Early Detection of Ventilator-associated Pneumonia (VAP) (cheqVAP)

Diagnostics of VAP relies on two complementary strategies: meeting pre-defined clinical criteria and evidence of pathogens in the lower respiratory tract. Mere reliance on clinical symptoms, such as radiologic evidence, systemic signs of inflammation and indices of compromised pulmonary function reportedly lead to misdiagnosis. Current diagnostic procedures recommend gathering of evidence for new or progressive lung infiltrates from serial chest radiographies, together with co-existing clinical signs of impaired respiratory function. Microbiological confirmation of pathogen presence requires examination of airway secretions collected by invasive bronchoalveolar lavage which demands specific technical skills and staff training. Although verification of causal pathogens is essential for the introduction of targeted antibiotic therapy, the procedure is time-consuming and qualitative in reportedly less than 30 % of the cases. Furthermore, the currently adopted diagnostic approaches are based on sporadic information sampling and do not support continuous monitoring and evaluation of the effect of therapeutic interventions. All above-listed flaws and shortcomings emphasize the need for rapid, reliable and non-invasive recognition of VAP, preferably in a setting that would permit continuous bedside monitoring and timely introduction of targeted drug therapy.

The study objective consists in sequential collection of exhaled breath condensates (EBC) in ICU patients receiving invasive ventilation. The EBC samples will be subjected to determination of volatile organic compound (VOC) profiles by Stimulated Raman Spectroscopy (SRS) which, upon individual matching to routinely collected clinical parameters, may become putative biomarkers for the early recognition of VAP. Evidence has accumulated in support of the assumption that certain metabolites in EBC might display significant profile differences as to their size, hydrophobicity and electrical charge. Identification of VAP-specific profiles of VOC will provide the basis for the generation of a data base enabling the construction and standardization of a bedside device for continuous real-time point-of-care monitoring of VAP hazard in patients on invasive ventilation.