Algorithm discovery by protein folding game players

Khatib, Firas; Cooper, Seth; Tyka, Michael D.; Xu, Kefan; Makedon, Ilya; Popović, Zoran; Baker, David; Players, Foldit

doi:10.1073/pnas.1115898108

Cited by 507 publications

(418 citation statements)

References 11 publications

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“…The first 'levels' of the Foldit game are designed to train the players in order to accomplish increasingly complicated tasks. Interactions among players have led to remarkable results from a biological point of view [ 106 , 107 , 108 ] but also to develop collaboratively new algorithms to solve a particular problem [ 109 ].…”

Section: Computing Power Revolution and New Algorithms: Gp-gpus Cloumentioning

confidence: 99%

Molecular simulations and visualization: introduction and overview

Hirst¹,

Glowacki²,

Baaden³

2014

Faraday Discuss.

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Section: Computing Power Revolution and New Algorithms: Gp-gpus Cloumentioning

confidence: 99%

Molecular simulations and visualization: introduction and overview

Hirst¹,

Glowacki²,

Baaden³

2014

Faraday Discuss.

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“…Although it is not clear how many participants in the flu inhibitor game were from developing countries, this example is important because it shows that non-experts can be involved in cutting edge research. Interestingly, several of the protein folding algorithms created by the 'non-expert' gamers have been superior to those developed using state-ofthe-art computational method (Khatib et al 2011). Similarly, it is not difficult to imagine that DIY-bio communities, comprised of individuals with broad differences in levels of formal scientific training, could be readily engaged to tackle problems in global health (see Landrain et al and Betten et al in this issue for further description of DIY-bio and the role for different stakeholders in developing these technologies, respectively).…”

Section: Research Agendas For Global Healthmentioning

confidence: 99%

Design-driven, multi-use research agendas to enable applied synthetic biology for global health

Carothers

2013

Syst Synth Biol

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Many of the synthetic biological devices, pathways and systems that can be engineered are multi-use, in the sense that they could be used both for commerciallyimportant applications and to help meet global health needs. The on-going development of models and simulation tools for assembling component parts into functionally-complex devices and systems will enable successful engineering with much less trial-and-error experimentation and laboratory infrastructure. As illustrations, I draw upon recent examples from my own work and the broader Keasling research group at the University of California Berkeley and the Joint BioEnergy Institute, of which I was formerly a part. By combining multi-use synthetic biology research agendas with advanced computer-aided design tool creation, it may be possible to more rapidly engineer safe and effective synthetic biology technologies that help address a wide range of global health problems.

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“…5 In some cases, networked crowds can produce useful new strategies for molecular optimization tasks. 35 These exciting studies, at the interface of human-computer interaction, distributed computing, and molecular science, raise the prospect that distributed infrastructures along with new interface technologies can utilize the power of the internet along with crowd intelligence to solve scientic problems, simultaneously engaging the public with fundamental research questions.…”

Section: Introductionmentioning

confidence: 99%

A GPU-accelerated immersive audio-visual framework for interaction with molecular dynamics using consumer depth sensors

et al. 2014

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A GPU-accelerated immersive audiovisual framework for interaction with molecular dynamics using consumer depth sensors. Faraday Discussions, 169. pp. 63-87. ISSN 1359-6640 Available from: http://eprints.uwe.ac.uk/23115We recommend you cite the published version. The publisher's URL is: http://dx.doi.org/10.1039/C4FD00008K Refereed: Yes First published online 19 Mar 2014Disclaimer UWE has obtained warranties from all depositors as to their title in the material deposited and as to their right to deposit such material. UWE makes no representation or warranties of commercial utility, title, or fitness for a particular purpose or any other warranty, express or implied in respect of any material deposited. UWE makes no representation that the use of the materials will not infringe any patent, copyright, trademark or other property or proprietary rights.UWE accepts no liability for any infringement of intellectual property rights in any material deposited but will remove such material from public view pending investigation in the event of an allegation of any such infringement. PLEASE SCROLL DOWN FOR TEXT.A GPU-accelerated immersive audio-visual framework for interaction with molecular dynamics using consumer depth sensors † With advances in computational power, the rapidly growing role of computational/ simulation methodologies in the physical sciences, and the development of new human-computer interaction technologies, the field of interactive molecular dynamics seems destined to expand. In this paper, we describe and benchmark the software algorithms and hardware setup for carrying out interactive molecular dynamics utilizing an array of consumer depth sensors. The system works by interpreting the human form as an energy landscape, and superimposing this landscape on a molecular dynamics simulation to chaperone the motion of the simulated atoms, affecting both graphics and sonified simulation data. GPU acceleration has been key to achieving our target of 60 frames per second (FPS), giving an extremely fluid interactive experience. GPU acceleration has also allowed us to scale the system for use in immersive 360 spaces with an array of up to ten depth sensors, allowing several users to simultaneously chaperone the dynamics. The flexibility of our platform for carrying out molecular dynamics simulations has been considerably enhanced by wrappers that facilitate fast communication with a portable selection of GPU-accelerated molecular force evaluation routines. In this paper, we describe a 360 atmospheric molecular dynamics simulation we have run in a chemistry/physics education context. We also describe initial tests in which users have been able to chaperone the dynamics of 10-alanine peptide embedded in an explicit water solvent. Using this system, both expert and novice users have been able to accelerate peptide rare event dynamics by 3-4 orders of magnitude.

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Algorithm discovery by protein folding game players

Cited by 507 publications

References 11 publications

Molecular simulations and visualization: introduction and overview

Molecular simulations and visualization: introduction and overview

Design-driven, multi-use research agendas to enable applied synthetic biology for global health

A GPU-accelerated immersive audio-visual framework for interaction with molecular dynamics using consumer depth sensors

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