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JAC-Antimicrobial Resistance logoLink to JAC-Antimicrobial Resistance
. 2023 Aug 3;5(4):dlad086. doi: 10.1093/jacamr/dlad086

The epidemiology and microbiological characteristics of infections caused by Gram-negative bacteria in Qatar: national surveillance from the Study for Monitoring of Antimicrobial Resistance Trends (SMART): 2017 to 2019

Mazen A Sid Ahmed 1, Hawabibee Mahir Petkar 2, Thoraya M Saleh 3, Mohamed Albirair 4, Lolita A Arisgado 5, Faiha K Eltayeb 6, Manal Mahmoud Hamed 7, Muna A Al-Maslamani 8, Abdul Latif Al Khal 9, Hussam Alsoub 10, Emad Bashir Ibrahim 11,12, Hamad Abdel Hadi 13,
PMCID: PMC10400155  PMID: 37546546

Abstract

Background

The global Study of Monitoring Antimicrobial Resistance Trends (SMART) is a surveillance program for evaluation of antimicrobial resistance (AMR) in Gram-negative bacteria (GNB) from different regions including Gulf countries.

Objectives

To evaluate AMR in GNB from various clinical specimens including microbiological and genetic characteristics for existing and novel antimicrobials.

Methods

A prospective study was conducted on clinical specimens from Hamad Medical Corporation, Qatar, between 2017 and 2019 according to the SMART protocol. Consecutive GNB from different sites were evaluated including lower respiratory, urinary tract, intrabdominal and bloodstream infections.

Results

Over the 3 years study period, 748 isolates were evaluated from the specified sites comprising 37 different GNB outlining four key pathogens: Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa and Stenotrophomonas maltophilia.

For the two major pathogens E. coli and K. pneumoniae, phenotypic ESBL was identified in 55.77% (116/208) compared to 39% (73/187), while meropenem resistance was 3.8% compared to 12.8% and imipenem/relebactam resistance was 2.97% compared to 11.76%, respectively. The overall ceftolozane/tazobactam resistance for E. coli was 9.6% (20/208) compared to 14.97% (28/187) for K. pneumoniae while resistance for ceftazidime/avibactam was 3.65% (5/137) and 5.98% (10/117), respectively. Genomic characteristics of 70 Enterobacterales including 48 carbapenem-resistant, revealed prevalence of β-lactamases from all classes, predominated by blaCXM-15 while carbapenem resistance revealed paucity of blaKPC and dominance of blaOXA-48 and blaNDM resistance genes.

Conclusions

Surveillance of GNB from Qatar showed prevalence of key pathogens similar to other regions but demonstrated significant resistance patterns to existing and novel antimicrobials with different underlying resistance mechanisms.

Background

In modern healthcare, challenges of antimicrobial resistance (AMR) have a major impact on public health, with significant morbidity and mortality as well as escalating costs of management.1 The consequences of AMR are particularly witnessed in Gram-negative bacteria (GNB) where the pathogens are responsible for a wide spectrum of community and healthcare-associated infections (HAIs), ranging from mild to severe that require critical care and frequently fatal outcomes. Over the last decades, the accumulation of diverse resistance mechanisms in GNB, led to the development of the notorious multidrug resistant organisms (MDROs) with critical consequences.1,2 The emergence of MDROs with limited therapeutic alternatives, has been associated with detrimental patient outcomes leading to prolonged length of hospital stay that necessitates urgent prevention and control strategies that include the development of novel antimicrobials options.3 Globally GNB encompassing MDROs, are the leading cause of human infections for all age groups, as they are the principal cause of urinary tract infections (UTIs) as well as hospital-acquired respiratory tract infections (RTIs).4,5 Similarly, they are amongst the leading causes of nosocomial bacteraemia as well as complicated or uncomplicated intra-abdominal infections (IAIs).6–9

When examining the global problem of AMR, it is clear it has regional variations attributed to pathogens and host factors as well as variance in local settings including antimicrobial prescribing choices and consumption, dominance of highly resistant clones as well as variable adherence to infection control and prevention measures.10 Furthermore, regional epidemiology does not only differ in prevalence, but also in microbiological characteristics and underlying resistance mechanisms. While extended-spectrum β-lactamases (ESBLs) are the most observed global resistance mechanism in GNB including Enterobacterales, other advanced mechanisms such as those observed in carbapenem-resistant Enterobacterales (CREs) have a different disease spectrum and are predicted to pose significant future challenges.1 In CREs, the underlying mechanisms of AMR are diverse, for example, while class A blaKPC is the dominant mechanism in North America and Europe, class B such as blaNDM, blaVIM as well as class D blaOXA type CREs are dominant in the Middle East and Gulf countries.11 Similarly, for Pseudomonas aeruginosa and Acinetobacter baumannii, resistance mechanisms are dominated by ESBLs and class C cephalosporinases in addition to other antimicrobial permeability resistance mechanisms such as efflux pumps and porins mutations that are unique in the study of the evolution resistance in GNB.12,13 Furthermore, antimicrobial characteristics for existing and novel antimicrobials therapy demonstrate regional variations that merit further evaluation to enhance clinical experience as well as aid research and development of future antimicrobial therapy.14

The high rate of AMR calls for accurate regional and global surveillance to assess pathogens epidemiology, microbiological and genomic characteristics that remains of paramount importance at all levels particularly for guidance of appropriate antimicrobial therapy. Consequently, in 2015, the World Health Organization developed a global AMR action plan that advocates regional and national monitoring strategies including implementing viable surveillance concepts.15

This study is part of the global surveillance of AMR in collaboration with the International Health Management Associates, Inc (IHMA), examining microbiological and genomic characteristics of selected GNB between 2017 and 2019 from Qatar. It includes the evaluation of in vitro susceptibility of GNB to the novel antimicrobial agents: imipenem/relebactam, ceftolozane/tazobactam, ceftazidime-avibactam and meropenem-vaborbactam compared to existing comparators from clinical practice, as well as molecular characterization of ESBLs, carbapenemases, plasmid and chromosomally encoded AmpC β-lactamases from specific aerobic Gram-negative species.

Materials and methods

Bacterial strains

All isolates were collected from specimens received at the central microbiology laboratory in Qatar according to the criteria in the SMART protocol as outlined. The laboratory receives specimens from 10 general and specialized facilities within Hamad Medical Corporation, which is the main provider of hospital services within the State of Qatar.

Specimens were collected from hospitalized patients from designated facilities. For each year of the study, consecutive clinically relevant isolates of aerobic GNB were collected from patients with lower RTIs (100 isolates), UTIs, (50 isolates) and IAIs (50 isolates) as well as from bloodstream infections (BSIs) (50 isolates). Only one isolate per patient per species was allowed. Isolate demographic information was documented on provided worksheets as per the study protocol. Following local identification using automated BD Phoenix™ Microbiology System (BD Diagnostics, Durham, NC, USA), isolates were transferred to IHMA for further analysis. Identification of all isolates received at each testing facility were confirmed using MALDI-TOF spectrometry (Bruker Daltonics, Billerica, MA, USA). Organism collection, transport, identification and confirmation, quality assurance and centralized database development and management were coordinated by IHMA (Schaumburg, IL, USA). Results were extracted and analysed from the central database by the study reporting group: https://globalsmartsite.com

Antimicrobials susceptibility testing (ASTs)

Minimum inhibitory concentrations (MICs) were determined at IHMA’s US and European laboratories using frozen in-house custom or commercially available broth microdilution panels. Separate custom panel configurations were made for isolates of Enterobacterales and Gram-negative non-fermenter species (Acinetobacter species, Pseudomonas species and Burkholderia species). All broth microdilution tests were set up according to the Clinical and Laboratory Standards Institute (CLSI) guidelines and MIC interpretive criteria used were those published in 2020 M100 guidelines by CLSI.16 Because not all GNB are tested against standard antimicrobial panels as well as some protocol changes during collection period that allowed incremental introduction of novel antimicrobials, not all isolates were uniformly tested against designated antimicrobials, which explains the non-congruent figures. Additionally, interpretive criteria for imipenem/relebactam were those assigned by CLSI, EUCAST and the United States Food and Drug Administration (US FDA).

Using CLSI guidelines, Escherichia coli, Klebsiella pneumoniae, K. oxytoca and Proteus mirabilis were classified as ESBL producers if there was at least an 8-fold reduction (i.e. three doubling dilutions) of the MIC for ceftazidime or cefotaxime tested in combination with clavulanic acid versus their MIC values when tested alone.16 Quality control (QC) of broth microdilution panels followed the manufacturer’s instructions and CLSI guidelines, using the following ATCC strains: E. coli ATCC 25922, P. aeruginosa ATCC 27853, K. pneumoniae ATCC 700603 and K. pneumoniae BAA-2814. Results were included in the analysis only when corresponding QC values tested were within the acceptable ranges as specified by CLSI.

Molecular characterization of β-lactamase genes

Enterobacterales isolates that met one or more of the following criteria (based on CLSI breakpoints) were screened for the presence of β-lactamase genes: Enterobacterales non-susceptible to ceftolozane/tazobactam (MICs ≥4 mg/L) and non-Morganellaceae Enterobacterales, excluding Serratia species, non-susceptible to imipenem (MICs ≥2 mg/L) and/or imipenem/relebactam (MICs ≥2 mg/L). P. aeruginosa isolates that met one or more of the following criteria were screened for the presence of β-lactamase genes: isolates non-susceptible to ceftolozane/tazobactam (MICs ≥8 mg/L) and isolates non-susceptible to imipenem (MICs ≥4 mg/L) and/or imipenem/relebactam (MICs ≥4 mg/L). The proportion of isolates that met the testing criteria that were characterized was determined based on budgetary constraints which included 70 MDR-GNB and 48 CREs. Qualifying Enterobacterales isolates were screened for the presence of β-lactamase genes (bla) encoding class A ESΒLs blaTEM, blaSHV, blaCTX-M, blaVEB, blaPER, and blaGES; blaAmpC, class B metallo-β-lactamase (MBL) genes blaNDM, blaIMP, blaVIM, blaGIM and blaSPM, class C β-lactamase genes blaACC, blaACT, blaCMY, blaDHA, blaFOX, blaMIR and blaMOX; class A carbapenemases blaKPC and blaGES and class D blaOXA-48-like, by multiplex PCR as described previously.17

Data handling and statistical analysis

Summary of statistics were calculated using R software v.4.1.3. The total number of isolates (n), MIC50 (mg/L), MIC90 (mg/L) and MIC range (mg/L) were determined for all antimicrobial agents tested. The percentage of susceptibility (%) was calculated according to both CLSI and EUCAST where available. Direct comparisons were made between different interpretive criteria using published breakpoints for each drug.

Ethical considerations and data management

The study and collaboration were approved by the Medical Research Centre of Hamad Medical Corporation (HMC), which abides by local and international research standards (ref. 17248/17). The study also received approval from the Ethical Committee and Institution Review Board of HMC after demonstrating utmost commitment towards observing outlined standards for data management and sharing including limited access to nominated primary investigators, data anonymity and governance. All shared data with collaborators had no traced patients’ identification.

Results

Prevalence and distribution of aerobic GNB isolates

The frequency and distribution of all isolated GNB is shown in Table 1. Thirty-seven different GNB species were isolated, with predominance of four key species accounting for about 80% of infections: E. coli (27.9%), K. pneumoniae (25%), P. aeruginosa (21.9%) and Stenotrophomonas maltophilia (6%) while organisms from the order Enterobacterales constituted 67.25% (503/748) of infections. Identified pathogens were isolated from RTIs 39.84% (298/748), IAIs 23.80% (178/748), UTIs at 23.53% (176/748) and BSIs at 12.83% (96/748). P. aeruginosa was the most common cause of RTIs and E. coli was the most common cause of infections from the three other outlined sites.

Table 1.

Frequency of Gram-negative organisms collected from blood, intra-abdominal, respiratory and UTIs in the SMART study (2017–2019)

Species Year of isolation Site of isolation Frequency %
2017 2018 2019 RT IA UT BS Unknown
Escherichia coli 72 73 64 8 77 76 48 0 209 27.94%
Klebsiella pneumoniae 70 59 58 68 44 55 20 1 187 25%
Pseudomonas aeruginosa 53 46 65 108 25 18 13 0 164 21.93%
Stenotrophomonas maltophilia 10 22 13 39 5 0 1 0 45 6.02%
Enterobacter cloacae 10 9 7 14 7 3 2 0 26 3.48%
Serratia marcescens 7 3 10 15 2 2 1 0 20 2.67%
Acinetobacter baumannii 8 5 6 15 1 3 1 0 19 2.54%
Klebsiella aerogenes 5 4 2 6 1 3 1 0 11 1.47%
Proteus mirabilis 4 3 3 1 0 7 2 0 10 1.34%
Klebsiella variicola 1 3 4 3 3 0 2 0 8 1.07%
Enterobacter non-speciated 2 4 0 5 1 0 0 0 6 0.80%
Morganella morganii 2 1 2 0 1 3 1 0 5 0.67%
Citrobacter freundii 1 3 0 1 1 1 1 0 4 0.53%
Salmonella non-speciated 0 1 3 0 4 0 0 0 4 0.53%
Acinetobacter non-speciated 0 2 1 2 0 1 0 0 3 0.40%
Achromobacter xylosoxidans 1 1 0 2 0 0 0 0 2 0.27%
Acinetobacter pittii 0 1 1 1 1 0 0 0 2 0.27%
Aeromonas caviae 1 1 0 0 2 0 0 0 2 0.27%
Klebsiella oxytoca 1 1 0 1 1 0 0 0 2 0.27%
Proteus non-speciated 0 1 1 1 0 0 1 0 2 0.27%
Aeromonas hydrophila 0 1 0 0 1 0 0 0 1 0.13%
Aeromonas veronii 0 1 0 0 0 0 1 0 1 0.13%
Burkholderia cenocepacia 0 1 0 1 0 0 0 0 1 0.13%
Burkholderia cepacia 0 0 1 1 0 0 0 0 1 0.13%
Burkholderia multivorans 0 1 0 1 0 0 0 0 1 0.13%
Citrobacter koseri 0 0 1 1 0 0 0 0 1 0.13%
Elizabethkingia miricola 0 1 0 1 0 0 0 0 1 0.13%
Enterobacter bugandensis 0 0 1 1 0 0 0 0 1 0.13%
Kluyvera ascorbata 1 0 0 0 1 0 0 0 1 0.13%
Pantoea non-speciated 0 0 1 0 0 1 0 0 1 0.13%
Proteus hauseri 0 1 0 0 0 0 1 0 1 0.13%
Proteus penneri 0 0 1 0 0 1 0 0 1 0.13%
Providencia stuartii 0 0 1 0 0 1 0 0 1 0.13%
Pseudomonas non-speciated 1 0 0 1 0 0 0 0 1 0.13%
Pseudomonas otitidis 0 0 1 1 0 0 0 0 1 0.13%
Ralstonia non-speciated 0 1 0 1 0 0 0 0 1 0.13%
Raoultella ornithinolytica 0 0 1 0 0 1 0 0 1 0.13%
Total (%) 250 (33.42) 250 (33.42) 248b (33.16) 298 (39.84) 178 (23.80) 176 (23.53) 96 (12.83) 1 (0.13) 748 (100) 100%

BS, blood stream; IA, intra-abdominal; RT, respiratory tract; UT, urinary tract.

Demographic profile of study population

The 748 specimens were collected from all age groups (0–99 years), with male preponderance (64.17%). Specimens were from medical, surgical and paediatrics departments while 39.1% of samples were from intensive and critical care units (Supplementary Table S1, available as Supplementary data at JAC-AMR Online).

Antimicrobial susceptibility patterns of GNB isolates

Antimicrobial susceptibility test results for the top 10 species-comprising 699 isolates (93.4%) of the study organisms, are summarized in Table 2.

Table 2.

Total number and percentages of in vitro antimicrobial susceptibility test for common selected Gram-negative organisms collected from blood, intra-abdominal, respiratory and UTIs in the SMART Study (2017–2019)

Species No. of isolates AST Amikacin Aztreonam Cefepime Cefotaxime Cefoxitin Ceftazidime Ceftazidime-avibactam Ceftolozane-tazobactam Ceftriaxone Ciprofloxacin Colistin Ertapenem Imipenem Imipenem-relebactam Levofloxacin Meropenem Meropenem-vaborbactam Piperacillin-tazobactam Tobramycin
Escherichia coli 209 No. of tested isolates 209 209 209 72 209 209 137 209 209 145 NA 209 209 209 209 209 64 209 NA
Susceptible (%) 205 (98.09%) 104 (49.76%) 107 (51.20%) 28 (38.89%) 143 (68.42%) 107 (51.20%) 132 (96.35%) 188 (89.95%) 92 (44.02%) 52 (35.86%) 198 (94.74%) 201 (96.17%) 203 (97.13%) 55 (26.32%) 201 (96.17%) 62 (96.88%) 179 (85.65%)
Klebsiella pneumoniae 187 No. of tested isolates 187 187 187 70 187 187 117 187 187 129 NA 187 187 187 187 187 58 187 NA
Susceptible (%) 179 (95.72%) 124 (66.31%) 122 (65.24%) 45 (64.29%) 144 (77.01%) 120 (64.17%) 110 (94.02%) 159 (85.03%) 114 (60.96%) 77 (59.69%) 160 (85.56%) 161 (86.10%) 165 (88.24%) 77 (41.18%) 163 (87.17%) 50 (86.21%) 140 (74.87%)
Pseudomonas aeruginosa 164 No. of tested isolates 164 164 164 NA NA 164 111 164 NA 99 164 NA 164 164 164 164 NA 164 111
Susceptible (%) 160 (97.56%) 105 (64.02%) 126 (76.83%) 120 (73.17%) 104 (93.69%) 156 (95.12%) 51 (51.52%) 0 (0.00%) 115 (70.12%) 150 (91.46%) 125 (76.22%) 120 (73.17%) 112 (68.29%) 108 (97.30%)
Stenotrophomonas maltophilia 45 No. of tested isolates NA NA NA NA NA 45 NA NA NA NA NA NA NA NA 45 NA NA NA NA
Susceptible (%) 15 (33.33%) 34 (75.56%)
Enterobacter cloacae 26 No. of tested isolates 26 26 26 13 26 26 16 26 26 22 NA 26 26 26 26 26 7 26 NA
Susceptible (%) 25 (96.15%) 20 (76.92%) 23 (88.46%) 8 (80%) 1 (4.35%) 20 (76.92%) 16 (100%) 20 (76.92%) 19 (27.08%) 16 (84.21%) 23 (88.46%) 23 (88.46%) 24 (92.31%) 16 (61.54%) 24 (92.31%) 7 (100%) 20 (76.92%)
Serratia marcescens 20 No. of tested isolates 20 20 20 7 20 20 13 20 20 10 20 20 20 20 20 10 20 NA
Susceptible (%) 20 (100%) 20 (100%) 19 (95%) 7 (100%) 1 (5%) 20 (100%) 13 (100%) 19 (95%) 17 (85%) 9 (90%) NA 19 (95%) 14 (70%) 17 (85%) 11 (55%) 19 (95%) 9 (90%) 18 (90%)
Acinetobacter baumannii 19 No. of tested isolates 19 NA 19 9 NA 19 NA NA 9 19 19 NA 19 NA 19 19 NA 19 11
Susceptible (%) 12 (63.16%) 11 (57.89%) 2 (25.00%) 12 (63.16%) 0 8 (61.54%) 0 12 (63.16%) 11 (57.89%) 12 (63.16%) 11 (57.89%) 8 (72.73%)
Klebsiella aerogenes 11 No. of tested isolates 11 11 11 5 11 11 6 11 11 9 11 11 11 11 11 11 2 11 NA
Susceptible (%) 11 (100%) 9 (81.82%) 11 (100%) 3 (60.00%) 0 8 (72.73%) 6 (100%) 10 (90.91%) 8 (72.73%) 6 (66.67%) 11 (100%) 11 (100%) 10 (90.91%) 11 (100%) 5 (45.45%) 11 (100%) 2 (100%) 9 (81.82%)
Proteus mirabilis 10 No. of tested isolates 10 10 10 4 10 10 6 10 10 7 NA 10 10 10 10 10 3 10 NA
Susceptible (%) 10 (100%) 9 (90%) 9 (90%) 2 (50.00%) 9 (90%) 9 (90%) 6 (100%) 9 (90%) 8 (80%) 5 (71.43%) 10 (100%) 8 (80%) 9 (90%) 5 (50%) 10 (100%) 3 (100%) 10 (100%)
Klebsiella variicola 8 No. of tested isolates 8 8 8 1 8 8 7 8 8 4 NA 8 8 8 8 8 4 8 NA
Susceptible (%) 8 (100%) 8 (100%) 8 (100%) 1 (100%) 8 (100%) 8 (100%) 7 (100%) 8 (100%) 8 (100%) 4 (100%) 6 (75%) 6 (75%) 6 (75%) 7 (87.5%) 7 (87.5%) 4 (100%) 6 (75%)

Susceptibility tests were reported according to breakpoints of the CLSI 2020 Edition.

Assessment of the AST of the 503 clinical isolates of Enterobacterales demonstrated that the aminoglycoside amikacin was the most potent, ranging between 95.72% and 100%. E. coli demonstrated the highest phenotypic detection of extended-spectrum β-lactamases (ESBLs) at 55.77% (116/208) compared to 39.04% (73/187) for K. pneumoniae. Conversely, carbapenem susceptibility patterns of Enterobacterales isolates (E. coli, K. pneumoniae, E. cloacae, S. marcescens, P. mirabilis, K. varicola and K. aerogenes) were highly retained being lowest for K. pneumoniae (96.17%, 87.17%, 92.31%, 95%, and 100%, respectively). Additionally, further exploration for the new β-lactams/β-lactamase inhibitors (BLBLIs) combinations revealed highest activity for ceftazidime/avibactam with low level resistance (E. coli, 3.65%, K. pneumoniae 3.98% while for E. cloacae, S. marcescens and K. aerogenes at 0%), respectively.

For the broad BLBLIs, imipenem/relebactam resistance rates were 2.97% for E. coli (5/208) compared to 11.76% (22/187) for K. pneumoniae. Similarly, for E. coli, the overall ceftolozane/tazobactam resistance was 9.62% (20/208) compared to 14.97% (28/187) for K. pneumoniae while resistance for ceftazidime/avibactam was 3.65% (5/137) and 5.98% (10/117), respectively (Table 2).

Furthermore, assessment of antibacterial activity of 164 P. aeruginosa isolates and 19 A. baumannii isolates are shown in Table 2. All P. aeruginosa isolates showed 100% susceptibility to colistin, with slightly reduced susceptibility to amikacin (97.56%) and tobramycin (97.30%). Unlike other BLBLIs combinations highest susceptibility was observed for ceftolozane/tazobactam (95.12%). All isolates of A. baumannii were 100% susceptible to colistin while susceptibility to tobramycin was (72.73%) and (63.16%) for both imipenem and ceftazidime.

The frequency and distribution of β-lactamase genes among Enterobacterales and P. aeruginosa

Genomic studies of 70 Enterobacterales (32 K. peumoniae, 22 E. coli, seven E. cloacae and nine others), revealed the presence of 157 different β-lactamases resistant genes representing all major classes; class A 71.42% (50/70), class B 24.29% (17/70), class C 25.71% (18/70) and class D 27.14% (19/70) with the overall dominance of the ESBLs blaTEM-OSBL. Combining microbiological and genetic characteristics, K. pneumoniae was more resistant with underlying class B MBLs blaNDM and class D OXA-48-like β-lactamases (specifically blaOXA-181 and blaOXA-232) when compared to E. coli that exhibit mainly class A β-lactamases (Table 3). Additionally, genomic studies of 49 carbapenem-resistant, P. aeruginosa isolates, Pseudomonas-derived cephalosporinases (PDCs) were the most prevalent resistance genes with predominance of blaPDC-3 (32.65%, 16/49), blaPDC-19A (10.2%, 5/49) and blaPDC-5 (8.16%, 4/49), while the MBL carbapenemase blaVIM-2 was detected in only four isolates (8.16%, 4/49), as shown in Table 4.

Table 3.

The frequency of different β-lactamase genes amongst 70 Enterobacterales isolates collected between 2017 and 2019, which was resistance to different β-lactam antibiotic classes

Organism name No. of isolates Class A β-lactamase Class B β-lactamase Class C β-lactamase Class D β-lactamase Total
CTX-M-15 CTX-M-1-240G CTX-M-TYPE CTX-M-14 CTX-M-1-TYPE CTX-M-9-240D SHV-OSBL SHV-31 SHV-12 SHV-ESBL TEM-OSBL KPC-2 VEB-6 NDM-1 NDM-19 NDM-5 NDM-7 NDM-TYPE VIM-2 VIM-4 PDC-3 PDC-19A PDC-5 PDC-1 PDC-12 PDC-14 PDC-37 PDC-35 PDC-39 PDC-TYPE PDC-11 PDC-117 PDC-15 PDC-16 PDC-59 PDC-60 CMY-2-TYPE CMY-TYPE CMY-42 CMY-59 DHA-1 DHA-TRUNC DHA-TYPE ACT-TYPE MIR-TYPE OXA-181 OXA-232 OXA-48 OXA-TYPE
Pseudomonas aeruginosa 49 4 16 5 4 3 3 3 3 2 2 2 1 1 1 1 1 1 53
Klebsiella pneumoniae 32 16 4 1 1 1 26 3 2 21 1 5 1 3 1 1 2 13 2 104
Escherichia coli 22 7 3 2 1 1 10 1 1 2 2 4 3 1 1 39
Enterobacter cloacae 7 1 1 1 3 1 7
Serratia marcescens 3 1 1 2
Klebsiella variicola 2 2 2
Klebsiella aerogenes 2 1 1
Citrobacter freundii 1 1 1
Proteus mirabilis 1 1 1
Total 119 23 7 3 1 1 1 26 3 1 2 31 1 1 8 1 3 3 2 4 1 16 5 4 3 3 3 3 2 2 2 1 1 1 1 1 1 4 4 1 1 2 1 1 3 1 2 13 4 1 210
Subtotals 101 22 67 20 210

Table 4.

The frequency and distribution of different β-lactamase genes among 49 carbapenem-resistant Pseudomonas aeruginosa and 48 CREs isolates collect between 2017 and 2019

Species No. of isolates Class A β-lactamase Class B β-lactamase Class C β-lactamase Class D β-lactamase
CTX-M-15 CTX-M-1-240G CTX-M-TYPE CTX-M-14 CTX-M-1-TYPE CTX-M-9-240D SHV-OSBL SHV-31 SHV-ESBL TEM-OSBL KPC-2 NDM-1 NDM-19 NDM-5 NDM-7 NDM-TYPE VIM-2 VIM-4 PDC-3 PDC-19A PDC-5 PDC-1 PDC-12 PDC-14 PDC-37 PDC-35 PDC-39 PDC-TYPE PDC-11 PDC-117 PDC-16 PDC-59 PDC-60 CMY-2-TYPE CMY-42 DHA-1 DHA-TRUNC ACT-TYPE OXA-181 OXA-232 OXA-48 OXA-TYPE Total no. of genes
Pseudomonas aeruginosa 49 4 16 4 4 2 2 3 3 2 2 2 1 1 1 1 1 49
Klebsiella pneumoniae 27 12 4 1 1 1 21 2 2 17 1 5 1 3 1 1 13 2 88
Escherichia coli 11 2 3 1 3 1 1 2 2 1 1 17
Enterobacter cloacae 4 1 1 1 1 4
Serratia marcescens 3 1 1
Klebsiella variicola 2 2 2
Klebsiella aerogenes 1 1 1
Total 97 14 7 1 1 1 1 21 2 2 20 1 7 1 3 3 2 4 1 16 4 4 2 2 3 3 2 2 2 1 1 1 1 1 1 1 1 1 1 1 13 4 1 161
Subtotals 71 21 50 19 161

Microbiological and genetic characteristics of carbapenem-resistant Enterobacterales and carbapenem-resistant P. aeruginosa

Microbiological and genetic characteristics of 48 studied CREs (27 K. pneumonias, 11 E. coli, four Enterobacter cloacae and six others) revealed prevalence of ertapenem resistance in 89.58% (43/48), imipenem at 87.5% (42/48) and meropenem at 72.91% (35/48) of clinical isolates with 70.83% (34/48) concordant resistance to all three agents (Table 5). Furthermore, genetic studies revealed extreme rarity of other types of carbapenem-resistance genes with predominance of class D (blaOXA-48-like type, specifically: 12 blaOXA-232, 4 blaOXA-48, 2 blaOXA-181, and 1 blaOXA-type) and class B MBL (7 blaNDM-1, 3 blaNDM-5, 3 blaNDM-7, 2 blaNDM-type, 1 blaNDM-19 and 1 blaVIM-4) (Table 4).

Table 5.

Demographic profile of patients and phenotypic antimicrobial susceptibility among 49 carbapenem-resistant P. aeruginosa and 48 CREs isolates collected between 2017 and 2019. Sites of isolation: respiratory tract (RT), intrabdominal (IA), urinary tract UT, blood stream (BS)

Species Pseudomonas aeruginosa Klebsiella pneumoniae Escherichia coli Enterobacter cloacae Serratia marcescens Klebsiella variicola Klebsiella aerogenes Total (%)
Gender Number (%)
 Male 37 (75.51) 20 (74.07) 5 (44.45) 1 (25) 3 (100) 2 (100) 1 (100) 69 (71.13)
 Female 12 (24.49) 7 (25.93) 6 (54.55) 3 (75) 0 0 0 28 (28.87)
Location
 In-patient 27 (55.1) 21 (77.78) 8 (72.73) 3 (75) 0 0 0 59 (60.82)
 Intensive care unit 22 (44.9) 6 (22.22) 3 (27.27) 1 (25) 3 (100) 2 (100) 1 (100) 38 (39.18)
Age
 Paediatric < 14 years 2 (4.08) 1 (3.7) 0 0 0 0 0 3 (3.09)
 Adult 14-65 years 31 (63.27) 15 (55.56) 8 (72.73) 3 (75) 3 (100) 2 (100) 1 (100) 63 (64.95)
 Geriatric > 65 16 (32.65) 8 (29.63) 3 (27.27) 1 (25) 0 0 0 28 (28.87)
Site of isolation
 RT 36 (73.47) 11 (40.74) 0 1 (25) 3 (100) 1 (50) 1 (100) 53 (54.64)
 IA 5 (10.2) 5 (18.52) 6 (54.55) 1 (25) 0 1 (50) 0 18 (18.56)
 UT 2 (4.08) 7 (25.93) 5 (45.45) 2 (50) 0 0 0 16 (16.49)
 BS 6 (12.24) 4 (14.81) 0 0 0 0 0 10 (10.31)
No. of isolates susceptible to
 Aztreonam 14 (28.57) 9 (33.33) 0 1 (25) 3 (100) 2 (100) 1 (100)
 Cefepime 28 (57.14) 5 (18.52) 0 2 (50) 2 (66.67) 2 (100) 1 (100)
 Cefotaxime NA 10 (37.04) 0 2 (50) 3 (100) 2 (100) 1 (100)
 Ceftazidime 24 (48.98) 6 (22.22) 0 1 (25) 3 (100) 2 (100) 0
 Ceftriaxone NA 5 (18.52) 0 1 (25) 2 (66.67) 2 (100) 0
 Colistin 49 (100) NA NA NA NA NA NA
 Meropenem 8 (16.33) 4 (14.81) 3 (27.27) 2 (50) 2 (66.67) 1 (50) 1 (100)
 Ertapenem NA 1 (3.7) 0 1 (25) 2 (66.67) 0 1 (100)
 Imipenem 0 2 (7.41) 3 (27.27) 1 (25) 0 0 0
 Ceftolozane/tazobactam 41 (83.67) 5 (18.52) 1 (9.09) 1 (25) 2 (66.67) 2 (100) 1 (100)
 Imipenem/relebactam 35 (71.43) 6 (22.22) 5 (45.45) 2 (50) 0 0 1 (100)
 Pipracillin/tazobactam 19 (38.78) 2 (7.41) 0 1 (25) 2 (66.67) 0 1 (100)
Total (%) 49 (100) 27 (100) 11 (100) 4 (100) 3 (100) 2 (100) 1 (100) 97 (100)

Microbiological evaluation of the 49 carbapenems-resistant P. aeruginosa isolates against imipenem and imipenem/relebactam, revealed that 14 isolates were resistant to both (concordant resistance), while 35 P. aeruginosa isolates were resistant to imipenem but susceptible to imipenem/relebactam (discordant resistant group) indicating relebactam restored 71.4% (35/49) of imipenem activity. Four of the concordant resistant isolates harboured class B MBL blaVIM2 while the rest were AmpC-type β-lactamases in the form of PDCs speared by blaPDC-3. Conversely, the discordant group although showed embedded PDCs including blaPDC-3 (eight isolates), were of diverse types including blaPDC-19A, blaPDC-1, blaPDC-5, blaPDC-14 and blaPDC-37 (five then three isolates each respectively). Furthermore, the eight P. aeruginosa isolates that were resistant to ceftolozane/tazobactam harboured the following β-lactamase genes: four blaVIM-2, four blaPDC-3, two blaPDC-5 and two blaPDC-35 Supplementary Table S2).

Discussion

The impact of AMR is a major global threat to humanity because of direct clinical as well as indirect economic and social consequences.12 To overcome AMR challenges, the widely adopted recommendation is to implement cornerstone concepts of basic and advanced surveillance studies to assess pathogens evolving microbiological characteristics as well as examine dynamic resistance mechanisms.18 Furthermore, following the implementation of conventional practices in modern healthcare such as regular bacterial phenotypic analysis, genotypic and molecular epidemiology has been advocated as crucial advanced concept to face unexpected challenges particularly at different regional healthcare settings.19

The SMART is an international research collaboration for the study of AMR in GNB focusing on four key infections: RTIs and UTIs together with IAIs and BSIs. The study started about two decades ago on a small scale then expanded as an ongoing global surveillance study.17 In the Middle East and Africa regions, 24 medical centres participated in the study detailed as follows (arranged alphabetically): Israel, Jordan, Kenya, Kuwait, Lebanon, Morocco, Qatar, Saudi Arabia, South Africa, Tunisia and the United Arab Emirates.

The results of surveillance of GNB from secondary and tertiary healthcare from Qatar with emphasis on the four specified sites of infections demonstrated dominance of four key pathogens namely, E coli, K. pneumoniae, P. aeruginosa and S. maltophiila, which are in line with published regional surveillance studies.6,20–23 Of note, E. coli remains the main pathogen for UTIs in contrast to K. pneuminae that were isolated mainly from RTIs followed by UTIs and IAIs but with established higher AMR (Table 2). This reflects that K. pneumoniae isolates from HAIs are mainly secondary to hospital or ventilation-associated pneumonia, which probably explains the high observed resistance rates. Similar epidemiological studies highlighted escalating MDR-GNB at critical care settings particularly rising trends of extremely-drug resistant K. pneumoniae.21,24,25

The presented results are the first comprehensive surveillance study in the country, and it reflects an alarmingly high-level AMR profile since for E. coli, the prevalence of phenotypic resistance pattern for ESBLs was higher than half of isolates (55.7%) while for K. pneumoniae was 39%. Almost a decade earlier, limited studies from Qatar at the existed but smaller healthcare settings focusing on 452 episodes of BSIs, established almost half ESBL prevalence (27.8% for E. coli and 17.9% for K. pneumoniae respectively) while a surveillance study of 629 consecutive Enterobacterales from critical care settings between 2012 and 2013 revealed the overall prevalence of 17.3%.26,27

In the Middle East region, focusing on GNB, the escalating problem of AMR is predominated by ESBL production with multifactorial explanations mainly from existing diverse population, frequent influx of seasonal international travellers together with the widely practised inappropriate and high antimicrobial consumption.28–30

Although E. coli exhibited higher ESBLs phenotypic resistance patterns compared to K. pneumoniae, detailed microbiological and genetic characteristics points towards the opposite where E. coli demonstrated lower-level resistance to carbapenems when compared to K. pneumoniae (meropenem resistance of 3.83% and 12.83%, respectively), which has not changed even for novel agents not currently available at the hospital formulary such as imipenem/relebactam (2.83% and 11.76%, respectively). Similarly, regarding newer agents of BLBLIs such as ceftazidime/avibactam and ceftolozane/tazobactam, in E. coli the overall resistance rates for the two agents were 3.65% and 10.05%, while for K. pneumoniae these were 5.98% and 14.97%, respectively. Again, this is showing rising trends for the two agents since between 2012 and 2013, when 109 ESBL producing Enterobacterales isolated from critical care were tested against ceftazidime/avibactam and ceftolozane/tazobactam, it demonstrated AMR rates of 0.9%.31

Distinctively when 49 carbapenem-resistant P. aeruginosa were tested against imipenem and imipenem/relebactam, all isolates were resistant to imipenem. Whereas relebactam restored in vitro imipemen activity in 71.4% (35/49) of isolates. Four of these isolates resistant to imipenem/relebactam harboured the MBL blaVIM-2 while the rest harboured different class C AmpC-type β-lactamases in the form of PDCs. Intriguingly, none of the resistant isolates harboured blaIMP as observed elsewhere.32 Comparatively, avibactam, which is a potent BLBLI capable of inhibiting class A, C and D β-lactamases but is overwhelmed by class B MBL such as blaNDM and blaVIM whereas the closely related relebactam has similar inhibition spectrum albeit with absent activity against class D OXA-type carbapenemases, demonstrated supplementary antimicrobial potency.33 Of note, for P. aeruginosa the classic pearl of wisdom that genotypic resistance patterns does not always equate phenotypic ones because there are other complex resistance mechanisms involving diverse membrane pathways such as the loss of porin channels and overproduction efflux pumps.34 While imipenem is more resistant to GNB ejecting efflux pumps when compared to meropenem, it remains susceptible to porin channel mutations that hinder its inward penetration conferring phenotypic resistance.33,35 In P. aeruginosa, the loss of OprD porin channels together with class C ESBLs and AmpC such as PDC is the hallmark of imipenem resistance.36

Among carbapenem-resistant P. aeruginosa, eight isolates that were resistant to ceftolozane/tazobactam harboured different β-lactamase genes: class B blaVIM-2; class C blaPDC-3, blaPDC-5 and blaPDC-35 and class B blaVIM-2 and blaPDC-35, which have been associated with high-level resistance to ceftolozane/tazobactam.37,38 When comparing discordant results of the in vitro activity for the novel BLBLIs for most Enterobacterales, it favours ceftazidime/avibactam over ceftolozane/tazobactam but not for P. aeruginosa where the latter demonstrated superior activity. Nevertheless, antimicrobials activity cannot be reliably extrapolated to clinical practice since evaluation for the two agents, demonstrated similar efficacy with no noticeable significant clinical differences.31,39–41

Genetic characterization of 70 Enterobacterales including 48 isolates that were CREs revealed the presence of all major β-lactamase classes with a predominance of blaCXM-15 ESBLs in conjunction with other historic resistant genes such as blaTEM and blaSHV distributed in K. pneumoniae and E. coli when compared to other GNB (Tables 3 and 4). The plasmid-mediated ESBL gene, blaCXM-15 has a global distribution with a direct link to advanced cephalosporins resistance being the most widely reported resistant gene from all global regions including the Middle East and Gulf countries.27,28,42,43 Noticeably, E. coli resistant genes were mainly class A ESBLs while K. pneumonia demonstrated more divergent pattern with the presence of a multitude of class D OXA-type ESBLs as well as carbapenemases such as blaNMD and blaOXA-48 and its closely related blaOXA-181 and blaOXA-232. These mutated resistant genes are derivatives from their parent carbapenemase blaOXA-48 with few point mutations.44 Locally, our PCR-based molecular techniques will report these different resistant genes grouped as blaOXA-48. Distinctively, among the 70 Enterobacterales and 48 CREs only a single K. pneumoniae isolate harboured blaKPC-2, which was probably imported as shown in similar local CREs studies.45 The plasmid-mediated KPCs serine carbapenemases are historically linked to the West, particularly North America and Southern Europe, although they have been reported in some other distant countries such as Israel and China but this has been extremely rare in our region.42,45,46 Furthermore, current molecular epidemiology, affirms reported and observed dominance of the carbapenemase blaOXA types and blaNDM in the region.28,45,47

Despite the diverse microbiological and genomic outcomes of the study, there are some noticeable limitations. The prospective study collected representative pathogens from specific infection sites that have changed over the study period, which might lessen the overall epidemiological accuracy. Furthermore, for microbiological and genetic testing, although the defined protocol was followed, it did change over time. For example, as novel antibiotics were introduced into clinical practice, they were evaluated but against fewer isolates. Therefore, a true comparison cannot be accurately reported. Last, the methods for genetic and molecular characterization of resistance followed the central study protocol, which is more detailed when compared to local practice. That might generate more elaborative results that are difficult to benchmark at local levels.

In conclusion, the SMART surveillance study from Qatar between 2017 and 2019 encompassed a sizeable collection of 748 isolates comprising 37 different GNB dominated by E. coli, K. pneumoniae, P. aeruginosa and S. maltophilia showing significant microbiological and genetic characteristics with a prevalence of divergent types of ARGs particularly blaCXM-15 whereas K. pneumonia isolates collected mainly from respiratory specimens were more resistant to existing as well as novel antimicrobials with a distinct overall dominance of blaOXA type and blaNDM carbapenemases.

Supplementary Material

dlad086_Supplementary_Data

Acknowledgements

We would like to express our gratitude to all involved staff at the division of microbiology of the department of laboratory medicine and pathology at Hamad Medical Corporation who were pivotal in adhering to the study protocol through timely processing of isolates, logging of details as well as facilitating collaborative links throughout the study period. The publication of the academic research is facilitated through collaboration and agreement with Qatar National Library (QNL).

Contributor Information

Mazen A Sid Ahmed, Philadelphia Department of Public Health, Laboratory Services, Philadelphia, USA.

Hawabibee Mahir Petkar, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar.

Thoraya M Saleh, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar.

Mohamed Albirair, Department of Global Health, University of Washington, Seattle, USA.

Lolita A Arisgado, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar.

Faiha K Eltayeb, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar.

Manal Mahmoud Hamed, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar.

Muna A Al-Maslamani, Division of Infectious Diseases, Communicable Diseases Centre, Hamad Medical Corporation, Doha, Qatar.

Abdul Latif Al Khal, Division of Infectious Diseases, Communicable Diseases Centre, Hamad Medical Corporation, Doha, Qatar.

Hussam Alsoub, Division of Infectious Diseases, Communicable Diseases Centre, Hamad Medical Corporation, Doha, Qatar.

Emad Bashir Ibrahim, Division of Microbiology, Department of Laboratory Medicine and Pathology, Hamad Medical Corporation, Doha, Qatar; Biomedical Research Centre, Qatar University, Doha, Qatar.

Hamad Abdel Hadi, Division of Infectious Diseases, Communicable Diseases Centre, Hamad Medical Corporation, Doha, Qatar.

Funding

The SMART surveillance program is sponsored by MSD. We thank MSD and International Health Management Associates, S.A., Schaumburg, Illinois, USA (IHMA) for providing access to the database of the SMART epidemiological surveillance study for the purpose of analysis and evaluation. We must emphasize that there were no pharmaceutical influences during the interpretation of analysed results.

Transparency declarations

H.A.H. and E.B.I. disclose honorarium for collaboration in educational meetings sponsored by MSD. The rest of the authors have no conflicts of interest related to this academic publication.

Supplementary data

Tables S1 and S2 are available as Supplementary data at JAC-AMR Online.

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Supplementary Materials

dlad086_Supplementary_Data

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