AI Article Synopsis
- The COVID-19 pandemic has spurred researchers to explore new treatments, with a focus on combination therapy and the antiviral potential of ionic liquids (ILs).
- Choline-based ILs were specifically chosen for their lower toxicity, making them safer options for biomedical applications.
- A study utilized molecular docking to assess the effectiveness of combining antiviral drugs with choline-based ILs, showing that these combinations have better antiviral potential and stability compared to using the drugs or ILs individually.
Article Abstract
The pandemic due to COVID-19 caused by SARS-CoV-2 has led to the recorded deaths worldwide and is still a matter of concern for scientists to find an effective counteragent. The combination therapy is always been a successful attempt in treating various threatful diseases. Recently, Ionic liquids (ILs) are known for their antiviral activity. Fascinating tunable properties of ILs make them a potential candidate for designing the therapeutic agent. The concern while using ILs in biomedical field remains is toxicity therefore, choline-based ILs were used in the study as they are considered to be greener as compared to other ILs. In the present study strategically, we performed the blind molecular docking of antiviral drug (Abacavir, Acyclovir, and Galidesivir)-choline based ILs conjugates with the target protein (M protease). The molecules were screened on the basis of binding energy. The data suggested that the combination of AVDs-ILs have greater antiviral potential as compared to the drugs and ILs alone. Further, the ADME properties and toxicity analysis of the screened conjugates was done which revealed the non-toxicity of the conjugates. Additionally, the energetic profiling of the ILs drugs and their conjugates was done using DFT calculations which revealed the stability of the conjugates and have a better option to be developed as a therapeutic agent. Also, from molecular dynamic simulation was done and results showed the stability of the complex formed between target protein and the designed conjugates of AVDs and ILs.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9061583 | PMC |
| http://dx.doi.org/10.1016/j.molliq.2022.119277 | DOI Listing |
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