Detection of significant antiviral drug effects on COVID-19 with reasonable sample sizes in randomized controlled trials: A modeling study

Iwanami, Shoya; Ejima, Keisuke; Kim, Kwang Su; Noshita, Koji; Fujita, Yasuhisa; Miyazaki, Taiga; Kohno, Shigeru; Miyazaki, Yoshitsugu; Morimoto, Shimpei; Nakaoka, Shinji; Koizumi, Yoshiki; Asai, Yasufumi; Aihara, Kazuyuki; Watashi, Koichi; Thompson, Robin N; Shibuya, Kenji; Fujiu, Katsuhito; Perelson, Alan S.; Iwami, Shingo; Wakita, Takaji

doi:10.1371/journal.pmed.1003660

Cited by 37 publications

(61 citation statements)

References 54 publications

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“…This is because the treatment with RDV was initiated at day 0.5, which was close to the peak viral load in nose (i.e., day 0.680; Fig 1B ). Because only a very small fraction of target cells remain uninfected after the viral load peak ( 29 , 30 ), the number of ongoing de novo infections that the RDV can potentially interrupt is limited. Therefore, even if RDV blocked virus production with relatively high efficacy up to 100%, the viral load decay was not significantly influenced ( Figs 1E and S1A ).…”

Section: Resultsmentioning

confidence: 99%

“…There are various studies using mathematical models that can explain SARS-CoV-2 infection dynamics and give insight into treatment strategy ( 29 , 42 , 43 , 44 ). Another mathematical study of nasal viral load also showed a longer duration of virus shedding under RDV treatment; however, that study did not directly estimate treatment efficacy ( 45 ).…”

Section: Discussionmentioning

confidence: 99%

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Incomplete antiviral treatment may induce longer durations of viral shedding during SARS-CoV-2 infection

et al. 2021

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The duration of viral shedding is determined by a balance between de novo infection and removal of infected cells. That is, if infection is completely blocked with antiviral drugs (100% inhibition), the duration of viral shedding is minimal and is determined by the length of virus production. However, some mathematical models predict that if infected individuals are treated with antiviral drugs with efficacy below 100%, viral shedding may last longer than without treatment because further de novo infections are driven by entry of the virus into partially protected, uninfected cells at a slower rate. Using a simple mathematical model, we quantified SARS-CoV-2 infection dynamics in non-human primates and characterized the kinetics of viral shedding. We counterintuitively found that treatments initiated early, such as 0.5 d after virus inoculation, with intermediate to relatively high efficacy (30–70% inhibition of virus replication) yield a prolonged duration of viral shedding (by about 6.0 d) compared with no treatment.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Incomplete antiviral treatment may induce longer durations of viral shedding during SARS-CoV-2 infection

et al. 2021

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“…They showed that if drugs such as remdesivir are administered very early, this may help control viral load, but may not have a major effect in severely ill patients. Iwanami et al also introduced a mathematical model to describe the within-host viral dynamics of SARS-CoV-2 and demonstrated that late timing of treatment initiation can mask the effect of antivirals in clinical studies of COVID-19 [7]. However, none of these models have included the impact of the immune response directly into their model, which plays an important role in the outcomes of the infection.…”

Section: Introductionmentioning

confidence: 99%

Comparing antiviral strategies against COVID-19 via multiscale within-host modelling

et al. 2021

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Within-host models of COVID-19 infection dynamics enable the merits of different forms of antiviral therapy to be assessed in individual patients. A stochastic agent-based model of COVID-19 intracellular dynamics is introduced here, that incorporates essential steps of the viral life cycle targeted by treatment options. Integration of model predictions with an intercellular ODE model of within-host infection dynamics, fitted to patient data, generates a generic profile of disease progression in patients that have recovered in the absence of treatment. This is contrasted with the profiles obtained after variation of model parameters pertinent to the immune response, such as effector cell and antibody proliferation rates, mimicking disease progression in immunocompromised patients. These profiles are then compared with disease progression in the presence of antiviral and convalescent plasma therapy against COVID-19 infections. The model reveals that using both therapies in combination can be very effective in reducing the length of infection, but these synergistic effects decline with a delayed treatment start. Conversely, early treatment with either therapy alone can actually increase the duration of infection, with infectious virions still present after the decline of other markers of infection. This suggests that usage of these treatments should remain carefully controlled in a clinical environment.

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“…To describe the temporal change in viral load of each infected individual in the school or the office, a mathematical model describing the viral dynamics of SARS-CoV-2 was employed as in our previous studies Ejima, Kim, Ludema, et al, 2021;Iwanami et al, 2021;Jeong et al, 2021;Kim et al, 2021). Briefly explaining, the model is composed of two compartments: the viral load (copies/mL) at time ‫,ݐ‬ ܸሺ‫ݐ‬ሻ, and the ratio between the number of uninfected cells at time to and that at time 0, ݂ሺ‫ݐ‬ሻ.…”

Section: Sars-cov-2 Viral Dynamics Model and Viral Load Data Generationmentioning

confidence: 99%

Safely return to schools and offices: early and frequent screening with high sensitivity antigen tests effectively identifies COVID-19 patients

Jeong

Ejima

Kim

et al. 2021

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Background: In-person interaction at school and offices offers invaluable experience to students and benefits to companies. In the midst of the pandemic, ways to safely go back to schools and offices have been argued. Centers for Disease Control and Prevention (CDC) recommends taking all precautions such as vaccination and universal indoor masking. However, even if all the precautions are implemented and transmission is perfectly prevented in the facilities, they may be infected outside of the facilities, which would be a source of transmission in the facilities. Therefore, identifying those infected outside of the facility through screening is essential to safely go back to schools or offices. However, studies investigating the effectiveness of screening are limited. Further, it is not well clarified now which screening strategy (e.g., low or high sensitivity antigen tests, intervals and the number of tests) effectively identify infected and infectious individuals to avoid transmission in facilities Methods: We assessed the effectiveness of various screening strategies in schools and offices through quantitative simulation. The effectiveness was assessed by the proportion of identified infected and infectious participants. Infection dynamics in the facility is governed by transmission dynamics of the population they belong to, and the screening is initiated at different epidemic phases: growth, peak, and declining phases. The viral load trajectory over time for each infected individual was modelled by the viral dynamics model, and the transmission process at the population level was modelled by a deterministic compartment model. The model parameters were estimated from clinical and epidemiological data. Screening strategies were varied by antigen tests with different sensitivity and schedules of screening over 10 days. Results: Under the daily screening, we found high sensitivity antigen tests (the detection limit: 63000 copies/mL) yielded 88% (95%CI 86-89) of effectiveness by the end of 10 days screening period, which is about 20% higher than that with low sensitivity antigen tests (2000000 copies/mL). Comparing screening scenarios with different schedules, we found early and frequent screening is the key to maximize the effectiveness. Sensitivity analysis revealed that less frequent tests might be an option when the number of antigen tests is limited especially when the screening is performed at the growth phase. Discussion: High sensitivity antigen tests, high frequency screening, and immediate initiation of screening are the key to safely restart educational and economic activities allowing in-person interactions. Our computational framework is useful in assessment of screening strategies by incorporating additional factors for specific situations.

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Detection of significant antiviral drug effects on COVID-19 with reasonable sample sizes in randomized controlled trials: A modeling study

Cited by 37 publications

References 54 publications

Incomplete antiviral treatment may induce longer durations of viral shedding during SARS-CoV-2 infection

Incomplete antiviral treatment may induce longer durations of viral shedding during SARS-CoV-2 infection

Comparing antiviral strategies against COVID-19 via multiscale within-host modelling

Safely return to schools and offices: early and frequent screening with high sensitivity antigen tests effectively identifies COVID-19 patients

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