Automated electrotransformation of <i>Escherichia coli</i> on a digital microfluidic platform using bioactivated magnetic beads

Moore, James A.; Nemat‐Gorgani, Mohsen; Madison, Andrew C.; Sandahl, Melissa; Punnamaraju, Srikoundinya; Eckhardt, Allen E.; Pollack, Martha E.; Vigneault, Frederic; Church, George M.; Fair, Richard B.; Horowitz, Mark; Griffin, P.B.

doi:10.1063/1.4975391

Cited by 18 publications

(21 citation statements)

References 46 publications

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“…Synthetic biology : Using OpenDrop to transform bacteria cells. Recently, researchers have proven that E. coli can be transformed on an electromicrofluidic platform by using magnetic beads [ 54 ]. We are aware of several research laboratories that are pushing the boundaries further as in trying to adapt the existing DIY kits for CRISPR/CAS9.…”

Section: Resultsmentioning

confidence: 99%

OpenDrop: An Integrated Do-It-Yourself Platform for Personal Use of Biochips

Alistar¹,

Gaudenz²

2017

Bioengineering

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Biochips, or digital labs-on-chip, are developed with the purpose of being used by laboratory technicians or biologists in laboratories or clinics. In this article, we expand this vision with the goal of enabling everyone, regardless of their expertise, to use biochips for their own personal purposes. We developed OpenDrop, an integrated electromicrofluidic platform that allows users to develop and program their own bio-applications. We address the main challenges that users may encounter: accessibility, bio-protocol design and interaction with microfluidics. OpenDrop consists of a do-it-yourself biochip, an automated software tool with visual interface and a detailed technique for at-home operations of microfluidics. We report on two years of use of OpenDrop, released as an open-source platform. Our platform attracted a highly diverse user base with participants originating from maker communities, academia and industry. Our findings show that 47% of attempts to replicate OpenDrop were successful, the main challenge remaining the assembly of the device. In terms of usability, the users managed to operate their platforms at home and are working on designing their own bio-applications. Our work provides a step towards a future in which everyone will be able to create microfluidic devices for their personal applications, thereby democratizing parts of health care.

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Section: Resultsmentioning

confidence: 99%

OpenDrop: An Integrated Do-It-Yourself Platform for Personal Use of Biochips

Alistar¹,

Gaudenz²

2017

Bioengineering

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“…Multiplexed electroporation, however, is difficult to perform on-chip for multiple reasons, including cross contamination, and electrical wiring and footprint limitations. Previous efforts for multiplexing have relied on serial single-plex electroporation, such as flow-through devices with a single electroporation site 10,17,18 , or the number of parallel reactions is limited to less than 10 due to physical constraints of the device configuration and electrical systems 8,19,20 . These are slow, inefficient and low-throughput processes.…”

Section: Electroporation In a Microfluidic Chipmentioning

confidence: 99%

Scalable and Automated CRISPR-Based Strain Engineering Using Droplet Microfluidics

Iwai

Wehrs

Garber

et al. 2021

Preprint

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We present a droplet-based microfluidic system that enables CRISPR-based gene editing and high-throughput screening on chip. The microfluidic device contains a 10 x 10 element array, each element containing sets of electrodes for two electric field actuated operations- electrowetting for merging droplets to mix reagents and electroporation for transformation. It can perform up to 100 genetic modifications in parallel, providing a scalable platform for generating the large number of engineered strains required for combinatorial optimization of genetic pathways and predictable bioengineering. We demonstrate the system's capabilities through CRISPR-based engineering of two test cases- 1) disruption of the function of enzyme galactokinase (galK) in E. coli and 2) targeted engineering of glutamine synthetase gene (glnA) and blue-pigment synthetase (bpsA) enzyme to improve indigoidine production in E. coli.

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“…54 Alternatively, Moore and colleagues modified the Illumina digital microfluidic system with similar electroporation electrodes to enable multiple multiplex automation genetic engineering (MAGE) cycles to deliver DNA into E. coli cells. 55 In addition to droplet transport and mixing by DMF, magnetic beads were bound to the E. coli cells to allow the several washing steps and media transfers required for MAGE. Another technique directly interfaced pin headers with a microfluidic chamber to improve the controllability of and ease of electroporation.…”

Section: Transformation/transfection Of Cellsmentioning

confidence: 99%