The aim of the research is to estimate the levels of cellular and humoral immunity to the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) among Moscow residents over 18 years old. During the study, participants will be divided into four groups: healthy volunteers; individuals recovered from coronavirus disease 2019 (COVID-19) with different severity; individuals vaccinated against SARS-CoV-2; individuals who have had COVID-19 concomitantly with comorbidities that characterized by the impact on the immune system (tuberculosis, chronic obstructive pulmonary disease, HIV infection, hematological neoplasia). For all participants included into the study peripheral blood will be collected and the titers of SARS-CoV-2 specific immunoglobulins M (IgM) and immunoglobulins G (IgG), frequencies of the T cells specific to nucleocapsid (N), membrane (M), and spike (S) proteins of SARS-CoV-2 in peripheral blood, as well as the fractions of virus specific T helpers and cytotoxic T cells will be estimated. For smaller cohorts of the participants in all groups the antibody titers and T cell response levels will be examined in dynamics. All participants will be monitored for the incidence of primary or repeated COVID-19 for 1-2 years after inclusion in the study.
Based on the results of the study, the relationship between the formation of humoral and cellular immunity against COVID-19, the duration of these types of immunity, as well as their individual contribution to protection against primary or secondary SARS-CoV-2 infection will be analyzed. Additionally, data concerning patients recovered from COVID-19 and having concomitant diseases will provide a valuable information that may help to understand in more details the mechanisms of the development of the SARS-CoV-2 specific immune response.

Start Date20 Oct 2020

Sponsor / Collaborator

Yevdokimov MSUMD

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100 Clinical Results associated with Moscow Engineering Physics Institute

0 Patents (Medical) associated with Moscow Engineering Physics Institute

1,929

Literatures (Medical) associated with Moscow Engineering Physics Institute

01 Jan 2025·Optics Communications

Optical beam spread in seawater

Author: Rogozkin, D. B. ; Sheberstov, S. V. ; Marinyuk, V.V. ; Marinyuk, V. V. ; Sheberstov, S.V. ; Rogozkin, D.B.

We study the spatial and angular distribution of light in a narrow stationary beam propagating in a medium like seawater.For a power-law parametrization of the seawater phase function, using radiative transfer anal., we derive anal. expressions that determine the radiance distribution in the medium.Both the case of intermediate source-receiver distances, where absorption only begins to affect spreading of the beam, and the asymptotic regime of beam propagation are examinedFor the main characteristics of the radiance distribution (the total power, the variance of the angular and radial distributions), scaling relations involving the inherent optical parameters of seawater are found.To validate the expressions obtained we carry out Monte Carlo simulation for commonly adopted seawater scattering models (of Petzold and Morel et al) and their anal. parameterizations.For optical parameters typical to seawater, the predicted anal. laws are in excellent agreement with the results of the Monte Carlo computations.

01 Jan 2025·Physics Letters B

Soliton foam formation in the early Universe

Author: Nikulin, V. V. ; Murygin, B. S. ; Kirillov, A. A.

The formation of composite solitons produced by scalar fields without thermal phase transitions in the early Universe is considered.We present numerical simulations of the formation and evolution of soliton structures at the post-inflationary stage.The realistic initial conditions are obtained through the simulation of multiple quantum fluctuations during the inflation epoch.The initial field distributions allow to form local soliton clusters in the early Universe without the need for the thermal production of a soliton network throughout the Universe.We find that in three-dimensional space, the nontrivial composite field structures are formed in the form of <>, consisting of closed domain walls, domain walls bounded by cosmic strings, and scalar field radiation.The possible cosmol. implications of the soliton foam are discussed.

01 Dec 2024·Russian Microelectronics

Predictive Analysis of Microcircuits’ Radiation Hardness in the Fabrication Process. II. Selection of Test Objects and the Statistical Processing of the Obtained Results

Author: Moskovskaya, Yu. M. ; Boychenko, D. V.

The requirements on the radiation hardness (RH) of mass produced products must be confirmed for each wafer lot.The core manufacturing process (CMP) must be controlled to ensure the accuracy and stability of all the declared product parameters, including RH.The development of a monitoring and statistical control system for the CMP is based on the data obtained during the radiation-oriented characterization (ROC) of the CMP or during preliminary tests during the product development process.At each stage of manufacturing, appropriate test structures (TSs) are used to predict an estimate of the radiation hardness of the product.Based on the results of an anal. of engineering practice and the published data, a set of TSs for monitoring the technol. process using the example of 250-nm SOI CMOS technol., which meets the requirements for radiation hardness, is proposed in this study.Statistical processing of the data from monitoring production batches of wafers is aimed at checking the degree of deviation of the current batch from the base group, which is selected as the referenceHowever, as the sample size is only 3 pieces, it is proposed to evaluate the homogeneity of production batches using nonparametric statistical evaluation criteria.The considered approach makes it possible to guarantee radiation hardness due to the controllability and stability of the CMP, which helps to minimize tech. and economic costs and the volume of radiation tests.

100 Deals associated with Moscow Engineering Physics Institute

100 Translational Medicine associated with Moscow Engineering Physics Institute

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