulanic acid, Ampicillin, Amoxicillin and Ciprofloxacin but sensitive to Vancomycin and Linzolid. Vancomycin (92%) was the most effective drug followed by Linzolid (90%). Present study conclude that high prevalence of MRSA was found in hospitals of Faisalabad, males were more prone to MRSA infection. All MRSA isolates were resistant to commonly used antibiotics only Vancomycin was the drug resistant against MRSA hence considered as the most effective drug.


The Staphylococci are the bacteria which are Gram-positive rounded cells, normally exist in the order of grape like clusters belong to family Staphylococcaceae. Staphylococcus aureus is the most common and ominous staphylococcal bacteria in this family. S. aureus is the cause of many infections but it may also occur as a beneficial bacteria. Tissues can be infectious with S. aureus on rupturing of skin or mucosal barriers. This rupture can cause different types of infections including blisters and abscesses. Due to their pathogenic nature staphylococci often hemolyze blood, coagulate plasma and produce a variety of extracellular enzymes and toxins. The more dangerous forms of S. aureus produce such toxins which are source of host tissue damages, hindering phagocytosis and causing disease symptoms (Lowy, 1998). In systemic infections, it causes osteomyelitis, mastitis, wound infection & occasionally toxic shock syndrome (Mahmood et al., 2010). The main cause of these infections are the toxins produced by staphylococci. For example S. aureus produce enterotoxins which are important source of food poisoning (Salyers and Whitt, 2002).
Post-surgical infections accounts for approximately one-fourth of all hospital acquired infections. Many risk factors for S. aureus infection are linked with patients stay in a surgical intensive care unit (SICU) in hospitals, i.e. care procedure numbers, nearness of infected patients, surgical wounds and foreign bodies presence and long-term antibiotic treatment (Longfield et al., 1985). Throughout the world, particularly in developing countries burn wounds remains an important problem of public health associated with diseases, long-term disability and mortality (Othman and Kendrick, 2010; Othman and Kendrick, 2011). The burned dead moist tissues, along with damaged tissues, provide a nutrient medium which will favor the growth of a many species of bacteria. In a definite part of burns this type of control of bacteria causes septicemia and death (Nakhla and Sanders, 1991).
In the North America almost 20% of all admissions are associated with foot infections which are the source of hospitalization of patients with diabetes (Bild et al., 1989). In diabetic foot ulcers (DFUs) staphylococcus aureus is the most common organism, minor or major amputations of the lower limbs (15’27%) are required by the patients of Diabetes mellitus and infection is the main reason in more than 50% of cases (Mendes et al., 2012). Diabetic foot infections caused by MRSA are linked with lethal results, i.e. slow healing and more repeated amputations, in compared to other pathogens (Lipsky and Stoutenburgh, 2005). In diabetic foot infections MRSA infection is common and is associated with increased time of healing with antibiotic treatment (Tentolouris et al., 1999). In developing countries like Pakistan MRSA infection has become a major ailment in hospitals and they have been a cause of increasing cost, disease rate and deaths associated with surgical operations.
The sensitivity shown by staphylococci against antimicrobial drugs is variable. Staphylococcal resistance falls into many classes. Under the control of plasmid the production of ��-lactamase is common, and to many penicillin groups it makes the organisms resistant (penicillin G, ampicillin, ticarcillin, piperacillin, and similar drugs). The production of ��-Lactamase does not depends upon methicillin resistance. For methicillin resistance the responsible gene mecA exists on the chromosomes. The resistance mechanism is related to lack of inaccessibility of certain penicillin-binding proteins (PBPs) in the organisms. There is a high attraction for antibiotics having ��-lactam shows by PBPs; in MRSA this attraction is decreased which results in resistance to antibiotics. A protein called as PBP2a, possess a less attraction to antibiotics, encoded by a mecA gene on chromosome (Cook, 1998). When the infecting strain is MRSA then there is a poor diagnosis of infections caused by S. aureus (Cosgrove et al., 2003). Increased synthesis of cell wall and modification of cell wall are associated with resistance mechanism and Van genes present in enterococci are not responsible for this.
Since first reported in 1961 (Jevons, 1961), number of diseases, death rate and treatment expenses associated with infection of skin and soft tissue, pneumonia associated with ventilator, bacteremia and many other nosocomial and community infections has been gradually increasing. Treatment and managerial costs associated with MRSA infections continue to increase whereas the number of effective antibiotics remains relatively constant (Krikland and Adams, 2008). Earlier the MRSA infection was detected in hospitals but now community associated MRSA is increasing also (Chambers, 2001). For example in large hospitals of US about 40% of infections of S. aureus are Methicillin-Resistant acquired (Red Book: American Academy of Pediatrics, 2003).
Transmission of MRSA occurs by direct contact to a colonized carrier. The main source of spread is from patient to patient on the hands of hospital staff. A study conducted in a nursing home where MRSA was found to be endemic in the past, the results indicated 65% patients were negative for MRSA, 25% were found to be colonized even before admission to the nursing home whereas 10% patients were found to acquire MRSA during their stay (Bradley et al., 1991). Health care workers (HCWs) possibly related to principles of hygiene regarding uniforms, equipment sterilization and washing, transmitting the pathogenic organisms on moving from patient to patient (Elmanama et al., 2013). Use of different types of antibiotics especially during long-term treatment and other factors related to MRSA colonization are; long-term hospital stay, burns, surgical wound care (Sanford et al., 1994). In recent US studies, in community the rate of prevalence of MRSA has ranged from 0.2% to 2.8% and prevalence is higher in poor & populated areas where use of injection drug is common (Frazee et al., 2005).
All over the world, increased prevalence and antibiotic resistant bacteria are the issues, faced by the hospitals. For public health and hospitals, antimicrobial resistance is becoming a matter of great concern. In USA, S. aureus is considered to be susceptible to vancomycin (Bhateja et al., 2006). Moreover, numerous reports of completely resistant S. aureus with respect to Vancomycin have also been published (Chang et al., 2003). It was described as ‘Superbugs’ MRSA organisms are generally resistant to many antibiotics including aminoglycosides, chloramphenicol, macrolides, flouroquinolones, clindamycin, trimethoprim and beta-lactams (Novick et al., 2001). Prevalence of MRSA infection is continuously elevating in many countries and in some hospitals (Voss and Doebbeling, 1995). In the developing countries like Nigeria the antibiotics are used without prescription of doctor and no control measures are adopted having no regulatory policies in this respect has make less effective antibiotics for the treatment of infections of S. aureus. (Onwubiko and Sadiq, 2011).

Keeping in view the importance of the subject, present study has been planned to achieve the following objectives:
1. Isolation, Identification and Molecular characterization of indigenous MRSA strains from accidental and surgical wounds.
2. Determination of Prevalence of MRSA in various kinds of wounds.
3. Study of Antimicrobial Susceptibility pattern of MRSA against commonly used antibiotics.

Lesseva and Hadjiiski (1996) studied the burn patients to estimate frequency, features and role of staphylococcal infections in the Sofia Burns Centre. The cause of wound infections and bacteremia in burned patients was studied for a period of 8 years (1987-94). Both in wound samples and blood cultures the prevalence of staphylococci was studied. From 19.4% to 28.0% in 1993-1994 the infections of MRSA have increased during the last year of the study. In 18.8 percent of patients MRSA was the cause of infection. Against gentamicin, and tetracycline more than 70 % of the MRSA strains were resistant and against lincomycin, co-trimoxazole, chloramphenicol and ciprofloxacinabout 1/3rd were resistant. Against Vancomycin all the MRSA strains were sensitive and to rifampicin 71.1 % were sensitive. These results shows the need of quick steps to control the more spread of MRSA infections in burn units.
Majumder et al. (2001) worked in a hospital in Assam-India to analyze the prevalence of methicillin resistant S. aureus infections. Resistance was 15% among coagulase negative staphylococci and 52.9% was among S. aureus isolates. 23.2% methicillin-resistant and 6.6% methicillin sensitive staphylococci were observed in antimicrobial susceptibility testing. Against most antibiotics the methicillin resistant strains were found highly resistant as compared to isolates which were methicillin sensitive.
Vidhani et al. (2001) worked on selective number of MRSA isolates in patients in burn and orthopedic units. The prevalence of MRSA among S. aureus was found to be 51.6% and isolates were multidrug resistant. The readability of these isolates was obtained 41.8% by the MRSA set of phages. From burns and orthopedic units prevalence of MRSA was observed high, against antibiotics all isolates were found to be highly resistant.
Supriya et al. (2002) studied the prevalence of MRSA: sensitivity pattern of antimicrobials and phage typing. Out of 230 isolates (19.56%) of S. aureus 45 were MRSA. From pus and wound swabs maximum numbers of MRSA (26.92%) were obtained. Beta-lactamase production was shown by all MRSA strains. All MRSA strains were multidrug resistant. Against penicillin (100%), cotrimoxazole (97%) and chloramphenicol maximum strains were resistant. Against gentamicin (6.66%) least resistance was observed. Against Vancomycin all strains were found to sensitive. Against ciprofloxacin 4.86 less resistance was observed while against gentamycin no strains of MSSA were resistant. Out of 44 strains 28 were non-typeable for Oxacillin by phage values less than ug/ml. MIC values 4ug/ml were shown by maximum number of isolates. MIC of 12ug/nil was shown by 9 and MIC values of 250 ��g/ml was shown by 2 strains. For phage typing 28 were non-typeable out of 44 strains subjected. 11 strains were from mixed group, while 4 were from the group three indicating hospital strains.
Lipsky and Stoutenburgh (2004) analyzed a set of diabetic patients with an infected ulcer enrolled in two controlled trials of patients with complicated skin and soft-tissue infections (Gram-positive organisms) to compare the effectiveness of daptomycin against penicillins or vancomycin. 103 were important clinically out of 133 patients with a diabetic ulcer infection; dapatomycin was received by 47 and 56 received a comparator of daptomycin. Staphylococcus aureus was the prevailing organism and most infections were monomicrobial. Treatment with dapatomycin and comparators both had most strict stagesof severity, generally well tolerated.
Orrett and Land (2006) studied the isolates at a regional hospital in Trinidad to determine the prevalence of methicillin resistance and found the current resistance pattern of MRSA and MSSA against commonly used antibiotics. Over a period of 6-year 2430 isolates of S. aureus were obtained from various nosocomial and community sources. MRSA prevalence were 60.1%, 15.5% and 6.6% from surgical/burn wounds, urine and pus/abscess. Against erythromycin (86.7%) and clindamycin (75.3%) greatest prevalence of resistance of MRSA was seen. For ampicillin (70%) highest resistance rates were shown by MSSA. Resistance rates were (78.7%) and (73.5%) shown by MRSA and MSSA against tetracycline. There is an increase MRSA prevalence was found in hospital from 12.5% in 1999 to 20.8% in 2004.””��
Harbarth et al. (2008) designed a study to compare 2 MRSA control conditions between July 2004 and May 2006 from 21754 post-surgical patients and to analyze effect of the finding of detected MRSA on hospital acquired MRSA infection rates in patients. During the interference periods 10193 of 10844 patients (94%) were screened. Out of 515 identified MRSA positive patients 337 were previously unknown carriers of MRSA. In comparing with 76 in the control periods, 93 patients developed nosocomial MRSA infection in the intervention periods. At the time of admission 93 of infected patients, 53 were MRSA-free and during hospitalization MRSA infection was developed.
Tillotson et al. (2008) worked during the years 2005-07 to analyze the rates of antimicrobial susceptibility of S. aureus from skin and wound infections reported from nine regions of the USA. Over 380 000 isolates of S. aureus were tested and reported for the period 2005-07. With little change from 2005 Methicillin resistance was observed in 57.8% in 2007. Against trimethoprim/sulfamethoxazole and gentamicin high activity was observed. Linezolid resistance was rare. No resistance mechanism was shown by less than a third of all isolates. 46% of all resistant strains showed 3 distinct resistance. Overall, there were more highly drug-resistant isolates from the ICU with four, five or six drug-resistant phenotypes accounting for over a third of all strains.
Tiwari et al. (2008) studied the prevalence of multidrug resistant MRSA strains in clinical specimens and sensitivity pattern of these strains against various antibiotics used for treating hospitalized and out patients. Among 783 isolates of S. aureus 301 (38.44%) were Methicillin-Resistant, of which 217 (72.1%) were found to be multidrug-resistant. Almost all MRSA strains were resistant to penicillin, 95.68% were resistant to cotrimoxazole, 92.36% were resistant to chloramphenicol, 90.7% were resistant to norfloxacin, 76.1% were resistant to tetracycline, and 75.75% were resistant to ciprofloxacin. Vancomycin was the most effective drug with only 0.33% of MRSA strains being resistant to it.
Thyagarajan et al. (2009) analyzed 440 patients, sequentially admitted to the trauma unit with hip fracture. 5.2% (21/403) were found to be colonized with MRSA out of the 403 who had a swab on admission. Colonization rate of patients with MRSA was as follows; 52 percent of MRSA colonized patients were admitted from their own home, 29% from residential homes and 19% from nursing homes. MRSA colonization was found in 3.6% of patients admitted from their own home, 10.9% of residential home patients, and 17.4% of nursing home patients. The high prevalence of previous hospitalization among people from institutional care may explain the higher rates of MRSA carriage among these individuals a high proportion (80.9%) of colonized patients had been admitted to a hospital within the previous one year.
Shukla et al. (2009) examined patients admitted to the Leicester Royal Infirmary Trauma Unit between January 2004 and June 2006 to find the incidence of infection with Methicillin-Resistant Staphylococcus aureus (MRSA). Using multi-variant analysis the status of MRSA at the time of their admission was examined, together with age, gender and diagnosis. Out of 2473 patients 2394 (96.8%) were MRSA-negative and 79 (3.2%) were MRSA carriers. The chances of developing surgical site infections with MRSA was more in patients those carrying MRSA at the time of admission than non-MRSA carriers. Risk factors of MRSA infections analyzed in the study included hip fracture and increasing age. Increased rate of developing MRSA wound infection is associated with MRSA carriage at admission, age and the pathology.
Wang et al. (2009) analyzed the distribution, drug resistance and epidemiology of pathogenic bacteria in the burn wards of Ruijin Hospital. From January 2004 to December 2006 17 strains of Methicillin resistant staphylococcus aureus (MRSA), 52 strains of Pseudomonas aeruginosa (PA) and 11 strains of Acinetobacter baumannii (AB) isolated from the wound secretion, venous catheters, blood, urine and stool etc. were collected from burn patients. MRSA, PA and AB were the major strains in burn wards in recent years, of which Staphylococcus aureus was the most dominant. During these 3 years, MRSA accounted for 77% (63/82), 85% (63/74), and 75% (74/99), respectively. PA was resistant to Amikacin, Gentamicin, Piperacillin, Ceftazidime, Cefoperazone, Aztreonam and Imipenem; MRSA was resistant to Amikacin, Gentamicin, Erythromycin, Clindamycin and Levofloxacin; AB was resistant to Amikacin, Gentamicin, Piperacillin, Ceftazidime, Imipenem and Ciprofloxacin. In the randomly amplified polymorphic DNA (RAPD) homology analysis three bacteria were found to belong the same type.
Recinos et al. (2009) worked from April 2003 to April 2007 to identify all trauma patients surviving 48 hours or more that had a positive culture result during their SICU stay. Examination of cultures was made and 582 SICU patients with 2860 cultures were assessed for MRSA infection. 36 patients were reported as MRSA positive among 368 cultures (12.9%). Criteria for a CA-MRSA infection was fulfilled by 13 patients. No significant difference in mortality (8.7% vs 15.4%, P = 0.540) or hospital related charges ($364,231 +/- 323,719 vs $242,458 +/- 276,630, P = 0.091) was noted when results were analyzed. Among critically ill trauma patients MRSA constituted an important source of infection.
Delorme et al. (2009) performed a survey on all staphylococcal infections diagnosed by the Ashtabula County Medical Center (Ashtabula, OH) during 2006 and 2007. For the antibiotic resistance 1612 S. aureus were evaluated, number of MRSA isolates were 947. The increase in MRSA infections was noticeable among youth (6’25 years old), middle-aged people (45’50 years old), and elderly people (86’90 years old). MRSA infections increased among nursing home residents by 183%, among inpatients by 58% and among outpatients by 43%. Among healthy people with no apparent risk factors more than 66% of MRSA infections were found. Antibiotic resistance profile showed only 9 profiles were distributed among inpatients, outpatients, and nursing home residents and 88.7% of infections belong to these profiles.
Sisirak et al. (2010) studied the prevalence of Methicillin-Resistant Staphylococcus aureus (MRSA) from the surgical wounds (January 2006 to December 2008), MRSA infection in surgical department and antimicrobial susceptibility pattern of MRSA isolates. Conventional methods were used to identify the isolates. Kirby-Bauer disc-diffusion method was used for antimicrobial susceptibility testing. A total of 5755 wound swabs were examined: aseptic swabs were 938 and 4817 (83.7%) were positive. S. aureus was isolated in 1050 (22.0%) swabs. MRSA prevalence was varied in study duration and trend was as follows; from 12.4% samples in 2006, from 6.7% samples in 2007 and from 3.7% samples during 2008. In the department of plastic surgery (24.4%) and in the department of orthopaedic surgery (24.1%) wound infections caused by MRSA were dominant. 73% of MRSA isolates were sensitive only to vancomycin, tetracycline, fucidic acid and trimethoprim/sulfamethoxazole by performing antimicrobial sensitivity test. Antimicrobial susceptibility testing showed that 73% of MRSA isolates were with the same antibiotic sensitivity pattern (antibiotype) sensitive only to vancomycin, tetracycline, fucid acid and trimethoprim/sulfamethoxazole.
Richard et al. (2010) studied the management of diabetic patients with infected foot wounds in hospital including an evaluation of the outcome 1 year after discharge, the study included 291 patients (73% male; 85% type 2 diabetes; mean age: 64.3��11.7 years). Wounds were located mostly on toes and forefoot, and moderate infection was observed; osteomyelitis was suspected in about 50% of patients. The most frequently isolated microorganisms were Gram-positive cocci and Staphylococcus aureus. During hospitalization, 35% patients undergo lower-limb amputation; in 52%, the wound healed or had a positive outcome. 150 non-amputated patients were examined after one year of discharge this time, 19% had to undergo amputation, whereas without any gap 79% had healed their wounds. Location (toes), severity of the wound and presence of osteomyelitis were the risk factors for amputation.
Xu et al. (2010) studied the surgical upper limb infections in patients with End-stage renal failure, their epidemiology and management. In the study period 47 out of 803 (6%) patients with surgical upper limb infections had end-stage renal failure (ESRF). Most common infections included were abscesses (34%), wet gangrene (26%) and osteomyelitis (11%). Out of all samples collected Methicillin-Resistant Staphylococcus aureus (MRSA) was the common organism (29%) isolated. 18% of single organisms cultured were gram-negative, 29% were multiple organisms. Amputation was needed among 36% of all cases. During treatment 25 percent of patients had a life-threatening event (septic shock).
Motamedi et al. (2010) examined the specimens that have been collected from patients of one of the hospitals of Ahvaz to determine the pattern of antibiotic resistance among Staphylococcus aureus isolates and to identify community-acquired Methicillin-Resistant Staphylococcus aureus (CA-MRSA). S. aureus isolates were separated for antibiotic resistance including methicillin. The MRSA was also treated with ethidium bromide to find the origin of resistance. Among the bacterial isolates, all of 11 S. aureus were resistant to methicillin and cefixime, resistance pattern against other antibiotics was as follows; 2 were resistant to ciprofloxacin, 6 to tetracycline and the remainder were sensitive or intermediate to other antibiotics. The treated isolates were resistant to methicillin and this suggested that the plasmid was not the origin of resistance in these isolates.
Suzuki et al. (2010) studied the prevalence of surgical site infections (SSI) following acetabular fracture open reduction and internal fixation. A total of 326 patients who undergo acetabular fracture surgery were selected. Out of 17 patients (5.2%) who developed a SSI, including 10 deep infections and 7 superficial infections. In 9 patients S. aureus was the most common responsible organism and was Methicillin-Resistant in 3 patients. Enterococcus faecalis was found in 6 patients, Staphylococcus epidermidis in 3 patients, and Pseudomonas aeruginosa and enterobacter cloacae in 2 patients each. Within 4 weeks after the fixation 14 of 17 patients developed their infection.
Mahmood et al. (2010) worked according to NCCL protocol using control strains ATCC 29213 (oxacillin susceptible) and S. aureus ATCC 43300 (oxacillin resistant) and collected 265 MRSA samples from different departments of tertiary care hospital. High prevalence was observed in males 155 (58.5%). Routine antimicrobial sensitivity of MRSA showed 28.7% to Ciprofloxacin, 37.5% to Gentamycin, 35% to Clindamycin, 27.5% to Erythromycin, 18% to fusidic acid, 8% to Penicillin, 87% to Moxi-floxacin, 0% to Oxacillin, 100% to Vancomycin, Teicoplanin, Linezolid and Teigecycline. MRSA is more prevalent in ICUs patients. Effective antimicrobials were Vancomycin, Teicoplanin, Linezolid and Teigecycline.
Lin et al. (2011) evaluated the prevalence and susceptibility pattern of Methicillin-Resistant S. aureus (MRSA) in skin and soft tissues infections (SSTIs). Out of 443 SSTI samples included, 40.4% were females and 59.6% were males. Most important cause found was S aureus (53.3%) and 53.0% were MRSA. The major susceptible antimicrobial agents to MRSA were Minocycline (94.4%), trimethoprim/sulfamethoxazole (95.2%), levofloxacin (95.7%), and fusidic acid (98.9%). Susceptibility to clindamycin was found to be 14.4%. 75.6% were community-associated isolates among MRSA infected inpatients. Based on the susceptibility results 15 inpatients with poor clinical response to beta-lactam empirical antimicrobial therapy received minocycline as combination.
Onwubiko and Sadiq (2011) worked on150 clinical isolates in tertiary care institution in Nigeria to observe the antibiotic sensitivity pattern of Staphylococcus aureus. Disc diffusion method was used to perform antibiotic sensitivity. Wound infections had the highest frequency of S. aureus isolates (30.7%) while the age group with the highest number of isolates was (0-10) yrs. Males (62.0%) were more infected than females (38.0%). The antibiotics sensitivity pattern of S. aureus was 92.4%, 63.0%, 44.2%, 35.8%, 52.4%, 61.9%, 15.5%, 31.2%, 7.1%, 78.9%, 76.6%, 100%, 71.4%, 30.7% and 100% respectively against following antibiotics; Gentamicin, Amoxycillin/clavulanate, Streptomycin, Cloxacillin, Erythromycin, Chloramphenicol, Cotrimoxazole, Tetracycline, Penicillin, Ciprofloxacin, Ofloxacin, Levofloxacin, Ceftriaxone, Amoxycillin and vancomycin. Levofloxacin 93.7% and Ofloxacin 68.7% were the drugs showed sensitivity by methicillin resistant isolates.
Knapp et al. (2011) studied the treatment of superficial and deep incisional surgical site infections with dapatomycin. Out of 69 selective patients, 60 were determine for efficacy. Abdominal wounds were more among deep SSIs (n = 30), whereas extremity wounds predominated among superficial incisional surgical site infections (n= 30). The overall clinical success rate was 92%, the success rate was 100% in superficial incisional SSI and 83% in deep SSI. Most frequently isolated organism was S. aureus (28/36 Methicillin-Resistant). Out of 10 patients who had fever initially, the median time of suppression was five days and 11.2 days was the mean duration of treatment. Well toleration was shown by dapatomycin.
Agudo et al. (2011) studied the CA-MRSA strains isolated in last three years in the Microbiology Lab of Hospital General La Mancha-Centro to examine the epidemiologic characteristics and resistance to antimicrobial agents by those strains. Out of a total of 97 S. aureus isolates in 2007 (26.8%) the number of CA-MRSA was 26, 40/113 in 2008 (35.4%) and 57/157 in 2009 (36.3%). 63.4% isolates were obtained from purulent skin and soft tissue infections. All strains were susceptible to linezolid, quinupristin/dalfopristin and glycopeptides. The pattern of resistance to antibiotics was flouroquinolones (94.3%), erythromycin (87.0%), tobramycin (82.9%), and clindamycin (65.3%).
Buzaid et al. (2011) worked in a major tertiary surgical hospital in Benghazi, Libya investigated the prevalence of MRSA isolates and their sensitivity patterns against various antibiotics used for treating hospitalized patients. From different clinical samples they investigated 200 non-duplicate S. aureus isolates. 31% (62/200) were the MRSA from the isolated S. aureus. Samples of burns and surgical wound infections were consisted of high number of MRSA. 62 patients with MRSA showed antibiotic resistance pattern as 17.7%, 33.9%, 41.9%, 38.7% and 46.8% against vancomycin, ciprofloxacin, fusidic acid, chloramphenicol and erythromycin.
Kitara et al. (2011) worked in Lacor Hospital (Uganda) to determine the prevalence and antibiotic susceptibility of Staphylococcus aureus in suppurative lesions of the surgical ward and outpatients. The number of Staphylococcus aureus in 122 patients was 59.4% for the surgical inpatients and 48.3% for outpatients giving an average rate of 53.9%. The average antibiotic susceptibility patterns for the 8 antibiotic tested were: Ampicillin (75.0%), Chloramphenicol (34.4%), Ciprofloxacin (1.6%), Erythromycin (7.8%), Gentamycin (0%), Methicillin (1.6%), Tetracycline (45.3%) and Co-trimoxazole (50.0%). Surgical inpatients showed higher resistance than outpatients (t=1299, p<0.05).
Liu et al. (2011) studied the reasons of scalp wound infections among craniocerebral trauma patients followed by the 2008 Wenchuan earthquake. A total of 82 patients suffered from scalp trauma, including 52.4% cases (43/82) with wound infections. Isolates of infectious bacteria were 59. The most common organisms isolated was Gram positive bacteria (64.4%), including Staphylococcus aureus (26/59, 44.1%) and Staphylococcus epidermidis (12/59, 20.3%). 35.6% of samples were isolated as Gram-negative bacteria, 22.0% (13/59) were Enterobacter cloacae, 5.1% (3/59) were Klebsiella pneumonia and 8.5% (5/59) were Serratiarubidaea.
Duckworth et al. (2012) worked on the patients who were diagnosed with deep infection following hip fracture surgery ant to analyze the predictors of mortality. Over a 3-year period there were 2718 successive operations performed for a fracture of the proximal femur. A deep postoperative infection was diagnosed in fluid and tissue samples in 43 (1.6%) patients. 65% were female and the mean age was 73 years (25-94). The main procedure in 25 (58%) patients was reduction and internal fixation, with 18 (42%) experiencing hemi-arthroplasty out of 43 patients who developed deep infection. The most common responsible organism was Staphylococcus epidermidis (n=13, 30%) with MRSA prevalence was 23% (n=10). The patients with no deep infection (19% vs. 6.5%; p=0.004) had less mortality. On distribution analysis, increasing age, dementia and diabetes were indication of both 30-day and 1-year mortality (all p<0.05).
Belthur at al. (2012) studied the risk factors for pathologic fracture in children with Staphylococcus aureus osteomyelitis between January 2001 and January 2009 at a tertiary-care pediatric hospital. Seventeen children who were treated for infective long-bone fracture secondary to Staphylococcus aureus osteomyelitis were compared with a control group matched for age, sex and methicillin susceptibility consisting of 49 children with S. aureus osteomyelitis having no fracture. Two out of 17 patients had methicillin-susceptible Staphylococcus aureus (MSSA) isolates and 15 had Methicillin-Resistant Staphylococcus aureus (MRSA). 72.1 days (range, twenty to 150 days) was the mean time for development of disease to fracture.
Mendes et al. (2012) worked on the bacterial profile on the basis of patient history, diabetic foot characteristics, ulcer duration and antibiotic therapy in diabetic foot infections in Lisbon. In the study 49 were hospitalized patients, and 147 microbial isolates were cultured. The main genus isolated was Staphylococcus, and out of total cases 24.5% were MRSA. 93% of the antibiotic trials were considered not sufficient on the basis of antibiotic susceptibility of clinical samples. 29 days were the average duration of ulcer with any MDR and previous treatment with flouroquinolones was statistically associated with antibiotic resistance.
Mina et al. (2012) isolated Staphylococcus aureus from burnt patients and checked the antimicrobial susceptibility of Vancomycin and nitrofurantoin in S. aureus. In between May 2008 to December 2011 data was collected from the 2938 hospitalized burn patients. Patients with longer hospital stay (P<0.001) were more likely to have infection as compared to other patients. Vancomycin and nitrofurantion seem to be the most effective antibiotics for MRSA among all tested antibiotics. With increasing in age the resistance to antibiotics also increased.
Dubey et al. (2013) collected the strains of multidrug resistant S. aureus both of community and hospital acquired by a surveillance over a period of 30 months in a teaching hospital. Of a total of 1507 S. aureus isolates, 485 strains from community and 1022 isolates were from hospital acquired sources; Out of 485 (100%) OPD S. aureus isolates, 390 (80.41%) were MRSA strains. Similarly, from wards and cabins of 564 (100%) isolates, 461 (81.73%) strains were MRSA; whereas 363 (79.25%) strains were MRSA out of 458 (100%) isolates obtained from ICU and NICU. 80 (20.51%) were vancomycin resistant (VRSA) and 173 (44.35%) strains were vancomycin intermediate strains from 390 (100%) MRSA strains isolated from OPD. Out of 461 (100%) MRSA isolates obtained from hospital acquired sources 110 (23.86%) strains were VRSA and 208 (45.11%) were VISA strains, whereas from ICU and NICU out of 363 MRSA isolates, 164 (45.17%) VISA and 61 (16.8%) VRSA strains were found.
Islam et al. (2013) in Trinidad and Tobago examined the microbial profile of diabetic foot infections. At a mean age of 56.9��12.4 years there were 139 patients. 56.8% of cases were included mixed poly-microbial infections. 64.7% were gram- negative aerobes, 1% was gram-positive aerobes and 3.2% were obligate anaerobes out of 221 organisms isolated. 25.9% of cases were of multidrug resistant organisms and included extended spectrum ��-lactamase (ESBL) producers (11.3%), MRSA (4.5%) and VRE (1.4%). Against gram-negative and gram-positive pathogens both ciprofloxacin and ceftazidime had good overall anti-microbial activity. Due to institutional constraints obligate anaerobes were uncommonly isolated.
Udobi et al. (2013) worked in the orthopedic ward of Ahmadu Bello University Teaching Hospital (ABUTH), Zaria- Nigeria the prevalence and antibiotic resistance pattern of MRSA. Out of 217 samples taken from the orthopedic wards of the hospital 185 isolates of Staphylococcus aureus were confirmed. Out of these 185 isolates, 44 (23.8%) were from the wounds and 70 (37.8%) from the skin. Beds and the atmospheric air comprised of remaining 65 (35.1%) and 6 (3.2%), respectively. The prevalence of MRSA out of these were found to be 33 (75%), 36 (51.4%), and 48 (73.8%) from wounds, skin, and bed, respectively. From the atmosphere no MRSA isolate was detected. The level of resistance against ampicillin was found to be 100% in all the three sites, pefloxacin 90.9%, 72.2%, 66.7%, ceftriaxone 69.7%, 72.2%, 70.8%, gentamicin 54.5%, 52.8%, 37.5%, and ciprofloxacin 51.5%, 47.2%, 35.4% by performing antimicrobial susceptibility test.
Yali et al. (2013) compared pathogens and their antibiotic resistances of burn patients from burn intensive care unit (ICU) or common burn ward. Of 2395 clinical samples from 63 patients in burn ICU, pathogens were detected in 1621 samples, in which 1203 strains (74.2%) were Gram negative bacteria, 248 strains (15.3%) were Gram positive bacteria, 170 strains (10.5%) were fungi. Top-4 microorganisms isolated from patients in burn ICU were Bauman’s Acinetobacter (557, 34.4%), Pseudomonas aeruginosa (287.17.7%), Staphylococcus aureus (199, 12.3%) and Klebsiella pneumoniae (171, 10.5%). Pathogens were detected in 373 samples out of 512 clinical samples in which 189 (50.6%) strains were Gram negative bacteria, 150 strains (40.2%) were Gram positive bacteria, 34 strains (9.2%) were fungi. S. aureus (103, 27.6%), P. aeruginosa (46, 12.3%), K. pneumoniae (38, 10.2%) and Escherichia coli (32, 8.6%) were the top-4 microorganisms isolated from burn unit patients. Clinical samples of burn patients from ICU showed antibiotic resistance significantly higher than those from common units.
Kahsay et al. (2014) worked in an Ethiopian hospital to analyze the prevalence, antimicrobial susceptibility patterns and associated risk factors of S. aureus in patients with surgical site infections. S. aureus was isolated from 73 (39.7%) cases from 184 surgical patients who had developed surgical site infection and 36 (49.7%) were MRSA. The clinical isolates showed <50% level of resistance was observed against clindamycin, oxacillin, tetracycline and vancomycin whereas >80% level of resistance to ampicillin, amoxicillin, penicillin G, erythromycin, gentamicin and cotrimoxazole. The resistance showed by MRSA strains was ranging from 5.6% (vancomycin) to 100% (cotrimoxazole). The identified risk factors for infection by S. aureus included sex, age, pus consistency, duration of operation, type of surgery, ward and hospital stay, laparotomy and type of surgery.
Shibabaw et al. (2014) examined the healthy hospital staff members for the antimicrobial susceptibility pattern of S. aureus isolates, the prevalence of MRSA, and the nasal carriage rate. There were 118 Health Care Workers (HCWs), 34 had S. aureus and 15 had MRSA with a positive rate of 28.8% and 12.7%, respectively. The sensitivity to penicillin by S. aureus was found to be 0%. Against commonly available antibiotics MRSA isolates were resistant. From the nasal isolates only two (13.3%) were vancomycin- resistant.
Radji et al. (2014) studied the antibiotic susceptibility patterns and microbiology of diabetic foot infections. A total of 288 of diabetic patients were admitted to hospital, and 35 patients had diabetic foot infections during January to December 2012. In 37.1% of patients diabetic control care was carried out and in 62.9% of patients surgical intervention was carried out. A total of 59 pathogens were isolated. Staphylococcus aureus (47.5%) was the most common infecting microorganism isolated on pus followed by Pseudomonas spp (16.9%), E. coli (10.2%), Streptococcus spp. (8.5%), Enterobacter spp. (7.0%), Proteus spp. (6.7%), and Acinetobacter spp. (3.2%). A single microorganism caused 37.2% of the diabetic foot infection and 62.8% had polymicrobial infections. Ceftriaxone (40.0%), ciprofloxacin (11.4%) and meropenem (8.6%) were the most frequently administered antibiotics.
Islam et al. (2014) carried out a study in a tertiary care hospital in Dhaka, Bangladesh to check the prevalence of Methicillin-Resistant Staphylococcus aureus (MRSA), vancomycin-resistant S. aureus (VRSA), and Panton-Valentine leukocidin (PVL)-positive S. aureus. Between July 2011 and June 2012 S. aureus strains were isolated from 200 postoperative wound swab samples. Out of 44 isolates of S. aureus 15 were MRSA (2 of them were VRSA) and 29 were MSSA. The resistance to Oxacillin (MIC ‘ 256 mg/mL) by all MRSA isolates was found to be very high. The sensitivity and specificity of the Oxacillin disc diffusion method were 93.33% and 100% when compared with polymerase chain reaction (PCR); both the sensitivity and specificity were 100% for the cefoxitin disc diffusion method and minimum inhibitory concentration of Oxacillin. Four (26.67%) MRSA isolates were mecA genes positive which PVL positive were also. The MRSA strains were highly resistant to ciprofloxacin (93.33%), ceftriaxone (86.63%), azithromycin (73.33%), gentamycin (73.33%), and amoxiclav (66.67%). 86.67% sensitivity was shown by Vancomycin and 100% by Linzolid by all MRSA strains.
Haleem et al. (2014) studied the consistency between nasal and diabetic foot ulcer (DFU) Staphylococcus aureus carriage. 29 (36.7%) subjects had DFU colonization with Staphylococcus aureus and 25 (31.6%) had nares colonization with Staphylococcus aureus. 7 (8.8%) subjects had DFU colonization with MRSA and 7 (8.8%) had nares colonization with MRSA. The MRSA presence (P = 0.01) was associated with duration of ulcer. 41% and 74% was the sensitivity and specificity of positive nasal S. aureus colonization with positive DFU colonization. The results were found dissimilar with S. aureus strains infecting DFU and the nasal cavity. Staphylococcus aureus colonization of a DFU by Staphylococcus aureus strains can’t be supposed due to poor positive isolates of S. aureus in a DFU of nasal carriers.

3.1. Isolation and Identification of Methicillin-Resistant Staphylococcus aureus (MRSA)
3.1.1. Sample collection
The samples were collected from three busy and tertiary care hospitals in Faisalabad namely Allied Hospital, District Headquarter Hospital (DHQ) and National Hospital. A total of 150 swab samples were collected from different types of accidental & surgical wounds, burn wounds and diabetic foot with pus discharge and purulent discharge as shown in plate 1 & plate 2. Under aseptic conditions, samples were collected from wound depth using a clean cotton swab and transferred to Microbiology Laboratory of Department of Clinical Medicine and Surgery, University of Agriculture, Faisalabad, for further processing.
3.1.2. Processing of samples for bacterial isolation and identification
Swab samples collected from different wounds were processed according to procedures described by Wolk et al. (2009). For isolation of S. aureus, swabs samples taken from humans were inoculated individually into Oxacillin broth (sodium chloride, mannitol, tryptone, yeast extract and Oxacillin) and incubated at 37 ��C for 24 hours. Following incubation, a loopful of broth was streaked on CHROMagar’ MRSA (CrA; CHROMagar, Paris, France) plates (90mm plastic Petri-plates) and incubated at 37��C for 24 hours as shown in plate 3.

Plate.1. A swab sample being collected from a patient with diabetic foot

Plate. 2. A swab sample being collected from a patient with burn wound

3.1.3. Identification of isolates of MRSA
Following incubation, colonies on CHROMagar’ MRSA were observed for identification of Staphylococci through specific colony characters; mauve colored, round colonies on CrA. For further identification of staphylococci, isolates were subjected to Gram staining reaction (Kahsay et al., 2014).
‘ With the help of sterile loop, smear of bacterial colony was prepared.
‘ Smear was heat fixed by passing the slide through burner 2-3 times.
‘ Then it was flooded with crystal violet (principle stain) for 1 minute, rinsed off with distilled water.
‘ Then flooded with Gram’s iodine for 1 minute and rinsed off.
‘ Slide was decolorized with 95% ethyl alcohol drop by drop for 5-10 seconds, immediately rinsed with water.
‘ Smear was flooded with Safranine (counter stain) gently and left for 1 minute, then rinsed with water.
‘ Slide was viewed using light microscope under oil-immersion lens.
‘ Shape, arrangements and staining character of bacteria were observed.
3.1.4. Identification on the basis of Hemolysis
All previously identified isolates including MRSA on CHROMagar’ MRSA were sub-cultured on plates of blood agar and incubated at 37��C for 24 hours for further identification through colony morphology, hemolysis (��-hemolysis) and pigment production (golden yellow) (Schuenck et al. 2006).

Plate.3. Culturing of samples on CHROMagr’ MRSA
3.1.5. Identification through Tube Coagulase test
All hemolytic isolates from blood agar plates were tested for presence of free/extracellular coagulase using rabbit plasma. Staphylococcus aureus produce coagulase (clumping factor) which can clot plasma into gel in tubes and this property makes it different from coagulase-negative staphylococci. The detail protocol is given below:
‘ All tubes for test were marked as 1, 2, 3’n, according to the hemolytic isolates on blood agar plates.
‘ 1 ml rabbit plasma was poured in all marked coagulase tubes.
‘ A loop full of suspected S. aureus was picked up from blood agar plate and mixed with rabbit plasma.
‘ All cultured tubes were incubated at 37��C for 4 hours.
‘ The clot formation was observed and results were recorded as coagulase positive or coagulase negative.
3.1.6. Identification of the S. aureus on the basis of Latex Agglutination test (Capsular Polysaccharide)
Staphytect is a test to differentiate S. aureus by the detection of clumping factor, Protein A and capsular polysaccharides found in MRSA from those staphylococci that do not possess these properties. Hemolytic isolates from blood agar were tested for Staphytect latex agglutination test. The detail protocol is given below:
‘ First of all, circles of test card were labeled for each colony sample to be tested.
‘ Reagent was dispensed onto the circles on the test card.
‘ With the help of sterile wire loop, 4-5 average sized suspected staphylococcal colonies from culture media plate were picked up and mixed onto the circle with test latex.
‘ Card was rocked/rotated for up to 20 seconds and observed for agglutination.
‘ Results of the test were recorded as +ve and ‘ve.
3.2. Confirmation & Molecular Characterization of Methicillin-Resistant S. aureus (MRSA)
3.2.1. Confirmation of Methicillin-Resistant Staphylococcus aureus (MRSA)
Isolates of S. aureus were checked by latex agglutination test (PBP2a test kit; Oxoid Ltd., Basingstoke, UK) for the presence of penicillin binding protein 2a. MRSA latex agglutination test was carried out as per manufacturer’s instructions (Shore et al., 2011).
‘ 4 drops of Extraction Reagent#1 (0.1 M NaOH) were added into centrifuge tube.
‘ With the help of sterile 1��l loop, a loopful of growth was removed from blood agar plate and suspended in Extraction reagent 1.
‘ Tubes were placed in water bath at 95��C for 3 minutes.
‘ Tubes were removed from water bath and allowed to cool to room temperature.
‘ 1 drop of Extraction Reagent #2 (0.5 N KH2PO4) was added into the tubes and mixed well.
‘ For 5 minutes tubes were centrifuged at 1500 �� g.
‘ On test card 50 ��L of the supernatant was added and mixed with 1 drop of test latex (anti-PBP2a monoclonal antibody sensitized latex particles) for 3 minutes.
‘ Agglutination was observed and recorded as strong positive, moderately positive or negative.
3.2.2. Molecular Characterization of Methicillin-Resistant S. aureus (MRSA) Detection of nuc and mecA genes by Polymerase Chain Reaction (PCR)
The isolates were tested for the chromosomal genes ‘nuc’ encoding (thermo-nuclease specific for S. aureus) and mecA (methicillin resistant specific gene) (Brakstad et al., 1992) using commercially available multiplex PCR kit (BactReady’ multiplex PCR system; Genescript, USA). Sequence of primers used and size of PCR product is mentioned in the Table 1. All primers were purchased from GeneLink’ (USA) through local vendor (The Worldwide Scientific, Lahore, Pakistan). Preparation of Genomic DNA
For PCR, genomic DNA was prepared using extraction components (solution) available with BactReady’ (Genescript, USA) the composition was mentioned in table 2. All preparations were made according to instruction manual. Briefly, single, isolated, 24-hour old colony from blood agar plate was picked up and thoroughly suspended in 25 microliter of DNAse free water and 1 microliter of cell suspension was mixed with 20 microliter of cell lysis buffer (BR-A buffer supplied with BactReady) and lysate was spun down by short centrifugation at 2000 rpm for 1 minute. The supernatant containing genomic DNA was used directly for amplification PCR amplification
The reaction was performed using BactReady’ multiplex PCR system (Genescript, USA). The reaction mixture (20 ��l) was prepared in thin walled with flat cape, DNase-RNase free 0.2 mL tubes Thermo-Tubes, (Thermo-scientific, UK) with 1 ��L of template DNA. Amplifications were performed using a micro-processed controlled Swift’ Maxi Thermal Cycler Block (ESCO Technologies Inc. France) under the following conditions: activation of Script’ DNA polymerase at 94 ��C for 15 minutes followed by 35 cycles of denaturation (95��C for 1 min), annealing (55��C for 1 min), extension (72��C for 1 min), and a final extension step of 72��C for 3 minutes. The composition of reaction mixture is given in the Table 2.
The analysis of amplicons were made by agarose gel electrophoresis using a horizontal mini agarose gel electrophoresis system (ENDURO’ Lab net International Inc., Woodbridge, NJ, USA). A mixture of undiluted PCR products (5 ��L) and 5X loading dye (1 ��L; Fermentas Thermo Fischer Scientific Inc., UK) was loaded to 1.2% Agrose gel (multipurpose agarose, low EEO, multipurpose, Fischer Scientific Ltd, Loughborough, UK) containing ethidium bromide (0.5 ��g./mL; Fischer Scientific Ltd, Loughborough, UK) for DNA staining. The gels were run in 1X TAE buffer (50X TAE Buffer, Fischer Scientific Ltd, Loughborough, UK) at 80 volts (80mA) for 1 hour. The amplicons were visualized on a trans-illuminator (Vilbert Lourmart, Cedex France) and saved using gel documentation systems (DP-CF-011, France). The size of the products was measured using a ready to use 100 bp molecular markers (O gene-Ruler 100bp DNA ladder, Fermentas, Thermo-scientific, UK).

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