High-dose Inhalations of Nitric Oxide in the Treatment of Pneumonia

Principal investigator: T.P. Kalashnikova, MD, PhD. Sub-investigators: N.O.Kamenshchikov, MD, PhD, I.V. Kravchenko, MD, Yu.A. Arsenyeva, MD, Yu.K. Podoksenov, MD, PhD, DMedSci, M.S. Kozulin, MD, M.B. Gorchakova, MD, B.N. Kozlov, MD, PhD, DMedSci, A.A. Boshchenko, MD, PhD, DMedSci.

RESEARCH RELEVANCE Pneumonia remains one of the most common infectious respiratory diseases worldwide. Community-acquired pneumonia (CAP) is defined as pneumonia that is acquired outside the hospital or diagnosed in the first 48 hours from hospitalization. Nosocomial pneumonia (NP) is diagnosed in individuals with symptoms of the disease that develop 48 hours or more after the patient's hospitalization. The most common causative agents of CAP are S. pneumoniae, M. pneumoniae, C. pneumoniae, H. influenza, as well as viruses and microbial associations. In recent years, there has been an increase in the resistance of CAP pathogens to antibiotics of the group of aminopenicillins, cephalosporins, and macrolides.

In the etiological structure of NP, the leading role belongs to gram-negative microorganisms. The main pathogens are representatives of Enterobacteriaceae (including Klebsiella pneumoniae and E.coli), Acinetobacter baumannii, Pseudomonas aeruginosa, characterized by a high level of resistance to antimicrobial drugs.

Considering the high prevalence of pneumonia, the continuous increase in the resistance of microorganisms to antimicrobial agents, the high mortality rate from adverse reactions caused by multidrug-resistant bacteria, the lack of development of new drugs with proven antibacterial effectiveness, and the high economic costs of treatment, it is urgent to search for alternative ways to increase efficiency in the treatment of pneumonia . From this point of view, the addition of inhaled high doses of nitric oxide (iNO) to standard antibacterial therapy seems promising.

The positive results of using NO have been proven in the treatment of patients with pulmonary hypertension, chronic obstructive pulmonary disease, acute respiratory distress syndrome (ARDS), and in the treatment of wound processes. There is a cardioprotective and nephroprotective effect of this molecule that has been described. In recent years, data have appeared on the successful use of iNO in the treatment of viral pneumonia, in particular in pneumonia caused by the Severe acute respiratory syndrome-related coronavirus 2 (SARS-CoV2). High concentrations of nitric oxide cause cytotoxic, antibacterial, antiviral, and antifungal effects.

The use of iNO for pneumonia is pathogenetically justified. It has a selective vasodilating effect on pulmonary blood vessels with no systemic effect on hemodynamics. By reducing vascular resistance in the ventilated areas of lungs, it improves ventilation-perfusion ratio and can increase systemic oxygenation, reduce pulmonary hypertension and right ventricular dysfunction, and promotes the inclusion of previously unventilated alveoli in gas exchange.

The use of NO appears even more justified in the treatment of pneumonia in patients undergoing cardiac surgery under cardiopulmonary bypass (CPB), since their lungs are subject to ischemia and reperfusion injury during CPB.

In recent years, more and more evidence has emerged that the mechanisms of antimicrobial action of NO differ from those of modern traditional antibiotics, which is most relevant in the treatment of infections caused by multidrug-resistant bacteria and polymicrobial infections.

The antibacterial effect of NO at a dose of 160 ppm (parts per million) and higher has been described for a number of microorganisms. The safety of using iNO for humans in doses of 160-200 ppm for 15-30 minutes 2 to 5 times a day has been demonstrated in a number of clinical studies with Mycobacterium abscessus, other complex clinical situations, in patients with cystic fibrosis, in pregnant women and newborns. In contrast to bacterial membranes sensitive to NO, the stability of membranes of epithelial cells and fibroblasts and the absence of cytolysis when exposed to nitric oxide 200 ppm 3 times a day was proven in experimental studies and on cells of living human tissues.

PRIMARY OBJECTIVE To test the hypothesis that the addition of high-dose inhaled nitric oxide therapy to standard treatment has a positive effect on the clinical course of pneumonia and the structure and function of cardiopulmonary system.

SECONDARY OBJECTIVES

• To assess the timing of resolution of pneumonia in the main (with iNO) and control (without iNO) groups
• To assess differences in the dynamics of acute phase reactants in the main and control groups.
• To assess differences in the X-ray of the lungs and its dynamics in the main and control groups.
• To assess differences in variables of the functional state of the lungs and their dynamics according to spirometry and the 6-minute walk test under the influence of therapy in the main and control groups.
• To study differences in the dynamics of the main variables of the structural and functional state of the heart during echocardiography in the main and control groups.

The effectiveness of the study will be assessed by such a concept as "end point".

The primary composite endpoint will be resolution of pneumonia. The term "resolution of pneumonia" will include three criteria: achieving an oxygenation index SpO2/fraction of inspired oxygen (FiO2) >315; Respiratory Rate (RR)<20; discontinuation of antibacterial therapy.

Secondary hospital endpoints:

1. Difference in the duration of systemic inflammatory response syndrome (fever, leukocytosis, a shift in the white blood cells (WBC) towards more immature cells, increased levels of C-reactive protein (CRP), procalcitonin (PCT) in the study groups.
2. Difference in the duration of respiratory support in the study groups.
3. Difference in the frequency of changing antibacterial treatment regimens due to ineffectiveness in the compared study groups.
4. Difference in the frequency of transfer of patients to non-invasive ventilation (NIV), mechanical ventilation in the study groups.
5. Difference in the incidence of sepsis and septic shock in both groups.
6. Difference in the frequency of decrease in oxygen saturation after 72 hours from the start of therapy below 95% with an initially normal level or by 3% or more with an initially reduced level in the main and control groups.
7. Difference in the frequency of negative computer tomography (CT) dynamics after 72 hours of therapy in the study groups.
8. Difference in the frequency of increase in right atrial and ventricle volume index and/or peak tricuspid regurgitation velocity and/or decrease in contractile function of the right ventricle after 72 hours of therapy and with the resolution of pneumonia in groups
9. Difference in the distance traveled according to the 6-minute walk test (6MWT) with the resolution of pneumonia in the main and control groups.
10. Difference in the frequency and severity of the development of ventilatory disorders during spirometry at the time of resolution of pneumonia in the main and control groups.
11. Difference in scores according to EQ-5D-5L quality of life questionnaire in the main and control groups.
12. Difference in the percentage of mortality caused by pneumonia or its complications (sepsis, multiple organ failure, acute respiratory failure) in the compared groups.

The study will include patients who underwent cardiac surgery under CPB with NP diagnosed in the postoperative period, as well as patients hospitalized for CAP. Patients will be randomized into 4 groups:

Subproject NO-PNEUMONIA-NP Group 1, main group, n=50 Standard antibacterial therapy + NO 200 ppm 3 times a day for 30 minutes Group 2, control group, n=50, Standard antibacterial therapy Subproject NO-PNEUMONIA-CAP Group 3, main group, n=50 Standard antibacterial therapy + NO 200 ppm 3 times a day for 30 minutes Group 4, control group, n=50 Standard antibacterial therapy. A special device, which synthesizes nitric oxide from atmospheric air directly during therapy, will be used. The technology is based on the process of oxidation of atmospheric nitrogen in a nonequilibrium gas discharge plasma and is characterized by high operating accuracy and stable maintenance of NO concentration in the breathing mixture.

ASSESSMENT OF CLINICAL EFFECTIVENESS Clinical effectiveness will be assessed daily with registration of data at control points (day of development of pneumonia, 72 hours from the onset of the disease, resolution of pneumonia) according to the dynamics of the temperature curve, oxygen saturation (SpO2), respiratory rate, oxygenation index SpO2∕FiO2, assessment of quality of life according to European Quality-of-Life-5 Dimension (EQ -5D-5L) questionnaire.

LABORATORY ASSESSMENT Laboratory effectiveness will be assessed by the levels of peripheral blood leukocytes, the significance of blood shift in the leukocyte formula, the dynamics of CRP, PCT (screening, 72 hours from the onset of the disease, resolution of pneumonia).

ASSESSMENT OF INSTRUMENTAL EFFICIENCY

1. Distance traveled during the 6-minute walk test on the day the pneumonia resolved.
2. Spirometry will be performed on the day of screening and on the day of resolution of pneumonia and include assessment of Vital capacity, Forced vital capacity, Forced expiratory volume in one second, Peak expiratory flow, Forced expiratory flow at 25% of Forced vital capacity (FVC), Forced expiratory flow at 50% of FVC, Forced expiratory flow at 75% of FVC.
3. Chest CT scan on the day of screening, after 72 hours and on the day of resolution of pneumonia with determination of localization and size of consolidation, localization and size of the Ground-glass opacity, air bronchograms (yes/no), hemodynamic abnormalities (yes/no), fluid volume in the pleural cavities.
4. Cardiac ultrasound will be performed on the day of screening, 72 hours later, and on the day of resolution of pneumonia and will include assessment of end-diastolic, end-systolic volume indexes and left ventricular ejection fraction, right ventricular antero-posterior diameter, right ventricular fractional area change, tricuspid regurgitation velocity, Tricuspid annular plane systolic excursion (TAPSE) , tricuspid annular systolic velocity (S'), right ventricular free wall longitudinal strain (if possible), diameter of the inferior vena cava and its collapse during inspiration, fluid in the pericardial cavity (yes/no, volume insignificant/moderate/severe/tamponade ) and pleural cavities.