Original Research
2016 September
Volume : 4 Issue : 3


Resistance pattern of enterococcal isolates, phenotypic characterization of vancomycin resistant isolates from various clinical samples in a tertiary care hospital

Prasanna Lakshmi Kakarla, Anil Kumar Bilolikar

Pdf Page Numbers :- 101-105

 1Department of Microbiology, Krishna Institute of Medical Sciences, Minister Road, Secunderabad–500003, Telangana, India

 

*Corresponding author: Dr. Prasanna Lakshmi Kakarla, Department of Microbiology, Department of Laboratory sciences, Krishna Institute of Medical Sciences, Minister Road, Secunderabad–500003, Telangana, India. Tel.: 8332055939; Email: prasannakakarla380@gmail.com

 

Received 04 April 2016; Revised 26 May 2015; Accepted 17 June 2015; Published 29 June 2016

 

Citation: Kakarla PL, Bilolikar AK. Resistance pattern of enterococcal isolates, phenotypic characterization of vancomycin resistant isolates from various clinical samples in a tertiary care hospital. J Med Sci Res. 2016; 4(3):101-105. DOI: http://dx.doi.org/10.17727/JMSR.2016/4-024



Abstract

 Introduction: Enterococci cause a multitude of infections and emergence of vancomycin resistance is of special concern, as it is the primary alternative drug to penicillin for treating Enterococcal infections.

Objectives: The present study was taken up to know the species predominance, resistance pattern and various phenotypes of vancomycin resistant Enterococci in a tertiary care hospital in south India.

Material & Methods: The Data collected from the department of Microbiology at Krishna Institute of Medical Sciences, Secunderabad from January 2012 to December 2015 was retrospectively analysed. 226 Enterococci were speciated, antibiograms were analyzed and phenotyping of VRE was done based on standard guidelines.

Results & discussion: The predominant species was found to be E. faecalis (51.3%) followed by E. faecium (43.3%), E. gallinarum (2.2%), E. durans (1.32%), E. casseliflavus (0.88%) and E. raffinosus (0.88). E. faecalis showed less resistance (30.39%) to antimicrobials than E. faecium (50.64%). The resistance pattern was less in out-patient samples when compared to in-patient samples. Vancomycin resistant Enterococci were 13(5.75%), all isolated from inpatients. Among the 13 isolates, 6(46.15%) were VanA, 4(30.76%) were VanB and 3(23.07%) were VanC phenotypes. VanC phenotype was observed in E. casseliflavus and E. gallinarum due to intrinsic resistance.

Conclusion: The species predominance of E. faecalis and E. faecium reflects the change in recent decade. Drug resistance pattern and phenotyping is correlating with other studies, VanA being the commonest. Monitoring for vancomycin resistant Enterococci is critical in hospital infection control and for effective treatment.

 

 

 

Keywords: phenotyping; antibiogram; vancomycin-resistant Enterococci; infection control

Full Text

 

 Introduction

 

The term ‘Enterococcus’ originates from the Greek enteron meaning ‘the gut or intestine’ and kokkos meaning ‘a berry or kernel’. This is helpful as multidrug resistant Enterococci are associated with the gastrointestinal tract and have become ‘kernels’ of antimicrobial resistance [1].

 

 

 

Enterococci, previously classified as group D Streptococci, are normal part of enteric microbiota. On Grams stain they appear typically as Gram positive oval cocci of size approximately 1µm arranged in pairs at angles, or in short chains. They are usually nonhemolytic, grow in presence of bile, hydrolyze esculin, grow well in 6.5% NaCl and grow well between 10 and 45℃ (Characteristics that differentiate Enterococci from Streptococci).

 

Most common sites of infection are the urinary tract, wounds, biliary tract and blood. They are also associated with meningitis and bacteremia in neonates and endocarditis in adults. Among the total species of Enterococci identified till date, only one third are implicated in human disease. Although Enterococcus faecalis was the most common species isolated earlier, a shift to Enterococcus faecium is observed in the last few decades [2].

 

Enterococcus is an important pathogen because of its intrinsic as well as acquired antibiotic resistance. The intensive use of broad spectrum antibiotics in hospitals provides selective pressure favoring growth of intrinsically drug-resistant commensal organisms, one of them being Enterococcus. The first case of Vancomycin Resistant Enterococci (VRE) was reported in England in 1988 by Uttley et al; since then observed all over the world [3]. In India there are reports from New Delhi, Chandigarh and Mumbai [4-6].

 

Several genes, including VanA, VanB, VanC, VanD, and VanE, contribute to resistance to vancomycin in Enterococci. Acquired resistance is mediated by VanA and VanB phenotypes whereas intrinsic resistance is VanC mediated.

 

Newer agents such as linezolid, daptomycin, quinupristin- dalfopristin and tigecycline (among others) are used for the treatment of Vancomycin Resistant Enterococci infections [7].

 

The importance of VRE is because of the few options available for treatment, the difficulty to eradicate once established and the possibility of transfer of vancomycin resistance to Staphylococcus aureus and Listeria monocytogenes [8].

 

Material and methods

Study area: Department of Microbiology at Krishna Institute of Medical Sciences, Secunderabad

Study population: All patients admitted to KIMS and visiting out-patient departments were included.

 

Inclusion criteria: 1) All age groups, 2) IP and OP patients of all departments, 3) Both males and females are included, 4) Percentage Identification more than 89% in VITEK 2 compact (bioMerieux).

 

Exclusion criteria: Percentage identification less than 89%in VITEK 2 compact (bioMerieux)

 

Study design: Retrospective lab based observational study of antibiotic resistance of Enterococci. Phenotyping of Vancomycin resistant Enterococci in our hospital.

 

Study duration: 1 January 2012 to 31 December 2015

 

 

 

Method of measurement of outcome of interest

All clinical samples of patients which showed growth of Enterococci were analyzed. In the study, 226 enterococcal isolates were speciated by VITEK 2 compact (with percentage identification > 89%).

 

Antibiogram was analysed according to Clinical Laboratory Standards Institute (CLSI) guidelines [9] prevailing at that point of time.

 

Isolates showing resistance to Vancomycin were phenotyped into VanA, VanB VanC, based on MIC values of Vancomycin and Teicoplanin, according to CDC guidelines [8, 10].

 

Table 1: Characteristics of phenotypes of glycopeptide resistant Enterococci

S. No

Phenotype

Van MIC
(μg/ml)

Tei MIC
(μg/ml)

Common

species

Location

Genetic determinant

Expression

Transferable

1

VanA

> 128

≥16

E. faecium,

E. faecalis

Plasmid

Acquired

Inducible by Vancomycin & Teicoplanin

Yes

2

VanB

16-64

≤1

E. faecium,

E. faecalis

Plasmid/ Chr

Acquired

Inducible by Vancomycin

Yes

3

VanC

Feb-16

≤0.5

E. gallinarum,

E. casseliflavus

 

Intrinsic

Constitutive

No

4

VanD

64-128

04-Aug

E. faecium

Chr

Acquired

 

No

5

VanE

64-128

04-Aug

E. faecalis

Chr

Acquired

 

No

Results

A total number of 226 isolates of Enterococci were identified during the study period, among which 13 were Vancomycin Resistant (VRE). All Vancomycin Resistant Enterococci were isolated from inpatient samples only. When vancomycin phenotypes were further analyzed, 6 were found to be VanA, 4 were VanB and 3 were VanC.

 

Figure 1: Distribution of various species of Enterococci isolated.

 

 

 

Table 2: Various enterococcus species & van phenotypes in different samples.

S.No

Enterococcus species

Inpatient

Outpatient

Total number

VanA

VanB

VanC

1

E. faecalis

66

50

116

2

2

0

2

E. faecium

83

15

98

4

2

0

3

E. gallinarum

4

1

5

0

0

1

4

E. durans

Jan-00

0

3

0

0

0

5

E. casseliflavus

2

00-Jan

2

0

0

2

6

E. raffinosus

2

00-Jan

2

0

0

0

Total number (n)

160

66

226

6

4

3

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 3: Antibiotic resistance pattern of E. faecium, E. faecalis & VRE.

S.No

Antibiotic

E. faecium
(n=98)

E. faecalis
(n=116)

VRE isolates
(n=13)

   

IP

OP

Total

IP

OP

Total

 

1

Ampicillin

48.19

40

46.93

6.06

0

34.4

30.77

2

Ciprofloxacin

93.97

86.66

92.85

65.15

0.66

65.5

69.23

3

Nitrofurantoin (urine isolates only)

34.93

26.66

33.67

12.12

2

7.75

38.46

4

High Level Gentamicin Resistance

73.49

66.66

72.44

62.12

54

58.6

69.23

5

High Level Streptomycin Resistance

43.37

40

42.85

21.21

16

18.9

38.46

6

Levofloxacin

90.36

80

88.77

65.15

60

62.93

76.92

7

Linezolid

1.2

0

1.02

7.57

0

4.31

7.69

8

Penicillin

83.13

0.6

89.79

28.78

18

24.13

69.23

9

Quinupristin – Dalfopristin

12.04

13.33

12.24

-

-

-

-

10

Tetracycline

78.31

0.8

78.57

87.87

78

83.6

69.23

11

Vancomycin

7.28

0

6.12

6.06

0

3.44

-

12

Teicoplanin

4.81

0

4.08

3.03

0

1.72

-

 

Table 4 Vancomycin phenotypes of vancomycin resistant enterococcus – Details.

S.No

Organism

Sample

VAN MIC
(μg/ml)

TEI MIC
(μg/ml)

Phenotype

1

E. faecium

Blood

≥128

≥32

VanA

2

E. faecium

CSF

≥128

≥32

VanA

3

E. faecium

Tissue

≥128

≥32

VanA

4

E. faecium

Urine (Catheter catch)

≥128

≥32

VanA

5

E. faecium

CSF

≥32

<1

VanB

6

E. faecium

Urine (Catheter catch)

≥32

<1

VanB

7

E. faecalis

Central line tip

≥128

≥32

VanA

8

E. faecalis

Urine (Catheter catch)

≥128

≥32

VanA

9

E. faecalis

Urine (Catheter catch)

≥32

≤ 0.5

VanB

10

E. faecalis

Urine (Catheter catch)

≥32

<1

VanB

11

E. casseliflavus

Urine (clean catch)

4

0.5

VanC

12

E. casseliflavus

US guided fluid

4

0.5

VanC

13

E. gallinarum

Pus

4

0.25

VanC

 

 

 

Abbreviations: Van: Vancomycin; Tei: Teicoplanin; MIC: Minimal Inhibitory Concentration

 

 

 

 

 

 

Figure 2: Resistance pattern of van phenotypes.

Abbreviations: AM: Ampicillin; CIP: Ciprofloxacin; FT: Nitrofurantoin; HLG: High Level Gentamicin; HLS: High Level Streptomycin; LEV: Levofloxacin; LNZ: Linezolid; P: Penicillin; TE: Tetracycline

 

Discussion

A total of 226 enterococcal isolates could be identified by VITEK 2 compact (bioMerieux). The predominant species was found to be E. faecalis (116, 51.3%), followed by E. faecium (98, 43.3%). Ratio of E. faecalis and E. faecium is 1.18: 1. This supports the study saying that there is a progressive decline in the ratio in recent years, ie, progressive increase in E. faecium infection [3].

 

All together 11 (6.87%) isolates were identified as non- E. faecalis non- E. faecium in the present study, comparable to other studies [11, 12]. Other species isolated include E.gallinarum (5, 2.2%), E. durans (3, 1.32%), E. casseliflavus (2, 0.88%) and E. raffinosus (2, 0.88%). Most of the isolates were from inpatients (70.79%) especially so in case of E. faecium (84.69%). No gender difference was noted in isolation of different species.

Enterococci have adequate intrinsic and acquired resistance to many antibiotics [13]. They are intrinsically resistant to penicillinase resistant penicillins and cephalosporins; have acquired resistance to chloramphenicol, erythromycin and high level resistance to aminoglycosides, penicillin, fluoroquinolones and vancomycin [14]. E. faecium and E. faecalis were more resistant when compared to other species. Among the two, E. faecalis is less resistant (30.39%) to antimicrobials than E .faecium (50.64%). Antimicrobial resistant Enterococci are being reported with increasing frequency in United States and other parts of the world [15]. Their number in Asian subcontinent is comparatively less.

 

The phenotypic classification scheme used usually corresponds well to the genotypic classification. It is an inexpensive method as it uses information that is derived simply in a laboratory. However there are certain limitations [10].

 

Thirteen Vancomycin resistant phenotypes were isolated (5.75%), majority of them from urine samples. VanA is the commonest (6 out of 13), closely followed by VanB (4 out of 13) and then VanC (3 out of 13). When the resistance pattern is looked into, majority of the isolates were found to be sensitive to Linezolid. Nitrofurantoin though useful in vancomycin susceptible isolates, 5 out of 13 (38.46%) VRE isolates were resistant to it. VRE were highly resistant to levofloxacin, penicillin, tetracycline and ciprofloxacin.

 

The overall resistance of VRE isolates was higher than non-VRE isolates except for ciprofloxacin and tetracycline. Even though tigecycline is reported to have good activity against VRE infections, it could not be tested as majority isolates were from urine. Use of tigecycline for the treatment of Urinary Tract Infections (UTIs) has been questioned because of low peak serum concentrations and limited excretion into urine [16, 17].

 

Conclusion

The present study concludes that the overall incidence of vancomycin resistant enterococci among all infections is 5.75%, majority being urinary tract infections. Although Enterococcus faecalis was the predominant species, the percentage prevalence in our study is consistent with the change in trend mentioned by other authors. Drug resistance of E.faecium was more as compared to E. faecalis. VanA is the commonest phenotype observed in our study as is the case in all other studies. Linezolid remains a promising drug to combat VRE till date. Nitrofurantoin is a good alternative for vancomycin resistant enterococcal urinary tract infections. The finding that all VRE are isolated from inpatients highlights the role of Hospital Infection Control in controlling the drug resistance. Early detection and reporting of VRE plays an important role in initiating effective infection control practices. However, there is a continued need for the development of new antimicrobial agents for treating VRE infection, as well as a regimen that would eradicate VRE colonization.

 

Limitations of study

      The study would have been better had it been prospective

      Clinical history, treatment given and outcome of patients are not known

      Phenotypic classification system used in the study is not fool proof

      Genotypic confirmation of Van phenotypes using PCR was not done

 

Acknowledgements

I sincerely thank the whole department of Microbiology and Laboratory sciences, Krishna Institute of Medical sciences without whose support I would not have carried out this work.

 

 

 

Conflicts of interest

Authors declare no conflicts of interest.

 

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