RESUMO
The menace of antimicrobial resistance affecting public health is rising globally. Many pathogenic bacteria use mechanisms such as mutations and biofilm formation, significantly reducing the efficacy of antimicrobial agents. In this cross-sectional study, we aimed to determine the prevalence of selected extended-spectrum ß-lactamase (ESßL) genes and analyse the biofilm formation abilities of the isolated bacteria causing urinary tract infection among adult patients seeking Medicare at Kiambu Level 5 Hospital, Kenya. The double-disc synergy test was used for phenotypic identification of ESßL-producing isolates, while microtitre plate assays with some modifications were used for the biofilm formation test. Ten isolates were bioassayed for ESßL genes out of 57 bacterial isolates obtained from urine samples. This study found the bla TEM genes to be the most prevalent ESßL type [10/10 (100â%)], followed by blaOXA and blaSHV genes at 4/10 (40â%) and 3/10 (30â%), respectively. In addition, co-carriage of blaTEM and blaSHV was 50â% lower than that of blaTEM+bla OXA genes at 66.7â% among Escherichia coli isolates studied. Biofilm formation was positive in 36/57 (63.2â%) of the isolates tested, with most being Gram-negative [25/36 (69.4â%)]. Escherichia coli [15/36 (41.7â%)], Klebsiella species [7/36 (19.4â%)] and Staphylococcus aureus [7/36 (19.4â%)] were the dominant biofilm formers. However, there was no significant difference in biofilm formation among all tested isolates, with all isolates recording P-values >0.05. In light of these findings, biofilm formation potential coupled with antimicrobial resistance genes in urinary tract infection isolates may lead to difficult-to-treat infections.
RESUMO
Antibiotic resistance poses a grave global public health threat, exacerbated by widespread and often inappropriate antibiotic usage. Vigilant surveillance of antibiotic utilization and emergence of antimicrobial resistance (AMR) is essential. Of particular concern in the era of AMR is the persistent issue of chronic wound infections. To address this, we conducted a comprehensive evaluation of wound isolates from chronic wounds at Jaramogi Oginga Odinga Teaching and Referral Hospital (JOOTRH) in Kenya, to identify relevant bacteria and assess their drug resistance patterns.Wound samples were collected and processed using standard microbiological methods. Bacterial isolates were identified and assessed for their susceptibility to a panel of antibiotics using the Kirby-Bauer disk diffusion method. A total of 103 bacterial isolates were obtained from the wound samples, with a higher prevalence in male patients (59%). Staphylococcus aureus (20.7â%) emerged as the most predominant pathogen, followed by Klebsiella spp. (14.8â%), Pseudomonas aeruginosa spp. (14.8â%) and Escherichia coli (4.4â%) in wound samples. High levels of antibiotic resistance were observed among the isolates, with the highest resistance rates reported for cotrimoxazole (48.1â%), clindamycin (25.9â%) and erythromycin (25.9â%). Furthermore, among the isolates, 75â% produced haemolysin and protease, while 50â% produced lipase and phospholipase, factors that enhance virulence and survival. The findings of this study highlight the alarmingly high prevalence of antibiotic resistance among bacterial pathogens isolated from chronic wounds in Kenya. This poses a major challenge to the effective management of chronic wound infections. There is an urgent need to implement effective antimicrobial stewardship programs and develop new antibiotics to combat the growing threat of antibiotic resistance.
RESUMO
Vibrio cholerae is a biofilm-forming pathogen with various virulence phenotypes and antimicrobial resistance traits. Phenotypic characteristics play a critical role in disease transmission and pathogenesis. The current study elucidated antibiofilm formation activity, profiled antibiotic-resistant genes and virulence factors of toxigenic Vibrio cholerae isolates from the cholera outbreak in Kisumu County, Kenya. Vibrio cholerae O1 isolates collected during the 2017 cholera outbreak in Kisumu County, Kenya, were utilized. Biofilm and virulence factors were profiled using standard procedures. The study confirmed 100 isolates as Vibrio cholerae , with 81 of them possessing cholera toxin gene (ctxA). Additionally, 99 of the isolates harboured the toxR gene. The study further revealed that 81 and 94 of the isolates harboured the class I integron (encoded by inDS gene) and integrating conjugative element (ICE), respectively. Antibiotic resistance assays confirmed tetracycline resistance genes as the most abundant (97 isolates). Among them were seven isolates resistant to commonly used antibiotics. The study further screened the isolates for antibiofilm formation using various antibiotics. Unlike the four strains (03/17-16, 02/17-09, 04/17-13), three of the strains (04/17-07, 06/17-14 and 05/17-03) did not form biofilms. Further, all the seven isolates that exhibited extensive antibiotic resistance produced haemolysin while 71.42%, 85.71 and 71.42â% of them produced protease, phospholipases and lipase, respectively. This study provides and in-depth understanding of essential features that were possibly responsible for V. cholerae outbreak. Understanding of these features is critical in the development of strategies to combat future outbreaks.
RESUMO
BACKGROUND: Multiple drug resistance has become a major threat to the treatment of cholera. Recent studies in Kenya have described the epidemiology, especially the risk factors, of cholera; however, there is little information on the phenotypic and drug susceptibility patterns of Vibrio cholerae (V. cholerae) in outbreaks that in the recent past have occurred in western Kenya. AIM: To characterise and determine the antibiotics' susceptibility profiling of toxigenic V. cholerae isolates from Kisumu County. SETTING: The project was conducted in Kisumu County, Kenya. METHODS: A total of 119 V. cholerae O1, biotype El Tor, isolates collected during 2017 cholera outbreak in Kisumu County were used for this study. The samples were cultured on thiosulphate-citrate-bile salts sucrose (TCBS) agar and biochemical tests were carried out using standard procedures. Susceptibility tests were conducted by using various conventional antibiotics against standard procedures. RESULTS: Of the 119 isolates, 101 were confirmed to be V. cholerae belonging to serotypes Inaba and Ogawa, with Inaba being the predominant serotype (73.95%). The isolates were susceptible to ciprofloxacin (100%), ofloxacin (100%), gentamycin (100%), doxycycline (99%), ceftriaxone (99%) and streptomycin (96.04%) antimicrobials, and resistant to erythromycin (53.47%), amoxicillin (64.4%), nalidixic acid (83.2%) and ampicillin (89.11%), with high resistance to cotrimoxazole (99%) and tetracycline (97%). CONCLUSION: Vibrio cholerae was resistant to multiple antibiotics, including those commonly used in the management of cholera. Taken together, there is a need to carry out regular surveillance on antimicrobial drug resistance during outbreaks.
