Sonakshi Dwivedi, Vaishali Rahangdale, Swati Bhise, Sunanda Zodpey,
Volume 18, Issue 3 (May-Jun 2024)
Abstract
Background: Rampant and irrational use of antibiotics led to antimicrobial resistance in intensive care units, directly influencing the clinical outcome. The prior introduction of antibiotics, especially broad-spectrum antibiotics, has been identified as a leading cause of hospital-acquired pneumonia. The present study aims to examine the existing scenario of antibiotic resistance due to multidrug-resistant organisms that are detected in mechanically ventilated patients.
Methods: This cross-sectional study was conducted in the department of Microbiology of a tertiary care hospital in Central India. A total of 410 endotracheal secretions were collected. The endotracheal aspirate of adult patients admitted to the medicine intensive care unit and on mechanical ventilation was received at the microbiology laboratory for processing by standard bacteriological techniques. Drug susceptibility testing was done using the Kirby-Bauer disc diffusion method according to the indications mentioned in Clinical and Laboratory Standards Institute 2021.
Results: Out of 410 collected endotracheal secretion samples, 332 (81 %) samples demonstrated bacterial growth. A total of 265 (80%) cases fulfilled the inclusion criteria. From 265 samples, 92 (34.7 %) patients were clinically and microbiologically confirmed as cases of ventilator-associated pneumonia. Over eighty percent of gram-negative bacilli were multidrug-resistant strains (Acinetobacter baumannii, Klebsiella pneumoniae, and Pseudomonas aeruginosa).
Conclusion: Real understanding of multidrug-resistant pathogens, early isolation as well as avoiding long-term antibiotic intake can reduce mortality levels currently linked with late-onset ventilator-associated pneumonia.
Shayosree Sarkar, Sonal Chavan, Geetika Agrawal, Heena Rahangdale, Sunanada Zodpey,
Volume 19, Issue 4 (Jul-Aug 2025)
Abstract
Background: Burkholderia cepacia complex (BCC) is an opportunistic nosocomial pathogen known to cause severe infections in neonates, including those affecting the respiratory and urinary tracts, as well as bloodstream infections. Consequently, BCC has the potential to instigate outbreaks originating from various sources. This study was undertaken to facilitate the early detection and effective control of a BCC-related outbreak.
Methods: A cross-sectional study, conducted in July 2023 at a tertiary care hospital, investigated bacterial isolates from neonates. Over a one-month period, eleven neonates' blood cultures grew motile, oxidase-positive, non-fermenting gram-negative bacilli. These isolates were presumptively identified as BCC based on conventional biochemical tests and their antimicrobial susceptibility profiles. The recurring isolation of an identical bacterial strain within the neonatal intensive care unit (NICU) strongly suggested an ongoing outbreak. Consequently, active surveillance was initiated to identify the source of the infection and implement containment measures. The identity of the isolated strains was subsequently confirmed using the VITEK 2 Compact microbiology analyser (BioMérieux, France).
Results: Surveillance identified the BCC sources for all 11 affected neonates. The investigation traced the infection origins to several environmental factors within the healthcare setting, including intravenous (IV) catheters and neonatal cradles, operating theatre (OT) beds, and instrument trolleys in the labour room where the deliveries occurred. Furthermore, all environmental BCC isolates demonstrated genetic relatedness to the clinical isolates concurrently exhibiting a similar antibiotic susceptibility pattern. Timely interventions were instrumental in controlling the outbreak.
Conclusion: This study highlights the critical role of the hospital infection control team in effectively managing a BCC outbreak among neonates.
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