AI Article Synopsis
- The global pandemic highlighted the shortcomings of the traditional drug discovery process, revealing it to be costly, inefficient, and slow, particularly in screening potential antiviral compounds.
- By merging machine learning techniques with physics-based methods, researchers are finding new ways to enhance the drug discovery workflow, capitalizing on the strengths of both approaches.
- This innovative method relies on supercomputing capabilities, allowing for large-scale calculations, which have successfully identified lead antiviral compounds targeting COVID-19 proteins.
Article Abstract
The race to meet the challenges of the global pandemic has served as a reminder that the existing drug discovery process is expensive, inefficient and slow. There is a major bottleneck screening the vast number of potential small molecules to shortlist lead compounds for antiviral drug development. New opportunities to accelerate drug discovery lie at the interface between machine learning methods, in this case, developed for linear accelerators, and physics-based methods. The two methods, each have their own advantages and limitations which, interestingly, complement each other. Here, we present an innovative infrastructural development that combines both approaches to accelerate drug discovery. The scale of the potential resulting workflow is such that it is dependent on supercomputing to achieve extremely high throughput. We have demonstrated the viability of this workflow for the study of inhibitors for four COVID-19 target proteins and our ability to perform the required large-scale calculations to identify lead antiviral compounds through repurposing on a variety of supercomputers.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8504892 | PMC |
| http://dx.doi.org/10.1098/rsfs.2021.0018 | DOI Listing |
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