RADDOSE‐XFEL: femtosecond time‐resolved dose estimates for macromolecular X‐ray free‐electron laser experiments

For macromolecular structure determination at synchrotron sources, radiation damage remains a major limiting factor. Estimation of the absorbed dose (J kg−1) during data collection at these sources by programs such as RADDOSE‐3D has allowed direct comparison of radiation damage between experiments c...

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Veröffentlicht in:	Journal of applied crystallography 2020-04, Vol.53 (2), p.549-560
Hauptverfasser:	Dickerson, Joshua L., McCubbin, Patrick T. N., Garman, Elspeth F.
Format:	Artikel
Sprache:	eng
Schlagworte:	computer programs Data collection Diffraction patterns dose Experiments Lasers Macromolecules Mathematical analysis Molecular structure protein crystallography Radiation damage serial femtosecond crystallography Structural damage XFELs X‐ray free‐electron lasers
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creator	Dickerson, Joshua L. McCubbin, Patrick T. N. Garman, Elspeth F.
description	For macromolecular structure determination at synchrotron sources, radiation damage remains a major limiting factor. Estimation of the absorbed dose (J kg−1) during data collection at these sources by programs such as RADDOSE‐3D has allowed direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has enabled prediction of roughly when radiation damage will manifest so it can potentially be avoided. X‐ray free‐electron lasers (XFELs), which produce intense X‐ray pulses only a few femtoseconds in duration, can be used to generate diffraction patterns before most of the radiation damage processes have occurred and hence hypothetically they enable the determination of damage‐free atomic resolution structures. In spite of this, several experimental and theoretical studies have suggested that structures from XFELs are not always free of radiation damage. There are currently no freely available programs designed to calculate the dose absorbed during XFEL data collection. This article presents an extension to RADDOSE‐3D called RADDOSE‐XFEL, which calculates the time‐resolved dose during XFEL experiments. It is anticipated that RADDOSE‐XFEL could be used to facilitate the study of radiation damage at XFELs and ultimately be used prior to data collection so that experimenters can plan their experiments to avoid radiation damage manifesting in their structures. A new extension to RADDOSE‐3D, RADDOSE‐XFEL, is presented. RADDOSE‐XFEL estimates the dose absorbed during macromolecular X‐ray free‐electron laser experiments by tracking physical phenomena on the femtosecond timescale.
doi_str_mv	10.1107/S1600576720000643
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N. ; Garman, Elspeth F.</creator><creatorcontrib>Dickerson, Joshua L. ; McCubbin, Patrick T. N. ; Garman, Elspeth F.</creatorcontrib><description>For macromolecular structure determination at synchrotron sources, radiation damage remains a major limiting factor. Estimation of the absorbed dose (J kg−1) during data collection at these sources by programs such as RADDOSE‐3D has allowed direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has enabled prediction of roughly when radiation damage will manifest so it can potentially be avoided. X‐ray free‐electron lasers (XFELs), which produce intense X‐ray pulses only a few femtoseconds in duration, can be used to generate diffraction patterns before most of the radiation damage processes have occurred and hence hypothetically they enable the determination of damage‐free atomic resolution structures. In spite of this, several experimental and theoretical studies have suggested that structures from XFELs are not always free of radiation damage. There are currently no freely available programs designed to calculate the dose absorbed during XFEL data collection. This article presents an extension to RADDOSE‐3D called RADDOSE‐XFEL, which calculates the time‐resolved dose during XFEL experiments. It is anticipated that RADDOSE‐XFEL could be used to facilitate the study of radiation damage at XFELs and ultimately be used prior to data collection so that experimenters can plan their experiments to avoid radiation damage manifesting in their structures. A new extension to RADDOSE‐3D, RADDOSE‐XFEL, is presented. 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N.</creatorcontrib><creatorcontrib>Garman, Elspeth F.</creatorcontrib><title>RADDOSE‐XFEL: femtosecond time‐resolved dose estimates for macromolecular X‐ray free‐electron laser experiments</title><title>Journal of applied crystallography</title><description>For macromolecular structure determination at synchrotron sources, radiation damage remains a major limiting factor. Estimation of the absorbed dose (J kg−1) during data collection at these sources by programs such as RADDOSE‐3D has allowed direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has enabled prediction of roughly when radiation damage will manifest so it can potentially be avoided. X‐ray free‐electron lasers (XFELs), which produce intense X‐ray pulses only a few femtoseconds in duration, can be used to generate diffraction patterns before most of the radiation damage processes have occurred and hence hypothetically they enable the determination of damage‐free atomic resolution structures. In spite of this, several experimental and theoretical studies have suggested that structures from XFELs are not always free of radiation damage. There are currently no freely available programs designed to calculate the dose absorbed during XFEL data collection. This article presents an extension to RADDOSE‐3D called RADDOSE‐XFEL, which calculates the time‐resolved dose during XFEL experiments. It is anticipated that RADDOSE‐XFEL could be used to facilitate the study of radiation damage at XFELs and ultimately be used prior to data collection so that experimenters can plan their experiments to avoid radiation damage manifesting in their structures. A new extension to RADDOSE‐3D, RADDOSE‐XFEL, is presented. 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N.</creatorcontrib><creatorcontrib>Garman, Elspeth F.</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Journal of applied crystallography</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Dickerson, Joshua L.</au><au>McCubbin, Patrick T. N.</au><au>Garman, Elspeth F.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>RADDOSE‐XFEL: femtosecond time‐resolved dose estimates for macromolecular X‐ray free‐electron laser experiments</atitle><jtitle>Journal of applied crystallography</jtitle><date>2020-04</date><risdate>2020</risdate><volume>53</volume><issue>2</issue><spage>549</spage><epage>560</epage><pages>549-560</pages><issn>1600-5767</issn><issn>0021-8898</issn><eissn>1600-5767</eissn><abstract>For macromolecular structure determination at synchrotron sources, radiation damage remains a major limiting factor. Estimation of the absorbed dose (J kg−1) during data collection at these sources by programs such as RADDOSE‐3D has allowed direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has enabled prediction of roughly when radiation damage will manifest so it can potentially be avoided. X‐ray free‐electron lasers (XFELs), which produce intense X‐ray pulses only a few femtoseconds in duration, can be used to generate diffraction patterns before most of the radiation damage processes have occurred and hence hypothetically they enable the determination of damage‐free atomic resolution structures. In spite of this, several experimental and theoretical studies have suggested that structures from XFELs are not always free of radiation damage. There are currently no freely available programs designed to calculate the dose absorbed during XFEL data collection. This article presents an extension to RADDOSE‐3D called RADDOSE‐XFEL, which calculates the time‐resolved dose during XFEL experiments. It is anticipated that RADDOSE‐XFEL could be used to facilitate the study of radiation damage at XFELs and ultimately be used prior to data collection so that experimenters can plan their experiments to avoid radiation damage manifesting in their structures. 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subjects	computer programs Data collection Diffraction patterns dose Experiments Lasers Macromolecules Mathematical analysis Molecular structure protein crystallography Radiation damage serial femtosecond crystallography Structural damage XFELs X‐ray free‐electron lasers
title	RADDOSE‐XFEL: femtosecond time‐resolved dose estimates for macromolecular X‐ray free‐electron laser experiments
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