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Related Experiment Video

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Drug Repurposing Hypothesis Generation Using the "RE:fine Drugs" System
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A performance/cost evaluation for a GPU-based drug discovery application on volunteer computing.

Ginés D Guerrero1, Baldomero Imbernón2, Horacio Pérez-Sánchez2

  • 1National Laboratory for High Performance Computing, Center of Mathematical Modeling, University of Chile, 8370456 Santiago, Chile.

Biomed Research International
|July 16, 2014
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Summary
This summary is machine-generated.

Volunteer computing offers a cost-effective solution for scaling bioinformatics applications, like drug discovery, on graphics processing units (GPUs). This approach bypasses the need for expensive local high-performance computing (HPC) infrastructure.

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Area of Science:

  • Bioinformatics
  • Computational Biology
  • High-Performance Computing (HPC)

Background:

  • Bioinformatics relies heavily on high-performance computing (HPC) for analyzing large biological datasets.
  • Graphics Processing Units (GPUs) have made HPC more accessible, enabling powerful desktop computing.
  • Scaling bioinformatics applications on GPU-based systems faces challenges with power consumption, heat, and total cost of ownership (TCO).

Purpose of the Study:

  • To explore volunteer computing as a scalable and cost-effective alternative to owning large GPU-based HPC infrastructures for bioinformatics.
  • To evaluate the feasibility of volunteer computing for demanding applications like drug discovery.

Main Methods:

  • Utilized a GPU-based drug discovery application, BINDSURF, as a computational benchmark.
  • Assessed volunteer computing as a method to scale computational tasks beyond single-machine capabilities.

Main Results:

  • Volunteer computing provides a viable method for scaling bioinformatics applications that require significant data processing.
  • It presents a cost-effective alternative to investing in and maintaining large, in-house GPU-based HPC systems.
  • The approach is suitable for applications where rapid response times are not the primary concern.

Conclusions:

  • Volunteer computing is a practical and economical solution for scaling bioinformatics workloads, particularly for computationally intensive tasks like drug discovery.
  • It democratizes access to HPC resources for research institutions and scientists facing infrastructure limitations.
  • This model addresses the TCO and environmental concerns associated with large GPU clusters.