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In the Taylor lab we develop dynamic micro- and nanosystems for enabling novel applications in biometry, force spectroscopy, and cardiovascular biomechanics. For our nanoscale work we use structural DNA nanotechnology to build nanobiosensors that are undergo global shape change upon binding. At the microscale we are interested in developing strategies to allow our systems to assemble and actuate without hands-on (serial) fabrication. We are currently using stretch to drive folding and actuation in elastomeric microstructures.
We are also looking at how DNA nanosystems can act as adapters to facilitate microscale assembly. For instance, we are working to fabricate articulated microdevices wherein connectors made using structural DNA nanotechnology control the assembly of a larger microsystem.
Research Interests: microsystems; nanotechnology; DNA origami; biomechanics; nanobiosensors
We are also looking at how DNA nanosystems can act as adapters to facilitate microscale assembly. For instance, we are working to fabricate articulated microdevices wherein connectors made using structural DNA nanotechnology control the assembly of a larger microsystem.
Research Interests: microsystems; nanotechnology; DNA origami; biomechanics; nanobiosensors
研究兴趣
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Weitao Wang, Bhavya Chopra, Vismaya Walawalkar, Zijuan Liang, Rebekah Adams,Markus Deserno,Xi Ren,Rebecca E. Taylor
JOURNAL OF MECHANICAL DESIGNno. 5 (2024)
biorxiv(2023)
2023 22nd International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers)pp.2141-2144, (2023)
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APL bioengineeringno. 4 (2020): 041507-041507
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