Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) rapidly spread around the globe after its emergence in Wuhan in December 2019. With no specific therapeutic and prophylactic options available, the virus has infected millions of people of which more than half a million succumbed to the viral disease, COVID-19. The urgent need for an effective treatment together with a lack of small animal infection models has led to clinical trials using repurposed drugs without preclinical evidence of their in vivo efficacy. We established an infection model in Syrian hamsters to evaluate the efficacy of small molecules on both infection and transmission. Treatment of SARS-CoV-2−infected hamsters with a low dose of favipiravir or hydroxychloroquine with(out) azithromycin resulted in, respectively, a mild or no reduction in virus levels. However, high doses of favipiravir significantly reduced infectious virus titers in the lungs and markedly improved lung histopathology. Moreover, a high dose of favipiravir decreased virus transmission by direct contact, whereas hydroxychloroquine failed as prophylaxis. Pharmacokinetic modeling of hydroxychloroquine suggested that the total lung exposure to the drug did not cause the failure. Our data on hydroxychloroquine (together with previous reports in macaques and ferrets) thus provide no scientific basis for the use of this drug in COVID-19 patients. In contrast, the results with favipiravir demonstrate that an antiviral drug at nontoxic doses exhibits a marked protective effect against SARS-CoV-2 in a small animal model. Clinical studies are required to assess whether a similar antiviral effect is achievable in humans without toxic effects.
Background: Favipiravir and Molnupiravir, orally available antivirals, have been reported to exert antiviral activity against SARS-CoV-2. First efficacy data have been recently reported in COVID-19 patients. Methods: We here report on the combined antiviral effect of both drugs in a SARS-CoV-2 Syrian hamster infection model. The infected hamsters were treated twice daily with the vehicle (the control group) or a suboptimal dose of each compound or a combination of both compounds. Findings: When animals were treated with a combination of suboptimal doses of Molnupiravir and Favipiravir at the time of infection, a marked combined potency at endpoint is observed. Infectious virus titers in the lungs of animals treated with the combination are reduced by »5 log10 and infectious virus are no longer detected in the lungs of >60% of treated animals. When start of treatment was delayed with one day a reduction of titers in the lungs of 2.4 log10 was achieved. Moreover, treatment of infected animals nearly completely prevented transmission to co-housed untreated sentinels. Both drugs result in an increased mutation frequency of the remaining viral RNA recovered from the lungs of treated animals. In the combotreated hamsters, an increased frequency of C-to-T mutations in the viral RNA is observed as compared to the single treatment groups which may explain the pronounced antiviral potency of the combination. Interpretation: Our findings may lay the basis for the design of clinical studies to test the efficacy of the combination of Molnupiravir/Favipiravir in the treatment of COVID-19. Funding: stated in the acknowledgment.
27SARS-CoV-2 rapidly spread around the globe after its emergence in Wuhan in December 28 2019. With no specific therapeutic and prophylactic options available, the virus was able to 29 infect millions of people. To date, close to half a million patients succumbed to the viral disease, 30 COVID-19. The high need for treatment options, together with the lack of small animal models 31 of infection has led to clinical trials with repurposed drugs before any preclinical in vivo 32 evidence attesting their efficacy was available. We used Syrian hamsters to establish a model 33 to evaluate antiviral activity of small molecules in both an infection and a transmission setting. 34Upon intranasal infection, the animals developed high titers of SARS-CoV-2 in the lungs and 35 pathology similar to that observed in mild COVID-19 patients. Treatment of SARS-CoV-2-36 infected hamsters with favipiravir or hydroxychloroquine (with and without azithromycin) 37 resulted in respectively a mild or no reduction in viral RNA and infectious virus. Micro-CT scan 38 analysis of the lungs showed no improvement compared to non-treated animals, which was 39 confirmed by histopathology. In addition, both compounds did not prevent virus transmission 40 through direct contact and thus failed as prophylactic treatments. By modelling the PK profile 41 of hydroxychloroquine based on the trough plasma concentrations, we show that the total lung 42 exposure to the drug was not the limiting factor. In conclusion, we here characterized a hamster 43 infection and transmission model to be a robust model for studying in vivo efficacy of antiviral 44 compounds. The information acquired using hydroxychloroquine and favipiravir in this model 45 is of critical value to those designing (current and) future clinical trials. At this point, the data 46 here presented on hydroxychloroquine either alone or combined with azithromycin (together 47 with previously reported in vivo data in macaques and ferrets) provide no scientific basis for 48 further use of the drug in humans. 49
A heavy chain–only antibody drug with broad SARS coronavirus neutralizing activity protects mice and hamsters.
Since its emergence in Wuhan, China in December 2019, the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has spread worldwide resulting in a global pandemic with >2 million deaths within a year of the emergence of the virus. In the search for small molecule inhibitors of SARS-CoV-2 Molnupiravir (EIDD-2801), an orally bioavailable nucleoside analog that was originally developed as an antiviral against influenza viruses but that exerts also activity against a number of other RNA viruses, including SARS-CoV2 and other coronaviruses. We here report on the effect of EIDD-2801 in a well-established Syrian hamster SARS-CoV-2 infection model. Oral treatment of SARS-CoV-2-infected hamsters with EIDD-2801 for four consecutive days, starting from the day of infection, significantly reduced infectious virus titers and viral RNA loads in the lungs and markedly improved lung histopathology in a dose-dependent manner when assessed at 4 dpi. When onset of treatment with 500 mg/kg/dose was delayed until 24h post-infection, a modest but significant antiviral effect was observed. When suboptimal doses of both favipiravir (300 mg/kg, BID) and EIDD-2801 (150 mg/kg, BID) were combined, a complete reduction (~5 log10) of infectious virus titers was observed in the lungs of most of the combo-treated animals whereas either compound alone resulted in a reduction of respectively 1.2 and 1.3 log10. The potential of EIDD-2801 for the treatment and/or prevention of SARS-CoV-2 alone or in combination with favipiravir deserves further attention.
Background: The antifungal drug itraconazole exerts in vitro activity against SARS-CoV-2 in Vero and human Caco-2 cells. Preclinical and clinical studies are required to investigate if itraconazole is effective for the treatment and/or prevention of COVID-19. Methods: Due to the initial absence of preclinical models, the effect of itraconazole was explored in a clinical, proof-of-concept, open-label, single-center study, in which hospitalized COVID-19 patients were randomly assigned to standard of care with or without itraconazole. Primary outcome was the cumulative score of the clinical status until day 15 based on the 7-point ordinal scale of the World Health Organization. In parallel, itraconazole was evaluated in a newly established hamster model of acute SARS-CoV-2 infection and transmission, as soon as the model was validated. Findings: In the hamster acute infection model, itraconazole did not reduce viral load in lungs, stools or ileum, despite adequate plasma and lung drug concentrations. In the transmission model, itraconazole failed to
Despite the emerging threat of the Mayaro virus (MAYV) in Central and South-America, there are no licensed antivirals or vaccines available for this neglected mosquito-borne virus. Here, we optimized a robust antiviral assay based on the inhibition of the cytopathogenic effect that could be used for high-throughput screening to identify MAYV inhibitors. We first evaluated different cell lines and virus inputs to determine the best conditions for a reliable and reproducible antiviral assay. Next, we used this assay to evaluate a panel of antiviral compounds with known activity against other arboviruses. Only three drugs were identified as inhibitors of MAYV: β-D-N4-hydroxycytidine (EIDD-1931), favipiravir and suramin. The in vitro anti-MAYV activity of these antiviral compounds was further confirmed in a virus yield assay. These antivirals can therefore serve as reference compounds for future anti-MAYV compound testing. In addition, it is of interest to further explore the activity of EIDD-1931 and its orally bioavailable pro-drug molnupiravir in animal infection models to determine whether it offers promise for the treatment of MAYV infection.
We have identified camelid single-domain antibodies (VHHs) that cross-neutralize SARS-CoV-1 and -2, such as VHH72, which binds to a unique highly conserved epitope in the viral receptor-binding domain (RBD) that is difficult to access for human antibodies. Here, we establish a protein engineering path for how a stable, long-acting drug candidate can be generated out of such a VHH building block. When fused to human IgG1-Fc, the prototype VHH72 molecule prophylactically protects hamsters from SARS-CoV-2. In addition, we demonstrate that both systemic and intranasal application protects hACE-2-transgenic mice from SARS-CoV-2 induced lethal disease progression. To boost potency of the lead, we used structure-guided molecular modeling combined with rapid yeast-based Fc-fusion prototyping, resulting in the affinity-matured VHH72_S56A-Fc, with subnanomolar SARS-CoV-1 and -2 neutralizing potency. Upon humanization, VHH72_S56A was fused to a human IgG1 Fc with optimized manufacturing homogeneity and silenced effector functions for enhanced safety, and its stability as well as lack of off-target binding was extensively characterized. Therapeutic systemic administration of a low dose of VHH72_S56A-Fc antibodies strongly restricted replication of both original and D614G mutant variants of SARS-CoV-2 virus in hamsters, and minimized the development of lung damage. This work led to the selection of XVR011 for clinical development, a highly stable anti-COVID-19 biologic with excellent manufacturability. Additionally, we show that XVR011 is unaffected in its neutralizing capacity of currently rapidly spreading SARS-CoV-2 variants, and demonstrate its unique, wide scope of binding across the Sarbecovirus clades.
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