PERSONALIZED CORRECTION OF HEMOSTASIS SYSTEM DISORDERS IN PATIENTS WITH COVID-19.

Violations of the hemostasis (blood aggregation control, BAC) system in patients with COVID-19 in the acute period and at the stage of convalescence have been studied and methods of targeted correction of the identified disorders are considered. Prevention of serious complications related to COVID-19 infection requires complex assessment of the hemostasis system and prompt correction of disorders. Methods of clinical hemostasiograms and low-frequency piezothromboelastography (LPTEG) provide comprehensive and informative assessment of functional state of the BAC system and monitoring of the effectiveness of therapy, both in hospital and on outpatient basis. It was established that hemostasis system disorders had unspecified character with hyper- or hypocoagulation in the acute period and structural or chronometric hypercoagulation in the recovery period. Under LPTEG monitoring in hospital, the identified disorders were corrected by low-molecular-weight (LMW) heparins, blood-based preparations, and fibrinolysis inhibitors;at the outpatient stage, the therapy was supplemented with sulodexide and anticoagulants. Personalized correction of the hemostatic potential was based on the following LPTEG parameters. Prescription of the anti-aggregant and vasoprotective therapy required that the response time (t1) would be reduced below 0.9 min and thrombin activity (TA) constant increased above 40 relative units. The anticoagulant therapy was prescribed when the gelation point (t3) decreased to 4.7 min and the coagulation drive intensity (CDI) index was above 50 relative units. The fibrinolytic activity was corrected when the clot polymerization intensity (CPI) index was above 20 relative units, the cross-linked fibrin formation time (t5) decreased to 27 min, and the clot retraction and lysis intensity (CRLI) index exceeded 15%. The boundary values of these LPTEG parameters were adjusted at the levels of moderate hypercoagulation or reference normal coagulation. The LPTEG monitoring and personalization of the prescribed antithrombotic therapy allowed the risk of thrombo-hemorrhagic complications to be reduced at all stages of COVID-19 treatment.Copyright © 2021 Authors. All rights reserved.

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.

Antiviral activity against sars-cov-2 of a pharmaceutical Substance based on immobilized recombinant human interferon lambda-1

Despite significant advances in the pharmaceutical industry, there are currently no effective universal drugs for the treatment of viral infections. This fact became especially evident during the COVID-19 pandemic. One type of the potential antiviral agents are interferons, which have already proved to be effective for the treatment of diseases caused by viruses. This article discusses the possibility of using recombinant human interferon lambda-1 and its pegylated form for the treatment of infection caused by SARS-CoV-2. Experiments on a Vero E6 cell culture showed that a pharmaceutical substance based on recombinant human interferon lambda-1 immobilized on PEG 1500 by electron-beam pegylation exhibited significant antiviral activity with high therapeutic index against SARS-CoV-2 and produced low cytotoxic effect on Vero E6 cells. It is concluded that this substance can be used to create a drug for the treatment of viral infection caused by SARS-CoV-2.