Abstract
Increasingly, microbeams and microcrystals are being used for macromolecular crystallography (MX) experiments at synchrotrons. However, radiation damage remains a major concern since it is a fundamental limiting factor affecting the success of macromolecular structure determination. The rate of radiation damage at cryotemperatures is known to be proportional to the absorbed dose, so to optimize experimental outcomes, accurate dose calculations are required which take into account the physics of the interactions of the crystal constituents. The program RADDOSE‐3D estimates the dose absorbed by samples during MX data collection at synchrotron sources, allowing direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has aided the study of MX radiation damage and enabled prediction of approximately when it will manifest in diffraction patterns so it can potentially be avoided. However, the probability of photoelectron escape from the sample and entry from the surrounding material has not previously been included in RADDOSE‐3D, leading to potentially inaccurate does estimates for experiments using microbeams or microcrystals. We present an extension to RADDOSE‐3D which performs Monte Carlo simulations of a rotating crystal during MX data collection, taking into account the redistribution of photoelectrons produced both in the sample and the material surrounding the crystal. As well as providing more accurate dose estimates, the Monte Carlo simulations highlight the importance of the size and composition of the surrounding material on the dose and thus the rate of radiation damage to the sample. Minimizing irradiation of the surrounding material or removing it almost completely will be key to extending the lifetime of microcrystals and enhancing the potential benefits of using higher incident X‐ray energies.
Highlights
Radiation damage, which has been a major concern in MX for over 50 years,[1] is caused as X-rays deposit energy in the sample as they interact with it through the photoelectric and Compton effects
This paper reports an extension of RADDOSE-3D to perform full Monte Carlo simulations of a rotating crystal during MX experiments, which comprehensibly track the path and energy loss of photoelectrons and Compton recoil electrons produced both in the crystal and the surrounding material
A comparison of the dose calculated by RADDOSE-3D Monte Carlo simulations for different oil based cryoprotectants (Table 1) shows that simulations of two of the three oil based cryoprotectants resulted in a lower dose than pure water, with polyphenyl ether and polyisobutylene having a 25% and 46% lower ADER, respectively
Summary
Radiation damage, which has been a major concern in MX for over 50 years,[1] is caused as X-rays deposit energy in the sample as they interact with it through the photoelectric and Compton effects. This paper reports an extension of RADDOSE-3D to perform full Monte Carlo simulations of a rotating crystal during MX experiments, which comprehensibly track the path and energy loss of photoelectrons and Compton recoil electrons produced both in the crystal and the surrounding material. This version (version 4), which includes an option for estimating time-resolved doses for experiments using femtosecond pulses at Free Electron Lasers[24] supersedes previous releases of the software. Output is a “RADDOSE-3D style” dose calculated analytically from the relevant equations, where all energy from the photoelectric and Compton effects
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
