Non-Contact Universal Sample Presentation for Room Temperature Macromolecular Crystallography Using Acoustic Levitation

Morris, Robert H.; Dye, E.; Axford, Danny; Newton, Michael I.; Beale, John; Docker, Peter

doi:10.1038/s41598-019-48612-4

Cited by 18 publications

(17 citation statements)

References 36 publications

(36 reference statements)

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“…Being non-contact ADE has distinct advantages in liquid handling and has found great application throughout the crystallography pipeline starting from crystallization [150], microseeding [151], and ligand soaking [152][153][154] to crystal mounting [155,156]. Since droplets are ejected at a frequency compatible with the repetition rate of first generation XFEL facilities, ADE has also been utilized as a sample delivery method at both XFEL and synchrotron [157][158][159][160]. By altering the transducer's frequency, the volume of ejected droplets can be tuned to accommodate different sizes of crystals from 5 to 800 µm [160,161].…”

Section: Drop-on-demand-potential To Maximize Sample Efficiencymentioning

confidence: 99%

“…Since droplets are ejected at a frequency compatible with the repetition rate of first generation XFEL facilities, ADE has also been utilized as a sample delivery method at both XFEL and synchrotron [157][158][159][160]. By altering the transducer's frequency, the volume of ejected droplets can be tuned to accommodate different sizes of crystals from 5 to 800 µm [160,161]. Ejected droplets carry significant volumes of mother liquor [157], which contributes to more background compared to jet or fixed-target chip [157].…”

Section: Drop-on-demand-potential To Maximize Sample Efficiencymentioning

confidence: 99%

“…This requires very high accuracy and precision in the ejection trajectory and timing [157]. Alternatively, ejected droplets could be trapped in pressure node and levitated into mid-air using a reflector [159,160]. This maintains the position of the droplet while being probed by X-rays.…”

Section: Drop-on-demand-potential To Maximize Sample Efficiencymentioning

confidence: 99%

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Towards an Optimal Sample Delivery Method for Serial Crystallography at XFEL

Cheng¹

2020

Crystals

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The advent of the X-ray free electron laser (XFEL) in the last decade created the discipline of serial crystallography but also the challenge of how crystal samples are delivered to X-ray. Early sample delivery methods demonstrated the proof-of-concept for serial crystallography and XFEL but were beset with challenges of high sample consumption, jet clogging and low data collection efficiency. The potential of XFEL and serial crystallography as the next frontier of structural solution by X-ray for small and weakly diffracting crystals and provision of ultra-fast time-resolved structural data spawned a huge amount of scientific interest and innovation. To utilize the full potential of XFEL and broaden its applicability to a larger variety of biological samples, researchers are challenged to develop better sample delivery methods. Thus, sample delivery is one of the key areas of research and development in the serial crystallography scientific community. Sample delivery currently falls into three main systems: jet-based methods, fixed-target chips, and drop-on-demand. Huge strides have since been made in reducing sample consumption and improving data collection efficiency, thus enabling the use of XFEL for many biological systems to provide high-resolution, radiation damage-free structural data as well as time-resolved dynamics studies. This review summarizes the current main strategies in sample delivery and their respective pros and cons, as well as some future direction.

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Section: Drop-on-demand-potential To Maximize Sample Efficiencymentioning

confidence: 99%

Section: Drop-on-demand-potential To Maximize Sample Efficiencymentioning

confidence: 99%

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Towards an Optimal Sample Delivery Method for Serial Crystallography at XFEL

Cheng¹

2020

Crystals

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“…In sample presentation scenarios however, the shape of the droplet can be an important factor which directly impacts the results. Consequently, there is an increasing shift from awareness towards control of droplet shape by balancing the confinement potential of the acoustic field against the forces applied to the droplets to maximise sphericity, for example in Non-Contact Universal Sample Presentation for Room Temperature Macromolecular Crystallography Using Acoustic Levitation [50] the droplet sphericity as a function of voltage applied to the TinyLev system was determined and optimised to balance these key parameters.…”

Section: New Perspectives -The Future Of Acoustic Levitation Of Liquidsmentioning

confidence: 99%

“…In recent publications such as [50] this new era of low-cost phased array ultrasonic levitation devices are beginning to find use in sample presentation to non-contact measurement techniques in applications previously making use of Langevin horns [51]. This facilitates containerless, background free spectroscopy which ushers in a new wave of experimental techniques and brings with it significant advantages in terms of measurement resolution without imparting significant energy into the sample.…”

Section: New Perspectives -The Future Of Acoustic Levitation Of Liquidsmentioning

confidence: 99%

Beyond the Langevin horn: Transducer arrays for the acoustic levitation of liquid drops

et al. 2019

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The acoustic levitation of liquid drops has been a key phenomenon for more than 40 years, driven partly by the ability to mimic a microgravity environment. It has seen more than 700 research articles published in this time and has seen a recent resurgence in the past 5 years thanks to low cost developments. As well as investigating the basic physics of levitated drops, acoustic levitation has been touted for container free delivery of samples to a variety of measurements systems, most notably in various spectroscopy techniques including Raman, Fourier Transform InfraRed (FTIR) in addition to numerous X-Ray techniques. For 30 years the workhorse of the acoustic levitation apparatus was a stack comprising a piezoelectric transducer coupled to a horn shaped radiative element often referred to as the Langevin horn. Decades of effort have been dedicated to such devices, paired with a matching and opposing device or a reflector, but they have a significant dependence on temperature and require precision alignment. The last decade has seen a significant shift away from these in favour of arrays of digitally driven, inexpensive transducers, giving a new dynamic to the topic which we review herein.

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Elevating Chemistry Research with a Modern Electronics Toolkit

Prabhu

Urban

2020

Chem. Rev.

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With the rapid development of high technology, chemical science is not as it used to be a century ago. Many chemists acquire and utilize skills that are well beyond the traditional definition of chemistry. The digital age has transformed chemistry laboratories. One aspect of this transformation is the progressing implementation of electronics and computer science in chemistry research. In the past decade, numerous chemistry-oriented studies have benefited from the implementation of electronic modules, including microcontroller boards (MCBs), single-board computers (SBCs), professional grade control and data acquisition systems, as well as field-programmable gate arrays (FPGAs). In particular, MCBs and SBCs provide good value for money. The application areas for electronic modules in chemistry research include construction of simple detection systems based on spectrophotometry and spectrofluorometry principles, customizing laboratory devices for automation of common laboratory practices, control of reaction systems (batch- and flow-based), extraction systems, chromatographic and electrophoretic systems, microfluidic systems (classical and nonclassical), custom-built polymerase chain reaction devices, gas-phase analyte detection systems, chemical robots and drones, construction of FPGA-based imaging systems, and the Internet-of-Chemical-Things. The technology is easy to handle, and many chemists have managed to train themselves in its implementation. The only major obstacle in its implementation is probably one’s imagination.

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Non-Contact Universal Sample Presentation for Room Temperature Macromolecular Crystallography Using Acoustic Levitation

Cited by 18 publications

References 36 publications

Towards an Optimal Sample Delivery Method for Serial Crystallography at XFEL

Towards an Optimal Sample Delivery Method for Serial Crystallography at XFEL

Beyond the Langevin horn: Transducer arrays for the acoustic levitation of liquid drops

Elevating Chemistry Research with a Modern Electronics Toolkit

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