Page 144

Notes:

conferenceseries

.com

Volume 10, Issue 8 (Suppl)

J Proteomics Bioinform, an open access journal

ISSN: 0974-276X

Structural Biology 2017

September 18-20, 2017

9

th

International Conference on

Structural Biology

September 18-20, 2017 Zurich, Switzerland

Micro robotics enables non-contact, fully automated protein crystal harvesting

David F Sargent

ETH Zurich, Switzerland

Statement of the Problem:

Most aspects of macromolecular structure determination, from synthesis and purification of

materials, through crystallization, data collection and model building, are highly automated. But the recognition, harvesting

and cryocooling of crystals reminds of a predominantly manual task. Several concepts, including

in situ

crystallography, are

being developed to overcome these difficulties, but frequently impose other restrictions such as data collection strategies. We

are developing hardware and software to support crystal harvesting using standard crystallization procedures, thus avoiding

such limitations.

Methodology & Theoretical Orientation:

We use a magnetically driven mobile, rolling micro robot, the “RodBot”, to locally

move the liquid surrounding crystal. The crystal then passively follows the flow. Crystal position is monitored using low level

UV-light. Transport is controlled using flexible algorithms that allow for error-recovery, following stochastic disturbances.

Findings:

We demonstrated the effectiveness of the technique using crystals of different geometries and densities in a variety

of buffers and cryoprotectants. Even at this developmental stage average harvesting time is reduced compared to manual

operations.

Conclusion & Significance:

This non-destructive, non-contact method allows crystals to be extracted reliably from the growth

droplet in a completely automated process. Harvesting can take place remotely in climate-controlled chambers, ensuring

optimal conditions throughout the process with respect to temperature, humidity and composition of the environment.

Damage to valuable crystals due to operator jitter or fatigue is eliminated. Incorporation into existing robotics setup for sample

handling will also allow increased reproducibility of flash-cooling. Fully automated structure determination pipelines using

well-established techniques are now possible and can yield improved data quality at reduced cost.

Biography

David F Sargent obtained his PhD in Biophysics from the University of Western Ontario, Canada, followed by Postdoctoral studies at the ETH Zurich and the

University of Sydney (Australia). He has extensive experience in macromolecular crystallography at the ETH Zurich, and recently has also been associated with the

Multiscale Robotics Laboratory (ETH Zurich) of Bradley J Nelson. He is one of the founders of MagnebotiX, a spinoff of the ETH, which provides tools for magnetic

propulsion and guidance at the microscopic scale. The work reported above uses this technology to streamline and accelerate the process of macromolecular

crystal structure determination.

david.sargent@magnebotix.com

David F Sargent, J Proteomics Bioinform 2017, 10:8(Suppl)

DOI: 10.4172/0974-276X-C1-0101

Figure1:

Crystal harvesting using the RodBot micro robot (in red

circle). From left: Selecting one of several crystals in a droplet

of a 96-well plate; fluid flow from the approaching RodBot raises

the crystal off the bottom of the droplet and transports the

crystal towards the micro-mount; the crystal is deposited on the

micromount, where upon the crystal can be harvested, flash-

cooled and stored using a robotic arm.