Physical Laboratory Automation in Synthetic Biology

Stephenson, Ashley; Lastra, Lauren; Nguyen, Bichlien; Chen, Yuan-Jyue; Nivala, Jeff; Ceze, Luis; Strauss, Karin

doi:10.1021/acssynbio.3c00345

Cited by 4 publications

(2 citation statements)

References 81 publications

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“…Fortunately, this need arises in conjunction with the availability of liquid-handling robots that have enabled increased throughput with less human labor and reduced potential for error 24 , 25 . Considerable development in this area has been seen in the commercial sector with automation systems available at a wide range of prices.…”

Section: Mainmentioning

confidence: 99%

Enabling high-throughput enzyme discovery and engineering with a low-cost, robot-assisted pipeline

Norton-Baker,

Denton,

Murphy

et al. 2024

Sci Rep

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As genomic databases expand and artificial intelligence tools advance, there is a growing demand for efficient characterization of large numbers of proteins. To this end, here we describe a generalizable pipeline for high-throughput protein purification using small-scale expression in E. coli and an affordable liquid-handling robot. This low-cost platform enables the purification of 96 proteins in parallel with minimal waste and is scalable for processing hundreds of proteins weekly per user. We demonstrate the performance of this method with the expression and purification of the leading poly(ethylene terephthalate) hydrolases reported in the literature. Replicate experiments demonstrated reproducibility and enzyme purity and yields (up to 400 µg) sufficient for comprehensive analyses of both thermostability and activity, generating a standardized benchmark dataset for comparing these plastic-degrading enzymes. The cost-effectiveness and ease of implementation of this platform render it broadly applicable to diverse protein characterization challenges in the biological sciences.

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Section: Mainmentioning

confidence: 99%

Enabling high-throughput enzyme discovery and engineering with a low-cost, robot-assisted pipeline

Norton-Baker,

Denton,

Murphy

et al. 2024

Sci Rep

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“…Also, field-driven nanorobots using magnetic and electric force were reported for automated and efficient assays. − Additionally, our group and others have introduced the robotic-assisted platforms, where the world-to-chip interface integrates microfluidic chips on the end effector of robots for automated molecular tests and cell manipulation, , instead of the standard well plates utilized in the commercially available pipetting workstations (e.g., Tecan, Beckman, Opentron, GenMark, etc. ). − Notably, compared to the electro-wetting and microvalve actuation platforms, the robotic systems provide several distinctive benefits, such as programmed paths and free motion over five axes to operate in broader working conditions and the ease of use microfluidic chips without specific needs of surfactants . The combination of robot and microfluidics allows for high-throughput sample processing at a minimal footprint and is more suitable for resource-limited settings.…”

mentioning

confidence: 99%

Multicolor-Assay-on-a-Chip Processed by Robotic Operation (MACpro) with Improved Diagnostic Accuracy for Field-Deployable Detection

Liu,

Cheng,

Pan

et al. 2024

Anal. Chem.

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The ability to deploy decentralized laboratories with autonomous and reliable disease diagnosis holds the potential to deliver accessible healthcare services for public safety. While microfluidic technologies provide precise manipulation of small fluid volumes with improved assay performance, their limited automation and versatility confine them to laboratories. Herein, we report the utility of multicolor assay-on-a-chip processed by robotic operation (MACpro), to address this unmet need. The MACpro platform comprises a robot-microfluidic interface and an eye-in-hand module that provides flexible yet stable actions to execute tasks in a programmable manner, such as the precise manipulation of the microfluidic chip along with different paths. Notably, MACpro shows improved detection performance by integrating the microbead-based antibody immobilization with enhanced target recognition and multicolor sensing via Cu2+-catalyzed plasmonic etching of gold nanorods for rapid and sensitive analyte quantification. Using interferon-gamma as an example, we demonstrate that MACpro completes a sample-to-answer immunoassay within 30 min and achieves a 10-fold broader dynamic range and a 10-fold lower detection limit compared to standard enzyme-linked immunosorbent assays (0.66 vs 5.2 pg/mL). MACpro extends the applications beyond traditional laboratories and presents an automated solution to expand diagnostic capacity in diverse settings.

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Robot-assisted phenotyping of a Corynebacterium strain library towards valorization of next-generation feedstocks

Weiß,

Hartmann,

Seibold

2024

Bioresource Technology Reports

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Physical Laboratory Automation in Synthetic Biology

Cited by 4 publications

References 81 publications

Enabling high-throughput enzyme discovery and engineering with a low-cost, robot-assisted pipeline

Enabling high-throughput enzyme discovery and engineering with a low-cost, robot-assisted pipeline

Multicolor-Assay-on-a-Chip Processed by Robotic Operation (MACpro) with Improved Diagnostic Accuracy for Field-Deployable Detection

Robot-assisted phenotyping of a Corynebacterium strain library towards valorization of next-generation feedstocks

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