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⚫ | {{Use American English|date=August 2021}} | ||
{{third-party|date=January 2020}} | |||
{{short description|Distributed computing project simulating protein folding}} | {{short description|Distributed computing project simulating protein folding}} | ||
⚫ | {{Use American English|date=August 2021}} | ||
{{Infobox software | {{Infobox software | ||
| name = Folding@home | | name = Folding@home | ||
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| logo_size = 200px | | logo_size = 200px | ||
| author = Vijay Pande | | author = Vijay Pande | ||
| developer = Pande Laboratory, ], ], ATI Technologies, Joseph Coffland, Cauldron Development<ref name="About Partners"/> | | developer = Pande Laboratory, ], ], ], Joseph Coffland, Cauldron Development<ref name="About Partners"/> | ||
| released = {{Start date and age|2000|10|01}} | | released = {{Start date and age|2000|10|01}} | ||
| latest release version = 7.6.21 | | latest release version = 7.6.21 | ||
| latest release date = {{Start date and age|2020|10|23}}<ref name="7.6 windows releases"/> | | latest release date = {{Start date and age|2020|10|23}}<ref name="7.6 windows releases"/> | ||
| latest preview version = 8.1.18 | |||
| latest preview date = {{Start date and age|2023|04|18}}<ref name="7.6 windows releases"/> | |||
| operating system = ], ], ], ] (discontinued as of firmware version 4.30) | | operating system = ], ], ], ] (discontinued as of firmware version 4.30) | ||
| platform = ], ], ], ]<ref>{{cite web | url=https://foldingathome.org/alternative-downloads/?lng=en | title=Alternative Downloads }}</ref> | | platform = ], ], ], ]<ref>{{cite web | url=https://foldingathome.org/alternative-downloads/?lng=en | title=Alternative Downloads }}</ref> | ||
| language = English, French, Spanish, Swedish |
| language = English, French, Spanish, Swedish | ||
| genre = ] | | genre = ] | ||
| license = Proprietary software<ref name="Open Source FAQ"/> | | license = Proprietary software<ref name="Open Source FAQ"/> | ||
| website = {{URL |
| website = {{official URL}} | ||
}} | }} | ||
'''Folding@home''' ('''FAH''' or '''F@h''') is a ] project aimed to help scientists develop new therapeutics for a variety of diseases by the means of simulating protein dynamics. This includes the process of protein folding and the movements of |
'''Folding@home''' ('''FAH''' or '''F@h''') is a ] project aimed to help scientists develop new therapeutics for a variety of diseases by the means of simulating ]. This includes the process of ] and the movements of ]s, and is reliant on simulations run on volunteers' ]s.<ref>{{harvnb|Folding@home|n.d.e}}: "Folding@home (FAH or F@h) is a distributed computing project for simulating protein dynamics, including the process of protein folding and the movements of proteins implicated in a variety of diseases. It brings together citizen scientists who volunteer to run simulations of protein dynamics on their personal computers. Insights from this data are helping scientists to better understand biology, and providing new opportunities for developing therapeutics."</ref> Folding@home is currently based at the ] and led by ], a former student of ].<ref name="FAH leadership change"/> | ||
The project utilizes ]s (GPUs), |
The project utilizes ]s (GPUs), ]s (CPUs), and ] processors like those on the ] for distributed computing and scientific research. The project uses statistical ] methodology that is a ] from traditional computing methods.<ref name="10.1016/j.ymeth.2010.06.002"/> As part of the ] ], the volunteered machines each receive pieces of a simulation (work units), complete them, and return them to the project's ]s, where the units are compiled into an overall simulation. Volunteers can track their contributions on the Folding@home website, which makes volunteers' participation competitive and encourages long-term involvement. | ||
Folding@home is one of the world's fastest computing systems. With heightened interest in the project as a result of the ],<ref>{{harvnb|News 12 Long Island|2020}}: "Since the start of the COVID-19 pandemic, Folding@home has seen a significant surge in downloads, a clear indication that people around the world are concerned about doing their part to help researchers find a remedy to this virus," said Dr. Sina Rabbany, dean of the DeMatteis School."</ref> the system achieved a speed of approximately 1.22 ] by late March 2020 and reached 2.43 exaflops by April 12, 2020,<ref>{{cite web | url = https://stats.foldingathome.org/os | archive-url = https://archive.today/20200412111010/https://stats.foldingathome.org/os | url-status = dead | archive-date = April 12, 2020 | title = Client Statistics by OS | author = Pande lab | publisher = Archive.is | access-date = April 12, 2020}}</ref> making it the world's first ]. This level of performance from its large-scale computing network has allowed researchers to run ] atomic-level simulations of protein folding thousands of times longer than formerly achieved. Since its launch on October 1, |
Folding@home is one of the world's fastest computing systems. With heightened interest in the project as a result of the ],<ref>{{harvnb|News 12 Long Island|2020}}: "Since the start of the COVID-19 pandemic, Folding@home has seen a significant surge in downloads, a clear indication that people around the world are concerned about doing their part to help researchers find a remedy to this virus," said Dr. Sina Rabbany, dean of the DeMatteis School."</ref> the system achieved a speed of approximately 1.22 ] by late March 2020 and reached 2.43 exaflops by April 12, 2020,<ref>{{cite web | url = https://stats.foldingathome.org/os | archive-url = https://archive.today/20200412111010/https://stats.foldingathome.org/os | url-status = dead | archive-date = April 12, 2020 | title = Client Statistics by OS | author = Pande lab | publisher = Archive.is | access-date = April 12, 2020}}</ref> making it the world's first ]. This level of performance from its large-scale computing network has allowed researchers to run ] atomic-level simulations of protein folding thousands of times longer than formerly achieved. Since its launch on October 1, 2000, Folding@home was involved in the production of 226 ].<ref name="papers-july-2020">{{cite web |title=Papers & Results |url=https://foldingathome.org/papers-results/ |website=Folding@home.org |access-date=December 9, 2021}}</ref> Results from the project's simulations agree well with experiments.<ref name="10.1021/ja9090353"/><ref name="10.1073/pnas.1003962107"/><ref name="10.1038/nature01160"/> | ||
== Background == | == Background == | ||
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The simulations run on Folding@home are used in conjunction with laboratory experiments,<ref name="10.1016/j.sbi.2010.10.006"/> but researchers can use them to study how folding '']'' differs from folding in native cellular environments. This is advantageous in studying aspects of folding, misfolding, and their relationships to disease that are difficult to observe experimentally. For example, in 2011, Folding@home simulated protein folding inside a ] exit tunnel, to help scientists better understand how natural confinement and crowding might influence the folding process.<ref name="forum: 7808/7809 to FAH"/><ref name="10.1073/pnas.0608256104"/> Furthermore, scientists typically employ chemical ] to unfold proteins from their stable native state. It is not generally known how the denaturant affects the protein's refolding, and it is difficult to experimentally determine if these denatured states contain residual structures which may influence folding behavior. In 2010, Folding@home used GPUs to simulate the unfolded states of ], and predicted its collapse rate in strong agreement with experimental results.<ref name="10.1021/ja908369h"/> | The simulations run on Folding@home are used in conjunction with laboratory experiments,<ref name="10.1016/j.sbi.2010.10.006"/> but researchers can use them to study how folding '']'' differs from folding in native cellular environments. This is advantageous in studying aspects of folding, misfolding, and their relationships to disease that are difficult to observe experimentally. For example, in 2011, Folding@home simulated protein folding inside a ] exit tunnel, to help scientists better understand how natural confinement and crowding might influence the folding process.<ref name="forum: 7808/7809 to FAH"/><ref name="10.1073/pnas.0608256104"/> Furthermore, scientists typically employ chemical ] to unfold proteins from their stable native state. It is not generally known how the denaturant affects the protein's refolding, and it is difficult to experimentally determine if these denatured states contain residual structures which may influence folding behavior. In 2010, Folding@home used GPUs to simulate the unfolded states of ], and predicted its collapse rate in strong agreement with experimental results.<ref name="10.1021/ja908369h"/> | ||
The large data sets from the project are freely available for other researchers to use upon request and some can be accessed from the Folding@home website.<ref name="typepad: Simbios"/><ref name="papers for free"/> The Pande lab has collaborated with other molecular dynamics systems such as the ] supercomputer,<ref name="10.1038/sj.embor.7400108"/> and they share Folding@home's key software with other researchers, so that the algorithms which benefited Folding@home may aid other scientific areas.<ref name="typepad: Simbios"/> In 2011, they released the open-source Copernicus software, which is based on Folding@home's MSM and other parallelizing methods and aims to improve the efficiency and scaling of molecular simulations on large ]s or ]s.<ref name="Pronk et al, 2011"/><ref name="Copernicus download"/> Summaries of all scientific findings from Folding@home are posted on the Folding@home website after publication.<ref name="papers"/> | The large data sets from the project are freely available for other researchers to use upon request and some can be accessed from the Folding@home website.<ref name="typepad: Simbios"/><ref name="papers for free"/> The Pande lab has collaborated with other molecular dynamics systems such as the ] supercomputer,<ref name="10.1038/sj.embor.7400108"/> and they share Folding@home's key software with other researchers, so that the algorithms which benefited Folding@home may aid other scientific areas.<ref name="typepad: Simbios"/> In 2011, they released the open-source Copernicus software, which is based on Folding@home's MSM and other parallelizing methods and aims to improve the efficiency and scaling of molecular simulations on large ]s or ]s.<ref name="Pronk et al, 2011" /><ref name="Copernicus download"/> Summaries of all scientific findings from Folding@home are posted on the Folding@home website after publication.<ref name="papers"/> | ||
=== Alzheimer's disease === | === Alzheimer's disease === | ||
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Approximately half of all known ]s interfere with the workings of a bacteria's ], a large and complex biochemical machine that performs ] by ] ] into proteins. ] clog the ribosome's exit tunnel, preventing synthesis of essential bacterial proteins. In 2007, the Pande lab received a ] to study and design new antibiotics.<ref name="diseases FAQ"/> In 2008, they used Folding@home to study the interior of this tunnel and how specific molecules may affect it.<ref name="10.1073/pnas.0801795105"/> The full structure of the ribosome was determined only as of 2011, and Folding@home has also simulated ]s, as many of their functions remain largely unknown.<ref name="description: 5765"/> | Approximately half of all known ]s interfere with the workings of a bacteria's ], a large and complex biochemical machine that performs ] by ] ] into proteins. ] clog the ribosome's exit tunnel, preventing synthesis of essential bacterial proteins. In 2007, the Pande lab received a ] to study and design new antibiotics.<ref name="diseases FAQ"/> In 2008, they used Folding@home to study the interior of this tunnel and how specific molecules may affect it.<ref name="10.1073/pnas.0801795105"/> The full structure of the ribosome was determined only as of 2011, and Folding@home has also simulated ]s, as many of their functions remain largely unknown.<ref name="description: 5765"/> | ||
==Potential applications in biomedical research== | |||
There are many more ] that can be benefited from Folding@home to either discern the misfolded protein structure or the misfolding kinetics, and assist in drug design in the future. The often fatal ] is among the most significant. | |||
===Prion diseases=== | |||
{{Synthesis|section|date=March 2020}} | |||
A ] (PrP) is a ] cellular protein found widely in ]. In mammals, it is more abundant in the ]. Although its function is unknown, its high conservation among species indicates an important role in the cellular function. The conformational change from the normal prion protein (PrPc, stands for cellular) to the disease causing ] PrPSc (stands for prototypical prion disease–]) causes a host of diseases collectly known as ] (TSEs), including ] (BSE) in bovine, ] (CJD) and ] in human, ] (CWD) in the deer family. The conformational change is widely accepted as the result of ]. What distinguishes TSEs from other protein misfolding diseases is its transmissible nature. The ‘seeding’ of the infectious PrPSc, either arising spontaneously, hereditary or acquired via exposure to contaminated tissues,<ref>{{cite web|url=https://www.ninds.nih.gov/Disorders/Patient-Caregiver-Education/Fact-Sheets/Creutzfeldt-Jakob-Disease-Fact-Sheet|title=Creutzfeldt-Jakob Disease Fact Sheet|author=National Institute of Neurological Disorders and Stroke|publisher=NIH|date=August 21, 2018|access-date=March 2, 2019}}</ref> can cause a chain reaction of transforming normal PrPc into ] aggregates or ] like plaques consist of PrPSc.<ref name=kupfer>{{cite journal|last1=Kupfer|first1=L|last2=Hinrichs|first2=W|last3=Groschup|first3=M.H.|title=Prion Protein Misfolding|journal=Current Molecular Medicine|volume=9|issue=7|pages=826–835|year=2009|publisher=Bentham Science Publishers|doi=10.2174/156652409789105543|pmid=19860662|pmc=3330701}}</ref> | |||
The molecular structure of PrPSc has not been fully characterized due to its aggregated nature. Neither is known much about the mechanism of the protein misfolding nor its ]. Using the known structure of PrPc and the results of the in vitro and in vivo studies described below, Folding@home could be valuable in elucidating how PrPSc is formed and how the infectious protein arrange themselves to form fibrils and amyloid like plaques, bypassing the requirement to purify PrPSc or dissolve the aggregates. | |||
The PrPc has been ] dissociated from the membrane and purified, its structure studied using structure characterization techniques such as ] and ]. ] PrPc has 231 ] (aa) in murine. The molecule consists of a long and unstructured ] region spanning up to aa residue 121 and a structured ] domain.<ref name=kupfer/> This globular domain harbors two short sheet-forming anti-parallel ] (aa 128 to 130 and aa 160 to 162 in murine PrPc) and three ] (helix I: aa 143 to 153; helix II: aa 171 to 192; helix III: aa 199 to 226 in murine PrPc),<ref name=riek>{{cite journal|last1=Riek|first1=Poland|last2=Hornemann|first2=Simone|last3=Wider|first3=Gerhard|last4=Billeter|first4=Martin|last5=Glockshuber|first5=Rudi|last6=Wüthrich|first6=Kurt|title=NMR structure of the mouse prion protein domain in PrP(121-231)|journal=Nature|volume=382|issue=6587|pages=180–182|year=1996|publisher=Nature Research|doi=10.1038/382180a0|pmid=8700211|bibcode=1996Natur.382..180R|s2cid=4251606}}</ref> Helices II and III are anti-parallel orientated and connected by a short loop. Their structural stability is supported by a ], which is parallel to both sheet-forming β-strands. These α-helices and the β-sheet form the rigid core of the globular domain of PrPc.<ref name=ziegler>{{cite journal|last1=Ziegler|first1=J|last2=Sticht|first2=H|last3=Marx|first3=UC|last4=Müller|first4=W|last5=Rösch|first5=P|last6=Schwarzinger|first6=S|title=CD and NMR studies of prion protein (PrP) helix1. Novel implications for its role in the PrPC-->PrPSc conversion process|journal=J Biol Chem|volume=278|issue=50|pages=50175–81|year=2003|publisher=American Society for Biochemistry and Molecular Biology|doi=10.1074/jbc.M305234200|pmid=12952977|s2cid=29498217|url=http://espace.library.uq.edu.au/view/UQ:164149/UQ164149_OA.pdf|doi-access=free}}</ref> | |||
The disease causing PrPSc is ] resistant and insoluble. Attempts to purify it from the brains of infected animals invariably yield heterogeneous mixtures and aggregated states that are not amenable to characterization by NMR spectroscopy or X-ray crystallography. However, it is a general consensus that PrPSc contains a high percentage of tightly stacked β-sheets than the normal PrPc that renders the protein insoluble and resistant to proteinase. Using techniques of ] and structural modeling based on similar common protein structures, it has been discovered that PrPSc contains ß-sheets in the region of aa 81–95 to aa 171, while the carboxy terminal structure is supposedly preserved, retaining the disulfide-linked α-helical conformation in the normal PrPc. These ß-sheets form a parallel left-handed beta-helix.<ref name=kupfer/> Three PrPSc molecules are believed to form a primary unit and therefore build the basis for the so-called scrapie-associated fibrils.<ref>{{cite journal|last1=Govaerts|first1=Cedric|last2=Wile|first2=Holger|last3=Brusiner|first3=Stanley B.|last4=Cohen|first4=Fred|title=Evidence for assembly of prions with left-handed β-helices into trimers|journal=Proc Natl Acad Sci USA|volume=101|issue=22|pages=8342–47|year=2004|publisher=National Academy of Sciences|doi=10.1073/pnas.0402254101|pmid=15155909|pmc=420396|bibcode=2004PNAS..101.8342G|doi-access=free}}</ref> The catalytic activity depends on the size of the particle. PrPSc particles which consist of only 14-28 PrPc molecules exhibit the highest rate of infectivity and conversion.<ref>{{cite journal|last1=Silveira|first1=Jay|last2=Raymond|first2=Gregory|last3=Hughson|first3=Andrew|last4=Race|first4=Richard|last5=Sim|first5=Valerie|last6=Caughey|first6=Byron|last7=Hayes|first7=Stanley|title=The most infectious prion protein particles|journal=Nature|volume=437|issue=7056|pages=257–261|year=2005|publisher=Nature Research|doi=10.1038/nature03989|pmid=16148934|pmc=1513539|bibcode=2005Natur.437..257S}}</ref> | |||
Despite the difficulty to purify and characterize PrPSc, from the known molecular structure of PrPc and using ] and N-terminal deletion,<ref name=moore>{{cite journal|last1=Moore|first1=Roger A.|last2=Taubner|first2=Lara M.|last3=Priola|first3=Suzette|title=Prion Protein Misfolding and Disease|journal=Curr Opin Struct Biol|volume=19|issue=1|pages=14–22|year=2009|publisher=Elsevier|doi=10.1016/j.sbi.2008.12.007|pmid=19157856|pmc=2674794}}</ref> the potential ‘hot spots’ of protein misfolding leading to the pathogenic PrPSc could be deduced and Folding@home could be of great value in confirming these. Studies found that both the ] and ] structure of the prion protein can be of significance of the conversion. | |||
There are more than twenty ] of the prion protein gene (]) that are known to be associated with or that are directly linked to the hereditary form of human TSEs , indicating single amino acids at certain position, likely within the carboxy domain,<ref name=riek/> of the PrPc can affect the susceptibility to TSEs. | |||
The post-translational amino terminal region of PrPc consists of residues 23-120 which make up nearly half of the amino sequence of full-length matured PrPc. There are two sections in the amino terminal region that may influence conversion. First, residues 52-90 contains an octapeptide repeat (5 times) region that likely influences the initial binding (via the octapeptide repeats) and also the actual conversion via the second section of aa 108–124.<ref>{{cite journal|last1=Moore|first1=Roger A.|last2=Herzog|first2=Christian|last3=Errett|first3=John|last4=Kocisko|first4=David A.|last5=Arnold|first5=Kevin M.|last6=Hayes|first6=Stanley F.|last7=Priola|first7=Suzette A.|title=Octapeptide repeat insertions increase the rate of protease-resistant prion protein formation|journal=Protein Science|volume=15|issue=3|pages=609–619|year=2006|publisher=Wiley-Blackwell|doi=10.1110/ps.051822606|pmid=16452616|pmc=2249780}}</ref> The highly ] AGAAAAGA is located between aa residue 113 and 120 and is described as putative aggregation site,<ref>{{cite journal|last1=Gasset|first1=M|last2=Baldwin|first2=M|last3=Lloyd|first3=D|last4=Gabriel|first4=J|last5=Holtzman|first5=D|last6=Cohen|first6=F|last7=Fletterick|first7=R|last8=Brusiner|first8=S|title=Predicted alpha-helical regions of the prion protein when synthesized as peptides form amyloid|journal=Proc Natl Acad Sci USA|volume=89|issue=22|pages=10940–44|year=1992|publisher=National Academy of Sciences| pmid=1438300|pmc=50458|doi=10.1073/pnas.89.22.10940|bibcode=1992PNAS...8910940G|doi-access=free}}</ref> although this sequence requires its flanking parts to form fibrillar aggregates.<ref>{{cite journal|last1=Ziegler|first1=Jan|last2=Viehrig|first2=Christine|last3=Geimer|first3=Stefan|last4=Rosch|first4=Paul|last5=Schwarzinger|first5=Stephan|title=Putative aggregation initiation sites in prion protein| journal=FEBS Letters|volume=580|issue=8|pages=2033–40|year=2006|publisher=FEBS Press|doi=10.1016/j.febslet.2006.03.002|pmid=16545382|s2cid=23876100|doi-access=free}}</ref> | |||
In the carboxy globular domain,<ref name=ziegler/> among the three helices, study show that helix II has a significant higher propensity to β-strand conformation.<ref>{{cite journal|last1=Brusiner|first1=Stanley|title=Prions|journal= Proc Natl Acad Sci USA|volume=95|issue=23|pages=13363–83|year=1998|publisher=National Academy of Sciences| pmid=9811807|pmc=33918|doi=10.1073/pnas.95.23.13363|bibcode=1998PNAS...9513363P|doi-access=free}}</ref> Due to the high conformational flexvoribility seen between residues 114-125 (part of the unstructured N-terminus chain) and the high β-strand propensity of helix II, only moderate changes in the environmental conditions or interactions might be sufficient to induce misfolding of PrPc and subsequent fibril formation.<ref name=kupfer/> | |||
Other studies of NMR structures of PrPc showed that these residues (~108–189) contain most of the folded domain including both β-strands, the first two α-helices, and the loop/turn regions connecting them, but not the helix III.<ref name=moore/> Small changes within the loop/turn structures of PrPc itself could be important in the conversion as well.<ref>{{cite journal|last1=Vorberg|first1=I|last2=Groschup|first2=MH|last3=Pfaff|first3=E|last4=Priola|first4=SA|title=Multiple amino acid residues within the rabbit prion protein inhibit formation of its abnormal isoform|journal=J. Virol.|volume=77|issue=3|pages=2003–9|year=2003|publisher=American Society for Microbiology|doi=10.1128/JVI.77.3.2003-2009.2003| pmid=12525634|pmc=140934}}</ref> In another study, Riek et al. showed that the two small regions of β-strand upstream of the loop regions act as a nucleation site for the conformational conversion of the loop/turn and α-helical structures in PrPc to β-sheet.<ref name=riek/> | |||
The energy threshold for the conversion are not necessarily high. The folding stability, i.e. the ] of a globular protein in its environment is in the range of one or two ] thus allows the transition to an isoform without the requirement of high transition energy.<ref name=kupfer/> | |||
From the respective of the interactions among the PrPc molecules, hydrophobic interactions play a crucial role in the formation of β-sheets, a hallmark of PrPSc, as the sheets bring fragments of ] chains into close proximity.<ref>{{cite journal|last1=Barrow|first1=CJ|last2=Yasuda|first2=A|last3=Kenny|first3=PT|last4=Zagorski|first4=MG|title=Solution conformations and aggregational properties of synthetic amyloid beta-peptides of Alzheimer's disease. Analysis of circular dichroism spectra.|journal= J Biol Chem|volume=225|issue=4|pages=1075–93|year=1992|publisher=American Society for Biochemistry and Molecular Biology| pmid=1613791|doi=10.1016/0022-2836(92)90106-t}}</ref> Indeed, Kutznetsov and Rackovsky <ref>{{cite journal|last1=Kuznetsov|first1=Igor|last2=Rackovsky|first2=Shalom|title=Comparative computational analysis of prion proteins reveals two fragments with unusual structural properties and a pattern of increase in hydrophobicity associated with disease-promoting mutations|journal=Protein Science|volume=13|issue=12|pages=3230–44|year=2004|publisher=Wiley-Blackwell|doi=10.1110/ps.04833404|pmid=15557265|pmc=2287303}}</ref> showed that disease-promoting mutations in the human PrPc had a statistically significant tendency towards increasing local hydrophobicity. | |||
In vitro experiments showed the kinetics of misfolding has an initial lag phase followed by a rapid growth phase of fibril formation.<ref>{{cite journal|last1=Baskakov|first1=IV|last2=Legname|first2=G|last3=Baldwin|first3=MA|last4=Prusiner|first4=SB|last5=Cohen|first5=FE|title=Pathway complexity of prion protein assembly into amyloid|journal= J Biol Chem|volume=277|issue=24|pages=21140–8|year=2002|publisher=American Society for Biochemistry and Molecular Biology|doi=10.1074/jbc.M111402200| pmid=11912192|doi-access=free}}</ref> It is likely that PrPc goes through some intermediate states, such as at least partially unfolded or degraded, before finally ending up as part of an amyloid fibril.<ref name=kupfer/> | |||
== Patterns of participation == | == Patterns of participation == | ||
Like other ] projects, Folding@home is an online ] project. In these projects non-specialists contribute computer processing power or help to analyze data produced by professional scientists. Participants receive little or no obvious reward. | Like other ] projects, Folding@home is an online ] project. In these projects non-specialists contribute computer processing power or help to analyze data produced by professional scientists. Participants receive little or no obvious reward. | ||
Research has been carried out into the motivations of citizen scientists and most of these studies have found that participants are motivated to take part because of altruistic reasons; that is, they want to help scientists and make a contribution to the advancement of their research.<ref>{{Cite journal|last1=Raddick|first1=M. Jordan|last2=Bracey|first2=Georgia|last3=Gay|first3=Pamela L.|last4=Lintott|first4=Chris J.|last5=Murray|first5=Phil|last6=Schawinski|first6=Kevin|last7=Szalay|first7=Alexander S.|last8=Vandenberg|first8=Jan|date=December 2010|title=Galaxy Zoo: Exploring the Motivations of Citizen Science Volunteers|journal=Astronomy Education Review|volume=9|issue=1|pages=010103|doi=10.3847/AER2009036|arxiv=0909.2925|bibcode=2010AEdRv...9a0103R|s2cid=118372704}}</ref><ref>{{Cite book|title=Online citizen science and the widening of academia : distributed engagement with research and knowledge production|last=Vickie|first=Curtis|isbn=9783319776644|location=Cham, Switzerland|oclc=1034547418|date = April 20, 2018}}</ref><ref>{{Cite |
Research has been carried out into the motivations of citizen scientists and most of these studies have found that participants are motivated to take part because of altruistic reasons; that is, they want to help scientists and make a contribution to the advancement of their research.<ref>{{Cite journal|last1=Raddick|first1=M. Jordan|last2=Bracey|first2=Georgia|last3=Gay|first3=Pamela L.|last4=Lintott|first4=Chris J.|last5=Murray|first5=Phil|last6=Schawinski|first6=Kevin|last7=Szalay|first7=Alexander S.|last8=Vandenberg|first8=Jan|date=December 2010|title=Galaxy Zoo: Exploring the Motivations of Citizen Science Volunteers|journal=Astronomy Education Review|volume=9|issue=1|pages=010103|doi=10.3847/AER2009036|arxiv=0909.2925|bibcode=2010AEdRv...9a0103R|s2cid=118372704 |doi-access=free }}</ref><ref>{{Cite book|title=Online citizen science and the widening of academia : distributed engagement with research and knowledge production|last=Vickie|first=Curtis|isbn=9783319776644|location=Cham, Switzerland|oclc=1034547418|date = April 20, 2018}}</ref><ref>{{Cite book|last1=Nov|first1=Oded|last2=Arazy|first2=Ofer|last3=Anderson|first3=David|title=Proceedings of the 2011 iConference |chapter=Dusting for science |date=2011|chapter-url=http://portal.acm.org/citation.cfm?doid=1940761.1940771|location=Seattle, Washington|publisher=ACM Press|pages=68–74|doi=10.1145/1940761.1940771|isbn=9781450301213|series=IConference '11|s2cid=12219985}}</ref><ref>{{Cite journal|last=Curtis|first=Vickie|date=December 2015|title=Motivation to Participate in an Online Citizen Science Game: A Study of Foldit|journal=Science Communication|volume=37|issue=6|pages=723–746|doi=10.1177/1075547015609322|s2cid=1345402|issn=1075-5470|url=http://oro.open.ac.uk/44708/1/V%20Curtis%20Foldit%20Manuscript%20Oct%202015.pdf}}</ref> Many participants in citizen science have an underlying interest in the topic of the research and gravitate towards projects that are in disciplines of interest to them. Folding@home is no different in that respect.<ref name=":0">{{Cite journal|last=Curtis|first=Vickie|date=April 27, 2018|title=Patterns of Participation and Motivation in Folding@home: The Contribution of Hardware Enthusiasts and Overclockers|journal=Citizen Science: Theory and Practice|volume=3|issue=1|pages=5|doi=10.5334/cstp.109|issn=2057-4991|doi-access=free}}</ref> Research carried out recently on over 400 active participants revealed that they wanted to help make a contribution to research and that many had friends or relatives affected by the diseases that the Folding@home scientists investigate. | ||
Folding@home attracts participants who are computer hardware enthusiasts. These groups bring considerable expertise to the project and are able to build computers with advanced processing power.<ref>{{Cite journal|last=Colwell|first=B.|date=March 2004|title=The Zen of overclocking|journal=Computer|volume=37|issue=3|pages=9–12|doi=10.1109/MC.2004.1273994|s2cid=21582410|issn=0018-9162}}</ref> Other distributed computing projects attract these types of participants and projects are often used to benchmark the performance of modified computers, and this aspect of the hobby is accommodated through the competitive nature of the project. Individuals and teams can compete to see who can process the most computer processing units (CPUs). | Folding@home attracts participants who are computer hardware enthusiasts. These groups bring considerable expertise to the project and are able to build computers with advanced processing power.<ref>{{Cite journal|last=Colwell|first=B.|date=March 2004|title=The Zen of overclocking|journal=Computer|volume=37|issue=3|pages=9–12|doi=10.1109/MC.2004.1273994|s2cid=21582410|issn=0018-9162}}</ref>{{Request quotation|date=July 2022}} Other distributed computing projects attract these types of participants and projects are often used to benchmark the performance of modified computers, and this aspect of the hobby is accommodated through the competitive nature of the project. Individuals and teams can compete to see who can process the most computer processing units (CPUs). | ||
This latest research on Folding@home involving interview and ethnographic observation of online groups showed that teams of hardware enthusiasts can sometimes work together, sharing best practice with regard to maximizing processing output. Such teams can become ], with a shared language and online culture. This pattern of participation has been observed in other distributed computing projects.<ref>{{Cite journal|last1=Kloetzer|first1=Laure|last2=Da Costa|first2=Julien|last3=Schneider|first3=Daniel K.|date=December 31, 2016|title=Not so passive: engagement and learning in Volunteer Computing projects|journal=Human Computation|volume=3|issue=1|pages=25–68|doi=10.15346/hc.v3i1.4|issn=2330-8001|doi-access=free}}</ref><ref>{{Cite journal|last1=Darch Peter|last2=Carusi Annamaria|date=September 13, 2010|title=Retaining volunteers in volunteer computing projects|journal=Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences|volume=368|issue=1926|pages=4177–4192|doi=10.1098/rsta.2010.0163|pmid=20679130|bibcode=2010RSPTA.368.4177D|doi-access= |
This latest research on Folding@home involving interview and ethnographic observation of online groups showed that teams of hardware enthusiasts can sometimes work together, sharing best practice with regard to maximizing processing output. Such teams can become ], with a shared language and online culture. This pattern of participation has been observed in other distributed computing projects.<ref>{{Cite journal|last1=Kloetzer|first1=Laure|last2=Da Costa|first2=Julien|last3=Schneider|first3=Daniel K.|date=December 31, 2016|title=Not so passive: engagement and learning in Volunteer Computing projects|journal=Human Computation|volume=3|issue=1|pages=25–68|doi=10.15346/hc.v3i1.4|issn=2330-8001|doi-access=free}}</ref><ref>{{Cite journal|last1=Darch Peter|last2=Carusi Annamaria|date=September 13, 2010|title=Retaining volunteers in volunteer computing projects|journal=Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences|volume=368|issue=1926|pages=4177–4192|doi=10.1098/rsta.2010.0163|pmid=20679130|bibcode=2010RSPTA.368.4177D|s2cid=1675353 |doi-access=}}</ref> | ||
Another key observation of Folding@home participants is that many are male.<ref name=":0" /> This has also been observed in other distributed projects. Furthermore, many participants work in computer and technology-based jobs and careers.<ref name=":0" /><ref>{{Cite web|url=https://www.worldcommunitygrid.org/about_us/viewNewsArticle.do?articleId=323|title=2013 Member Study: Findings and Next Steps|publisher=World Community Grid}}</ref><ref>{{Cite journal|last=Krebs|first=Viola|date=January 31, 2010|title=Motivations of cybervolunteers in an applied distributed computing environment: MalariaControl.net as an example|journal=First Monday|volume=15|issue=2|doi=10.5210/fm.v15i2.2783}}</ref> | Another key observation of Folding@home participants is that many are male.<ref name=":0" /> This has also been observed in other distributed projects. Furthermore, many participants work in computer and technology-based jobs and careers.<ref name=":0" /><ref>{{Cite web|url=https://www.worldcommunitygrid.org/about_us/viewNewsArticle.do?articleId=323|title=2013 Member Study: Findings and Next Steps|publisher=World Community Grid}}</ref><ref>{{Cite journal|last=Krebs|first=Viola|date=January 31, 2010|title=Motivations of cybervolunteers in an applied distributed computing environment: MalariaControl.net as an example|journal=First Monday|volume=15|issue=2|doi=10.5210/fm.v15i2.2783 |doi-access= free}}</ref> | ||
Not all Folding@home participants are hardware enthusiasts. Many participants run the project software on unmodified machines and do take part competitively. |
Not all Folding@home participants are hardware enthusiasts. Many participants run the project software on unmodified machines and do take part competitively. By January 2020, the number of users was down to 30,000.<ref>{{cite web | url=https://arstechnica.com/science/2020/04/how-the-pandemic-revived-a-distributed-computing-project-and-made-history/ | title=The coronavirus pandemic turned Folding@Home into an exaFLOP supercomputer | date=April 14, 2020 }}</ref> However, it is difficult to ascertain what proportion of participants are hardware enthusiasts. Although, according to the project managers, the contribution of the enthusiast community is substantially larger in terms of processing power.<ref>{{Cite book|url=http://oro.open.ac.uk/42239/1/Vickie%20Curtis%20PhD%20Thesis%20Oct%202014.pdf|title=Online citizen science projects: an exploration of motivation, contribution and participation, PhD Thesis|last=Curtis|first=Vickie|publisher=The Open University|year=2015|location=United Kingdom}}</ref> | ||
=== Performance === | === Performance === | ||
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On September 16, 2007, due in large part to the participation of PlayStation 3 consoles, the Folding@home project officially attained a sustained performance level higher than one native ], becoming the first computing system of any kind to do so.<ref name="typepad: crossing 1 PF"/><ref name="10.1016/j.cub.2012.01.008"/> ]'s fastest supercomputer at the time was ], at 0.280 petaFLOPS.<ref name="Top500 June 2007"/> The following year, on May 7, 2008, the project attained a sustained performance level higher than two native petaFLOPS,<ref name="FAH reaches 2 PF"/> followed by the three and four native petaFLOPS milestones in August 2008<ref name="Nvidia-FAH milestone"/><ref name="3 PF barrier"/> and September 28, 2008 respectively.<ref name="past 4 petaFLOPS"/> On February 18, 2009, Folding@home achieved five native petaFLOPS,<ref name="typepad: FAH passes 5 PF"/><ref name="crossing 5 PF barrier"/> and was the first computing project to meet these five levels.<ref name="Community Grid Computing"/><ref name="review of FAH"/> In comparison, November 2008's fastest supercomputer was ]'s ] at 1.105 petaFLOPS.<ref name="Top500 November 2008"/> On November 10, 2011, Folding@home's performance exceeded six native petaFLOPS with the equivalent of nearly eight x86 petaFLOPS.<ref name="10.1016/j.cub.2012.01.008"/><ref name="6 petaFLOPS"/> In mid-May 2013, Folding@home attained over seven native petaFLOPS, with the equivalent of 14.87 x86 petaFLOPS. It then reached eight native petaFLOPS on June 21, followed by nine on September 9 of that year, with 17.9 x86 petaFLOPS.<ref name="FAH stats doc"/> On May 11, 2016 Folding@home announced that it was moving towards reaching the 100 x86 petaFLOPS mark.<ref>{{cite web|title=100 Petaflops nearly reached|url=https://foldingathome.org/home/closing-in-on-100-petaflops|publisher=foldingathome.org|access-date=August 9, 2016|date=May 11, 2016}}</ref> | On September 16, 2007, due in large part to the participation of PlayStation 3 consoles, the Folding@home project officially attained a sustained performance level higher than one native ], becoming the first computing system of any kind to do so.<ref name="typepad: crossing 1 PF"/><ref name="10.1016/j.cub.2012.01.008"/> ]'s fastest supercomputer at the time was ], at 0.280 petaFLOPS.<ref name="Top500 June 2007"/> The following year, on May 7, 2008, the project attained a sustained performance level higher than two native petaFLOPS,<ref name="FAH reaches 2 PF"/> followed by the three and four native petaFLOPS milestones in August 2008<ref name="Nvidia-FAH milestone"/><ref name="3 PF barrier"/> and September 28, 2008 respectively.<ref name="past 4 petaFLOPS"/> On February 18, 2009, Folding@home achieved five native petaFLOPS,<ref name="typepad: FAH passes 5 PF"/><ref name="crossing 5 PF barrier"/> and was the first computing project to meet these five levels.<ref name="Community Grid Computing"/><ref name="review of FAH"/> In comparison, November 2008's fastest supercomputer was ]'s ] at 1.105 petaFLOPS.<ref name="Top500 November 2008"/> On November 10, 2011, Folding@home's performance exceeded six native petaFLOPS with the equivalent of nearly eight x86 petaFLOPS.<ref name="10.1016/j.cub.2012.01.008"/><ref name="6 petaFLOPS"/> In mid-May 2013, Folding@home attained over seven native petaFLOPS, with the equivalent of 14.87 x86 petaFLOPS. It then reached eight native petaFLOPS on June 21, followed by nine on September 9 of that year, with 17.9 x86 petaFLOPS.<ref name="FAH stats doc"/> On May 11, 2016 Folding@home announced that it was moving towards reaching the 100 x86 petaFLOPS mark.<ref>{{cite web|title=100 Petaflops nearly reached|url=https://foldingathome.org/home/closing-in-on-100-petaflops|publisher=foldingathome.org|access-date=August 9, 2016|date=May 11, 2016}}</ref> | ||
Further use grew from increased awareness and participation in the project from the coronavirus pandemic in 2020. On March 20, 2020 Folding@home announced via Twitter that it was running with over 470 native petaFLOPS,<ref>{{Cite web|url=https://twitter.com/drGregBowman/status/1241037866215657472|title=Amazing! @foldingathome now has over 470 petaFLOPS of compute power. To put that in perspective, that's more than 2x the peak performance of the Summit super computer!|last=Bowman|first=Greg|date=March 20, 2020|website=@drGregBowman|language=en|access-date=March 20, 2020}}</ref> the equivalent of 958 x86 petaFLOPS.<ref>{{Cite web|url=https://stats.foldingathome.org/os|title=Folding@home stats report|date=March 20, 2020|archive-url=https://web.archive.org/web/20200320191855/https://stats.foldingathome.org/os|access-date=March 20, 2020|archive-date=March 20, 2020}}</ref> By March 25 it reached 768 petaFLOPS, or 1.5 x86 exaFLOPS, making it the first ].<ref>{{cite web | url = https://www.anandtech.com/show/15661/folding-at-home-reaches-exascale-1000000000000000000-operations-per-second-for-covid-19 | title = Folding@Home Reaches Exascale: 1,500,000,000,000,000,000 Operations Per Second for COVID-19 | first = Anton | last= Shilov | date =March 25, 2020 | access-date = March 26, 2020 | work = ] }}</ref> |
Further use grew from increased awareness and participation in the project from the coronavirus pandemic in 2020. On March 20, 2020 Folding@home announced via Twitter that it was running with over 470 native petaFLOPS,<ref>{{Cite web|url=https://twitter.com/drGregBowman/status/1241037866215657472|title=Amazing! @foldingathome now has over 470 petaFLOPS of compute power. To put that in perspective, that's more than 2x the peak performance of the Summit super computer!|last=Bowman|first=Greg|date=March 20, 2020|website=@drGregBowman|language=en|access-date=March 20, 2020}}</ref> the equivalent of 958 x86 petaFLOPS.<ref>{{Cite web|url=https://stats.foldingathome.org/os|title=Folding@home stats report|date=March 20, 2020|archive-url=https://web.archive.org/web/20200320191855/https://stats.foldingathome.org/os|access-date=March 20, 2020|archive-date=March 20, 2020}}</ref> By March 25 it reached 768 petaFLOPS, or 1.5 x86 exaFLOPS, making it the first ].<ref>{{cite web | url = https://www.anandtech.com/show/15661/folding-at-home-reaches-exascale-1000000000000000000-operations-per-second-for-covid-19 | title = Folding@Home Reaches Exascale: 1,500,000,000,000,000,000 Operations Per Second for COVID-19 | first = Anton | last= Shilov | date =March 25, 2020 | access-date = March 26, 2020 | work = ] }}</ref> | ||
{{as of|2024|12|23}}, the computing power of Folding@home stands at 14.3 petaFLOPS, or 27.5 x86 petaFLOPS.<ref>{{Cite web |url=https://stats.foldingathome.org/os |title=Folding@home stats report |access-date=December 23, 2024}}</ref> | |||
=== Points === | === Points === | ||
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Professional software developers are responsible for most of Folding@home's code, both for the client and server-side. The development team includes programmers from ], ], ], and Cauldron Development.<ref name="typepad: how does dev get done"/> Clients can be downloaded only from the official Folding@home website or its commercial partners, and will only interact with Folding@home computer files. They will upload and download data with Folding@home's data servers (over ] 8080, with 80 as an alternate), and the communication is verified using 2048-bit ]s.<ref name="Main FAQ"/><ref name="Uninstall"/> While the client's ] (GUI) is open-source,<ref name="FAHControl source code"/> the client is ] citing security and scientific integrity as the reasons.<ref name="FAH license"/><ref name="forum: FAH EULA"/><ref name="help ubuntu"/> | Professional software developers are responsible for most of Folding@home's code, both for the client and server-side. The development team includes programmers from ], ], ], and Cauldron Development.<ref name="typepad: how does dev get done"/> Clients can be downloaded only from the official Folding@home website or its commercial partners, and will only interact with Folding@home computer files. They will upload and download data with Folding@home's data servers (over ] 8080, with 80 as an alternate), and the communication is verified using 2048-bit ]s.<ref name="Main FAQ"/><ref name="Uninstall"/> While the client's ] (GUI) is open-source,<ref name="FAHControl source code"/> the client is ] citing security and scientific integrity as the reasons.<ref name="FAH license"/><ref name="forum: FAH EULA"/><ref name="help ubuntu"/> | ||
However, this rationale of using proprietary software is disputed since while the license could be enforceable in the legal domain retrospectively, it |
However, this rationale of using proprietary software is disputed since while the license could be enforceable in the legal domain retrospectively, it does not practically prevent the modification (also known as ]) of the executable ]s. Likewise, ] distribution does not prevent the malicious modification of executable binary-code, either through a ] while being downloaded via the internet,<ref>{{Cite web|url=https://www.leviathansecurity.com/blog/the-case-of-the-modified-binaries|title=The Case of the Modified Binaries|website=Leviathan Security}}</ref> or by the redistribution of binaries by a third-party that have been previously modified either in their binary state (i.e. ]),<ref>{{Cite web|url=http://www.blackhat.com/presentations/bh-usa-02/clowes/bh-us-02-clowes-binaries.ppt|title=Fixing/Making Holes in ELF Binaries/Programs - Black Hat}}</ref> or by decompiling<ref>probably using tools such as {{Webarchive|url=https://web.archive.org/web/20180707212104/https://github.com/thorkill/eresi |date=July 7, 2018 }}</ref> and recompiling them after modification.<ref>{{Cite web|url=https://stackoverflow.com/questions/4309771/how-to-disassemble-modify-and-then-reassemble-a-linux-executable|title=x86 - How to disassemble, modify and then reassemble a Linux executable?|website=Stack Overflow}}</ref><ref>{{Cite web|url=https://reverseengineering.stackexchange.com/questions/185/how-do-i-add-functionality-to-an-existing-binary-executable|title=linux - How do I add functionality to an existing binary executable?|website=Reverse Engineering Stack Exchange}}</ref> These modifications are possible unless the binary files – and the transport channel – are ] and the recipient person/system is able to verify the digital signature, in which case unwarranted modifications should be detectable, but not always.<ref>{{cite web |url=https://www.blackhat.com/docs/us-16/materials/us-16-Nipravsky-Certificate-Bypass-Hiding-And-Executing-Malware-From-A-Digitally-Signed-Executable-wp.pdf |title=Certificate Bypass: Hiding and Executing Malware from a Digitally Signed Executable |publisher=] |website=BlackHat.com |date=August 2016}}</ref> Either way, since in the case of Folding@home the input data and output result processed by the client-software are both digitally signed,<ref name="Main FAQ"/><ref name="Uninstall"/> the integrity of work can be verified independently from the integrity of the client software itself. | ||
Folding@home uses the ] software libraries for networking.<ref name="10.1109/IPDPS.2009.5160922"/><ref name="typepad: how does dev get done"/> Folding@home was launched on October 1, 2000, and was the first distributed computing project aimed at bio-molecular systems.<ref name="10.1039/C1CP22100K"/> Its first client was a ], which would run while the computer was not otherwise in use.<ref name="10.1126/science.290.5498.1903"/><ref name="Executive summary"/> In 2004, the Pande lab collaborated with ] to test a supplemental client on the open-source ] framework. This client was released to closed beta in April 2005;<ref name="FAH for BOINC soon"/> however, the method became unworkable and was shelved in June 2006.<ref name="High-Per FAQ"/> | Folding@home uses the ] software libraries for networking.<ref name="10.1109/IPDPS.2009.5160922"/><ref name="typepad: how does dev get done"/> Folding@home was launched on October 1, 2000, and was the first ] project aimed at bio-molecular systems.<ref name="10.1039/C1CP22100K"/> Its first client was a ], which would run while the computer was not otherwise in use.<ref name="10.1126/science.290.5498.1903"/><ref name="Executive summary"/> In 2004, the Pande lab collaborated with ] to test a supplemental client on the open-source ] framework. This client was released to closed beta in April 2005;<ref name="FAH for BOINC soon"/> however, the method became unworkable and was shelved in June 2006.<ref name="High-Per FAQ"/> | ||
==== Graphics processing units ==== | ==== Graphics processing units ==== | ||
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Before 2010, the computing reliability of GPGPU consumer-grade hardware was largely unknown, and circumstantial evidence related to the lack of built-in ] in GPU memory raised reliability concerns. In the first large-scale test of GPU scientific accuracy, a 2010 study of over 20,000 hosts on the Folding@home network detected ]s in the memory subsystems of two-thirds of the tested GPUs. These errors strongly correlated to board architecture, though the study concluded that reliable GPU computing was very feasible as long as attention is paid to the hardware traits, such as software-side error detection.<ref name="10.1109/CCGRID.2010.84"/> | Before 2010, the computing reliability of GPGPU consumer-grade hardware was largely unknown, and circumstantial evidence related to the lack of built-in ] in GPU memory raised reliability concerns. In the first large-scale test of GPU scientific accuracy, a 2010 study of over 20,000 hosts on the Folding@home network detected ]s in the memory subsystems of two-thirds of the tested GPUs. These errors strongly correlated to board architecture, though the study concluded that reliable GPU computing was very feasible as long as attention is paid to the hardware traits, such as software-side error detection.<ref name="10.1109/CCGRID.2010.84"/> | ||
The first generation of Folding@home's GPU client (GPU1) was released to the public on October 2, 2006,<ref name="High-Per FAQ"/> delivering a 20–30 times speedup for some calculations over its CPU-based ] counterparts.<ref name="ATI FAQ"/> It was the first time GPUs had been used for either distributed computing or major molecular dynamics calculations.<ref name="typepad: GPU news"/><ref name="978-3-642-14389-2"/> GPU1 gave researchers significant knowledge and experience with the development of ] software, but in response to scientific inaccuracies with ], on April 10, 2008 it was succeeded by GPU2, the second generation of the client.<ref name="ATI FAQ"/><ref name="typepad: GPU2 open beta"/> Following the introduction of GPU2, GPU1 was officially retired on June 6.<ref name="ATI FAQ"/> Compared to GPU1, GPU2 was more scientifically reliable and productive, ran on ] and ]-enabled ] GPUs, and supported more advanced algorithms, larger proteins, and real-time visualization of the protein simulation.<ref name="typepad: GPU2 goes live"/><ref name="typepad: GPU2 going well"/> Following this, the third generation of Folding@home's GPU client (GPU3) was released on May 25, 2010. While ] with GPU2, GPU3 was more stable, efficient, and flexibile in its scientific abilities,<ref name="typepad: GPU3 prep"/> and used OpenMM on top of an ] framework.<ref name="typepad: GPU3 prep"/><ref name="typepad: GPU3 open beta"/> Although these GPU3 clients did not natively support the operating systems ] and ], Linux users with Nvidia graphics cards were able to run them through the ] software application.<ref name="forum: 7.1.38 released"/><ref name="forum: GPU3 headless guide"/> GPUs remain Folding@home's most powerful platform in ]. As of November 2012, GPU clients account for 87% of the entire project's x86 FLOPS throughput.<ref name="FAH osstats2"/> | The first generation of Folding@home's GPU client (GPU1) was released to the public on October 2, 2006,<ref name="High-Per FAQ"/> delivering a 20–30 times speedup for some calculations over its CPU-based ] counterparts.<ref name="ATI FAQ"/> It was the first time GPUs had been used for either distributed computing or major molecular dynamics calculations.<ref name="typepad: GPU news"/><ref name="978-3-642-14389-2"/> GPU1 gave researchers significant knowledge and experience with the development of ] software, but in response to scientific inaccuracies with ], on April 10, 2008, it was succeeded by GPU2, the second generation of the client.<ref name="ATI FAQ"/><ref name="typepad: GPU2 open beta"/> Following the introduction of GPU2, GPU1 was officially retired on June 6.<ref name="ATI FAQ"/> Compared to GPU1, GPU2 was more scientifically reliable and productive, ran on ] and ]-enabled ] GPUs, and supported more advanced algorithms, larger proteins, and real-time visualization of the protein simulation.<ref name="typepad: GPU2 goes live"/><ref name="typepad: GPU2 going well"/> Following this, the third generation of Folding@home's GPU client (GPU3) was released on May 25, 2010. While ] with GPU2, GPU3 was more stable, efficient, and flexibile in its scientific abilities,<ref name="typepad: GPU3 prep"/> and used OpenMM on top of an ] framework.<ref name="typepad: GPU3 prep"/><ref name="typepad: GPU3 open beta"/> Although these GPU3 clients did not natively support the operating systems ] and ], Linux users with Nvidia graphics cards were able to run them through the ] software application.<ref name="forum: 7.1.38 released"/><ref name="forum: GPU3 headless guide"/> GPUs remain Folding@home's most powerful platform in ]. As of November 2012, GPU clients account for 87% of the entire project's x86 FLOPS throughput.<ref name="FAH osstats2"/> | ||
Native support for Nvidia and AMD graphics cards under Linux was introduced with FahCore |
Native support for Nvidia and AMD graphics cards under Linux was introduced with FahCore 17, which uses OpenCL rather than CUDA.<ref name="forum: core17 Linux"/> | ||
==== PlayStation 3 ==== | ==== PlayStation 3 ==== | ||
{{further|Life with PlayStation}} | {{further|Life with PlayStation}} | ||
] | ] | ||
From March 2007 until November 2012, Folding@home took advantage of the computing power of ]s. At the time of its inception, its main ] ] delivered a 20 times speed increase over PCs for some calculations, processing power which could not be found on other systems such as the ].<ref name="Press FAQ"/><ref name="Biotech 27"/> The PS3's high speed and efficiency introduced other opportunities for worthwhile optimizations according to ], and significantly changed the tradeoff between computing efficiency and overall accuracy, allowing the use of more complex molecular models at little added computing cost.<ref name="10.1002/jcc.21054"/> This allowed Folding@home to run biomedical calculations that would have been otherwise infeasible computationally.<ref name="cnn ps3"/> | From March 2007 until November 2012, Folding@home took advantage of the computing power of ]s. At the time of its inception, its main ] ] delivered a 20 times speed increase over PCs for some calculations, processing power which could not be found on other systems such as the ].<ref name="Press FAQ"/><ref name="Biotech 27"/> The PS3's high speed and efficiency introduced other opportunities for worthwhile optimizations according to ], and significantly changed the tradeoff between computing efficiency and overall accuracy, allowing the use of more complex molecular models at little added computing cost.<ref name="10.1002/jcc.21054"/> This allowed Folding@home to run biomedical calculations that would have been otherwise infeasible computationally.<ref name="cnn ps3"/> | ||
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The PS3 client was developed in a collaborative effort between ] and the Pande lab and was first released as a standalone client on March 23, 2007.<ref name="Press FAQ"/><ref name="PS3 to study cancer"/> Its release made Folding@home the first distributed computing project to use PS3s.<ref name="PS3 research project"/> On September 18 of the following year, the PS3 client became a channel of ] on its launch.<ref name="Life With PS3 live"/><ref name="typepad: life with PS"/> In the types of calculations it can perform, at the time of its introduction, the client fit in between a CPU's flexibility and a GPU's speed.<ref name="10.1109/IPDPS.2009.5160922"/> However, unlike clients running on ]s, users were unable to perform other activities on their PS3 while running Folding@home.<ref name="cnn ps3"/> The PS3's uniform console environment made ] easier and made Folding@home more ].<ref name="Press FAQ"/> The PS3 also had the ability to stream data quickly to its GPU, which was used for real-time atomic-level visualizing of the current protein dynamics.<ref name="10.1002/jcc.21054"/> | The PS3 client was developed in a collaborative effort between ] and the Pande lab and was first released as a standalone client on March 23, 2007.<ref name="Press FAQ"/><ref name="PS3 to study cancer"/> Its release made Folding@home the first distributed computing project to use PS3s.<ref name="PS3 research project"/> On September 18 of the following year, the PS3 client became a channel of ] on its launch.<ref name="Life With PS3 live"/><ref name="typepad: life with PS"/> In the types of calculations it can perform, at the time of its introduction, the client fit in between a CPU's flexibility and a GPU's speed.<ref name="10.1109/IPDPS.2009.5160922"/> However, unlike clients running on ]s, users were unable to perform other activities on their PS3 while running Folding@home.<ref name="cnn ps3"/> The PS3's uniform console environment made ] easier and made Folding@home more ].<ref name="Press FAQ"/> The PS3 also had the ability to stream data quickly to its GPU, which was used for real-time atomic-level visualizing of the current protein dynamics.<ref name="10.1002/jcc.21054"/> | ||
On November 6, 2012, Sony ended support for the Folding@home PS3 client and other services available under Life with PlayStation. Over its lifetime of five years and seven months, more than 15 |
On November 6, 2012, Sony ended support for the Folding@home PS3 client and other services available under Life with PlayStation. Over its lifetime of five years and seven months, more than 15 million users contributed over 100 million hours of computing to Folding@home, greatly assisting the project with disease research. Following discussions with the Pande lab, Sony decided to terminate the application. Pande considered the PlayStation 3 client a "game changer" for the project.<ref name="PS3 FAQ"/><ref name="PS3 4.30 update, drop F@h"/><ref name="LWP termination"/> | ||
==== Multi-core processing client ==== | ==== Multi-core processing client ==== | ||
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==== Google Chrome ==== | ==== Google Chrome ==== | ||
In 2014, a client for the ] and ] web browsers was released, allowing users to run Folding@home in their web browser. The client used ]'s ] (NaCl) feature on Chromium-based web browsers to run the Folding@home code at near-native speed in a ] on the user's machine.<ref>{{cite web|last1=Pande|first1=Vijay|title=Adding a completely new way to fold, directly in the browser|url=https://foldingathome.org/home/adding-a-completely-new-way-to-fold-directly-in-the-browser/|website=foldingathome.org|publisher=Pande Lab, Stanford University|access-date=February 13, 2015|date=February 24, 2014}}</ref> Due to the phasing out of NaCL and changes at Folding@home, the web client was permanently shut down in June 2019.<ref>{{cite web |title=NaCL Web Client Shutdown Notice |url=http://nacl.foldingathome.org/ |website |
In 2014, a client for the ] and ] web browsers was released, allowing users to run Folding@home in their web browser. The client used ]'s ] (NaCl) feature on Chromium-based web browsers to run the Folding@home code at near-native speed in a ] on the user's machine.<ref>{{cite web|last1=Pande|first1=Vijay|title=Adding a completely new way to fold, directly in the browser|url=https://foldingathome.org/home/adding-a-completely-new-way-to-fold-directly-in-the-browser/|website=foldingathome.org|publisher=Pande Lab, Stanford University|access-date=February 13, 2015|date=February 24, 2014}}</ref> Due to the phasing out of NaCL and changes at Folding@home, the web client was permanently shut down in June 2019.<ref>{{cite web |title=NaCL Web Client Shutdown Notice |url=http://nacl.foldingathome.org/ |website=Folding@Home |access-date=August 29, 2019 |archive-date=April 12, 2019 |archive-url=https://web.archive.org/web/20190412010651/http://nacl.foldingathome.org/ |url-status=dead }}</ref> | ||
==== Android ==== | ==== Android ==== | ||
In July 2015, a client for ] mobile phones was released on ] for devices running ] or newer.<ref>{{cite web |first=Vijay |last=Pande |title=First full version of our Folding@Home client for Android Mobile phones |url=https://foldingathome.org/home/first-full-version-of-our-foldinghome-client-for-android-mobile-phones/ |work=Folding@Home |publisher=foldingathome.org |date=July 7, 2015 |access-date=May 31, 2016}}</ref><ref>{{cite web |title=Folding@Home |url=https://play.google.com/store/apps/details?id=com.sonymobile.androidapp.gridcomputing |work=] |date=2016 |access-date=May 31, 2016}}</ref> | In July 2015, a client for ] mobile phones was released on ] for devices running ] or newer.<ref>{{cite web |first=Vijay |last=Pande |title=First full version of our Folding@Home client for Android Mobile phones |url=https://foldingathome.org/home/first-full-version-of-our-foldinghome-client-for-android-mobile-phones/ |work=Folding@Home |publisher=foldingathome.org |date=July 7, 2015 |access-date=May 31, 2016}}</ref><ref>{{cite web |title=Folding@Home |url=https://play.google.com/store/apps/details?id=com.sonymobile.androidapp.gridcomputing |work=] |date=2016 |access-date=May 31, 2016}}</ref> | ||
On February 16, 2018 the Android client, which was offered in cooperation with ], was removed from Google Play. Plans were announced to offer an open source alternative in the future.<ref>{{Cite web|url=https://foldingathome.org/2018/02/02/android-client-overhaul/|title=Android client overhaul|date=February 2, 2018|website=Folding@home|language=en-US|access-date=July 22, 2019}}</ref> | On February 16, 2018, the Android client, which was offered in cooperation with ], was removed from Google Play. Plans were announced to offer an open source alternative in the future.<ref>{{Cite web|url=https://foldingathome.org/2018/02/02/android-client-overhaul/|title=Android client overhaul|date=February 2, 2018|website=Folding@home|language=en-US|access-date=July 22, 2019}}</ref> | ||
== Comparison to other molecular simulators == | == Comparison to other molecular simulators == | ||
] is a distributed computing project aimed at protein structure prediction and is one of the most accurate ] predictors.<ref name="10.1002/prot.21804"/><ref name="10.1002/prot.22210"/> The conformational states from Rosetta's software can be used to initialize a Markov state model as starting points for Folding@home simulations.<ref name="Simulation FAQ"/> Conversely, structure prediction algorithms can be improved from thermodynamic and kinetic models and the sampling aspects of protein folding simulations.<ref name="10.1371/journal.pone.0005840"/> As Rosetta only tries to predict the final folded state, and not how folding proceeds, Rosetta@home and Folding@home are complementary and address very different molecular questions.<ref name="Simulation FAQ"/><ref name="F@H vs R@h"/> | ] is a distributed computing project aimed at protein structure prediction and is one of the most accurate ] predictors.<ref name="10.1002/prot.21804"/><ref name="10.1002/prot.22210"/> The conformational states from Rosetta's software can be used to initialize a Markov state model as starting points for Folding@home simulations.<ref name="Simulation FAQ"/> Conversely, structure prediction algorithms can be improved from thermodynamic and kinetic models and the sampling aspects of protein folding simulations.<ref name="10.1371/journal.pone.0005840"/> As Rosetta only tries to predict the final folded state, and not how folding proceeds, Rosetta@home and Folding@home are complementary and address very different molecular questions.<ref name="Simulation FAQ"/><ref name="F@H vs R@h"/> | ||
] is a special-purpose supercomputer built for molecular dynamics simulations. In October 2011, Anton and Folding@home were the two most powerful molecular dynamics systems.<ref name="typepad: comparison with Anton"/> Anton is unique in its ability to produce single ultra-long computationally costly molecular trajectories,<ref name="10.1021/ja207470h"/> such as one in 2010 which reached the millisecond range.<ref name="10.1145/1654059.1654099"/><ref name="10.1126/science.1187409"/> These long trajectories may be especially helpful for some types of biochemical problems.<ref name="10.1145/1364782.1364802"/><ref name="10.1146/annurev-biophys-042910-155245"/> However, Anton does not use Markov state models (MSM) for analysis. In 2011, the Pande lab constructed a MSM from two 100-] Anton simulations and found alternative folding pathways that were not visible through Anton's traditional analysis. They concluded that there was little difference between MSMs constructed from a limited number of long trajectories or one assembled from many shorter trajectories.<ref name="10.1021/ja207470h"/> In June 2011 Folding@home added sampling of an Anton simulation in an effort to better determine how its methods compare to Anton's.<ref name="forum: 7610/7611 in beta"/><ref name="description: 7610"/> However, unlike Folding@home's shorter trajectories, which are more amenable to distributed computing and other parallelizing methods, longer trajectories do not require adaptive sampling to sufficiently sample the protein's ]. Due to this, it is possible that a combination of Anton's and Folding@home's simulation methods would provide a more thorough sampling of this space.<ref name="10.1021/ja207470h"/> | ] is a special-purpose supercomputer built for molecular dynamics simulations. In October 2011, Anton and Folding@home were the two most powerful molecular dynamics systems.<ref name="typepad: comparison with Anton"/> Anton is unique in its ability to produce single ultra-long computationally costly molecular trajectories,<ref name="10.1021/ja207470h"/> such as one in 2010 which reached the millisecond range.<ref name="10.1145/1654059.1654099"/><ref name="10.1126/science.1187409"/> These long trajectories may be especially helpful for some types of biochemical problems.<ref name="10.1145/1364782.1364802"/><ref name="10.1146/annurev-biophys-042910-155245"/> However, Anton does not use Markov state models (MSM) for analysis. In 2011, the Pande lab constructed a MSM from two 100-] Anton simulations and found alternative folding pathways that were not visible through Anton's traditional analysis. They concluded that there was little difference between MSMs constructed from a limited number of long trajectories or one assembled from many shorter trajectories.<ref name="10.1021/ja207470h"/> In June 2011 Folding@home added sampling of an Anton simulation in an effort to better determine how its methods compare to Anton's.<ref name="forum: 7610/7611 in beta"/><ref name="description: 7610"/> However, unlike Folding@home's shorter trajectories, which are more amenable to distributed computing and other parallelizing methods, longer trajectories do not require adaptive sampling to sufficiently sample the protein's ]. Due to this, it is possible that a combination of Anton's and Folding@home's simulation methods would provide a more thorough sampling of this space.<ref name="10.1021/ja207470h"/> | ||
== See also == | == See also == | ||
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{{Div col|colwidth=25em}} | {{Div col|colwidth=25em}} | ||
* ] | * ] | ||
* ], for |
* ], for use on smartphones | ||
* ] | * ] | ||
* ] | * ] | ||
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<!-- *** Publications (sorted by date) *** --> | <!-- *** Publications (sorted by date) *** --> | ||
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<ref name="10.1126/science.290.5498.1903">{{cite journal |author1=M. R. Shirts |author2=V. S. Pande. |s2cid=2854586 |title= Screen Savers of the World, Unite! |journal= Science |year= 2000 |volume= 290 |issue= 5498 |pages= 1903–1904 |doi= 10.1126/science.290.5498.1903 |pmid= 17742054}}</ref> | <ref name="10.1126/science.290.5498.1903">{{cite journal |author1=M. R. Shirts |author2=V. S. Pande. |s2cid=2854586 |title= Screen Savers of the World, Unite! |journal= Science |year= 2000 |volume= 290 |issue= 5498 |pages= 1903–1904 |doi= 10.1126/science.290.5498.1903 |pmid= 17742054}}</ref> | ||
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<ref name="10.1146/annurev.biophys.34.040204.144447">{{cite journal |author1=C. D. Snow |author2=E. J. Sorin |author3=Y. M. Rhee |author4=V. S. Pande. |title= How well can simulation predict protein folding kinetics and thermodynamics? |type= review |journal= Annual Review of Biophysics |year= 2005 |volume= 34 |pages= 43–69 |doi= 10.1146/annurev.biophys.34.040204.144447 |pmid= 15869383}}</ref> | <ref name="10.1146/annurev.biophys.34.040204.144447">{{cite journal |author1=C. D. Snow |author2=E. J. Sorin |author3=Y. M. Rhee |author4=V. S. Pande. |title= How well can simulation predict protein folding kinetics and thermodynamics? |type= review |journal= Annual Review of Biophysics |year= 2005 |volume= 34 |pages= 43–69 |doi= 10.1146/annurev.biophys.34.040204.144447 |pmid= 15869383}}</ref> | ||
<ref name="10.1126/science.309.5731.78b">{{cite journal |title= So Much More to Know |journal= Science |year= 2005 |volume= 309 |issue= 5731 |pages= 78–102 |doi= 10.1126/science.309.5731.78b |pmid= 15994524| |
<ref name="10.1126/science.309.5731.78b">{{cite journal |title= So Much More to Know |journal= Science |year= 2005 |volume= 309 |issue= 5731 |pages= 78–102 |doi= 10.1126/science.309.5731.78b |pmid= 15994524 |s2cid= 33234834}}</ref> | ||
<ref name="10.1063/1.2221680">{{cite journal |author1=Guha Jayachandran |author2=M. R. Shirts |author3=S. Park |author4=V. S. Pande |title= Parallelized-Over-Parts Computation of Absolute Binding Free Energy with Docking and Molecular Dynamics |journal= Journal of Chemical Physics |year= 2006 |volume= 125 |issue= 8 |page= 084901 |doi= 10.1063/1.2221680 |pmid= 16965051 |bibcode= 2006JChPh.125h4901J}}</ref> | <ref name="10.1063/1.2221680">{{cite journal |author1=Guha Jayachandran |author2=M. R. Shirts |author3=S. Park |author4=V. S. Pande |title= Parallelized-Over-Parts Computation of Absolute Binding Free Energy with Docking and Molecular Dynamics |journal= Journal of Chemical Physics |year= 2006 |volume= 125 |issue= 8 |page= 084901 |doi= 10.1063/1.2221680 |pmid= 16965051 |bibcode= 2006JChPh.125h4901J}}</ref> | ||
<ref name="10.1137/06065146X">{{cite journal|last=Chodera|first=John D.|author2=Swope, William C. |author3=Pitera, Jed W. |author4= Dill, Ken A. |title= |
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<ref name="10.1002/prot.21804">{{cite journal |vauthors=Lensink MF, Méndez R, Wodak SJ |title= Docking and scoring protein complexes: CAPRI 3rd Edition |journal= Proteins |volume= 69 |issue= 4 |pages= 704–18 |date=December 2007 |pmid= 17918726 |doi= 10.1002/prot.21804|s2cid= 25383642 }}</ref> | <ref name="10.1002/prot.21804">{{cite journal |vauthors=Lensink MF, Méndez R, Wodak SJ |title= Docking and scoring protein complexes: CAPRI 3rd Edition |journal= Proteins |volume= 69 |issue= 4 |pages= 704–18 |date=December 2007 |pmid= 17918726 |doi= 10.1002/prot.21804|s2cid= 25383642 }}</ref> | ||
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<ref name="10.1016/j.abb.2007.05.014">{{cite journal |author1=Yiwen Chen |author2=Feng Ding |author3=Huifen Nie |author4=Adrian W. Serohijos |author5=Shantanu Sharma |author6=Kyle C. Wilcox |author7=Shuangye Yin |author8=Nikolay V. Dokholyan |title= Protein folding: Then and now |journal= Archives of Biochemistry and Biophysics |year= 2008 |volume= 469 |issue= 1 |pages= 4–19 |doi= 10.1016/j.abb.2007.05.014 |pmc= 2173875 |pmid= 17585870}}</ref> | <ref name="10.1016/j.abb.2007.05.014">{{cite journal |author1=Yiwen Chen |author2=Feng Ding |author3=Huifen Nie |author4=Adrian W. Serohijos |author5=Shantanu Sharma |author6=Kyle C. Wilcox |author7=Shuangye Yin |author8=Nikolay V. Dokholyan |title= Protein folding: Then and now |journal= Archives of Biochemistry and Biophysics |year= 2008 |volume= 469 |issue= 1 |pages= 4–19 |doi= 10.1016/j.abb.2007.05.014 |pmc= 2173875 |pmid= 17585870}}</ref> | ||
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<ref name="10.1002/iub.117">{{cite journal |author1=Heath Ecroyd |author2=John A. Carver |title= Unraveling the mysteries of protein folding and misfolding |type= review |journal= IUBMB Life |year= 2008 |volume= 60 |issue= 12 |pages= 769–774 |doi= 10.1002/iub.117 |pmid =18767168|s2cid=10115925 |url= https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1968&context=scipapers |doi-access= free }}</ref> | <ref name="10.1002/iub.117">{{cite journal |author1=Heath Ecroyd |author2=John A. Carver |title= Unraveling the mysteries of protein folding and misfolding |type= review |journal= IUBMB Life |year= 2008 |volume= 60 |issue= 12 |pages= 769–774 |doi= 10.1002/iub.117 |pmid =18767168|s2cid=10115925 |url= https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1968&context=scipapers |doi-access= free }}</ref> | ||
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<ref name="10.1073/pnas.0801795105">{{cite journal |author1=Paula M. Petrone |author2=Christopher D. Snow |author3=Del Lucent |author4=Vijay S. Pande |title= Side-chain recognition and gating in the ribosome exit tunnel |journal= Proceedings of the National Academy of Sciences |year= 2008 |volume= 105 |issue= 43 |pages=16549–54 |doi= 10.1073/pnas.0801795105 |bibcode= 2008PNAS..10516549P |pmid=18946046 |pmc=2575457|doi-access=free }}</ref> | <ref name="10.1073/pnas.0801795105">{{cite journal |author1=Paula M. Petrone |author2=Christopher D. Snow |author3=Del Lucent |author4=Vijay S. Pande |title= Side-chain recognition and gating in the ribosome exit tunnel |journal= Proceedings of the National Academy of Sciences |year= 2008 |volume= 105 |issue= 43 |pages=16549–54 |doi= 10.1073/pnas.0801795105 |bibcode= 2008PNAS..10516549P |pmid=18946046 |pmc=2575457|doi-access=free }}</ref> | ||
<ref name="10.1002/jcc.21054">{{cite journal |author1=Edgar Luttmann |author2=Daniel L. Ensign |author3=Vishal Vaidyanathan |author4=Mike Houston |author5=Noam Rimon |author6=Jeppe Øland |author7=Guha Jayachandran |author8=Mark Friedrichs |author9=Vijay S. Pande |title= Accelerating Molecular Dynamic Simulation on the Cell processor and PlayStation 3 |journal= Journal of Computational Chemistry |year= 2008 |volume= 30 |issue= 2 |pages= 268–274 |doi= 10.1002/jcc.21054 |pmid= 18615421|s2cid=33047431 }}</ref> | <ref name="10.1002/jcc.21054">{{cite journal |author1=Edgar Luttmann |author2=Daniel L. Ensign |author3=Vishal Vaidyanathan |author4=Mike Houston |author5=Noam Rimon |author6=Jeppe Øland |author7=Guha Jayachandran |author8=Mark Friedrichs |author9=Vijay S. Pande |title= Accelerating Molecular Dynamic Simulation on the Cell processor and PlayStation 3 |journal= Journal of Computational Chemistry |year= 2008 |volume= 30 |issue= 2 |pages= 268–274 |doi= 10.1002/jcc.21054 |pmid= 18615421|s2cid=33047431 |doi-access=free }}</ref> | ||
<ref name="10.1016/j.cbpa.2008.02.011">{{cite journal |author1=Leila M Luheshi |author2=Damian Crowther |author3=Christopher Dobson |title= Protein misfolding and disease: from the test tube to the organism |journal= Current Opinion in Chemical Biology |year= 2008 |volume= 12 |issue= 1 |pages= 25–31 |doi= 10.1016/j.cbpa.2008.02.011 |pmid= 18295611}}</ref> | <ref name="10.1016/j.cbpa.2008.02.011">{{cite journal |author1=Leila M Luheshi |author2=Damian Crowther |author3=Christopher Dobson |title= Protein misfolding and disease: from the test tube to the organism |journal= Current Opinion in Chemical Biology |year= 2008 |volume= 12 |issue= 1 |pages= 25–31 |doi= 10.1016/j.cbpa.2008.02.011 |pmid= 18295611}}</ref> | ||
<ref name="10.1001/archneurol.2007.56">{{cite journal |author1=Claudio Soto |author2=Lisbell D. Estrada |title= Protein Misfolding and Neurodegeneration |type= review |journal= Archives of Neurology |year= 2008 |volume= 65 |issue= 2 |pages= 184–189 |doi= 10.1001/archneurol.2007.56 |pmid= 18268186|doi-access= |
<ref name="10.1001/archneurol.2007.56">{{cite journal |author1=Claudio Soto |author2=Lisbell D. Estrada |title= Protein Misfolding and Neurodegeneration |type= review |journal= Archives of Neurology |year= 2008 |volume= 65 |issue= 2 |pages= 184–189 |doi= 10.1001/archneurol.2007.56 |pmid= 18268186|doi-access= }}</ref> | ||
<ref name="10.1074/jbc.R800036200">{{cite journal |author1=Robin Roychaudhuri |author2=Mingfeng Yang |author3=Minako M. Hoshi |author4=David B. Teplow |title= Amyloid β-Protein Assembly and Alzheimer Disease |journal= Journal of Biological Chemistry |year= 2008 |volume= 284 |issue= 8 |pages= 4749–53 |doi= 10.1074/jbc.R800036200 |pmid= 18845536|pmc=3837440 |doi-access=free }}</ref> | <ref name="10.1074/jbc.R800036200">{{cite journal |author1=Robin Roychaudhuri |author2=Mingfeng Yang |author3=Minako M. Hoshi |author4=David B. Teplow |title= Amyloid β-Protein Assembly and Alzheimer Disease |journal= Journal of Biological Chemistry |year= 2008 |volume= 284 |issue= 8 |pages= 4749–53 |doi= 10.1074/jbc.R800036200 |pmid= 18845536|pmc=3837440 |doi-access=free }}</ref> | ||
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<ref name="10.1016/j.bpj.2009.04.059">{{cite journal |vauthors=Gautieri A, Uzel S, Vesentini S, Redaelli A, Buehler MJ |title= Molecular and mesoscale disease mechanisms of Osteogenesis Imperfecta |journal= Biophysical Journal |year= 2009 |pages= 857–865 |volume= 97 |issue= 3 |pmid= 19651044 |doi= 10.1016/j.bpj.2009.04.059 |pmc= 2718154 |bibcode= 2009BpJ....97..857G}}</ref> | <ref name="10.1016/j.bpj.2009.04.059">{{cite journal |vauthors=Gautieri A, Uzel S, Vesentini S, Redaelli A, Buehler MJ |title= Molecular and mesoscale disease mechanisms of Osteogenesis Imperfecta |journal= Biophysical Journal |year= 2009 |pages= 857–865 |volume= 97 |issue= 3 |pmid= 19651044 |doi= 10.1016/j.bpj.2009.04.059 |pmc= 2718154 |bibcode= 2009BpJ....97..857G}}</ref> | ||
<ref name="10.1021/ja904557w">{{cite journal |author1=Peter M. Kasson |author2=Daniel L. Ensign |author3=Vijay S. Pande |title= Combining Molecular Dynamics with Bayesian Analysis To Predict and Evaluate Ligand-Binding Mutations in Influenza Hemagglutinin |journal= Journal of the American Chemical Society |year= 2009 |volume= 131 |issue= 32 |pages= 11338–11340 |doi= 10.1021/ja904557w |pmid= 19637916 |pmc= 2737089}}</ref> | <ref name="10.1021/ja904557w">{{cite journal |author1=Peter M. Kasson |author2=Daniel L. Ensign |author3=Vijay S. Pande |title= Combining Molecular Dynamics with Bayesian Analysis To Predict and Evaluate Ligand-Binding Mutations in Influenza Hemagglutinin |journal= Journal of the American Chemical Society |year= 2009 |volume= 131 |issue= 32 |pages= 11338–11340 |doi= 10.1021/ja904557w |pmid= 19637916 |pmc= 2737089|bibcode=2009JAChS.13111338K }}</ref> | ||
<ref name="19209725, 2811693">{{cite journal |author1=Peter M. Kasson |author2=Vijay S. Pande |title= Combining mutual information with structural analysis to screen for functionally important residues in influenza hemagglutinin |journal= Pacific Symposium on Biocomputing |year= 2009 |pages= 492–503 |pmid= 19209725 |pmc= 2811693|doi=10.1142/9789812836939_0047 |isbn=978-981-283-692-2 }}</ref> | <ref name="19209725, 2811693">{{cite journal |author1=Peter M. Kasson |author2=Vijay S. Pande |title= Combining mutual information with structural analysis to screen for functionally important residues in influenza hemagglutinin |journal= Pacific Symposium on Biocomputing |year= 2009 |pages= 492–503 |pmid= 19209725 |pmc= 2811693|doi=10.1142/9789812836939_0047 |isbn=978-981-283-692-2 }}</ref> | ||
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<ref name="10.1371/journal.pone.0005840">{{cite journal |author= G. R. Bowman and V. S. Pande |title= The Roles of Entropy and Kinetics in Structure Prediction |journal= PLOS ONE |year= 2009 |volume= 4 |issue= 6 |pages= e5840 |doi= 10.1371/journal.pone.0005840 |pmid= 19513117 |pmc= 2688754 |bibcode= 2009PLoSO...4.5840B |editor1-last= Hofmann |editor1-first= Andreas|doi-access= free }}</ref> | <ref name="10.1371/journal.pone.0005840">{{cite journal |author= G. R. Bowman and V. S. Pande |title= The Roles of Entropy and Kinetics in Structure Prediction |journal= PLOS ONE |year= 2009 |volume= 4 |issue= 6 |pages= e5840 |doi= 10.1371/journal.pone.0005840 |pmid= 19513117 |pmc= 2688754 |bibcode= 2009PLoSO...4.5840B |editor1-last= Hofmann |editor1-first= Andreas|doi-access= free }}</ref> | ||
<ref name="10.1145/1654059.1654099">{{cite book |author= David E. Shaw |title |
<ref name="10.1145/1654059.1654099">{{cite book |author= David E. Shaw |title= Proceedings of the Conference on High Performance Computing Networking, Storage and Analysis - SC '09 |year= 2009 |issue= 39 |pages= 1–11 |doi= 10.1145/1654059.1654099 |isbn= 978-1-60558-744-8 |display-authors= 1 |last2= Bowers |first2= Kevin J. |last3= Chow |first3= Edmond |last4= Eastwood |first4= Michael P. |last5= Ierardi |first5= Douglas J. |last6= Klepeis |first6= John L. |last7= Kuskin |first7= Jeffrey S. |last8= Larson |first8= Richard H. |last9= Lindorff-Larsen |first9= Kresten|chapter= Millisecond-scale molecular dynamics simulations on Anton |s2cid= 53234452 }}</ref> | ||
<ref name="10.1093/bib/bbp023">{{cite journal |author1=Chun Song |author2=Shen Lim |author3=Joo Tong |title= Recent advances in computer-aided drug design |type= review |journal= Briefings in Bioinformatics |year= 2009 |volume= 10 |issue= 5 |pages= 579–91 |doi= 10.1093/bib/bbp023 |pmid= 19433475|doi-access= free }}</ref> | <ref name="10.1093/bib/bbp023">{{cite journal |author1=Chun Song |author2=Shen Lim |author3=Joo Tong |title= Recent advances in computer-aided drug design |type= review |journal= Briefings in Bioinformatics |year= 2009 |volume= 10 |issue= 5 |pages= 579–91 |doi= 10.1093/bib/bbp023 |pmid= 19433475|doi-access= free }}</ref> | ||
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<ref name="10.1002/jcc.21209">{{cite journal |author1=M. S. Friedrichs |author2=P. Eastman |author3=V. Vaidyanathan |author4=M. Houston |author5=S. LeGrand |author6=A. L. Beberg |author7=D. L. Ensign |author8=C. M. Bruns |author9=V. S. Pande |title= Accelerating Molecular Dynamic Simulation on Graphics Processing Units |journal= Journal of Computational Chemistry |year= 2009 |volume= 30 |issue= 6 |pages= 864–72 |doi= 10.1002/jcc.21209 |pmid= 19191337 |pmc= 2724265}}</ref> | <ref name="10.1002/jcc.21209">{{cite journal |author1=M. S. Friedrichs |author2=P. Eastman |author3=V. Vaidyanathan |author4=M. Houston |author5=S. LeGrand |author6=A. L. Beberg |author7=D. L. Ensign |author8=C. M. Bruns |author9=V. S. Pande |title= Accelerating Molecular Dynamic Simulation on Graphics Processing Units |journal= Journal of Computational Chemistry |year= 2009 |volume= 30 |issue= 6 |pages= 864–72 |doi= 10.1002/jcc.21209 |pmid= 19191337 |pmc= 2724265}}</ref> | ||
<ref name="10.1109/IPDPS.2009.5160922">{{cite book |author1=Adam Beberg |author2=Daniel Ensign |author3=Guha Jayachandran |author4=Siraj Khaliq |author5=Vijay Pande |chapter= Folding@home: Lessons from eight years of volunteer distributed computing|title= 2009 IEEE International Symposium on Parallel & Distributed Processing |
<ref name="10.1109/IPDPS.2009.5160922">{{cite book |author1=Adam Beberg |author2=Daniel Ensign |author3=Guha Jayachandran |author4=Siraj Khaliq |author5=Vijay Pande |chapter= Folding@home: Lessons from eight years of volunteer distributed computing|title= 2009 IEEE International Symposium on Parallel & Distributed Processing|year= 2009 |pages= 1–8 |doi= 10.1109/IPDPS.2009.5160922 |issn= 1530-2075 |chapter-url= http://www.hicomb.org/papers/HICOMB2009-13.pdf |isbn= 978-1-4244-3751-1|s2cid=15677970 }}</ref> | ||
<ref name="10.1371/journal.pcbi.1000452">{{cite journal |author= Fabrizio Marinelli, Fabio Pietrucci, Alessandro Laio, Stefano Piana |title= A Kinetic Model of Trp-Cage Folding from Multiple Biased Molecular Dynamics Simulations |journal= PLOS Computational Biology |year= 2009 |volume= 5 |issue= 8 |pages= e1000452 |doi= 10.1371/journal.pcbi.1000452 |editor1-first= Vijay S. |editor1-last= Pande|bibcode= 2009PLSCB...5E0452M |pmid=19662155 |pmc=2711228}}</ref> | <ref name="10.1371/journal.pcbi.1000452">{{cite journal |author= Fabrizio Marinelli, Fabio Pietrucci, Alessandro Laio, Stefano Piana |title= A Kinetic Model of Trp-Cage Folding from Multiple Biased Molecular Dynamics Simulations |journal= PLOS Computational Biology |year= 2009 |volume= 5 |issue= 8 |pages= e1000452 |doi= 10.1371/journal.pcbi.1000452 |editor1-first= Vijay S. |editor1-last= Pande|bibcode= 2009PLSCB...5E0452M |pmid=19662155 |pmc=2711228 |doi-access= free }}</ref> | ||
<ref name="Protein Misfolding Diseases">{{cite journal|author1=Vittorio Bellotti |author2=Monica Stoppini |title=Protein Misfolding Diseases |journal=The Open Biology Journal |year=2009 |volume=2 |issue=2 |pages=228–234 |url=http://www.benthamscience.com/open/tobioj/articles/V002/SI0161TOBIOJ/228TOBIOJ.pdf |doi=10.2174/1874196700902020228 |url-status=bot: unknown |archive-url=https://web.archive.org/web/20140222042205/http://www.benthamscience.com/open/tobioj/articles/V002/SI0161TOBIOJ/228TOBIOJ.pdf |archive-date=February 22, 2014 }}</ref> | <ref name="Protein Misfolding Diseases">{{cite journal|author1=Vittorio Bellotti |author2=Monica Stoppini |title=Protein Misfolding Diseases |journal=The Open Biology Journal |year=2009 |volume=2 |issue=2 |pages=228–234 |url=http://www.benthamscience.com/open/tobioj/articles/V002/SI0161TOBIOJ/228TOBIOJ.pdf |doi=10.2174/1874196700902020228 |doi-broken-date=November 1, 2024 |url-status=bot: unknown |archive-url=https://web.archive.org/web/20140222042205/http://www.benthamscience.com/open/tobioj/articles/V002/SI0161TOBIOJ/228TOBIOJ.pdf |archive-date=February 22, 2014 }}</ref> | ||
<ref name="10.1016/j.jmb.2009.01.032">{{cite journal |author1=Nicholas W. Kelley |author2=Xuhui Huang |author3=Stephen Tam |author4=Christoph Spiess |author5=Judith Frydman |author6=Vijay S. Pande |title= The predicted structure of the headpiece of the Huntingtin protein and its implications on Huntingtin aggregation |journal= Journal of Molecular Biology |year= 2009 |volume= 388 |issue= 5 |pages= 919–27 |doi= 10.1016/j.jmb.2009.01.032 |pmid= 19361448 |pmc= 2677131}}</ref> | <ref name="10.1016/j.jmb.2009.01.032">{{cite journal |author1=Nicholas W. Kelley |author2=Xuhui Huang |author3=Stephen Tam |author4=Christoph Spiess |author5=Judith Frydman |author6=Vijay S. Pande |title= The predicted structure of the headpiece of the Huntingtin protein and its implications on Huntingtin aggregation |journal= Journal of Molecular Biology |year= 2009 |volume= 388 |issue= 5 |pages= 919–27 |doi= 10.1016/j.jmb.2009.01.032 |pmid= 19361448 |pmc= 2677131}}</ref> | ||
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<ref name="10.1073/pnas.1003962107">{{cite journal |author1=Gregory R. Bowman |author2=Vijay S. Pande |title= Protein folded states are kinetic hubs |journal= Proceedings of the National Academy of Sciences |year= 2010 |volume= 107 |issue= 24 |pages=10890–5 |doi= 10.1073/pnas.1003962107 |bibcode= 2010PNAS..10710890B |pmid=20534497 |pmc=2890711|doi-access=free }}</ref> | <ref name="10.1073/pnas.1003962107">{{cite journal |author1=Gregory R. Bowman |author2=Vijay S. Pande |title= Protein folded states are kinetic hubs |journal= Proceedings of the National Academy of Sciences |year= 2010 |volume= 107 |issue= 24 |pages=10890–5 |doi= 10.1073/pnas.1003962107 |bibcode= 2010PNAS..10710890B |pmid=20534497 |pmc=2890711|doi-access=free }}</ref> | ||
<ref name="10.1021/ja908369h">{{cite journal |author1=Vincent A. Voelz |author2=Vijay R. Singh |author3=William J. Wedemeyer |author4=Lisa J. Lapidus |author5=Vijay S. Pande |title= Unfolded-State Dynamics and Structure of Protein L Characterized by Simulation and Experiment |journal= Journal of the American Chemical Society |year= 2010 |volume= 132 |issue= 13 |pages= 4702–4709 |doi= 10.1021/ja908369h |pmid= 20218718 |pmc= 2853762}}</ref> | <ref name="10.1021/ja908369h">{{cite journal |author1=Vincent A. Voelz |author2=Vijay R. Singh |author3=William J. Wedemeyer |author4=Lisa J. Lapidus |author5=Vijay S. Pande |title= Unfolded-State Dynamics and Structure of Protein L Characterized by Simulation and Experiment |journal= Journal of the American Chemical Society |year= 2010 |volume= 132 |issue= 13 |pages= 4702–4709 |doi= 10.1021/ja908369h |pmid= 20218718 |pmc= 2853762|bibcode=2010JAChS.132.4702V }}</ref> | ||
<ref name="10.1109/CCGRID.2010.84">{{cite book |author1=I. Haque |author2=V. S. Pande |chapter= Hard Data on Soft Errors: A Large-Scale Assessment of Real-World Error Rates in GPGPU|title= 2010 10th IEEE/ACM International Conference on Cluster, Cloud and Grid Computing|year= 2010 |pages= 691–696 |doi= 10.1109/CCGRID.2010.84 |isbn= 978-1-4244-6987-1|arxiv= 0910.0505 |s2cid=10723933 }}</ref> | <ref name="10.1109/CCGRID.2010.84">{{cite book |author1=I. Haque |author2=V. S. Pande |chapter= Hard Data on Soft Errors: A Large-Scale Assessment of Real-World Error Rates in GPGPU|title= 2010 10th IEEE/ACM International Conference on Cluster, Cloud and Grid Computing|year= 2010 |pages= 691–696 |doi= 10.1109/CCGRID.2010.84 |isbn= 978-1-4244-6987-1|arxiv= 0910.0505 |s2cid=10723933 }}</ref> | ||
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<ref name="10.1073/pnas.1010880108">{{cite journal |author1=Kyle A. Beauchamp |author2=Daniel L. Ensign |author3=Rhiju Das |author4=Vijay S. Pande |title= Quantitative comparison of villin headpiece subdomain simulations and triplet–triplet energy transfer experiments |journal= Proceedings of the National Academy of Sciences |year= 2011 |volume= 108 |issue= 31 |pages=12734–9 |doi= 10.1073/pnas.1010880108 |bibcode= 2011PNAS..10812734B |pmid=21768345 |pmc=3150881|doi-access=free }}</ref> | <ref name="10.1073/pnas.1010880108">{{cite journal |author1=Kyle A. Beauchamp |author2=Daniel L. Ensign |author3=Rhiju Das |author4=Vijay S. Pande |title= Quantitative comparison of villin headpiece subdomain simulations and triplet–triplet energy transfer experiments |journal= Proceedings of the National Academy of Sciences |year= 2011 |volume= 108 |issue= 31 |pages=12734–9 |doi= 10.1073/pnas.1010880108 |bibcode= 2011PNAS..10812734B |pmid=21768345 |pmc=3150881|doi-access=free }}</ref> | ||
<ref name="Pronk et al, 2011">{{ |
<ref name="Pronk et al, 2011">{{Cite book |last1=Pronk |first1=Sander |last2=Larsson |first2=Per |last3=Pouya |first3=Iman |last4=Bowman |first4=Gregory R. |last5=Haque |first5=Imran S. |last6=Beauchamp |first6=Kyle |last7=Hess |first7=Berk |last8=Pande |first8=Vijay S. |last9=Kasson |first9=Peter M. |last10=Lindahl |first10=Erik |chapter=Copernicus: A new paradigm for parallel adaptive molecular dynamics |date=2011-11-12 |year=2011 |title=Proceedings of 2011 International Conference for High Performance Computing, Networking, Storage and Analysis |chapter-url=https://dl.acm.org/doi/10.1145/2063384.2063465 |language=en |publisher=ACM |pages=1–10 |doi=10.1145/2063384.2063465 |isbn=978-1-4503-0771-0}}</ref> | ||
<ref name="10.1039/c0cs00115e">{{cite journal |author1=Hana Robson Marsden |author2=Itsuro Tomatsu |author3=Alexander Kros |title= Model systems for membrane fusion |type= review |journal= Chemical Society Reviews |year= 2011 |volume= 40 |issue= 3 |pages= 1572–1585 |doi= 10.1039/c0cs00115e |pmid= 21152599}}</ref> | <ref name="10.1039/c0cs00115e">{{cite journal |author1=Hana Robson Marsden |author2=Itsuro Tomatsu |author3=Alexander Kros |title= Model systems for membrane fusion |type= review |journal= Chemical Society Reviews |year= 2011 |volume= 40 |issue= 3 |pages= 1572–1585 |doi= 10.1039/c0cs00115e |pmid= 21152599}}</ref> | ||
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<ref name="10.1371/journal.pone.0021776">{{cite journal |author= P. Novick, J. Rajadas, C.W. Liu, N. W. Kelley, M. Inayathullah, and V. S. Pande |title= Rationally Designed Turn Promoting Mutation in the Amyloid-β Peptide Sequence Stabilizes Oligomers in Solution |journal= PLOS ONE |year= 2011 |volume= 6 |issue= 7 |pages= e21776 |doi= 10.1371/journal.pone.0021776 |pmc= 3142112 |pmid= 21799748 |editor1-last= Buehler |editor1-first= Markus J.|bibcode= 2011PLoSO...621776R|doi-access= free }}</ref> | <ref name="10.1371/journal.pone.0021776">{{cite journal |author= P. Novick, J. Rajadas, C.W. Liu, N. W. Kelley, M. Inayathullah, and V. S. Pande |title= Rationally Designed Turn Promoting Mutation in the Amyloid-β Peptide Sequence Stabilizes Oligomers in Solution |journal= PLOS ONE |year= 2011 |volume= 6 |issue= 7 |pages= e21776 |doi= 10.1371/journal.pone.0021776 |pmc= 3142112 |pmid= 21799748 |editor1-last= Buehler |editor1-first= Markus J.|bibcode= 2011PLoSO...621776R|doi-access= free }}</ref> | ||
<ref name="10.1021/ja207470h">{{cite journal |author1=Thomas J. Lane |author2=Gregory R. Bowman |author3=Kyle A Beauchamp |author4=Vincent Alvin Voelz |author5=Vijay S. Pande |title= Markov State Model Reveals Folding and Functional Dynamics in Ultra-Long MD Trajectories |journal= Journal of the American Chemical Society |year= 2011 |volume= 133 |issue= 45 |pages= 18413–9 |doi= 10.1021/ja207470h |pmid= 21988563 |pmc= 3227799}}</ref> | <ref name="10.1021/ja207470h">{{cite journal |author1=Thomas J. Lane |author2=Gregory R. Bowman |author3=Kyle A Beauchamp |author4=Vincent Alvin Voelz |author5=Vijay S. Pande |title= Markov State Model Reveals Folding and Functional Dynamics in Ultra-Long MD Trajectories |journal= Journal of the American Chemical Society |year= 2011 |volume= 133 |issue= 45 |pages= 18413–9 |doi= 10.1021/ja207470h |pmid= 21988563 |pmc= 3227799|bibcode=2011JAChS.13318413L }}</ref> | ||
<ref name="10.1039/C1CP22100K">{{cite journal |author1=Phineus R. L. Markwick |author2=J. Andrew McCammon |title= Studying functional dynamics in bio-molecules using accelerated molecular dynamics |journal= Physical Chemistry Chemical Physics |year= 2011 |volume= 13 |issue= 45 |pages= 20053–65 |doi= 10.1039/C1CP22100K |pmid= 22015376 |bibcode= 2011PCCP...1320053M}}</ref> | <ref name="10.1039/C1CP22100K">{{cite journal |author1=Phineus R. L. Markwick |author2=J. Andrew McCammon |title= Studying functional dynamics in bio-molecules using accelerated molecular dynamics |journal= Physical Chemistry Chemical Physics |year= 2011 |volume= 13 |issue= 45 |pages= 20053–65 |doi= 10.1039/C1CP22100K |pmid= 22015376 |bibcode= 2011PCCP...1320053M}}</ref> | ||
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<ref name="10.1146/annurev-biophys-042910-155245">{{cite journal |title= Biomolecular Simulation: A Computational Microscope for Molecular Biology |author1=Ron O. Dror |author2=Robert M. Dirks |author3=J.P. Grossman |author4=Huafeng Xu |author5=David E. Shaw |journal= ] |year= 2012 |volume= 41 |pages= 429–52 |doi= 10.1146/annurev-biophys-042910-155245 |pmid=22577825 }}</ref> | <ref name="10.1146/annurev-biophys-042910-155245">{{cite journal |title= Biomolecular Simulation: A Computational Microscope for Molecular Biology |author1=Ron O. Dror |author2=Robert M. Dirks |author3=J.P. Grossman |author4=Huafeng Xu |author5=David E. Shaw |journal= ] |year= 2012 |volume= 41 |pages= 429–52 |doi= 10.1146/annurev-biophys-042910-155245 |pmid=22577825 }}</ref> | ||
<ref name="10.1016/j.cub.2012.01.008">{{cite journal |author= Michael Gross |title= Folding research recruits unconventional help |journal= Current Biology |year= 2012 |volume= 22 |issue= 2 |pages= R35–R38 |doi= 10.1016/j.cub.2012.01.008 |pmid= 22389910|doi-access= free }}</ref> | <ref name="10.1016/j.cub.2012.01.008">{{cite journal |author= Michael Gross |title= Folding research recruits unconventional help |journal= Current Biology |year= 2012 |volume= 22 |issue= 2 |pages= R35–R38 |doi= 10.1016/j.cub.2012.01.008 |pmid= 22389910|doi-access= free |bibcode= 2012CBio...22..R35G }}</ref> | ||
<!-- *** foldingathome.org pages *** --> | <!-- *** foldingathome.org pages *** --> | ||
<ref name="About Partners">{{cite web |url=https://foldingathome.org/about/partners/ |title=About Folding@home Partners |author=foldingathome.org|date=September 27, 2016 }}</ref> | <ref name="About Partners">{{cite web |url=https://foldingathome.org/about/partners/ |title=About Folding@home Partners |author=foldingathome.org |date=September 27, 2016 |access-date=September 2, 2019 |archive-date=April 23, 2020 |archive-url=https://web.archive.org/web/20200423092734/https://foldingathome.org/about/partners/ |url-status=dead }}</ref> | ||
<ref name="papers">{{cite web|url=https://foldingathome.org/papers-results/ |title=Papers & Results from Folding@home |author=Pande lab |work=Folding@home |publisher=foldingathome.org |date=July 27, 2012 |access-date= February 1, 2019 |archive-url=https://web.archive.org/web/20120717062813/http://folding.stanford.edu/English/Papers |archive-date=July 17, 2012 |url-status=live }}</ref> | <ref name="papers">{{cite web|url=https://foldingathome.org/papers-results/ |title=Papers & Results from Folding@home |author=Pande lab |work=Folding@home |publisher=foldingathome.org |date=July 27, 2012 |access-date= February 1, 2019 |archive-url=https://web.archive.org/web/20120717062813/http://folding.stanford.edu/English/Papers |archive-date=July 17, 2012 |url-status=live }}</ref> | ||
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<ref name="typepad: new client dev">{{cite web|url=http://folding.typepad.com/news/2008/03/new-windows-cli.html |title=New Windows client/core development (SMP and classic clients) |author=Vijay Pande |work=Folding@home |publisher=] |date=March 8, 2008 |access-date=September 30, 2011 |archive-url=https://web.archive.org/web/20121015011735/http://folding.typepad.com/news/2008/03/new-windows-cli.html |archive-date=October 15, 2012 |url-status=live }}</ref> | <ref name="typepad: new client dev">{{cite web|url=http://folding.typepad.com/news/2008/03/new-windows-cli.html |title=New Windows client/core development (SMP and classic clients) |author=Vijay Pande |work=Folding@home |publisher=] |date=March 8, 2008 |access-date=September 30, 2011 |archive-url=https://web.archive.org/web/20121015011735/http://folding.typepad.com/news/2008/03/new-windows-cli.html |archive-date=October 15, 2012 |url-status=live }}</ref> | ||
<ref name="typepad: GPU2 open beta">{{cite web|url=http://folding.typepad.com/news/2008/04/gpu2-open-beta.html |title=GPU2 open beta |author=Vijay Pande |work=Folding@home |publisher=] |date=April 10, 2008 |access-date=September 7, 2011 |archive-url=https:// |
<ref name="typepad: GPU2 open beta">{{cite web|url=http://folding.typepad.com/news/2008/04/gpu2-open-beta.html |title=GPU2 open beta |author=Vijay Pande |work=Folding@home |publisher=] |date=April 10, 2008 |access-date=September 7, 2011 |archive-url=https://archive.today/20120709022254/http://folding.typepad.com/news/2008/04/gpu2-open-beta.html |archive-date=July 9, 2012 |url-status=live }}</ref> | ||
<ref name="typepad: GPU2 going well">{{cite web|url=http://folding.typepad.com/news/2008/04/gpu2-open-bet-1.html |title=GPU2 open beta going well |author=Vijay Pande |work=Folding@home |publisher=] |date=April 11, 2008 |access-date=September 7, 2011 |archive-url=https://web.archive.org/web/20120922075704/http://folding.typepad.com/news/2008/04/gpu2-open-bet-1.html |archive-date=September 22, 2012 |url-status=live }}</ref> | <ref name="typepad: GPU2 going well">{{cite web|url=http://folding.typepad.com/news/2008/04/gpu2-open-bet-1.html |title=GPU2 open beta going well |author=Vijay Pande |work=Folding@home |publisher=] |date=April 11, 2008 |access-date=September 7, 2011 |archive-url=https://web.archive.org/web/20120922075704/http://folding.typepad.com/news/2008/04/gpu2-open-bet-1.html |archive-date=September 22, 2012 |url-status=live }}</ref> | ||
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<ref name="forum: 7.1.38 released">{{cite web|url=https://foldingforum.org/viewtopic.php?f=67&t=19795&start=45#p197198 |title=Re: FAHClient V7.1.38 released (4th Open-Beta) |author=Joseph Coffland (CEO of Cauldron Development LLC & lead developer at Folding@home) |work=Folding@home |publisher=] Group |date=October 13, 2011 |access-date=October 15, 2011 |archive-url=https://web.archive.org/web/20120331004019/http://foldingforum.org/viewtopic.php?f=67&t=19795&start=45 |archive-date=March 31, 2012 |url-status=live }}</ref> | <ref name="forum: 7.1.38 released">{{cite web|url=https://foldingforum.org/viewtopic.php?f=67&t=19795&start=45#p197198 |title=Re: FAHClient V7.1.38 released (4th Open-Beta) |author=Joseph Coffland (CEO of Cauldron Development LLC & lead developer at Folding@home) |work=Folding@home |publisher=] Group |date=October 13, 2011 |access-date=October 15, 2011 |archive-url=https://web.archive.org/web/20120331004019/http://foldingforum.org/viewtopic.php?f=67&t=19795&start=45 |archive-date=March 31, 2012 |url-status=live }}</ref> | ||
<ref name="forum: 7610/7611 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=18822 |title=Project 7610 & 7611 in Beta |author=TJ Lane (Pande lab member) |work=Folding@home |publisher=] Group |date=June 6, 2011 |access-date=February 25, 2012 |archive-url=https:// |
<ref name="forum: 7610/7611 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=18822 |title=Project 7610 & 7611 in Beta |author=TJ Lane (Pande lab member) |work=Folding@home |publisher=] Group |date=June 6, 2011 |access-date=February 25, 2012 |archive-url=https://web.archive.org/web/20140809222806/https://foldingforum.org/viewtopic.php?f=66&t=18822 |archive-date=August 9, 2014 |url-status=live }}{{registration required}}</ref> | ||
<ref name="forum: GPU3 headless guide">{{cite web|url=https://foldingforum.org/viewtopic.php?f=54&t=6793 |title=NVIDIA GPU3 Linux/Wine Headless Install Guide |work=Folding@home |publisher=] Group |date=November 8, 2008 |access-date=September 5, 2011 |archive-url=https://web.archive.org/web/20121009061606/http://foldingforum.org/viewtopic.php?f=54&t=6793 |archive-date=October 9, 2012 |url-status=live }}</ref> | <ref name="forum: GPU3 headless guide">{{cite web|url=https://foldingforum.org/viewtopic.php?f=54&t=6793 |title=NVIDIA GPU3 Linux/Wine Headless Install Guide |work=Folding@home |publisher=] Group |date=November 8, 2008 |access-date=September 5, 2011 |archive-url=https://web.archive.org/web/20121009061606/http://foldingforum.org/viewtopic.php?f=54&t=6793 |archive-date=October 9, 2012 |url-status=live }}</ref> | ||
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<ref name="forum: 10125">{{cite web |url= https://foldingforum.org/viewtopic.php?f=66&t=19423&p=193871#p193871 |title= Project 10125 |author= Gregory Bowman (Pande lab Member) |work= Folding@home |publisher= ] Group |access-date= December 2, 2011}}{{registration required |archive-url= https://www.webcitation.org/6Aqt4nOWS?url=http://foldingforum.org/viewtopic.php?f%3D66%26t%3D19423%26p%3D193871 |archive-date= September 20, 2012 |url-status= live}}</ref> | <ref name="forum: 10125">{{cite web |url= https://foldingforum.org/viewtopic.php?f=66&t=19423&p=193871#p193871 |title= Project 10125 |author= Gregory Bowman (Pande lab Member) |work= Folding@home |publisher= ] Group |access-date= December 2, 2011}}{{registration required |archive-url= https://www.webcitation.org/6Aqt4nOWS?url=http://foldingforum.org/viewtopic.php?f%3D66%26t%3D19423%26p%3D193871 |archive-date= September 20, 2012 |url-status= live}}</ref> | ||
<ref name="forum: 7600 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=18839 |title=Project 7600 in Beta |author=TJ Lane (Pande lab member) |work=Folding@home |publisher=] Group |date=June 8, 2011 |access-date=September 27, 2011 |archive-url=https:// |
<ref name="forum: 7600 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=18839 |title=Project 7600 in Beta |author=TJ Lane (Pande lab member) |work=Folding@home |publisher=] Group |date=June 8, 2011 |access-date=September 27, 2011 |archive-url=https://web.archive.org/web/20140810001102/https://foldingforum.org/viewtopic.php?f=66&t=18839 |archive-date=August 10, 2014 |url-status=live }}{{registration required}}</ref> | ||
<ref name="forum: 8021 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=20765&p=207880 |title=Project 8021 released to beta |author=Diwakar Shukla (Pande lab member) |work=Folding@home |publisher=] Group |date=February 10, 2012 |access-date=March 17, 2012 |archive-url=https:// |
<ref name="forum: 8021 in beta">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=20765&p=207880 |title=Project 8021 released to beta |author=Diwakar Shukla (Pande lab member) |work=Folding@home |publisher=] Group |date=February 10, 2012 |access-date=March 17, 2012 |archive-url=https://web.archive.org/web/20140809223548/https://foldingforum.org/viewtopic.php?f=66&t=20765&p=207880 |archive-date=August 9, 2014 |url-status=live }}{{registration required}}</ref> | ||
<ref name="forum: 6871">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=19201&p=191821 |title=New project p6871 |author=yslin (Pande lab member) |work=Folding@home |publisher=] Group |date=July 22, 2011 |access-date=March 17, 2012 |archive-url=https:// |
<ref name="forum: 6871">{{cite web|url=https://foldingforum.org/viewtopic.php?f=66&t=19201&p=191821 |title=New project p6871 |author=yslin (Pande lab member) |work=Folding@home |publisher=] Group |date=July 22, 2011 |access-date=March 17, 2012 |archive-url=https://web.archive.org/web/20131030165821/https://foldingforum.org/viewtopic.php?f=66&t=19201&p=191821 |archive-date=October 30, 2013 |url-status=live }}{{registration required}}</ref> | ||
<ref name="forum: 7808/7809 to FAH">{{cite web|url=https://foldingforum.org/viewtopic.php?f=24&t=19376&start=0#p193378 |title=Projects 7808 and 7809 to full fah |author=Christian "schwancr" Schwantes (Pande lab member) |work=Folding@home |publisher=] Group |date=August 15, 2011 |access-date=October 16, 2011 |archive-url=https://web.archive.org/web/20130131223022/http://foldingforum.org/viewtopic.php?f=24&t=19376&start=0 |archive-date=January 31, 2013 |url-status=live }}</ref> | <ref name="forum: 7808/7809 to FAH">{{cite web|url=https://foldingforum.org/viewtopic.php?f=24&t=19376&start=0#p193378 |title=Projects 7808 and 7809 to full fah |author=Christian "schwancr" Schwantes (Pande lab member) |work=Folding@home |publisher=] Group |date=August 15, 2011 |access-date=October 16, 2011 |archive-url=https://web.archive.org/web/20130131223022/http://foldingforum.org/viewtopic.php?f=24&t=19376&start=0 |archive-date=January 31, 2013 |url-status=live }}</ref> | ||
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<ref name="Copernicus download">{{cite web|url=http://copernicus-computing.org/?q=node/2 |title=Copernicus Download |author1=Sander Pronk |author2=Iman Pouya |author3=Per Larsson |author4=Peter Kasson |author5=Erik Lindahl |work=copernicus-computing.org |publisher=Copernicus |date=November 17, 2011 |access-date=October 2, 2012 |archive-url=https://web.archive.org/web/20121007045701/http://copernicus-computing.org/?q=node/2 |archive-date=October 7, 2012 |url-status=live }}</ref> | <ref name="Copernicus download">{{cite web|url=http://copernicus-computing.org/?q=node/2 |title=Copernicus Download |author1=Sander Pronk |author2=Iman Pouya |author3=Per Larsson |author4=Peter Kasson |author5=Erik Lindahl |work=copernicus-computing.org |publisher=Copernicus |date=November 17, 2011 |access-date=October 2, 2012 |archive-url=https://web.archive.org/web/20121007045701/http://copernicus-computing.org/?q=node/2 |archive-date=October 7, 2012 |url-status=live }}</ref> | ||
<ref name="MSMBuilder source">{{cite web|url=https://simtk.org/scm/instructions.php/msmbuilder |title=MSMBuilder Source Code Repository |work=MSMBuilder |publisher=simtk.org |year=2012 |access-date=October 12, 2012 |archive-url=https:// |
<ref name="MSMBuilder source">{{cite web|url=https://simtk.org/scm/instructions.php/msmbuilder |title=MSMBuilder Source Code Repository |work=MSMBuilder |publisher=simtk.org |year=2012 |access-date=October 12, 2012 |archive-url=https://archive.today/20121228125516/https://simtk.org/scm/instructions.php/msmbuilder |archive-date=December 28, 2012 |url-status=live }}</ref> | ||
<ref name="past 4 petaFLOPS">{{cite web|url=http://team52735.blogspot.com/2008_09_29_archive.html |title=Increase in 'active' PS3 folders pushes Folding@home past 4 Petaflops! |work=team52735.blogspot.com |publisher=] |date=September 29, 2008 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20131222204303/http://team52735.blogspot.com/2008_09_29_archive.html |archive-date=December 22, 2013 |url-status=live }}</ref> | <ref name="past 4 petaFLOPS">{{cite web|url=http://team52735.blogspot.com/2008_09_29_archive.html |title=Increase in 'active' PS3 folders pushes Folding@home past 4 Petaflops! |work=team52735.blogspot.com |publisher=] |date=September 29, 2008 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20131222204303/http://team52735.blogspot.com/2008_09_29_archive.html |archive-date=December 22, 2013 |url-status=live }}</ref> | ||
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<ref name="Biophysical society names recipients">{{cite web |url=http://www.biophysics.org/LinkClick.aspx?fileticket=k_JYSLGevzU%3d&tabid=504 |title=Biophysical Society Names Five 2012 Award Recipients |work=Biophysics.org |publisher=Biophysical Society |date=August 17, 2011 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120327180426/http://www.biophysics.org/LinkClick.aspx?fileticket=k_JYSLGevzU%3D&tabid=504 |archive-date=March 27, 2012 |url-status=dead }}</ref> | <ref name="Biophysical society names recipients">{{cite web |url=http://www.biophysics.org/LinkClick.aspx?fileticket=k_JYSLGevzU%3d&tabid=504 |title=Biophysical Society Names Five 2012 Award Recipients |work=Biophysics.org |publisher=Biophysical Society |date=August 17, 2011 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120327180426/http://www.biophysics.org/LinkClick.aspx?fileticket=k_JYSLGevzU%3D&tabid=504 |archive-date=March 27, 2012 |url-status=dead }}</ref> | ||
<ref name="FAH publishes cancer results">{{cite |
<ref name="FAH publishes cancer results">{{cite news|url=http://www.maximumpc.com/forums/viewtopic.php?p=112590 |title=F@H project publishes results of cancer related research |author=mah3, Vijay Pande |work=].com |publisher=Future US, Inc. |date=September 24, 2004 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20131029210338/http://www.maximumpc.com/forums/viewtopic.php?p=112590 |archive-date=October 29, 2013 |url-status=live }} ''To our knowledge, this is the first peer-reviewed results from a distributed computing project related to cancer.''</ref> | ||
<ref name="Peter Kasson">{{cite web |url=http://bme.virginia.edu/people/kasson.html |title=Peter M. Kasson |author=Peter Kasson |work=Kasson lab |publisher=] |year=2012 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120903200810/http://bme.virginia.edu/people/kasson.html |archive-date=September 3, 2012 |url-status=dead }}</ref> | <ref name="Peter Kasson">{{cite web |url=http://bme.virginia.edu/people/kasson.html |title=Peter M. Kasson |author=Peter Kasson |work=Kasson lab |publisher=] |year=2012 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120903200810/http://bme.virginia.edu/people/kasson.html |archive-date=September 3, 2012 |url-status=dead }}</ref> | ||
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<ref name="scientists boost IL-2 potency">{{cite web|url=http://medicalxpress.com/news/2012-03-scientists-boost-potency-side-effects.html |title=Scientists boost potency, reduce side effects of IL-2 protein used to treat cancer |work=MedicalXpress.com |publisher=Medical Xpress |date=March 18, 2012 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20121003154151/http://medicalxpress.com/news/2012-03-scientists-boost-potency-side-effects.html |archive-date=October 3, 2012 |url-status=live }}</ref> | <ref name="scientists boost IL-2 potency">{{cite web|url=http://medicalxpress.com/news/2012-03-scientists-boost-potency-side-effects.html |title=Scientists boost potency, reduce side effects of IL-2 protein used to treat cancer |work=MedicalXpress.com |publisher=Medical Xpress |date=March 18, 2012 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20121003154151/http://medicalxpress.com/news/2012-03-scientists-boost-potency-side-effects.html |archive-date=October 3, 2012 |url-status=live }}</ref> | ||
<ref name="Top500 June 2007">{{cite web |url= http://www.top500.org/list/2007/06/100 |title= TOP500 List — June 2007 |work= top500.org |publisher= ] |date= June 2007 |access-date= September 20, 2012}}</ref> | <ref name="Top500 June 2007">{{cite web |url= http://www.top500.org/list/2007/06/100 |title= TOP500 List — June 2007 |work= top500.org |publisher= ] |date= June 2007 |access-date= September 20, 2012 |archive-date= September 30, 2007 |archive-url= https://web.archive.org/web/20070930201044/http://www.top500.org/list/2007/06/100 |url-status= dead }}</ref> | ||
<ref name="Top500 November 2008">{{cite web |url= http://www.top500.org/list/2008/11/100 |title= TOP500 List — November 2008 |work= top500.org |publisher= ] |date= November 2008 |access-date= September 20, 2012}}</ref> | <ref name="Top500 November 2008">{{cite web |url= http://www.top500.org/list/2008/11/100 |title= TOP500 List — November 2008 |work= top500.org |publisher= ] |date= November 2008 |access-date= September 20, 2012 |archive-date= December 9, 2008 |archive-url= https://web.archive.org/web/20081209070813/http://www.top500.org/list/2008/11/100 |url-status= dead }}</ref> | ||
<ref name="FAH reaches 2 PF">{{cite web|url=http://n4g.com/news/143113/ps3-andamp-foldingahome-reach-2-petaflops |title=Folding@Home reach 2 Petaflops |work=n4g.com |publisher=HAVAmedia |date=May 8, 2008 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120610010619/http://n4g.com/news/143113/ps3-andamp-foldingahome-reach-2-petaflops |archive-date=June 10, 2012 |url-status=live }}</ref> | <ref name="FAH reaches 2 PF">{{cite web|url=http://n4g.com/news/143113/ps3-andamp-foldingahome-reach-2-petaflops |title=Folding@Home reach 2 Petaflops |work=n4g.com |publisher=HAVAmedia |date=May 8, 2008 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120610010619/http://n4g.com/news/143113/ps3-andamp-foldingahome-reach-2-petaflops |archive-date=June 10, 2012 |url-status=live }}</ref> | ||
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<ref name="Extreme overclocking forum">{{cite web|url=http://forums.extremeoverclocking.com/forumdisplay.php?f=45 |title=Official Extreme Overclocking Folding@home Team Forum |work=forums.extremeoverclocking.com |publisher=Extreme Overclocking |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120921141240/http://forums.extremeoverclocking.com/forumdisplay.php?f=45 |archive-date=September 21, 2012 |url-status=live }}</ref> | <ref name="Extreme overclocking forum">{{cite web|url=http://forums.extremeoverclocking.com/forumdisplay.php?f=45 |title=Official Extreme Overclocking Folding@home Team Forum |work=forums.extremeoverclocking.com |publisher=Extreme Overclocking |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120921141240/http://forums.extremeoverclocking.com/forumdisplay.php?f=45 |archive-date=September 21, 2012 |url-status=live }}</ref> | ||
<ref name="MaximumPC Chimp Challenge">{{cite |
<ref name="MaximumPC Chimp Challenge">{{cite news|url=http://www.maximumpc.com/article/news/help_maximum_pcs_folding_team_win_next_chimp_challenge |title=Help Maximum PC's Folding Team Win the Next Chimp Challenge! |author=Norman Chan |work=Maximumpc.com |publisher=Future US, Inc. |date=April 6, 2009 |access-date=September 20, 2012 |archive-url=https://web.archive.org/web/20120707061249/http://www.maximumpc.com/article/news/help_maximum_pcs_folding_team_win_next_chimp_challenge |archive-date=July 7, 2012 |url-status=live }}</ref> | ||
<ref name="help ubuntu">{{cite web|url=https://help.ubuntu.com/community/FoldingAtHome |title=FoldingAtHome |author=unikuser |work=Ubuntu Documentation |publisher=help.ubuntu.com |date=August 7, 2011 |access-date=September 22, 2012 |archive-url=https://web.archive.org/web/20120422031744/https://help.ubuntu.com/community/FoldingAtHome |archive-date=April 22, 2012 |url-status=live }}</ref> | <ref name="help ubuntu">{{cite web|url=https://help.ubuntu.com/community/FoldingAtHome |title=FoldingAtHome |author=unikuser |work=Ubuntu Documentation |publisher=help.ubuntu.com |date=August 7, 2011 |access-date=September 22, 2012 |archive-url=https://web.archive.org/web/20120422031744/https://help.ubuntu.com/community/FoldingAtHome |archive-date=April 22, 2012 |url-status=live }}</ref> | ||
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Latest revision as of 20:03, 23 December 2024
Distributed computing project simulating protein folding
Original author(s) | Vijay Pande |
---|---|
Developer(s) | Pande Laboratory, Sony, Nvidia, ATI Technologies, Joseph Coffland, Cauldron Development |
Initial release | October 1, 2000; 24 years ago (2000-10-01) |
Stable release | 7.6.21 / October 23, 2020; 4 years ago (2020-10-23) |
Preview release | 8.1.18 / April 18, 2023; 20 months ago (2023-04-18) |
Operating system | Microsoft Windows, macOS, Linux, PlayStation 3 (discontinued as of firmware version 4.30) |
Platform | IA-32, x86-64, ARM64, CUDA |
Available in | English, French, Spanish, Swedish |
Type | Distributed computing |
License | Proprietary software |
Website | foldingathome |
Folding@home (FAH or F@h) is a distributed computing project aimed to help scientists develop new therapeutics for a variety of diseases by the means of simulating protein dynamics. This includes the process of protein folding and the movements of proteins, and is reliant on simulations run on volunteers' personal computers. Folding@home is currently based at the University of Pennsylvania and led by Greg Bowman, a former student of Vijay Pande.
The project utilizes graphics processing units (GPUs), central processing units (CPUs), and ARM processors like those on the Raspberry Pi for distributed computing and scientific research. The project uses statistical simulation methodology that is a paradigm shift from traditional computing methods. As part of the client–server model network architecture, the volunteered machines each receive pieces of a simulation (work units), complete them, and return them to the project's database servers, where the units are compiled into an overall simulation. Volunteers can track their contributions on the Folding@home website, which makes volunteers' participation competitive and encourages long-term involvement.
Folding@home is one of the world's fastest computing systems. With heightened interest in the project as a result of the COVID-19 pandemic, the system achieved a speed of approximately 1.22 exaflops by late March 2020 and reached 2.43 exaflops by April 12, 2020, making it the world's first exaflop computing system. This level of performance from its large-scale computing network has allowed researchers to run computationally costly atomic-level simulations of protein folding thousands of times longer than formerly achieved. Since its launch on October 1, 2000, Folding@home was involved in the production of 226 scientific research papers. Results from the project's simulations agree well with experiments.
Background
Further information: Protein foldingProteins are an essential component to many biological functions and participate in virtually all processes within biological cells. They often act as enzymes, performing biochemical reactions including cell signaling, molecular transportation, and cellular regulation. As structural elements, some proteins act as a type of skeleton for cells, and as antibodies, while other proteins participate in the immune system. Before a protein can take on these roles, it must fold into a functional three-dimensional structure, a process that often occurs spontaneously and is dependent on interactions within its amino acid sequence and interactions of the amino acids with their surroundings. Protein folding is driven by the search to find the most energetically favorable conformation of the protein, i.e., its native state. Thus, understanding protein folding is critical to understanding what a protein does and how it works, and is considered a holy grail of computational biology. Despite folding occurring within a crowded cellular environment, it typically proceeds smoothly. However, due to a protein's chemical properties or other factors, proteins may misfold, that is, fold down the wrong pathway and end up misshapen. Unless cellular mechanisms can destroy or refold misfolded proteins, they can subsequently aggregate and cause a variety of debilitating diseases. Laboratory experiments studying these processes can be limited in scope and atomic detail, leading scientists to use physics-based computing models that, when complementing experiments, seek to provide a more complete picture of protein folding, misfolding, and aggregation.
Due to the complexity of proteins' conformation or configuration space (the set of possible shapes a protein can take), and limits in computing power, all-atom molecular dynamics simulations have been severely limited in the timescales that they can study. While most proteins typically fold in the order of milliseconds, before 2010, simulations could only reach nanosecond to microsecond timescales. General-purpose supercomputers have been used to simulate protein folding, but such systems are intrinsically costly and typically shared among many research groups. Further, because the computations in kinetic models occur serially, strong scaling of traditional molecular simulations to these architectures is exceptionally difficult. Moreover, as protein folding is a stochastic process (i.e., random) and can statistically vary over time, it is challenging computationally to use long simulations for comprehensive views of the folding process.
Protein folding does not occur in one step. Instead, proteins spend most of their folding time, nearly 96% in some cases, waiting in various intermediate conformational states, each a local thermodynamic free energy minimum in the protein's energy landscape. Through a process known as adaptive sampling, these conformations are used by Folding@home as starting points for a set of simulation trajectories. As the simulations discover more conformations, the trajectories are restarted from them, and a Markov state model (MSM) is gradually created from this cyclic process. MSMs are discrete-time master equation models which describe a biomolecule's conformational and energy landscape as a set of distinct structures and the short transitions between them. The adaptive sampling Markov state model method significantly increases the efficiency of simulation as it avoids computation inside the local energy minimum itself, and is amenable to distributed computing (including on GPUGRID) as it allows for the statistical aggregation of short, independent simulation trajectories. The amount of time it takes to construct a Markov state model is inversely proportional to the number of parallel simulations run, i.e., the number of processors available. In other words, it achieves linear parallelization, leading to an approximately four orders of magnitude reduction in overall serial calculation time. A completed MSM may contain tens of thousands of sample states from the protein's phase space (all the conformations a protein can take on) and the transitions between them. The model illustrates folding events and pathways (i.e., routes) and researchers can later use kinetic clustering to view a coarse-grained representation of the otherwise highly detailed model. They can use these MSMs to reveal how proteins misfold and to quantitatively compare simulations with experiments.
Between 2000 and 2010, the length of the proteins Folding@home has studied have increased by a factor of four, while its timescales for protein folding simulations have increased by six orders of magnitude. In 2002, Folding@home used Markov state models to complete approximately a million CPU days of simulations over the span of several months, and in 2011, MSMs parallelized another simulation that required an aggregate 10 million CPU hours of computing. In January 2010, Folding@home used MSMs to simulate the dynamics of the slow-folding 32-residue NTL9 protein out to 1.52 milliseconds, a timescale consistent with experimental folding rate predictions but a thousand times longer than formerly achieved. The model consisted of many individual trajectories, each two orders of magnitude shorter, and provided an unprecedented level of detail into the protein's energy landscape. In 2010, Folding@home researcher Gregory Bowman was awarded the Thomas Kuhn Paradigm Shift Award from the American Chemical Society for the development of the open-source MSMBuilder software and for attaining quantitative agreement between theory and experiment. For his work, Pande was awarded the 2012 Michael and Kate Bárány Award for Young Investigators for "developing field-defining and field-changing computational methods to produce leading theoretical models for protein and RNA folding", and the 2006 Irving Sigal Young Investigator Award for his simulation results which "have stimulated a re-examination of the meaning of both ensemble and single-molecule measurements, making Pande's efforts pioneering contributions to simulation methodology."
Examples of application in biomedical research
Protein misfolding can result in a variety of diseases including Alzheimer's disease, cancer, Creutzfeldt–Jakob disease, cystic fibrosis, Huntington's disease, sickle-cell anemia, and type II diabetes. Cellular infection by viruses such as HIV and influenza also involve folding events on cell membranes. Once protein misfolding is better understood, therapies can be developed that augment cells' natural ability to regulate protein folding. Such therapies include the use of engineered molecules to alter the production of a given protein, help destroy a misfolded protein, or assist in the folding process. The combination of computational molecular modeling and experimental analysis has the possibility to fundamentally shape the future of molecular medicine and the rational design of therapeutics, such as expediting and lowering the costs of drug discovery. The goal of the first five years of Folding@home was to make advances in understanding folding, while the current goal is to understand misfolding and related disease, especially Alzheimer's.
The simulations run on Folding@home are used in conjunction with laboratory experiments, but researchers can use them to study how folding in vitro differs from folding in native cellular environments. This is advantageous in studying aspects of folding, misfolding, and their relationships to disease that are difficult to observe experimentally. For example, in 2011, Folding@home simulated protein folding inside a ribosomal exit tunnel, to help scientists better understand how natural confinement and crowding might influence the folding process. Furthermore, scientists typically employ chemical denaturants to unfold proteins from their stable native state. It is not generally known how the denaturant affects the protein's refolding, and it is difficult to experimentally determine if these denatured states contain residual structures which may influence folding behavior. In 2010, Folding@home used GPUs to simulate the unfolded states of Protein L, and predicted its collapse rate in strong agreement with experimental results.
The large data sets from the project are freely available for other researchers to use upon request and some can be accessed from the Folding@home website. The Pande lab has collaborated with other molecular dynamics systems such as the Blue Gene supercomputer, and they share Folding@home's key software with other researchers, so that the algorithms which benefited Folding@home may aid other scientific areas. In 2011, they released the open-source Copernicus software, which is based on Folding@home's MSM and other parallelizing methods and aims to improve the efficiency and scaling of molecular simulations on large computer clusters or supercomputers. Summaries of all scientific findings from Folding@home are posted on the Folding@home website after publication.
Alzheimer's disease
Alzheimer's disease is linked to the aggregation of amyloid beta protein fragments in the brain (right). Researchers have used Folding@home to simulate this aggregation process, to better understand the cause of the disease.Alzheimer's disease is an incurable neurodegenerative disease which most often affects the elderly and accounts for more than half of all cases of dementia. Its exact cause remains unknown, but the disease is identified as a protein misfolding disease. Alzheimer's is associated with toxic aggregations of the amyloid beta (Aβ) peptide, caused by Aβ misfolding and clumping together with other Aβ peptides. These Aβ aggregates then grow into significantly larger senile plaques, a pathological marker of Alzheimer's disease. Due to the heterogeneous nature of these aggregates, experimental methods such as X-ray crystallography and nuclear magnetic resonance (NMR) have had difficulty characterizing their structures. Moreover, atomic simulations of Aβ aggregation are highly demanding computationally due to their size and complexity.
Preventing Aβ aggregation is a promising method to developing therapeutic drugs for Alzheimer's disease, according to Naeem and Fazili in a literature review article. In 2008, Folding@home simulated the dynamics of Aβ aggregation in atomic detail over timescales of the order of tens of seconds. Prior studies were only able to simulate about 10 microseconds. Folding@home was able to simulate Aβ folding for six orders of magnitude longer than formerly possible. Researchers used the results of this study to identify a beta hairpin that was a major source of molecular interactions within the structure. The study helped prepare the Pande lab for future aggregation studies and for further research to find a small peptide which may stabilize the aggregation process.
In December 2008, Folding@home found several small drug candidates which appear to inhibit the toxicity of Aβ aggregates. In 2010, in close cooperation with the Center for Protein Folding Machinery, these drug leads began to be tested on biological tissue. In 2011, Folding@home completed simulations of several mutations of Aβ that appear to stabilize the aggregate formation, which could aid in the development of therapeutic drug therapies for the disease and greatly assist with experimental nuclear magnetic resonance spectroscopy studies of Aβ oligomers. Later that year, Folding@home began simulations of various Aβ fragments to determine how various natural enzymes affect the structure and folding of Aβ.
Huntington's disease
Huntington's disease is a neurodegenerative genetic disorder that is associated with protein misfolding and aggregation. Excessive repeats of the glutamine amino acid at the N-terminus of the huntingtin protein cause aggregation, and although the behavior of the repeats is not completely understood, it does lead to the cognitive decline associated with the disease. As with other aggregates, there is difficulty in experimentally determining its structure. Scientists are using Folding@home to study the structure of the huntingtin protein aggregate and to predict how it forms, assisting with rational drug design methods to stop the aggregate formation. The N17 fragment of the huntingtin protein accelerates this aggregation, and while there have been several mechanisms proposed, its exact role in this process remains largely unknown. Folding@home has simulated this and other fragments to clarify their roles in the disease. Since 2008, its drug design methods for Alzheimer's disease have been applied to Huntington's.
Cancer
More than half of all known cancers involve mutations of p53, a tumor suppressor protein present in every cell which regulates the cell cycle and signals for cell death in the event of damage to DNA. Specific mutations in p53 can disrupt these functions, allowing an abnormal cell to continue growing unchecked, resulting in the development of tumors. Analysis of these mutations helps explain the root causes of p53-related cancers. In 2004, Folding@home was used to perform the first molecular dynamics study of the refolding of p53's protein dimer in an all-atom simulation of water. The simulation's results agreed with experimental observations and gave insights into the refolding of the dimer that were formerly unobtainable. This was the first peer reviewed publication on cancer from a distributed computing project. The following year, Folding@home powered a new method to identify the amino acids crucial for the stability of a given protein, which was then used to study mutations of p53. The method was reasonably successful in identifying cancer-promoting mutations and determined the effects of specific mutations which could not otherwise be measured experimentally.
Folding@home is also used to study protein chaperones, heat shock proteins which play essential roles in cell survival by assisting with the folding of other proteins in the crowded and chemically stressful environment within a cell. Rapidly growing cancer cells rely on specific chaperones, and some chaperones play key roles in chemotherapy resistance. Inhibitions to these specific chaperones are seen as potential modes of action for efficient chemotherapy drugs or for reducing the spread of cancer. Using Folding@home and working closely with the Center for Protein Folding Machinery, the Pande lab hopes to find a drug which inhibits those chaperones involved in cancerous cells. Researchers are also using Folding@home to study other molecules related to cancer, such as the enzyme Src kinase, and some forms of the engrailed homeodomain: a large protein which may be involved in many diseases, including cancer. In 2011, Folding@home began simulations of the dynamics of the small knottin protein EETI, which can identify carcinomas in imaging scans by binding to surface receptors of cancer cells.
Interleukin 2 (IL-2) is a protein that helps T cells of the immune system attack pathogens and tumors. However, its use as a cancer treatment is restricted due to serious side effects such as pulmonary edema. IL-2 binds to these pulmonary cells differently than it does to T cells, so IL-2 research involves understanding the differences between these binding mechanisms. In 2012, Folding@home assisted with the discovery of a mutant form of IL-2 which is three hundred times more effective in its immune system role but carries fewer side effects. In experiments, this altered form significantly outperformed natural IL-2 in impeding tumor growth. Pharmaceutical companies have expressed interest in the mutant molecule, and the National Institutes of Health are testing it against a large variety of tumor models to try to accelerate its development as a therapeutic.
Osteogenesis imperfecta
Osteogenesis imperfecta, known as brittle bone disease, is an incurable genetic bone disorder which can be lethal. Those with the disease are unable to make functional connective bone tissue. This is most commonly due to a mutation in Type-I collagen, which fulfills a variety of structural roles and is the most abundant protein in mammals. The mutation causes a deformation in collagen's triple helix structure, which if not naturally destroyed, leads to abnormal and weakened bone tissue. In 2005, Folding@home tested a new quantum mechanical method that improved upon prior simulation methods, and which may be useful for future computing studies of collagen. Although researchers have used Folding@home to study collagen folding and misfolding, the interest stands as a pilot project compared to Alzheimer's and Huntington's research.
Viruses
Folding@home is assisting in research towards preventing some viruses, such as influenza and HIV, from recognizing and entering biological cells. In 2011, Folding@home began simulations of the dynamics of the enzyme RNase H, a key component of HIV, to try to design drugs to deactivate it. Folding@home has also been used to study membrane fusion, an essential event for viral infection and a wide range of biological functions. This fusion involves conformational changes of viral fusion proteins and protein docking, but the exact molecular mechanisms behind fusion remain largely unknown. Fusion events may consist of over a half million atoms interacting for hundreds of microseconds. This complexity limits typical computer simulations to about ten thousand atoms over tens of nanoseconds: a difference of several orders of magnitude. The development of models to predict the mechanisms of membrane fusion will assist in the scientific understanding of how to target the process with antiviral drugs. In 2006, scientists applied Markov state models and the Folding@home network to discover two pathways for fusion and gain other mechanistic insights.
Following detailed simulations from Folding@home of small cells known as vesicles, in 2007, the Pande lab introduced a new computing method to measure the topology of its structural changes during fusion. In 2009, researchers used Folding@home to study mutations of influenza hemagglutinin, a protein that attaches a virus to its host cell and assists with viral entry. Mutations to hemagglutinin affect how well the protein binds to a host's cell surface receptor molecules, which determines how infective the virus strain is to the host organism. Knowledge of the effects of hemagglutinin mutations assists in the development of antiviral drugs. As of 2012, Folding@home continues to simulate the folding and interactions of hemagglutinin, complementing experimental studies at the University of Virginia.
In March 2020, Folding@home launched a program to assist researchers around the world who are working on finding a cure and learning more about the coronavirus pandemic. The initial wave of projects simulate potentially druggable protein targets from SARS-CoV-2 virus, and the related SARS-CoV virus, about which there is significantly more data available.
Drug design
Drugs function by binding to specific locations on target molecules and causing some desired change, such as disabling a target or causing a conformational change. Ideally, a drug should act very specifically, and bind only to its target without interfering with other biological functions. However, it is difficult to precisely determine where and how tightly two molecules will bind. Due to limits in computing power, current in silico methods usually must trade speed for accuracy; e.g., use rapid protein docking methods instead of computationally costly free energy calculations. Folding@home's computing performance allows researchers to use both methods, and evaluate their efficiency and reliability. Computer-assisted drug design has the potential to expedite and lower the costs of drug discovery. In 2010, Folding@home used MSMs and free energy calculations to predict the native state of the villin protein to within 1.8 angstrom (Å) root mean square deviation (RMSD) from the crystalline structure experimentally determined through X-ray crystallography. This accuracy has implications to future protein structure prediction methods, including for intrinsically unstructured proteins. Scientists have used Folding@home to research drug resistance by studying vancomycin, an antibiotic drug of last resort, and beta-lactamase, a protein that can break down antibiotics like penicillin.
Chemical activity occurs along a protein's active site. Traditional drug design methods involve tightly binding to this site and blocking its activity, under the assumption that the target protein exists in one rigid structure. However, this approach works for approximately only 15% of all proteins. Proteins contain allosteric sites which, when bound to by small molecules, can alter a protein's conformation and ultimately affect the protein's activity. These sites are attractive drug targets, but locating them is very computationally costly. In 2012, Folding@home and MSMs were used to identify allosteric sites in three medically relevant proteins: beta-lactamase, interleukin-2, and RNase H.
Approximately half of all known antibiotics interfere with the workings of a bacteria's ribosome, a large and complex biochemical machine that performs protein biosynthesis by translating messenger RNA into proteins. Macrolide antibiotics clog the ribosome's exit tunnel, preventing synthesis of essential bacterial proteins. In 2007, the Pande lab received a grant to study and design new antibiotics. In 2008, they used Folding@home to study the interior of this tunnel and how specific molecules may affect it. The full structure of the ribosome was determined only as of 2011, and Folding@home has also simulated ribosomal proteins, as many of their functions remain largely unknown.
Patterns of participation
Like other distributed computing projects, Folding@home is an online citizen science project. In these projects non-specialists contribute computer processing power or help to analyze data produced by professional scientists. Participants receive little or no obvious reward.
Research has been carried out into the motivations of citizen scientists and most of these studies have found that participants are motivated to take part because of altruistic reasons; that is, they want to help scientists and make a contribution to the advancement of their research. Many participants in citizen science have an underlying interest in the topic of the research and gravitate towards projects that are in disciplines of interest to them. Folding@home is no different in that respect. Research carried out recently on over 400 active participants revealed that they wanted to help make a contribution to research and that many had friends or relatives affected by the diseases that the Folding@home scientists investigate.
Folding@home attracts participants who are computer hardware enthusiasts. These groups bring considerable expertise to the project and are able to build computers with advanced processing power. Other distributed computing projects attract these types of participants and projects are often used to benchmark the performance of modified computers, and this aspect of the hobby is accommodated through the competitive nature of the project. Individuals and teams can compete to see who can process the most computer processing units (CPUs).
This latest research on Folding@home involving interview and ethnographic observation of online groups showed that teams of hardware enthusiasts can sometimes work together, sharing best practice with regard to maximizing processing output. Such teams can become communities of practice, with a shared language and online culture. This pattern of participation has been observed in other distributed computing projects.
Another key observation of Folding@home participants is that many are male. This has also been observed in other distributed projects. Furthermore, many participants work in computer and technology-based jobs and careers.
Not all Folding@home participants are hardware enthusiasts. Many participants run the project software on unmodified machines and do take part competitively. By January 2020, the number of users was down to 30,000. However, it is difficult to ascertain what proportion of participants are hardware enthusiasts. Although, according to the project managers, the contribution of the enthusiast community is substantially larger in terms of processing power.
Performance
Supercomputer FLOPS performance is assessed by running the legacy LINPACK benchmark. This short-term testing has difficulty in accurately reflecting sustained performance on real-world tasks because LINPACK more efficiently maps to supercomputer hardware. Computing systems vary in architecture and design, so direct comparison is difficult. Despite this, FLOPS remain the primary speed metric used in supercomputing. In contrast, Folding@home determines its FLOPS using wall-clock time by measuring how much time its work units take to complete.
On September 16, 2007, due in large part to the participation of PlayStation 3 consoles, the Folding@home project officially attained a sustained performance level higher than one native petaFLOPS, becoming the first computing system of any kind to do so. Top500's fastest supercomputer at the time was BlueGene/L, at 0.280 petaFLOPS. The following year, on May 7, 2008, the project attained a sustained performance level higher than two native petaFLOPS, followed by the three and four native petaFLOPS milestones in August 2008 and September 28, 2008 respectively. On February 18, 2009, Folding@home achieved five native petaFLOPS, and was the first computing project to meet these five levels. In comparison, November 2008's fastest supercomputer was IBM's Roadrunner at 1.105 petaFLOPS. On November 10, 2011, Folding@home's performance exceeded six native petaFLOPS with the equivalent of nearly eight x86 petaFLOPS. In mid-May 2013, Folding@home attained over seven native petaFLOPS, with the equivalent of 14.87 x86 petaFLOPS. It then reached eight native petaFLOPS on June 21, followed by nine on September 9 of that year, with 17.9 x86 petaFLOPS. On May 11, 2016 Folding@home announced that it was moving towards reaching the 100 x86 petaFLOPS mark.
Further use grew from increased awareness and participation in the project from the coronavirus pandemic in 2020. On March 20, 2020 Folding@home announced via Twitter that it was running with over 470 native petaFLOPS, the equivalent of 958 x86 petaFLOPS. By March 25 it reached 768 petaFLOPS, or 1.5 x86 exaFLOPS, making it the first exaFLOP computing system.
As of 23 December 2024, the computing power of Folding@home stands at 14.3 petaFLOPS, or 27.5 x86 petaFLOPS.
Points
Similarly to other distributed computing projects, Folding@home quantitatively assesses user computing contributions to the project through a credit system. All units from a given protein project have uniform base credit, which is determined by benchmarking one or more work units from that project on an official reference machine before the project is released. Each user receives these base points for completing every work unit, though through the use of a passkey they can receive added bonus points for reliably and rapidly completing units which are more demanding computationally or have a greater scientific priority. Users may also receive credit for their work by clients on multiple machines. This point system attempts to align awarded credit with the value of the scientific results.
Users can register their contributions under a team, which combine the points of all their members. A user can start their own team, or they can join an existing team. In some cases, a team may have their own community-driven sources of help or recruitment such as an Internet forum. The points can foster friendly competition between individuals and teams to compute the most for the project, which can benefit the folding community and accelerate scientific research. Individual and team statistics are posted on the Folding@home website.
If a user does not form a new team, or does not join an existing team, that user automatically becomes part of a "Default" team. This "Default" team has a team number of "0". Statistics are accumulated for this "Default" team as well as for specially named teams.
Software
Folding@home software at the user's end involves three primary components: work units, cores, and a client.
Work units
A work unit is the protein data that the client is asked to process. Work units are a fraction of the simulation between the states in a Markov model. After the work unit has been downloaded and completely processed by a volunteer's computer, it is returned to Folding@home servers, which then award the volunteer the credit points. This cycle repeats automatically. All work units have associated deadlines, and if this deadline is exceeded, the user may not get credit and the unit will be automatically reissued to another participant. As protein folding occurs serially, and many work units are generated from their predecessors, this allows the overall simulation process to proceed normally if a work unit is not returned after a reasonable period of time. Due to these deadlines, the minimum system requirement for Folding@home is a Pentium 3 450 MHz CPU with Streaming SIMD Extensions (SSE). However, work units for high-performance clients have a much shorter deadline than those for the uniprocessor client, as a major part of the scientific benefit is dependent on rapidly completing simulations.
Before public release, work units go through several quality assurance steps to keep problematic ones from becoming fully available. These testing stages include internal, beta, and advanced, before a final full release across Folding@home. Folding@home's work units are normally processed only once, except in the rare event that errors occur during processing. If this occurs for three different users, the unit is automatically pulled from distribution. The Folding@home support forum can be used to differentiate between issues arising from problematic hardware and bad work units.
Cores
Main article: List of Folding@home coresSpecialized molecular dynamics programs, referred to as "FahCores" and often abbreviated "cores", perform the calculations on the work unit as a background process. A large majority of Folding@home's cores are based on GROMACS, one of the fastest and most popular molecular dynamics software packages, which largely consists of manually optimized assembly language code and hardware optimizations. Although GROMACS is open-source software and there is a cooperative effort between the Pande lab and GROMACS developers, Folding@home uses a closed-source license to help ensure data validity. Less active cores include ProtoMol and SHARPEN. Folding@home has used AMBER, CPMD, Desmond, and TINKER, but these have since been retired and are no longer in active service. Some of these cores perform explicit solvation calculations in which the surrounding solvent (usually water) is modeled atom-by-atom; while others perform implicit solvation methods, where the solvent is treated as a mathematical continuum. The core is separate from the client to enable the scientific methods to be updated automatically without requiring a client update. The cores periodically create calculation checkpoints so that if they are interrupted they can resume work from that point upon startup.
Client
A Folding@home participant installs a client program on their personal computer. The user interacts with the client, which manages the other software components in the background. Through the client, the user may pause the folding process, open an event log, check the work progress, or view personal statistics. The computer clients run continuously in the background at a very low priority, using idle processing power so that normal computer use is unaffected. The maximum CPU use can be adjusted via client settings. The client connects to a Folding@home server and retrieves a work unit and may also download the appropriate core for the client's settings, operating system, and the underlying hardware architecture. After processing, the work unit is returned to the Folding@home servers. Computer clients are tailored to uniprocessor and multi-core processor systems, and graphics processing units. The diversity and power of each hardware architecture provides Folding@home with the ability to efficiently complete many types of simulations in a timely manner (in a few weeks or months rather than years), which is of significant scientific value. Together, these clients allow researchers to study biomedical questions formerly considered impractical to tackle computationally.
Professional software developers are responsible for most of Folding@home's code, both for the client and server-side. The development team includes programmers from Nvidia, ATI, Sony, and Cauldron Development. Clients can be downloaded only from the official Folding@home website or its commercial partners, and will only interact with Folding@home computer files. They will upload and download data with Folding@home's data servers (over port 8080, with 80 as an alternate), and the communication is verified using 2048-bit digital signatures. While the client's graphical user interface (GUI) is open-source, the client is proprietary software citing security and scientific integrity as the reasons.
However, this rationale of using proprietary software is disputed since while the license could be enforceable in the legal domain retrospectively, it does not practically prevent the modification (also known as patching) of the executable binary files. Likewise, binary-only distribution does not prevent the malicious modification of executable binary-code, either through a man-in-the-middle attack while being downloaded via the internet, or by the redistribution of binaries by a third-party that have been previously modified either in their binary state (i.e. patched), or by decompiling and recompiling them after modification. These modifications are possible unless the binary files – and the transport channel – are signed and the recipient person/system is able to verify the digital signature, in which case unwarranted modifications should be detectable, but not always. Either way, since in the case of Folding@home the input data and output result processed by the client-software are both digitally signed, the integrity of work can be verified independently from the integrity of the client software itself.
Folding@home uses the Cosm software libraries for networking. Folding@home was launched on October 1, 2000, and was the first distributed computing project aimed at bio-molecular systems. Its first client was a screensaver, which would run while the computer was not otherwise in use. In 2004, the Pande lab collaborated with David P. Anderson to test a supplemental client on the open-source BOINC framework. This client was released to closed beta in April 2005; however, the method became unworkable and was shelved in June 2006.
Graphics processing units
The specialized hardware of graphics processing units (GPU) is designed to accelerate rendering of 3-D graphics applications such as video games and can significantly outperform CPUs for some types of calculations. GPUs are one of the most powerful and rapidly growing computing platforms, and many scientists and researchers are pursuing general-purpose computing on graphics processing units (GPGPU). However, GPU hardware is difficult to use for non-graphics tasks and usually requires significant algorithm restructuring and an advanced understanding of the underlying architecture. Such customization is challenging, more so to researchers with limited software development resources. Folding@home uses the open-source OpenMM library, which uses a bridge design pattern with two application programming interface (API) levels to interface molecular simulation software to an underlying hardware architecture. With the addition of hardware optimizations, OpenMM-based GPU simulations need no significant modification but achieve performance nearly equal to hand-tuned GPU code, and greatly outperform CPU implementations.
Before 2010, the computing reliability of GPGPU consumer-grade hardware was largely unknown, and circumstantial evidence related to the lack of built-in error detection and correction in GPU memory raised reliability concerns. In the first large-scale test of GPU scientific accuracy, a 2010 study of over 20,000 hosts on the Folding@home network detected soft errors in the memory subsystems of two-thirds of the tested GPUs. These errors strongly correlated to board architecture, though the study concluded that reliable GPU computing was very feasible as long as attention is paid to the hardware traits, such as software-side error detection.
The first generation of Folding@home's GPU client (GPU1) was released to the public on October 2, 2006, delivering a 20–30 times speedup for some calculations over its CPU-based GROMACS counterparts. It was the first time GPUs had been used for either distributed computing or major molecular dynamics calculations. GPU1 gave researchers significant knowledge and experience with the development of GPGPU software, but in response to scientific inaccuracies with DirectX, on April 10, 2008, it was succeeded by GPU2, the second generation of the client. Following the introduction of GPU2, GPU1 was officially retired on June 6. Compared to GPU1, GPU2 was more scientifically reliable and productive, ran on ATI and CUDA-enabled Nvidia GPUs, and supported more advanced algorithms, larger proteins, and real-time visualization of the protein simulation. Following this, the third generation of Folding@home's GPU client (GPU3) was released on May 25, 2010. While backward compatible with GPU2, GPU3 was more stable, efficient, and flexibile in its scientific abilities, and used OpenMM on top of an OpenCL framework. Although these GPU3 clients did not natively support the operating systems Linux and macOS, Linux users with Nvidia graphics cards were able to run them through the Wine software application. GPUs remain Folding@home's most powerful platform in FLOPS. As of November 2012, GPU clients account for 87% of the entire project's x86 FLOPS throughput.
Native support for Nvidia and AMD graphics cards under Linux was introduced with FahCore 17, which uses OpenCL rather than CUDA.
PlayStation 3
Further information: Life with PlayStationFrom March 2007 until November 2012, Folding@home took advantage of the computing power of PlayStation 3s. At the time of its inception, its main streaming Cell processor delivered a 20 times speed increase over PCs for some calculations, processing power which could not be found on other systems such as the Xbox 360. The PS3's high speed and efficiency introduced other opportunities for worthwhile optimizations according to Amdahl's law, and significantly changed the tradeoff between computing efficiency and overall accuracy, allowing the use of more complex molecular models at little added computing cost. This allowed Folding@home to run biomedical calculations that would have been otherwise infeasible computationally.
The PS3 client was developed in a collaborative effort between Sony and the Pande lab and was first released as a standalone client on March 23, 2007. Its release made Folding@home the first distributed computing project to use PS3s. On September 18 of the following year, the PS3 client became a channel of Life with PlayStation on its launch. In the types of calculations it can perform, at the time of its introduction, the client fit in between a CPU's flexibility and a GPU's speed. However, unlike clients running on personal computers, users were unable to perform other activities on their PS3 while running Folding@home. The PS3's uniform console environment made technical support easier and made Folding@home more user friendly. The PS3 also had the ability to stream data quickly to its GPU, which was used for real-time atomic-level visualizing of the current protein dynamics.
On November 6, 2012, Sony ended support for the Folding@home PS3 client and other services available under Life with PlayStation. Over its lifetime of five years and seven months, more than 15 million users contributed over 100 million hours of computing to Folding@home, greatly assisting the project with disease research. Following discussions with the Pande lab, Sony decided to terminate the application. Pande considered the PlayStation 3 client a "game changer" for the project.
Multi-core processing client
Folding@home can use the parallel computing abilities of modern multi-core processors. The ability to use several CPU cores simultaneously allows completing the full simulation far faster. Working together, these CPU cores complete single work units proportionately faster than the standard uniprocessor client. This method is scientifically valuable because it enables much longer simulation trajectories to be performed in the same amount of time, and reduces the traditional difficulties of scaling a large simulation to many separate processors. A 2007 publication in the Journal of Molecular Biology relied on multi-core processing to simulate the folding of part of the villin protein approximately 10 times longer than was possible with a single-processor client, in agreement with experimental folding rates.
In November 2006, first-generation symmetric multiprocessing (SMP) clients were publicly released for open beta testing, referred to as SMP1. These clients used Message Passing Interface (MPI) communication protocols for parallel processing, as at that time the GROMACS cores were not designed to be used with multiple threads. This was the first time a distributed computing project had used MPI. Although the clients performed well in Unix-based operating systems such as Linux and macOS, they were troublesome under Windows. On January 24, 2010, SMP2, the second generation of the SMP clients and the successor to SMP1, was released as an open beta and replaced the complex MPI with a more reliable thread-based implementation.
SMP2 supports a trial of a special category of bigadv work units, designed to simulate proteins that are unusually large and computationally intensive and have a great scientific priority. These units originally required a minimum of eight CPU cores, which was raised to sixteen later, on February 7, 2012. Along with these added hardware requirements over standard SMP2 work units, they require more system resources such as random-access memory (RAM) and Internet bandwidth. In return, users who run these are rewarded with a 20% increase over SMP2's bonus point system. The bigadv category allows Folding@home to run especially demanding simulations for long times that had formerly required use of supercomputing clusters and could not be performed anywhere else on Folding@home. Many users with hardware able to run bigadv units have later had their hardware setup deemed ineligible for bigadv work units when CPU core minimums were increased, leaving them only able to run the normal SMP work units. This frustrated many users who invested significant amounts of money into the program only to have their hardware be obsolete for bigadv purposes shortly after. As a result, Pande announced in January 2014 that the bigadv program would end on January 31, 2015.
V7
The V7 client is the seventh and latest generation of the Folding@home client software, and is a full rewrite and unification of the prior clients for Windows, macOS, and Linux operating systems. It was released on March 22, 2012. Like its predecessors, V7 can run Folding@home in the background at a very low priority, allowing other applications to use CPU resources as they need. It is designed to make the installation, start-up, and operation more user-friendly for novices, and offer greater scientific flexibility to researchers than prior clients. V7 uses Trac for managing its bug tickets so that users can see its development process and provide feedback.
V7 consists of four integrated elements. The user typically interacts with V7's open-source GUI, named FAHControl. This has Novice, Advanced, and Expert user interface modes, and has the ability to monitor, configure, and control many remote folding clients from one computer. FAHControl directs FAHClient, a back-end application that in turn manages each FAHSlot (or slot). Each slot acts as replacement for the formerly distinct Folding@home v6 uniprocessor, SMP, or GPU computer clients, as it can download, process, and upload work units independently. The FAHViewer function, modeled after the PS3's viewer, displays a real-time 3-D rendering, if available, of the protein currently being processed.
Google Chrome
In 2014, a client for the Google Chrome and Chromium web browsers was released, allowing users to run Folding@home in their web browser. The client used Google's Native Client (NaCl) feature on Chromium-based web browsers to run the Folding@home code at near-native speed in a sandbox on the user's machine. Due to the phasing out of NaCL and changes at Folding@home, the web client was permanently shut down in June 2019.
Android
In July 2015, a client for Android mobile phones was released on Google Play for devices running Android 4.4 KitKat or newer.
On February 16, 2018, the Android client, which was offered in cooperation with Sony, was removed from Google Play. Plans were announced to offer an open source alternative in the future.
Comparison to other molecular simulators
Rosetta@home is a distributed computing project aimed at protein structure prediction and is one of the most accurate tertiary structure predictors. The conformational states from Rosetta's software can be used to initialize a Markov state model as starting points for Folding@home simulations. Conversely, structure prediction algorithms can be improved from thermodynamic and kinetic models and the sampling aspects of protein folding simulations. As Rosetta only tries to predict the final folded state, and not how folding proceeds, Rosetta@home and Folding@home are complementary and address very different molecular questions.
Anton is a special-purpose supercomputer built for molecular dynamics simulations. In October 2011, Anton and Folding@home were the two most powerful molecular dynamics systems. Anton is unique in its ability to produce single ultra-long computationally costly molecular trajectories, such as one in 2010 which reached the millisecond range. These long trajectories may be especially helpful for some types of biochemical problems. However, Anton does not use Markov state models (MSM) for analysis. In 2011, the Pande lab constructed a MSM from two 100-μs Anton simulations and found alternative folding pathways that were not visible through Anton's traditional analysis. They concluded that there was little difference between MSMs constructed from a limited number of long trajectories or one assembled from many shorter trajectories. In June 2011 Folding@home added sampling of an Anton simulation in an effort to better determine how its methods compare to Anton's. However, unlike Folding@home's shorter trajectories, which are more amenable to distributed computing and other parallelizing methods, longer trajectories do not require adaptive sampling to sufficiently sample the protein's phase space. Due to this, it is possible that a combination of Anton's and Folding@home's simulation methods would provide a more thorough sampling of this space.
See also
- BOINC
- DreamLab, for use on smartphones
- Foldit
- List of distributed computing projects
- Comparison of software for molecular mechanics modeling
- Molecular modeling on GPUs
- SETI@home
- Storage@home
- Molecule editor
- Volunteer computing
- World Community Grid
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{{citation}}
: CS1 maint: numeric names: authors list (link) - Pande, Vijay S. (November 10, 2008), "Re: ATI and NVIDIA stats vs. PPD numbers", Folding Forum, the fifth post from below, archived from the original on March 31, 2012, retrieved April 26, 2020
External links
Listen to this article (1 hour and 13 minutes) This audio file was created from a revision of this article dated 7 October 2014 (2014-10-07), and does not reflect subsequent edits.(Audio help · More spoken articles)Health software | |||||||||||||
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Categories:
- Bioinformatics
- Computational biology
- Computational chemistry
- 2000 software
- Cross-platform software
- Data mining and machine learning software
- Distributed computing projects
- Hidden Markov models
- Mathematical and theoretical biology
- Medical technology
- Medical research organizations
- Molecular dynamics software
- Molecular modelling
- Molecular modelling software
- PlayStation 3 software
- Proprietary cross-platform software
- Protein folds
- Protein structure
- Simulation software
- Science software for Linux
- Science software for macOS
- Science software for Windows
- University of Pennsylvania