Xenon Antiaggregant Effects.

In in vitro model of short-term therapeutic inhalation of Xe/O2 mixture, xenon in millimolar concentrations led to a pronounced decrease in induced platelet aggregation in the platelet-enriched blood plasma. The maximum and statistically significant decrease occurred in response to induction by collagen (by ≈30%, p≤0.01) and ADP (by ≈25%, p≤0.01). A slightly weaker but statistically significant reduction in aggregation appeared in response to ristocetin (by ≈12%, p≤0.01) and epinephrine (by ≈9%, p≤0.01). It should be noted that the spontaneous aggregation exceeded the reference values in the control group. Nevertheless, even at minimal absolute values, spontaneous platelet aggregation decreased by 2 times in response to xenon (p≤0.01). The reasons for the decrease of spontaneous and induced aggregation are xenon accumulation in the lipid bilayer of the membrane with subsequent nonspecific (mechanical) disassociation of membrane platelet structures and specific block of its distinct from neuronal NMDA receptor.

Xenon-Induced Effects in Relieving Experimental Acute Respiratory Distress Syndrome.

The effects of inhalations of an oxygen-xenon (70%/30%) mixture were studied in two models of acute respiratory distress syndrome caused by intratracheal administration of 0.5 mg/kg LPS or 0.04 ml acidin-pepsin (pH 1.2). Inhalation of the oxygen-xenon mixture inhibited the development and reduced the intensity of the inflammatory process in the lung tissue, which was assessed by the dynamics of lung weight and body weight of animals: the therapeutic exposure decreased both parameters. It was found that the thrombogenic stimulus, pathognomonic for the development of acute respiratory distress syndrome, decreased under the effect of oxygen-xenon inhalations, while the level of natural anticoagulant antithrombin III increased.

Xenon-Induced Recovery of Functional Activity of Pulmonary Surfactant (In Silico Study).

To understand the nature of xenon-induced recovery of the functional activity of pulmonary surfactant during inhalation of a gas mixture of Xe/O2, the mechanisms of the ongoing processes were studied in silico. Impaired ability of pulmonary surfactant to maintain low surface tension preventing alveolar atelectasis occurs due to formation of aggregates of its phospholipids and a decrease in their lateral mobility. Aggregated lipid systems, whose structure can explain the loss of lateral mobility of surfactant phospholipids, were modeled in silico at the molecular level. Changes in the Gibbs energy and enthalpy in the reactions of the formation and decomposition of xenon intermediates with model systems of various compositions/structures were calculated. The simulation was carried out for atomic xenon and for xenon polarized by molecular oxygen in the gas phase and taking into account solvation with water. The loss of lateral mobility of phospholipids can be explained by specific features of electronic structure of hydrophobic hydrocarbon molecules (acyl chains), which, under certain conditions, are capable of forming structured common regions of the electrostatic potential, to which xenon has an affinity. In this case, inclusion coordination compounds of the "guest-host" type are formed, which subsequently decompose due to the nature of the polarization of the Xe atoms. The formation and decomposition of xenon intermediates in these systems lead to recovery of the lateral mobility (fluidity) of phospholipids, which restores functional activity of surfactant films.

Mechanisms of the Effects of Short-Term Inhalations of Xe and O2 Gas Mixture in the Rehabilitation of Post-COVID Ventilation Failure.

The article presents a theoretical rationale and a clinical case of relief of post-COVID ventilation failure by inhalation of Xe and O2 gas mixture. Pneumonitis of coronavirus etiology transforms saturated phospholipids of surfactant into a solid-ordered phase, which disrupts surface tension, alveolar pneumatization, and alveolar-capillary gas exchange. Using molecular modeling (B3LYP/lanl2dz; GAUSSIAN09), we demonstrated that Xe atom due to the van der Waals dispersion interaction increases the distance between the phospholipid acyl chains providing a phase transition from the solid-ordered to liquid phase and restored the surface-active monolayer surfactant film. A clinical case confirmed that short-term inhalations of the Xe and O2 gas mixture relieved manifestations of ventilation insufficiency and increased SpO2 and pneumatization of the terminal parts of the lungs.