guanosine-monophosphate and favipiravir

guanosine-monophosphate has been researched along with favipiravir* in 2 studies

Other Studies

2 other study(ies) available for guanosine-monophosphate and favipiravir

Article	Year
IDentif.AI-Omicron: Harnessing an AI-Derived and Disease-Agnostic Platform to Pinpoint Combinatorial Therapies for Clinically Actionable Anti-SARS-CoV-2 Intervention. ACS nano, 2022, 09-27, Volume: 16, Issue:9 Nanomedicine-based and unmodified drug interventions to address COVID-19 have evolved over the course of the pandemic as more information is gleaned and virus variants continue to emerge. For example, some early therapies (e.g., antibodies) have experienced markedly decreased efficacy. Due to a growing concern of future drug resistant variants, current drug development strategies are seeking to find effective drug combinations. In this study, we used IDentif.AI, an artificial intelligence-derived platform, to investigate the drug-drug and drug-dose interaction space of six promising experimental or currently deployed therapies at various concentrations: EIDD-1931, YH-53, nirmatrelvir, AT-511, favipiravir, and auranofin. The drugs were tested Topics: Amides; Artificial Intelligence; Auranofin; COVID-19 Drug Treatment; Guanosine Monophosphate; Humans; Phosphoramides; Pyrazines; SARS-CoV-2	2022
Structure-activity relationship analysis of mitochondrial toxicity caused by antiviral ribonucleoside analogs. Antiviral research, 2017, Volume: 143 Recent cases of severe toxicity during clinical trials have been associated with antiviral ribonucleoside analogs (e.g. INX-08189 and balapiravir). Some have hypothesized that the active metabolites of toxic ribonucleoside analogs, the triphosphate forms, inadvertently target human mitochondrial RNA polymerase (POLRMT), thus inhibiting mitochondrial RNA transcription and protein synthesis. Others have proposed that the prodrug moiety released from the ribonucleoside analogs might instead cause toxicity. Here, we report the mitochondrial effects of several clinically relevant and structurally diverse ribonucleoside analogs including NITD-008, T-705 (favipiravir), R1479 (parent nucleoside of balapiravir), PSI-7851 (sofosbuvir), and INX-08189 (BMS-986094). We found that efficient substrates and chain terminators of POLRMT, such as the nucleoside triphosphate forms of R1479, NITD-008, and INX-08189, are likely to cause mitochondrial toxicity in cells, while weaker chain terminators and inhibitors of POLRMT such as T-705 ribonucleoside triphosphate do not elicit strong in vitro mitochondrial effects. Within a fixed 3'-deoxy or 2'-C-methyl ribose scaffold, changing the base moiety of nucleotides did not strongly affect their inhibition constant (K Topics: Adenosine; Amides; Antiviral Agents; Cell Line; Cytidine; DNA-Directed RNA Polymerases; Guanosine Monophosphate; Humans; Inhibitory Concentration 50; Mitochondria; Mitochondrial Proteins; Nucleosides; Prodrugs; Protein Biosynthesis; Pyrazines; Ribonucleosides; RNA; RNA, Mitochondrial; Sofosbuvir; Structure-Activity Relationship; Transcription Initiation Site; Transcription, Genetic	2017

Article

Year

IDentif.AI-Omicron: Harnessing an AI-Derived and Disease-Agnostic Platform to Pinpoint Combinatorial Therapies for Clinically Actionable Anti-SARS-CoV-2 Intervention.

ACS nano, 2022, 09-27, Volume: 16, Issue:9

Nanomedicine-based and unmodified drug interventions to address COVID-19 have evolved over the course of the pandemic as more information is gleaned and virus variants continue to emerge. For example, some early therapies (e.g., antibodies) have experienced markedly decreased efficacy. Due to a growing concern of future drug resistant variants, current drug development strategies are seeking to find effective drug combinations. In this study, we used IDentif.AI, an artificial intelligence-derived platform, to investigate the drug-drug and drug-dose interaction space of six promising experimental or currently deployed therapies at various concentrations: EIDD-1931, YH-53, nirmatrelvir, AT-511, favipiravir, and auranofin. The drugs were tested

Topics: Amides; Artificial Intelligence; Auranofin; COVID-19 Drug Treatment; Guanosine Monophosphate; Humans; Phosphoramides; Pyrazines; SARS-CoV-2

2022

Structure-activity relationship analysis of mitochondrial toxicity caused by antiviral ribonucleoside analogs.

Antiviral research, 2017, Volume: 143

Recent cases of severe toxicity during clinical trials have been associated with antiviral ribonucleoside analogs (e.g. INX-08189 and balapiravir). Some have hypothesized that the active metabolites of toxic ribonucleoside analogs, the triphosphate forms, inadvertently target human mitochondrial RNA polymerase (POLRMT), thus inhibiting mitochondrial RNA transcription and protein synthesis. Others have proposed that the prodrug moiety released from the ribonucleoside analogs might instead cause toxicity. Here, we report the mitochondrial effects of several clinically relevant and structurally diverse ribonucleoside analogs including NITD-008, T-705 (favipiravir), R1479 (parent nucleoside of balapiravir), PSI-7851 (sofosbuvir), and INX-08189 (BMS-986094). We found that efficient substrates and chain terminators of POLRMT, such as the nucleoside triphosphate forms of R1479, NITD-008, and INX-08189, are likely to cause mitochondrial toxicity in cells, while weaker chain terminators and inhibitors of POLRMT such as T-705 ribonucleoside triphosphate do not elicit strong in vitro mitochondrial effects. Within a fixed 3'-deoxy or 2'-C-methyl ribose scaffold, changing the base moiety of nucleotides did not strongly affect their inhibition constant (K

Topics: Adenosine; Amides; Antiviral Agents; Cell Line; Cytidine; DNA-Directed RNA Polymerases; Guanosine Monophosphate; Humans; Inhibitory Concentration 50; Mitochondria; Mitochondrial Proteins; Nucleosides; Prodrugs; Protein Biosynthesis; Pyrazines; Ribonucleosides; RNA; RNA, Mitochondrial; Sofosbuvir; Structure-Activity Relationship; Transcription Initiation Site; Transcription, Genetic

2017