The therapeutics, based on virus specific antibodies, for special prophylactic and current of COVID-19

The analyses of effectiveness of medical means of protection based on virus specific antibodies, intended for special prophylactic and current of COVID-19 is conducted. The plasma of patients, obtained from the blood takes the leading part among these prepares. It is concluded, that convalescents plasma, containing virus neutralizing antibodies, may be used for emergency prevention or in the early stages of the disease. A risk group, that primarily needs in such drugs for special prophylactics, is medical workers. The other prepares, based on virus specific antibodies, including purified prepares of monoclonal antibodies, that may have certain advantages to convalescent's plasma due to their safety and high activity, due to complexity of their production and presumably high cost are unlikely to be available in the near future for mass use in the practice of medicine. The use of convalescents plasma for the prevention and treatment of COVID-19.can be based on the experience of their application in specialized medical centers and summarizing data from randomized clinical trials.Copyright © 2021 Moscow State University of Psychology and Education. All right reserved.

Studying The Effectiveness of Ribavirin in The Experimental Form of Severe Acute Respiratory Syndrome.

The effectiveness of Ribavirin was evaluated by the certainty of disease severity reduction and the coefficient of therapeutic action of drugs at the peak of the pathological process calculated by the following indicators: accumulation of the virus in the lungs, lung damage degree reduction, reduction observed in the severity of changes in the quantitative and qualitative characteristics of white blood, as well as the severity of changes in biochemical blood parameters. Ribavirin is most effective when used according to the emergency prevention regimen at a dose of 20 mg/kg (therapeutic action coefficient - 70%);at a dose of 40 mg/kg according to the therapeutic and prophylactic regimen (therapeutic action coefficient - 60%). Increasing the dose of Ribavirin did not contribute to the therapeutic effectiveness of the drug.Copyright © 2020 Media Sphera Publishing Group. All rights reserved.

Antiviral Activity of The Preparation Meflokhin Against COVID-19.

The COVID-19 virus has caused a global emergency and has attracted the attention of healthcare professionals and the public around the world. The significant increase in the number of new cases of infection with this virus demonstrates the relevance of the search for drugs that are effective against this pathogen. The aim of this work was to evaluate the antiviral efficacy of Mefloquin against COVID-19. The antiviral efficacy of Mefloquin against the new pandemic virus SARS-CoV-2 was studied in in vitro experiments in Vero C1008 cell culture and in vivo on Syrian golden hamsters. The results of the study revealed that the drug Mefloquine at a concentration of 2.0 microg ml-1, when applied after infection of cells, suppresses the reproduction of the SARS-CoV-2 virus by 1.7-1.9 lg, the inhibition rate is about 99%. When using Mefloquine, pathological changes in the lung tissue were less pronounced than in the control group. 6 days after infection, it was shown that when using Mefloquine, there was a statistically significant decrease in viral load in the lungs of infected Syrian golden hamsters, with an inhibition rate of 95.5%.Copyright © Team of Authors, 2022.

Immunogenicity evaluation of Gam-COVID-Vac (Sputnik V).

In November 2020, the Armed Forces of the Russian Federation began mass immunisation of the personnel with Gam-COVID-Vac (Sputnik V), the first Russia vaccine against the new coronavirus infection (COVID-19). Thus, it became necessary to assess post-vaccination antibody levels and the duration and intensity of humoral immunity to COVID-19. The aim of the study was to investigate the immunogenicity and efficacy of Gam-COVID-Vac in military medical staff after vaccination. Material(s) and Method(s): the authors determined the presence of specific antibodies in the serum of individuals immunised with Gam-COVID-Vac (477 volunteers) and COVID-19 convalescents (73 patients), using virus neutralisation (VN), enzyme-linked immunosorbent assay (ELISA) with reagent kits by several manufacturers, and immunoblotting. The results of the study were evaluated using analysis of variance. Result(s): VN detected virus neutralising antibodies in 90.7% of vaccinated subjects;ELISA, in 95.4%. Both VN and ELISA showed lower antibody levels in the vaccinated over 50 years of age. ELISA demonstrated a significantly higher concentration of anti-SARS-CoV-2 spike IgG in the Gam-COVID-Vac group than in the COVID-19 convalescent group. The correlation between antibody detection results by VN and ELISA was the strongest when the authors used their experimental reagent kit for quantitative detection of virus neutralising antibodies by competitive ELISA with the recombinant human ACE2 receptor. Having analysed the time course of neutralising antibody titres, the authors noted a significant, more than two-fold decrease in geometric means of the titres three months after administration of the second vaccine component. Conclusion(s): the subjects vaccinated with Gam-COVID-Vac gain effective humoral immunity to COVID-19. The decrease in titres indicates the need for revaccination in 6 months.Copyright © 2023 Safety and Risk of Pharmacotherapy. All rights reserved.

The Flow Cytometry Study of Cellular Immunity in Rhesus Monkeys after Experimental Infection with SARS-CoV-2 Virus

Cellular immunity plays an important role in the pathogenesis and formation of protective immune defense against the SARS-CoV-2 virus. The aim of the work was to study the cellular immunity of rhesus monkeys applying flow cytometry after experimental infection with the SARS-CoV-2 virus. Materials and methods. Male rhesus monkeys were intranasally inoculated with the SARS-CoV-2 virus, Isolate B strain and hCoV-19/Russia/SP48-1226/2020 strain (abbreviated name U-2), at a dose of 5.0 lg PFU. Using flow cytometry, the levels of 21 populations/subpopulations of mononuclear cells in the peripheral blood of animals were determined before experimental infection with the pathogen and on day 14 after infection. SARS-CoV-2 coronavirus RNA was assessed using real-time polymerase chain reaction. Determination of the titer of virus-neutralizing antibodies to the SARS-CoV-2 virus in the blood sera of animals was conducted through neutralization test evaluating the ability to suppress negative colonies. Results and discussion. Infection with Isolate B strain culture has led to an increase in the relative content of total T-lymphocytes (p<0.2), cytotoxic T-lymphocytes (p<0.1), as well as monocytes expressing the early activation marker CD25 (p<0.2). The decrease in levels has been observed for total B-lymphocytes (p<0.2) and T-helper cells (p<0.1). Infection with the U-2 strain culture revealed an increase in the relative content of monocytes expressing the early activation marker CD25 (p<0.2). Thus, for the first time in the Russian Federation, flow cytometry was used to study the cellular immunity of rhesus monkeys before and after experimental infection with the SARS-CoV-2 virus. The obtained information can be used for studying the pathogenesis of SARS-CoV-2 infection, course, and outcome of the disease, and developing strategies for vaccination and treatment. © 2022 Russian Research Anti-Plague Institute. All rights reserved.

Environmental, biological and social factors contributing to new rises in COVID-19 morbidity in Russia.

Morbidity surveys in certain regions during the COVID-19 pandemic have established that the infection spreads in a wave-like manner characterised with peaks and troughs in incidence. According to the analysis of COVID-19 epidemic development in Russia, surges in COVID-19 infections are mainly driven by seasonal factors, insufficient herd immunity, and emerging SARS-CoV-2 variants with increased transmissibility. The aim of the study was to analyse environmental, biological and social factors contributing to new rises in COVID-19 cases in Russia. The study covers the global epidemiological situation as of mid-2022 and the role of environmental, biological, and social factors in the spread of COVID-19 in the Russian Federation. The results suggest that new highly contagious SARS-CoV-2 variants and seasonality are the principal factors driving new rises in morbidity. The authors assume that the sixth and the seventh COVID-19 waves in Russia will be in line with the best case scenario, which predicts the spread of a SARS-CoV-2 variant with increased transmissibility and reduced virulence.Copyright © 2023 Safety and Risk of Pharmacotherapy. All rights reserved.

Environmental, biological and social factors contributing to new rises in COVID-19 morbidity in Russia

Morbidity surveys in certain regions during the COVID-19 pandemic have established that the infection spreads in a wave-like manner characterised with peaks and troughs in incidence. According to the analysis of COVID-19 epidemic development in Russia, surges in COVID-19 infections are mainly driven by seasonal factors, insufficient herd immunity, and emerging SARS-CoV-2 variants with increased transmissibility. The aim of the study was to analyse environmental, biological and social factors contributing to new rises in COVID-19 cases in Russia. The study covers the global epidemiological situation as of mid-2022 and the role of environmental, biological, and social factors in the spread of COVID-19 in the Russian Federation. The results suggest that new highly contagious SARS-CoV-2 variants and seasonality are the principal factors driving new rises in morbidity. The authors assume that the sixth and the seventh COVID-19 waves in Russia will be in line with the best case scenario, which predicts the spread of a SARS-CoV-2 variant with increased transmissibility and reduced virulence.

Antiviral Activity of The Preparation Meflokhin® Against COVID-19

The COVID-19 virus has caused a global emergency and has attracted the attention of healthcare professionals and the public around the world. The significant increase in the number of new cases of infection with this virus demonstrates the relevance of the search for drugs that are effective against this pathogen. The aim of this work was to evaluate the antiviral efficacy of Mefloquin® against COVID-19. The antiviral efficacy of Mefloquin® against the new pandemic virus SARS-CoV-2 was studied in in vitro experiments in Vero C1008 cell culture and in vivo on Syrian golden hamsters. The results of the study revealed that the drug Mefloquine® at a concentration of 2.0 µg ml-1, when applied after infection of cells, suppresses the reproduction of the SARS-CoV-2 virus by 1.7-1.9 lg, the inhibition rate is about 99%. When using Mefloquine, pathological changes in the lung tissue were less pronounced than in the control group. 6 days after infection, it was shown that when using Mefloquine, there was a statistically significant decrease in viral load in the lungs of infected Syrian golden hamsters, with an inhibition rate of 95.5%.

Immunogenicity evaluation of Gam-COVID-Vac (Sputnik V)

In November 2020, the Armed Forces of the Russian Federation began mass immunisation of the personnel with Gam-COVID-Vac (Sputnik V), the first Russia vaccine against the new coronavirus infection (COVID-19). Thus, it became necessary to assess post-vaccination antibody levels and the duration and intensity of humoral immunity to COVID-19. The aim of the study was to investigate the immunogenicity and efficacy of Gam-COVID-Vac in military medical staff after vaccination. Materials and methods: the authors determined the presence of specific antibodies in the serum of individuals immunised with Gam-COVID-Vac (477 volunteers) and COVID-19 convalescents (73 patients), using virus neutralisation (VN), enzyme-linked immunosorbent assay (ELISA) with reagent kits by several manufacturers, and immunoblotting. The results of the study were evaluated using analysis of variance. Results: VN detected virus neutralising antibodies in 90.7% of vaccinated subjects;ELISA, in 95.4%. Both VN and ELISA showed lower antibody levels in the vaccinated over 50 years of age. ELISA demonstrated a significantly higher concentration of anti-SARS-CoV-2 spike IgG in the Gam-COVID-Vac group than in the COVID-19 convalescent group. The correlation between antibody detection results by VN and ELISA was the strongest when the authors used their experimental reagent kit for quantitative detection of virus neutralising antibodies by competitive ELISA with the recombinant human ACE2 receptor. Having analysed the time course of neutralising antibody titres, the authors noted a significant, more than two-fold decrease in geometric means of the titres three months after administration of the second vaccine component. Conclusions: the subjects vaccinated with Gam-COVID-Vac gain effective humoral immunity to COVID-19. The decrease in titres indicates the need for revaccination in 6 months.

The Analysis of Anti-Epidemic Measures Carried Out in the Russian Federation in the Context of the COVID-19 Pandemic

The outbreak of a new coronavirus disease, COVID-19, started in December 2019 in China continues to be one of the most important realities of our time influencing all spheres of human activity March 11, 2022 marks two years since the WHO declared a pandemic it is expected that the number of cases by this time may reach the mark 500 million. Taking into account the widespread spread of infection, spontaneous appearance during the natural evolution of the pathogen new highly pathogenic variants of the COVID-19 pathogen for humans the most important is the implementation of anti-epidemic measures representing a set of measures, aimed at preventing the importation and spread of infection. The purpose of the presented article is a analysis of the anti-epidemic measures carried out in the Russian Federation in the context of a COVID-19 pandemic. Anti-epidemic measures include the implementation of measures, directed towards all links of epidemic: on the source, on the transmission path and on the receptive collective. From a wide range of sanitary and anti-epidemic measures carried out nationwide (including organizational and administrative, socio-economic, isolation and quarantine and others) the development of various methods of detection and identification of the COVID-19 pathogen, methods of serodiagnostics with which you can predict indicator of herd immunity, means of prevention and treatment of the disease, means and methods of disinfection is considered. As such measures, the development of means for detecting and identifying the pathogen, means of prevention and treatment of the disease, methods of serodiagnostics, with the help of which it is possible to predict indicator of herd immunity, means and methods of disinfection are considered. An assessment of the effectiveness of the developed tools of diagnostics, prevention and treatment in relation to new variants of the SARS-CoV-2 virus was carried out. The creation of a laboratory model to study an experimental infection which increases efficiency and reliability of ongoing preclinical studies of medical protective equipment is also important. Copyright © 2022 Izdatel'stvo Meditsina. All rights reserved.

The Omicron Variant of the Sars-Cov-2 Virus As the Dominant Agent of a New Risk of Disease amid the COVID-19 Pandemic.

Over the two years that have passed since the WHO announced on March 11, 2020, a pandemic of the new coronavirus disease COVID-19, more than 460 million cases of the disease have been detected in the world, of which more than five million have been fatal. During the natural evolution of the COVID-19 pathogen, dominant variants emerge that account for most new infections. The WHO constantly monitors coronavirus mutations that potentially pose an epidemiological danger. Currently, the WHO divides modified variants of the SARS-CoV-2 virus into variants of concern (VOC) and variants of interest (VOI). The WHO-designated group of variants of concern includes potentially the most dangerous lines, which are characterized by a complex of new properties. This group also includes the Omicron variant, which has become the dominant agent of the new wave of the COVID-19 pandemic. The aim of this work is to analyze the characteristics of the SARS-CoV-2 Omicron strain, the dominant agent of the new wave of the COVID-19 pandemic. The proposed mechanism of origin of the Omicron variant, its geographical distribution, the features of the disease caused by it, and the distinguishing features from diseases caused by the Delta variant and the original Wuhan strain of the SARS-CoV-2 virus, mutations of the Omicron variant compared to the parent strain of the SARS-CoV-2 virus, the genetic variability of the Omicron variant, and the epidemiological characteristics of the disease it causes are considered. Particular attention is paid to evaluation of the preventive and therapeutic effectiveness of the existing medical means of protection against COVID-19 in relation to the Omicron strain.

A new mouse unilateral model of diffuse alveolar damage of the lung.

OBJECTIVE AND DESIGN: The existing biological models of diffuse alveolar damage (DAD) in mice have many shortcomings. To offset these shortcomings, we have proposed a simple, nonsurgical, and reproducible method of unilateral total damage of the left lung in ICR mice. This model is based on the intrabronchial administration of a mixture of bacterial lipopolysaccharide (LPS) from the cell wall of S. enterica and α-galactosylceramide (inducing substances) to the left lung. METHODS: Using computer tomography of the lungs with endobronchial administration of contrast material, we have been able to perform an operative intravital verification of the targeted delivery of the inducer. The model presented is characterized by more serious and homogeneous damage of the affected lung compared to the existing models of focal pneumonia; at the same time, our model is characterized by longer animal survival since the right lung remains intact. RESULTS: The model is also characterized by diffuse alveolar damage of the left lung, animal survival of 100%, abrupt increases in plasma levels of TNFa, INFg, and IL-6, and significant myocardial overload in the right heart. It can be used to assess the efficacy of innovative drugs for the treatment of DAD and ARDS as the clinical manifestations that are developed in patients infected with SARS-CoV-2. Morphological patterns of lungs in the noninfectious ("sterile") model of DAD induced by LPS simultaneously with α-galactosylceramide (presented here) and in the infectious model of DAD induced by SARS-CoV-2 have been compared. CONCLUSION: The DAD model we have proposed can be widely used for studying the efficacy of candidate molecules for the treatment of infectious respiratory diseases, such as viral pneumonias of different etiology, including SARS-CoV-2.

Vaccination Against COVID-19: Emerging Issues and Future Prospects

The most effective means of combating the COVID-19 pandemic s the formation of herd immunity, with the formation of an immune population to infection. Vaccination rates are continuously increasing. In early February 2021, WHO announced that the number of people vaccinated against the disease for the first time exceeded the number of infected. In early June 2021 the vaccinated number exceeded 2 billion which is more than 12 times the total number infected for the entire duration of the pandemic. The high rate of vaccination leads to the formulation of a number of questions concerning the effectiveness of vaccines currently used for mass immunization the level of herd immunity, necessary to stop the spread of the disease, the actual duration of the vaccination carried out, long-term prospects of the platforms, used in the creation of vaccines. The purpose of this paper is to substantiate reasoned answers to the questions posed. © 2021 Izdatel'stvo Meditsina. All rights reserved.

Comparative analysis of existing platforms for the development of vaccines against dangerous and extremely dangerous viral infections with pandemic potential

The main triggers of new infectious diseases, including those with pandemic potential, are: spontaneous emergence of infectious strains which are more virulent for humans and contribute to transmission of pathogenic microorganisms, environmental changes, social and economic factors, increased contact rates between different regions. A successful pandemic response requires mass immunisation against a specific disease, aimed at the development of herd immunity which is based on the concept of indirect protection of the whole of the population by immunising a part of it. A well-grounded choice of the vaccine platform is central to dealing with this problem. The aim of the study was to compare characteristics of vaccine platforms (attenuated, inactivated, subunit, recombinant vector, DNA, and RNA vaccines) intended for mass immunisation against dangerous and extremely dangerous viral infections with pandemic potential. The study focused on the members of Poxviridae, Orthomyxoviridae and Coronaviridae families as potential pathogens. The vaccine platforms were compared in terms of the following parameters: capability of producing a robust immune response;protective efficacy;time required for vaccine development and testing;ability to produce vaccine in volumes required for mass immunisation;potential obstacles associated with the intended use of the vaccine. It is expected that in the next few decades DNA and RNA vaccine platforms will be most widely used for development of products against dangerous and extremely dangerous viral infections with pandemic potential, regardless of taxonomic groups of pathogens.

Comparative characteristics of COVID-19 vaccines used for mass immunisation

The pandemic of the new coronavirus (COVID-19) disease that began in December 2019 in China is still having a huge impact on all spheres of human life. The herd immunity, which is the most effective tool for preventing the spread of the disease, is formed in two ways: the passive way (i.e., the formation of a population not susceptible to re-infection due to the natural spread of the disease) and the active way (mass immunisation). High rates of COVID-19 vaccination were achieved thanks to the development and mass production of new vaccines. The selection of the most promising vaccine platforms is one of the key aspects of successful mass immunisation. The aim of the study was to compare the characteristics of COVID-19 vaccines used for mass immunisation. The paper analyses the vaccine technology platforms, efficacy of different types of vaccines based on clinical trial results, safety of vaccines for different population groups, and potential for scaling up vaccine production in order to ensure the necessary vaccination coverage. The vaccines currently used for mass immunisation are: BNT162b2 (Pfizer/BioNTech), mRNA1273 (Moderna), GamCOVID-Vac (N.F. Gamaleya National Research Center for Epidemiology and Microbiology), Ad26.COV2.S (Johnson & Johnson), ChAdOx1-S (AZD1222) (AstraZeneca), BBIBP-CorV (Sinopharm), CoronaVac (Sinovac Biotech), and NVX-CoV2373 (Novavax). The comparison of the main characteristics of the vaccines demonstrated that the most promising types of vaccines for COVID-19 specific prophylaxis are RNA vaccines and recombinant adenovirus vector-based vaccines.

[In vitro activity of human recombinant alpha-2b interferon against SARS-CoV-2 virus].

INTRODUCTION: The pandemic spread of a new coronavirus infection, COVID-19, has caused a global emergency and attracted the attention of public health professionals and the population of all countries. A significant increase in the number of new cases of SARS-CoV-2 infection demonstrates the urgency of finding drugs effective against this pathogen.The aim of this work was to evaluate the in vitro antiviral efficacy of human recombinant alpha-2b interferon (IFN-α2b) against SARS-CoV-2 virus. MATERIAL AND METHODS: The experiments had been carried out on Vero Cl008, the continuous line of African green monkey (Chlorocebus sabaeus) kidney cells. The effectiveness of the drugs was assessed by the suppression of viral reproduction in vitro. The biological activity was determined using titration of a virus-containing suspension in a Vero Cl008 cell culture by the formation of negative colonies. RESULTS: The antiviral efficacy of the IFN-α2b-based medications, which have a high safety profile and proven efficacy in the prevention and treatment of influenza and acute respiratory viral infections (ARVI), has been studied against the new pandemic SARS-CoV-2 virus in vitro experiments in Vero C1008 cell culture. IFN-α2b effectively inhibits the reproduction of the virus when applied both 24 hrs before and 2 hrs after infection. In the IFN-α2b concentration range 102-106 IU/ml a complete suppression of the reproduction of the SARS-CoV-2 virus had been demonstrated. DISCUSSION: IFN-α2b demonstrated in vitro high antiviral activity against SARS-CoV-2. In addition, the substance has a high chemotherapeutic index (>1000). CONCLUSION: Medications for intranasal use based on IFN-α2b have high antiviral activity and are promising drugs for in vivo study in terms of prevention and treatment of COVID-19.

Analysis of promising approaches to COVID-19 vaccine development

The number of confirmed COVID-19 cases worldwide amounted to 50 million at the beginning of November 2020. This is clearly not enough for the formation of herd immunity, which will prevent repeated outbreaks of the disease. Quarantine measures can only curb the spread of the disease to some extent, therefore specific preventive measures are needed to create collective immunity to COVID-19.The underlying principle of collective immunity is indirect protection of the whole of the population by immunising a certain part of it. Vaccination is the most effective approach to prevention of epidemic outbreaks. The aim of the study was to analyse promising approaches to the development of vaccines against novel coronavirus COVID-19 infection. The paper summarises data on development studies and clinical trials of COVID-19 vaccines conducted in different countries. It analyses the pros and cons of different platforms for vaccine development (attenuated vaccines, inactivated vaccines, subunit vaccines, DNA and RNA vaccines, recombinant vector vaccines). The paper presents a potential design of novel vaccines. It was concluded that COVID-19 vaccines might be developed both for immunising high-risk groups and for mass immunisation. An optimal solution for the second task would be to develop human or monkey adenovirus vector-based vaccines whose mass production has already been unveiled.

Preclinical Studies of Immunogenity, Protectivity, and Safety of the Combined Vector Vaccine for Prevention of the Middle East Respiratory Syndrome.

The Middle East Respiratory Syndrome (MERS) is an acute inflammatory disease of the respiratory system caused by the MERS-CoV coronavirus. The mortality rate for MERS is about 34.5%. Due to its high mortality rate, the lack of therapeutic and prophylactic agents, and the continuing threat of the spread of MERS beyond its current confines, developing a vaccine is a pressing task, because vaccination would help limit the spread of MERS and reduce its death toll. We have developed a combined vector vaccine for the prevention of MERS based on recombinant human adenovirus serotypes 26 and 5. Studies of its immunogenicity have shown that vaccination of animals (mice and primates) induces a robust humoral immune response that lasts for at least six months. Studies of the cellular immune response in mice after vaccination showed the emergence of a specific CD4+ and CD8+ T cell response. A study of the vaccine protectivity conducted in a model of transgenic mice carrying the human DPP4 receptor gene showed that our vaccination protected 100% of the animals from the lethal infection caused by the MERS-CoV virus (MERS-CoV EMC/2012, 100LD50 per mouse). Studies of the safety and tolerability of the developed vaccine in rodents, rabbits, and primates showed a good safety profile and tolerance in animals; they revealed no contraindications for clinical testing.

Antiviral Activity of Kagocel® in vitro Against Virus SARS-CoV-2

The antiviral activity of the drug Kagocel®, which has a high safety profile and proven efficacy for the prevention and treatment of influenza and AVRI as an interferon inducer, was studied against a new pandemic strain of SARS-CoV-2 in vitro in Vero C1008 cell culture. The results of the study revealed that at the addition of the substance Kagocel® at the concentration of 5000 mg/ml into the cell culture 1 h before the virus infection and 1 h after, there was 100% inhibition of the cytopathic activity of the virus. It was also found that Kagocel® at the dose of 5000 mg/ml effectively suppressed the reproduction of the SARS-CoV-2 virus, variant B, in Vero C1008 cell culture by 1.75 lg, the inhibition coefficient was 97.83 %. Изучена противовирусная активность лекарственного препарата Кагоцел®, имеющего высокий профиль безопасности и доказанную эффективность для профилактики и лечения гриппа и ОРВИ в качестве индуктора интерферонов, в отношении нового пандемического штамма SARS-CoV-2 в экспериментах in vitro в культуре клеток Vero C1008. Результаты исследования выявили, что при внесении субстанции Кагоцел® в культуру клеток за 1 ч до инфицирования и через 1 ч после в концентрации 5000 мкг/мл отмечалось подавление цитопатической активности вируса на 100%. Также было установлено, что Кагоцел® эффективно подавляет репродукцию вируса SARS-CoV-2, вариант В, в культуре клеток Vero C1008 в дозе 5000 мкг/мл на 1,75 lg, при этом коэффициент ингибирования по подавлению репродукции вируса составил 97,83%.

A heterologous virus-vectored vaccine for prevention of Middle East respiratory syndrome induces long protective immune response against MERS-CoV

Introduction. Middle East respiratory syndrome (MERS) is acute inflammatory disease of respiratory system with a high mortality, caused Ьу coronavirus MERS-CoV At present moment, we still lack specific therapeutic preparations and vaccines against MERS. Vaccine administration can help to limit the spread of the disease and lower the mortality. Duration of vaccine-induced immune response is one of the key characteristics of a vaccine, which is connected with duration of its protective effectiveness. Unfortunately, the data on duration of vaccine-induced immune response against MERS is scarce. The aim of the study was to determine duration of humoral immune response in mice and primates and duration of protective immune response in mice after immunization with the heterologous virus-vectored vaccine against MERS (BVRS-GamVac-Combi), developed earlier Ьу our research group. Material and methods. To study duration of humoral immune response, we used mice of C57BL/6 strain and common marmosets. Animals were immunized with the vaccine BVRS-GamVac-Combi, based on recomЬinant adenoviral vectors rAd26 and rAd5. Antigen-specific-antibody titers were determined with ELISA, virus-neutralizing antibody titers were measured with virus neutralization assay using MERS-CoV (EMC/2012). To study duration of protective immune response, we used a model of lethal infection on transgenic mice, carrying human DPP4 gene of viral receptor. Results. In present research, we showed that vaccination of animals with BVRS-GamVac-Combi induced robust humoral immune response, which persisted at least 18 months after immunization. In addition, our vaccine protected 100 % of animals from lethal infection for at least 7 months after immunization. Concluslon. Strength of vaccine-induced immune response is generally connected with a protective effectiveness of a vaccine. One of the key problems of vaccine design is to find a way to provide as long and robust immune response as possible. Duration of vaccine-induced immune response is one of the key characteristics of a vaccine, which demands quality control during multiple steps of a vaccine development. Введение. Ближневосточный респираторный синдром (БВРС) - это острое воспалительное заболевание дыхательной системы с высокой летальностью, возбудителем которого является коронавирус БВРС-КоВ. В настоящее время в мире не существует специфических профилактических и терапевтических средств против БВРС. Вакцино-профилактика позволит ограничить распространение данного заболевания и снизить летальность. Одной из ключевых характеристик вакцин является длительность индуцируемого иммунного ответа, от которой зависит продолжительность протективного эффекта вакцины. К сожалению, данных по длительности поствакцинального иммунного ответа для вакцин против БВРС сейчас недостаточно. Цель исследования - определение длительности гуморального иммунного ответа у грызунов и приматов и протективного иммунного ответа после иммунизации комбинированной векторной вакциной против БВРС (БВРС-ГамВак-Комби), разработанной нами ранее. Материал и методы. Длительность гуморального иммунитета исследовали на мышах линии C57BL/6 и обыкновенных игрунках. ЖивРтных иммунизировали вакциной БВРС-ГамВак-Комби на основе рекомбинантных векторов rAd26 и rAd5. Титр антиген-специфических антител определяли методом иммуноферментного анализа (ИФА). Титр вирус-нейтрализующих антител определяли с помощью реакции вирус-нейтрализации против вируса БВРС-КоВ (MERS-CoV EMC/2012). Длительность протективного иммунитета исследовали на модели летальной инфекции у трансгенных мышей, несущих ген человека DPP4, кодирующий рецептор к БВРС-КоВ. Результаты. Исследование длительности поствакцинального гуморального иммунного ответа у грызунов и приматов показало, что вакцинация животных БВРС-ГамВак-Комби индуцирует формирование напряженного гуморального иммунного ответа к гликопротеину S БВРС-КоВ, который сохраняется на протяжении не менее 18 мес. Также было показано, что вакцинация позволяет защитить 100 % животных от летальной инфекции, вызванной БВРС-КоВ (MERS-CoV EMC/2012, 100 ЛД50/мышь), через 7 мес после иммунизации. Заключение. Напряженность поствакцинального гуморального иммунного ответа, как правило, связана с протективностью вакцины. Одной из ключевых задачпри дизайне вакцин является обеспечение наиболее длительного напряженного иммунного ответа. Длительность поствакцинального иммунного ответа - одна из ключевых характеристик вакцин, которая требует контроля на различных этапах их разработки.