Research Paper Study

Myoungseok's Research Paper Study (RPS)

[ RPS I (01 - 50) ] [ RPS II (51 - Present) ] (In a wide view)

* Summarizing an interesting paper in a single page

* Including Key points, Not all data

[73] Liu, W., et al., & Gang, O. (2016). Nature chemistry, 8(9), 867-873.

[72] Pumm, A. K., et al., & Dietz, H. (2022). Nature, 607(7919), 492-498.

[71] Shi, X., et al., & Dekker, C. (2024). Nature Nanotechnology, 19(3), 338-344.

[70] Hayakawa, D., et al., & Rogers, W. B. (2024). arXiv preprint:2403.19518.

[69] Liu, X., et al., & Fan, C. (2018). Nature, 559(7715), 593-598.

[68] Grossi, G., et al., & Ebbe, S., A. (2017). Nature communications, 8(1), 992.

[67] Aksel, T., et al., & Douglas, S. M. (2021). Nature biotechnology, 39(3), 378-386.

[66] Ye, J., et al, & Seidel, R. (2019). Nano Letters, 19(4), 2707-2714.

[65] Ke, Y., et al. & Shih, W. M. (2012). JACS, 134(3), 1770-1774

[64] Stömmer, P., et al. & Dietz, H. (2021). Nature Communications, 12(1), 4393.

[63] Shrestha, P., et al. & Mao, H. (2016). Nucleic acids research, 44(14), 6574-6582.

[62] Kilwing, L., et al & Shih, W. M. (2023). ACS nano, 18(1), 885-893.

[61] Shaw, A., et al. & Bustamante, C. (2021). bioRxiv, 2021-11.

[60] Bayrak, T., et al. & Seidel, R. (2018). Nano letters, 18(3), 2116-2123.

[59] Sarraf, N., et al. & Qian, L. (2023). Science Robotics, 8(77), eadf1511.

[58] Pfitzner, E., et al. (2013). Angewandte Chemie International Edition, 52(30), 7766-7771.

[57] Jung, W. H., et al. (2020). Nucleic acids research, 48(21), 12407-12414.

[56] Sobczak, J. P. J., et al., & Dietz, H. (2012). Science, 338(6113), 1458-1461.

[55] Kilchherr, F., et al., & Dietz, H. (2016). Science, 353(6304), aaf5508.

[54] Kosuri, P., et al, Yin, P., & Zhuang, X. (2019). Nature, 572(7767), 136-140.

[53] Kretzmann, J. A., et al, & Dietz, H. (2023). Nature Communications, 14(1), 1017.

[52] Sun, W., et al, & Yin, P. (2014). Science, 346(6210), 1258361.

[51] Jungmann, R., et al., W. M., & Yin, P. (2014). Nature methods, 11(3), 313-318.

[50] Zhang, T., et al. & Liedl, T. (2018). Advanced Materials, 30(28), 1800273.

[49] Han, D., et al. (2011). Science, 332(6027), 342-346.

[48] Fu, D., et al. (2022). Science Advances, 8(51), eade4455.

[47] Trofymchuk, K., et al. (2021). Nature communications, 12(1), 1-8. & Trofymchuk, K., et al. (2023). ACS nano.

[46] Acuna, G. P., et al. (2012). Science, 338(6106), 506-510.

[45] Tikhomirov, G., et al. (2018). Journal of the American Chemical Society, 140(50), 17361-17364.

[44] Woo, S., & Rothemund, P. W. (2011). Nature chemistry, 3(8), 620-627.

[43] Suzuki, Y., et al. (2015). Nature communications, 6(1), 1-9.

[42] Woods, D., et al. (2019). Nature, 567(7748), 366-372.

[41] Minev, D., et al. (2021). Nature communications, 12(1), 1-9. / Wintersinger, C. M., et al. (2022). bioRxiv.

[40] Zhan, P., and Urban, M. J., et al. Science advances, 5(11), eaax6023.

[39] Roller, Eva-Maria, et al. Nature physics 13.8 (2017): 761-765.

[38] Kuzyk, Anton, et al. Nature materials 13.9 (2014): 862-866.

[37] Kuzyk, Anton, et al. Nature 483.7389 (2012): 311-314.

[36] Tikhomirov, Grigory, et al. Nature nanotechnology 12.3 (2017): 251-259.

[35] Gerling, Thomas, et al. Science Advances 4.8 (2018): eaau1157.

[34] Zhang, Cheng, et al. Science Advances 8.5 (2022): eabl4589.

[33] Sigl, Christian, et al. Nature materials 20.9 (2021): 1281-1289.

[32] Sun, Wei, et al. Science 368.6493 (2020): 874-877.

[31] Jun, Hyungmin, et al. Nucleic acids research 49.18 (2021): 10265-10274.

[30] Song, Tianqi, et al. Nature nanotechnology 14.11 (2019): 1075-1081.

[29] Llano, Elisa, et al. Nucleic acids research 48.15 (2020): 8269-8275.

[28] Heath, George R, et al. Nature 594.7863 (2021): 385-390.

[27] Gopinath, Ashwin, et al. Nature 535.7612 (2016): 401-405.

[26] Zhang, Yinan, et al. Nature communications 10.1 (2019): 1-8.

[25] Song, Jie, et al. Science 357.6349 (2017).

[24] Kopperger, Enzo, et al. Science 359.6373 (2018): 296-301.

[23] Nakazawa, Koyomi, et al. Angewandte Chemie 133.28 (2021): 15342-15347.

[22] Zhou, Lifeng, et al. Small 14.47 (2018): 1802580.

[21] Yao, Guangbao, et al. Nature chemistry 12.11 (2020): 1067-1075.

[20] Gopinath, Ashwin, et al. Science 371.6531 (2021).

[19] Tikhomirov, Grigory, et al. Nature 552.7683 (2017): 67-71.

[18] Wagenbauer, Klaus F., et al. Nature 552.7683 (2017): 78-83.

[17] Funke, Jonas J., et al. Nature nanotechnology 11.1 (2016): 47-52.

[16] Ke, Yonggang, et al. Chemical science 3.8 (2012): 2587-2597.

[15] Pan, Jinbo, et al. Angewandte Chemie International Edition 60.13 (2021): 7165-7173.

[14] Petersen, Philip, et al. Nature communications 9.1 (2018): 1-10.

[13] Lee, Jae Young, et al. ACS nano 15.1 (2021): 1002-1015.

[12] Jun, Hyungmin, et al. Science advances 5.1 (2019): eaav0655.

[11] Dietz, Hendrik, et al. Science 325.5941 (2009): 725-730.

[10] Yang, Jhen-Hong, et al. ACS nano 14.5 (2020): 5678-5685.

[9] Engel, Megan C., et al. Journal of Chemical Theory and Computation 16.12 (2020): 7764-7775.

[8] Veneziano, Rémi, et al. Nature nanotechnology 15.8 (2020): 716-723.

Liu, Shaoli, et al. Nature Materials 20.3 (2021): 421-430.

Ge, Zhilei, et al. Journal of the American Chemical Society 142.19 (2020): 8800-8808.

[7] Gerling, Thomas, et al. Science 347.6229 (2015): 1446-1452.

[6] Marin-Gonzalez, Alberto, et al. Physical review letters 122.4 (2019): 048102.

[5] Ma, Jie, et al. Science 340.6140 (2013): 1580-1583.

[4] Camunas-Soler, et al. Annual review of biophysics 45 (2016): 65-84.

[3] Shin, Yongdae, et al. Science 357.6357 (2017).

[1][2] Goodman, Russell P., et al. ChemBioChem 10.9 (2009): 1551-1557.

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