A potential role of aminoglycoside resistance in endemic occurrence of Pseudomonas aeruginosa strains in lower airways of mechanically ventilated patients

Abstract Background The bacterial density of Pseudomonas aeruginosa is closely related to its pathogenicity. We evaluated the effect of airway P. aeruginosa density on the clinical course of mechanically ventilated patients and the therapeutic efficacy of antibiotics. Methods We retrospectively analyzed data of mechanically ventilated ICU patients with P. aeruginosa isolated from endotracheal aspirates. Patients were divided into three groups according to the peak P. aeruginosa density during ICU stay: low (≤ 104 cfu/mL), moderate (105‒106 cfu/mL), and high (≥ 107 cfu/mL) peak density groups. The relationship between peak P. aeruginosa density and weaning from mechanical ventilation, risk factors for isolation of high peak density of P. aeruginosa, and antibiotic efficacy were investigated using multivariate and propensity score-matched analyses. Results Four-hundred-and-sixty-one patients were enrolled. Patients with high peak density of P. aeruginosa had higher inflammation and developed more severe respiratory infections. High peak density of P. aeruginosa was independently associated with few ventilator-free days on day 28 (P < 0.01) and increased ICU mortality (P = 0.047). Risk factors for high peak density of P. aeruginosa were prolonged mechanical ventilation (odd ratio [OR] 3.07 95% confidence interval [CI] 1.35‒6.97), non-antipseudomonal cephalosporins (OR 2.17, 95% CI 1.35‒3.49), hyperglycemia (OR 2.01, 95% CI 1.26‒3.22) during ICU stay, and respiratory diseases (OR 1.9, 95% CI 1.12‒3.23). Isolation of commensal colonizer was associated with lower risks of high peak density of P. aeruginosa (OR 0.43, 95% CI 0.26‒0.73). Propensity score-matched analysis revealed that antibiotic therapy for patients with ventilator-associated tracheobronchitis improved weaning from mechanical ventilation only in the high peak P. aeruginosa group. Conclusions Patients with high peak density of P. aeruginosa had worse ventilator outcome and ICU mortality. In patients with ventilator-associated tracheobronchitis, antibiotic therapy was associated with favorable ventilator weaning only in the high peak P. aeruginosa density group, and bacterial density could be a good therapeutic indicator for ventilator-associated tracheobronchitis due to P. aeruginosa.

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Disparate evolution of virus populations in upper and lower airways of mechanically ventilated patients

10.1101/509901 ◽

2019 ◽

Cited By ~ 1

Author(s):

Björn F. Koel ◽

Frank van Someren Gréve ◽

René M. Vigeveno ◽

Maarten Pater ◽

Colin A. Russell ◽

...

Keyword(s):

Influenza Virus ◽

Amino Acid ◽

Respiratory Tract ◽

Lower Respiratory Tract ◽

Mechanically Ventilated ◽

Mechanically Ventilated Patients ◽

Lower Airways ◽

Human Airways ◽

Virus Variation ◽

Ventilated Patients

AbstractIn routine surveillance and diagnostic testing, influenza virus samples are typically collected only from the upper respiratory tract (URT) due to the invasiveness of sample collection from the lower airways. Very little is known about virus variation in the lower respiratory tract (LRT) and it remains unclear if the virus populations at different sites of the human airways may develop to have divergent genetic signatures. We used deep sequencing of serially obtained matched nasopharyngeal swabs and endotracheal aspirates from four mechanically ventilated patients with influenza A/H3N2 infections. A physical barrier separating both compartments of the respiratory tract introduced as part of the medical procedures enabled us to track and compare the genetic composition of the virus populations during isolated evolution in the same host. Amino acid variants reaching majority proportions emerged during the course of infection in both nasopharyngeal swabs and endotracheal aspirates, and amino acid variation was observed in all influenza virus proteins. Genetic variation of the virus populations differed between the URT and LRT and variants were frequently uniquely present in either URT or LRT virus populations of a patient. These observations indicate that virus populations in spatially distinct parts of the human airways may follow different evolutionary trajectories. Selectively sampling from the URT may therefore fail to detect potentially important emerging variants.ImportanceInfluenza viruses are rapidly mutating pathogens that easily adapt to changing environments. Although advances in sequencing technology make it possible to identify virus variants at very low proportions of the within-host virus population, several aspects of intrahost viral evolution have not been studied because sequentially collected samples and samples from the lower respiratory tract are not routinely obtained for influenza surveillance or clinical diagnostic purposes. Importantly, how virus populations evolve in different parts of the human respiratory tract remains unknown. Here we used serial clinical specimens collected from mechanically ventilated influenza patients to compare how virus populations develop in the upper and lower respiratory tract. We show that virus populations in the upper and lower respiratory tract may evolve along distinct evolutionary pathways, and that current sampling and surveillance regimens likely capture only part of the complete intrahost virus variation.

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