(*通讯作者):
1. Zhou, L., “DNA Mechanisms and Machines for Nanorobotics,” invited book chapter for “Encyclopedia of Robotics”, Springer, 2021, Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-41610-1_217-1
2. Xiong, Y., Huang, Q., Canady, T. D., Barya, P., Liu, S., Arogundade, O. H., Race, C. M., Che, C., Wang, X., Zhou, L., Wang, X., Kohli, M., Smith, A. M., and Cunningham, B. T., 2022, “Photonic Crystal Enhanced Fluorescence Emission and Blinking Suppression for Single Quantum Dot Digital Resolution Biosensing,” Nat Commun, 13(1), p. 4647.
3. Zhou, L., Hayden, A., Chandrasekaran, A. R., Vilcapoma, J., Cavaliere, C., Dey, P., Mao, S., Sheng, J., Dey, B. K., Rangan, P., and Halvorsen, K., 2021 “Sequence-selective purification of biological RNAs using DNA nanoswitches,” Cell Reports Methods. 1(8), p. 100126 (Cover Article)
4. Zhou, L.*, Valsangkar V. A., Yan, M., Chandrasekaran, R. A., Feldblyum, J. I., R., Sheng, J., and Halvorsen, K.*, 2021, “A mini DNA-RNA Hybrid Origami Nanobrick,” Nanoscale Advances, D1NA00026H,
5. Punnoose, J. A., Hayden, A., Zhou, L., and Halvorsen, K., 2020, “A Wi-Fi Live Streaming Centrifuge Force Microscope for Benchtop Single-Molecule Experiments,” Biophysical Journal, 119(11), p. 2231-2239.
6. Zhou, L.; Chandrasekaran, A. R.; Punnoose, J. A.; Bonenfant, G.; Charles, S.; Levchenko, O.; Badu, P.; Cavaliere, C.; Pager, C. T.; Halvorsen, K. Programmable Low-Cost DNA-Based Platform for Viral RNA Detection. Science Advances 2020, eabc6246.
7. Zhou, L., Marras, A. E., Huang, C.-M., Castro, C. E., and Su, H.-J., 2018, “Paper Origami-Inspired Design and Actuation of DNA Nanomachines with Complex Motions,” Small, 14(47), p. e1802580.
8. Lei, D., Marras, A. E., Liu, J., Huang, C.-M., Zhou, L., Castro, C. E., Su, H.-J., and Ren, G., 2018, “Three-Dimensional Structural Dynamics of DNA Origami Bennett Linkages Using Individual-Particle Electron Tomography,” Nat. Commun., 9(1), p. 592.
9. Zhou, L., Su, H.-J., Marras, A. E., Huang, C.-M., and Castro, C. E., 2016, “Projection kinematic analysis of DNA origami mechanisms based on a two-dimensional TEM image,” Mech. Mach. Theory, 109, pp. 22–38.
10.Zhou L., Marras A. E., Castro, CE, Su, H., 2016, “Pseudorigid-Body Models of Compliant DNA Origami Mechanisms”. ASME. J. Mechanisms Robotics, 8(5):051013-051013-11. doi:10.1115/1.4032213.
11.Zhou, L., Marras, A. E., Su, H.-J, and Castro, C. E., 2015, “Direct design of an energy landscape with bistable DNA origami mechanisms,” Nano Lett., 15 (3), pp. 1815–1821.
12.Marras, A. E., Zhou, L., Su, H.-J., and Castro, C. E., 2015, “Programmable motion of DNA origami mechanisms,” Proc. Natl. Acad. Sci., 112, pp. 713–718.
13.Zhou, L., Marras, A. E., Su, H.-J., and Castro, C. E., 2013, “DNA Origami Compliant Nanostructures with Tunable Mechanical Properties,” ACS nano, 8, pp. 27–34.