用于生物晶体学实验的先进光束线自动化技术。

Advanced beamline automation for biological crystallography experiments.

作者信息

Cork Carl, O'Neill James, Taylor John, Earnest Thomas

机构信息

Physical Biosciences Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA.

出版信息

Acta Crystallogr D Biol Crystallogr. 2006 Aug;62(Pt 8):852-8. doi: 10.1107/S0907444906014120. Epub 2006 Jul 18.

DOI:10.1107/S0907444906014120

PMID:16855300

Abstract

An automated crystal-mounting/alignment system has been developed at Lawrence Berkeley National Laboratory and has been installed on three of the protein-crystallography experimental stations at the Advanced Light Source (ALS); it is currently being implemented at synchrotron crystallography beamlines at CHESS, NSLS and the APS. The benefits to using an automounter system include (i) optimization of the use of synchrotron beam time, (ii) facilitation of advanced data-collection techniques, (iii) collection of higher quality data, (iv) reduction of the risk to crystals and (v) exploration of systematic studies of experimental protocols. Developments on the next-generation automounter with improvements in robustness, automated alignment and sample tracking are under way, with an end-to-end data-flow process being developed to allow remote data collection and monitoring.

摘要

劳伦斯伯克利国家实验室开发了一种自动晶体安装/对准系统，并已安装在先进光源（ALS）的三个蛋白质晶体学实验站上；目前正在康奈尔高能同步加速器源（CHESS）、国家同步加速器光源（NSLS）和阿贡国家实验室先进光子源（APS）的同步加速器晶体学光束线上实施。使用自动安装系统的好处包括：（i）优化同步加速器光束时间的使用；（ii）便于采用先进的数据收集技术；（iii）收集更高质量的数据；（iv）降低晶体受损风险；（v）探索实验方案的系统研究。下一代自动安装器在稳健性、自动对准和样品跟踪方面的改进正在进行中，同时正在开发一个端到端的数据流过程，以实现远程数据收集和监测。

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用于生物晶体学实验的先进光束线自动化技术。

Advanced beamline automation for biological crystallography experiments.

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