Applications of laboratory findings in the prevention, diagnosis, treatment, and monitoring of COVID-19

Meng, Zhiyi; Guo, Shuo; Zhou, Yongzhao; Li, Mengjiao; Wang, Minjin; Ying, Binwu

doi:10.1038/s41392-021-00731-z

Cited by 25 publications

(21 citation statements)

References 392 publications

(496 reference statements)

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“…Furthermore, the different and somewhat discrepant symptoms of COVID-19, including the musculoskeletal ones, difficult the prognostic of the disease, and SARS-CoV-2 viral infection versus musculoskeletal symptomatology is still a subject poorly investigated and a challenge to the researchers in the Muscle Physiology field. Interestingly, some studies highlighted that laboratory findings (elevated levels of CK, LDH, C-reactive protein, creatinine, D-dimer and cytokines; lymphopenia and leukocytosis) and imaging tools (computed tomography—CT scan; magnetic resonance imaging—MRI; positron emission tomography—PET; ultrasound; radiography) can play a crucial role in the prognosis, diagnosis and evaluation of the manifestations of COVID-19, supporting a better treatment of the patients ( Feng et al, 2020 ; Ghayda et al, 2020 ; Orsucci, 2020 ; Ponti et al, 2020 ; Revzin et al, 2020 ; Afshar-Oromieh et al, 2021 ; Akbar et al, 2021 ; Capaccione et al, 2021 ; Chopra et al, 2021 ; Khamis et al, 2021 ; Meng et al, 2021 ; Ramani et al, 2021 ; Xie et al, 2021 ). Unfortunately, the majority of the laboratory and imaging techniques focus on the respiratory, cardiac, gastrointestinal and neurologic systems, and few findings are related to the musculoskeletal apparatus.…”

Section: The Musculoskeletal Symptomatologymentioning

confidence: 99%

The Musculoskeletal Involvement After Mild to Moderate COVID-19 Infection

et al. 2022

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COVID-19, a disease caused by the novel coronavirus SARS-CoV-2, has been drastically affecting the daily lives of millions of people. COVID-19 is described as a multiorgan disease that affects not only the respiratory tract of infected individuals, but it has considerable effects on the musculoskeletal system, causing excessive fatigue, myalgia, arthralgia, muscle weakness and skeletal muscle damage. These symptoms can persist for months, decreasing the quality of life of numerous individuals. Curiously, most studies in the scientific literature focus on patients who were hospitalized due to SARS-CoV-2 infection and little is known about the mechanism of action of COVID-19 on skeletal muscles, especially of individuals who had the mild to moderate forms of the disease (non-hospitalized patients). In this review, we focus on the current knowledge about the musculoskeletal system in COVID-19, highlighting the lack of researches investigating the mild to moderate cases of infection and pointing out why it is essential to care for these patients. Also, we will comment about the need of more experimental data to assess the musculoskeletal manifestations on COVID-19-positive individuals.

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Section: The Musculoskeletal Symptomatologymentioning

confidence: 99%

The Musculoskeletal Involvement After Mild to Moderate COVID-19 Infection

et al. 2022

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“…Although, numerous clinical trials including various vaccines developed and authorized in the meantime, there is still a lack of answers to relevant questions, such as the timepoint for re-administration of the vaccine maintaining an individually efficient immune response or its efficiency against new SARS-CoV-2 mutants [209]. Monitoring the body's immune response to both current and prior infection is therefore mandatory and can be accomplished by serological testing, also known as antibody testing [210,211]. It mainly targets the detection and quantification of pathogen-specific immunoglobulins expressed by B cells, namely IgM, IgA and IgG, which are also referred to as neutralizing antibodies [211,212].…”

Section: Photonic Solutions For Longitudinal Monitoring Of Vaccine Ef...mentioning

confidence: 99%

“…Monitoring the body's immune response to both current and prior infection is therefore mandatory and can be accomplished by serological testing, also known as antibody testing [210,211]. It mainly targets the detection and quantification of pathogen-specific immunoglobulins expressed by B cells, namely IgM, IgA and IgG, which are also referred to as neutralizing antibodies [211,212]. The former two types of antibodies are produced within the first 6 to 10 days after SARS-CoV-2 infection, while their concentration starts to decline rapidly after 4 to 5 weeks [213].…”

Section: Photonic Solutions For Longitudinal Monitoring Of Vaccine Ef...mentioning

confidence: 99%

Understanding viruses and viral infections by biophotonic methods

Ramoji

Pahlow

Pistiki

et al. 2022

Transl Biophotonics

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In the last few decades outbreaks of viral infections have often challenged the world‐wide health infrastructure and caused a significant financial burden as well as human suffering despite progress in diagnostic technologies. The recent outbreaks of the Ebola virus in the African continent, the Zika virus in the American continent, severe acute respiratory syndrome (SARS), Middle East respiratory syndrome (MERS), influenza A and lately severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) viral infections have repeatedly highlighted the importance of technological advancement enabling a better understanding of virions. In this review, we systematically discuss different aspects of virions and how their properties and functions can be studied using different light‐based technologies. We focus on virion classification, detection and interactions with the host's immune system. Further, the potential of advanced biophotonic methods, for example, Raman, infrared reflection, absorption and fluorescence spectroscopy, advanced microscopic techniques and biosensor‐based approaches for diagnosing viral infections, investigating therapeutics and vaccine development are described. Although significant advancements have already been made in photonic technologies, which even enable visualizing virion‐host interactions on single‐cell level, the continuous evolution of viruses demands further progress in biophotonic solutions for fast, affordable and robust health monitoring devices for screening viral infections.

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“…The development of a sensing platform capable of supporting the single-step detection of clinically relevant antibodies and proteins would strongly impact the current diagnostic approaches through high-frequency tests. [1,2] This, for example, would point-of-care testing could have a significant impact on current diagnostics.…”

Section: Introductionmentioning

confidence: 99%

“…The development of a sensing platform capable of supporting the single‐step detection of clinically relevant antibodies and proteins would strongly impact the current diagnostic approaches through high‐frequency tests. [ 1,2 ] This, for example, would enable mass serological screening directly from untreated clinical samples, thereby reducing the time lag between the diagnosis and the treatment (e.g., from infective to autoimmune diseases), [ 3,4 ] enabling easier global health monitoring and surveillance (i.e., monitoring vaccination statuses). [ 5–7 ] This new diagnostic technology needs not only to be rapid (i.e., taking <10 min), quantitative, highly specific, and adaptable to a wide range of diseases, but also to have a high‐throughput (i.e., capable of precisely analyzing hundreds of samples in a short time) and be easy to use so that even non‐trained personnel would be able to perform the tests properly.…”

Section: Introductionmentioning

confidence: 99%

A Programmable Electrochemical Y‐Shaped DNA Scaffold Sensor for the Single‐Step Detection of Antibodies and Proteins in Untreated Biological Fluids

Bonini

Parolo

Álvarez-Diduk

et al. 2022

Adv Funct Materials

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Proteins and antibodies are key biomarkers for diagnosing and monitoring specific medical conditions. Currently, gold standard techniques used for their quantification require laborious multi‐step procedures, involving high costs and slow response times. It is possible to overcome these limitations by exploiting the chemistry and programmability of DNA to design a reagentless electrochemical sensing platform. Specifically, three DNA single strands are engineered that can self‐assemble into a Y‐shaped DNA nanostructure that resembles one of the IgGs. In order to convert this DNA nanostructure into a responsive DNA‐scaffold bioreceptor, it is modified including two recognition elements, two redox tag molecules, and a thiol group. In the absence of the target, the scaffold receptor can efficiently collide with the electrode surface and generate a strong electrochemical signal. The presence of the target induces its bivalent binding, which produces steric hindrance interactions that limit the receptor's collisional activity. In its bound state, the redox tags can therefore approach the surface at a slower rate, leading to a signal decrease that is quantitatively related to the target concentration. The Y‐shape DNA scaffold sensor can detect nanomolar concentrations of antibodies and proteins in <15 min with a single‐step procedure directly in untreated biological fluids.

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Applications of laboratory findings in the prevention, diagnosis, treatment, and monitoring of COVID-19

Cited by 25 publications

References 392 publications

The Musculoskeletal Involvement After Mild to Moderate COVID-19 Infection

The Musculoskeletal Involvement After Mild to Moderate COVID-19 Infection

Understanding viruses and viral infections by biophotonic methods

A Programmable Electrochemical Y‐Shaped DNA Scaffold Sensor for the Single‐Step Detection of Antibodies and Proteins in Untreated Biological Fluids

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