Kim:Publications: Difference between revisions
No edit summary |
No edit summary |
||
| Line 35: | Line 35: | ||
<font face="trebuchet ms" size=4 style="color:#001">'''In Progress'''</font> | <font face="trebuchet ms" size=4 style="color:#001">'''In Progress'''</font> | ||
<br><br> | <br><br> | ||
[J66] A. Jiao, N. Trosper, H.S. Yang, J. Tsui, S. Frankel, C.E. Murry, and D.H. Kim#, “Fabrication of scaffold-free, three-dimensional tissues with controllable architecture using a thermoresponsive, nanotopographically-defined platform,” (in review) <br> <br> | [J66] A. Jiao, N. Trosper, H.S. Yang, J. Tsui, S. Frankel, C.E. Murry, and D.H. Kim#, “Fabrication of scaffold-free, three-dimensional tissues with controllable architecture using a thermoresponsive, nanotopographically-defined platform,” (in review) <br> <br> | ||
| Line 46: | Line 45: | ||
[J59] F. Pati, J. Jang, D.H. Ha, D.H. Kim, and D.W. Cho, “Printing three dimensional tissue analog with decellularized extracellular matrix bioink,” '''Nature Communications''', (in revision) <br> <br> | [J59] F. Pati, J. Jang, D.H. Ha, D.H. Kim, and D.W. Cho, “Printing three dimensional tissue analog with decellularized extracellular matrix bioink,” '''Nature Communications''', (in revision) <br> <br> | ||
[J58] C. Nemeth, K. Janebodin, A. E. Yuan, J.E. Dennis, M. Reyes#, and D.H. Kim#, “Enhanced in vitro chondrogenesis of dental pulp stem cells by nanopatterned hyaluronan hydrogels,” '''Tissue Engineering''' (in revision) <br> <br> | [J58] C. Nemeth, K. Janebodin, A. E. Yuan, J.E. Dennis, M. Reyes#, and D.H. Kim#, “Enhanced in vitro chondrogenesis of dental pulp stem cells by nanopatterned hyaluronan hydrogels,” '''Tissue Engineering''' (in revision) <br> <br> | ||
[J57] S. Chaterji, P. Kim, S.H. Choe, J.H. Tsui, A.B. Baker#, and D.H. Kim#, “Synergistic effects of matrix nanotopography and stiffness on vascular smooth muscle cell function,” '''Tissue Engineering''', | [J57] S. Chaterji, P. Kim, S.H. Choe, J.H. Tsui, A.B. Baker#, and D.H. Kim#, “Synergistic effects of matrix nanotopography and stiffness on vascular smooth muscle cell function,” '''Tissue Engineering''', (in revision) <br><br> | ||
[J56] J.H. Kim, H.N. Kim, K.T. Lim, Y. Kim, S. Hoon, S. H. Park, H. J. Lim, D.H. Kim, P.H. Choung, Y.H. Choung, K.Y. Suh, and J.H. Chung, "Designing nanotopographical density of extracellular matrix for controlled morphology and function of human mesencymal stem cells," '''Scientific Reports''', | [J56] J.H. Kim, H.N. Kim, K.T. Lim, Y. Kim, S. Hoon, S. H. Park, H. J. Lim, D.H. Kim, P.H. Choung, Y.H. Choung, K.Y. Suh, and J.H. Chung, "Designing nanotopographical density of extracellular matrix for controlled morphology and function of human mesencymal stem cells," '''Scientific Reports''', (in press) <br><br> | ||
[J55] J. Macadangdang, A. Jiao, D. Carson, H.J. Lee, J.A. Fugate, L.M. Pabon, M. Regnier, C. Murry, and D.H. Kim, “Capillary force lithography for cardiac tissue engineering,” '''Journal of Visualized Experiments''', (invited) (in press) <br> <br> | [J55] J. Macadangdang, A. Jiao, D. Carson, H.J. Lee, J.A. Fugate, L.M. Pabon, M. Regnier, C. Murry, and D.H. Kim, “Capillary force lithography for cardiac tissue engineering,” '''Journal of Visualized Experiments''', (invited) (in press) <br> <br> | ||
[J54] E.H. Ahn, Y.H. Kim, Kshitiz, S. An, S.W. Lee, M. Kwak, K.Y. Suh, D.H. Kim#, and A. Levchenko#, “Spatial control of adult stem cell fate using nanotopographic cues,” '''Biomaterials'''. (in press)<br> <br> | [J54] E.H. Ahn, Y.H. Kim, Kshitiz, S. An, S.W. Lee, M. Kwak, K.Y. Suh, D.H. Kim#, and A. Levchenko#, “Spatial control of adult stem cell fate using nanotopographic cues,” '''Biomaterials'''. (in press)<br> <br> | ||
Revision as of 01:19, 6 December 2013
Summary: 56 journal papers, 18 issued or pending patents, 76 conference proceedings and abstracts, 1 book and 8 book chapters.
Please direct any questions regarding publications or reprints to Dr. Kim;
[deokho@uw.edu]
Kim Lab Cover Art
.jpg)
In Progress
[J66] A. Jiao, N. Trosper, H.S. Yang, J. Tsui, S. Frankel, C.E. Murry, and D.H. Kim#, “Fabrication of scaffold-free, three-dimensional tissues with controllable architecture using a thermoresponsive, nanotopographically-defined platform,” (in review)
[J65] X. Niu, A. Bergman, D.H. Kim, Kshitiz, and A. Levchenko, “Nano retraction threads: a general cellular phenomenon in cell-substrate interactions and cell-cell communication,” (in review)
[J64] H. Jeon*, S.I. Jang*, J.H. Lee, J.H. Tsui, S. Park, D.H. Kim#, and Y.C. Boo#, “Mechanoregulation of endothelial cytokines/chemokines secretion by laminar shear stress and nanotopographical cues,” (in review)
[J63] M. Hnilova, J. Park, N. Shaw, M. Shennoy, C. Gresswell, D. Khatayevich, M. Gungormus, D.H. Kim, M. Sarikaya, and C. Tamerler, “Peptide enabled self-assembled heterofunctional nanoprobes for targeting bioimaging applications,” (in review).
[J62] Kshitiz J. Afzal, D.H. Kim, and A. Levchenko, "Mechanotransduction via p190RhoGAP regulates a switch between cardiomyogenic and endothelial lineages in adult cardiac progenitors," Stem Cells, (invited)(in review)
[J61] P. Kim, A. Yuan, A. Jiao, K. Nam, and D.H. Kim#, “Fabrication of poly(ethylene glycol):gelatin methacrylate composite nanostructures with tunable stiffness and degradation for vascular tissue engineering,” Biofabrication, (invited)(in review)
[J60] C.L. Smith, D.H. Kim, N. Sedora-Roman, H. Guerrero-Cazares, S. Gupta, T. O’Donnell, K. Chaichana, H.N. Kim, F. Rodriguez, S. Abbadi, M. Delannoy, K.Y. Suh, A. Quiñones‐Hinojosa, and A. Levchenko, “A novel nanotopographic platform for screening glioma cell migratory behavior and predicting patient outcomes,” Science Translational Medicine (in revision)
[J59] F. Pati, J. Jang, D.H. Ha, D.H. Kim, and D.W. Cho, “Printing three dimensional tissue analog with decellularized extracellular matrix bioink,” Nature Communications, (in revision)
[J58] C. Nemeth, K. Janebodin, A. E. Yuan, J.E. Dennis, M. Reyes#, and D.H. Kim#, “Enhanced in vitro chondrogenesis of dental pulp stem cells by nanopatterned hyaluronan hydrogels,” Tissue Engineering (in revision)
[J57] S. Chaterji, P. Kim, S.H. Choe, J.H. Tsui, A.B. Baker#, and D.H. Kim#, “Synergistic effects of matrix nanotopography and stiffness on vascular smooth muscle cell function,” Tissue Engineering, (in revision)
[J56] J.H. Kim, H.N. Kim, K.T. Lim, Y. Kim, S. Hoon, S. H. Park, H. J. Lim, D.H. Kim, P.H. Choung, Y.H. Choung, K.Y. Suh, and J.H. Chung, "Designing nanotopographical density of extracellular matrix for controlled morphology and function of human mesencymal stem cells," Scientific Reports, (in press)
[J55] J. Macadangdang, A. Jiao, D. Carson, H.J. Lee, J.A. Fugate, L.M. Pabon, M. Regnier, C. Murry, and D.H. Kim, “Capillary force lithography for cardiac tissue engineering,” Journal of Visualized Experiments, (invited) (in press)
[J54] E.H. Ahn, Y.H. Kim, Kshitiz, S. An, S.W. Lee, M. Kwak, K.Y. Suh, D.H. Kim#, and A. Levchenko#, “Spatial control of adult stem cell fate using nanotopographic cues,” Biomaterials. (in press)
[J53] H.S. Yang, N. Ieronimakis, J. Tsui, H.N. Kim, K.Y. Suh, M. Reyes, and D.H. Kim, “Nanopatterned muscle cell patches for enhanced myogenesis and dystrophin expression in a mouse model of muscular dystrophy,” Biomaterials. (in press)
[J52] J.E. Kim, S.M. Lee, S.H. Kim, P. Tatman, A.O. Gee, D.H. Kim, Y.M. Jung, and S.J. Kim, “The effect of self-assembled peptide-mesenchymal stem cell complex on the progression of osteoarthritis in rat model,” International Journal of Nanomedicine. (in press)
2013
[J51] J. Tsui, W. H. Lee, S. Pun, J. K. Kim, and D.H. Kim, "Microfluidics-assisted drug carrier production and drug screening," Advanced Drug Delivery Review, vol. 65, pp.1575-1588, 2013. Article
[J50] E.S. Kim, E.H. Ahn, E.H. Chung, and D.H. Kim#, “Recent advances in nanobiotechnology and high-throughput molecular techniques for systems biomedicine,“ Molecules and Cells, vol. 36, 2013. (invited) (in press)
[J49] S.H. Park, M.S. Kim, D. Lee, Y.W. Choi, D.H. Kim#, and K.Y. Suh#, “Hybrid microfabrication of nanofiber-based sheets and rods for tissue engineering applications,” Journal of Laboratory Automation, 2013. (# corresponding authors)Article
[J48] B. Lee, A. Jiao, S.J. Yu, J.B. You, D.H. Kim#, and S.K. Im#, “Initiated chemical vapor deposition of thermoresponsive poly(N-vinylcaprolactam) thin films for cell sheet engineering,” Acta Biomaterialia, vol. 9, pp. 7691–7698, 2013. ( # corresponding authors) Article
[J47] J. H. Kim, K. S. Choi, Y. Kim, K.-T. Lim, H. Seonwoo, Y. Park, D.H. Kim, P.H. Choung, C.-S. Cho, S.Y. Kim, Y.H. Choung, and J. H. Chung, "Bioactive effects of graphene oxide cell culture substratum on structure and function of human adipose-derived stem cells," Journal of Biomedical Materials Research: Part A, vol. 101, pp. 3520–3530, 2013. (Featured as a Cover Article) Article
[J46] M. E. Hubbi, Kshitiz, D.M. Gilkes, S. Rey, C. C. Wong, W. Luo, D.H. Kim, C. V. Dang, A. Levchenko, and G. Semenza, “A non-transcriptional role for HIF-1α as a direct inhibitor of DNA replication,” Science Signaling, vol. 6, pp. ra10, 2013. (Featured as a Cover Article; Highlighted in Science)Article; Podcast
[J45] Y. Suhail, Kshitiz, J. Lee, M. Walker, D.H. Kim, M.D. Brennan, J. Bader, and A. Levchenko, “Modeling intercellular transfer of biomolecules through tunneling nanotubes,” Bulletin of Mathematical Biology, vol. 75, pp. 1400-1416, 2013. Article
[J44] H. N. Kim, A. Jiao, N.S. Hwang, M.S. Kim, D.H. Kang, D.H. Kim, and K. Suh, "Nanotopography-guided tissue engineering and regenerative medicine" Advanced Drug Delivery Review vol. 64, pp. 536-558, 2013. (Featured as a Cover Article) Article
2012
[J43] D.H. Kim, Kshitiz, R. R. Smith, P. Kim, E. H. Ahn, H.N. Kim, E Marban, K.Y. Suh, and A. Levchenko, "Nanopatterned cardiac cell patches promote stem cell niche formation and myocardial regeneration" Integrative Biology, Vol. 4, pp. 1019-1033, 2012 (Featured as a Cover Article) Article
[J42] Kshitiz, J.S. Park, P. Kim, W. Helen, A.J. Engler, A. Levchenko, and D.H. Kim#, “Control of stem cell fate and function by engineering physical microenvironments” Integrative Biology, vol. 9, pp. 1008-1018, 2012. Article
[J41] Kshitiz, M.E. Hubbi, E.H. Ahn, J. Downey, D.H. Kim, S. Rey, J. Afzal, A. Kundo, G.L. Semenza, R. M. Abraham, and A. Levchenko, “Matrix rigidity controls endothelial differentiation and morphogenesis of cardiac precursors,” Science Signaling vol. 5, Issue. 227, ra41, 2012. (Featured as a Cover Article; also featured in "The matter of the heart" Science 336 (6088):1483-84 (2012) and the JHU press release) Article
[J40] H. N. Kim, D.H. Kang, M.S. Kim, A. Jiao, D.H. Kim, and K. Suh, "Patterning methods for polymers in cell and tissue engineering," Annals of Biomedical Engineering Vol. 40 No. 6, 1339-1355, 2012. (Award for Most Downloaded and Most Cited Review Article in 2012) Article
[J39] J. Kim*, D.H. Kim*, K. T. Lim, H. S. Woo, S. H. Park, Y.R. Kim, Y. Kim, Y.H. Choung, P.-H. Choung, and J. H. Chung, "Charged nanomatrices as efficient platforms for modulating cell adhesion and shape," Tissue Engineering Part C: Methods vol. 18, pp. 913-923 (Featured as a Cover Article) Article
[J38] T. Garzon-Muvdi, P. Schiapparelli, C. Rhys, H. Guerrero-Cazares, C. Smith, D.H. Kim, L. Kone, H. Farber, D.Y. Lee, S.S. An, A. Levchenko*, A. Quiñones-Hinojosa* "Regulation of brain tumor dispersal by NKCC1 through a novel role in focal adhesion regulation," PLoS Biology, Vol. 10, Issue. 5, e1001320, 2012. Article
[J37] D.H. Kim#, P. Provenzano, C.L. Smith, and A. Levchenko#, “Matrix nanotopography as a regulator of cell function,” Journal of Cell Biology vol. 197 no. 3 pp. 351-360, 2012.( # corresponding authors) Article
[J36] J.S. Park, H.N. Kim, D.H. Kim, A. Levchenko, and K.Y. Suh, “Quantitative analysis of the combined effect of substrate rigidity and topographic guidance on cell morphology,” IEEE Nanobioscience Vol. 11, pp. 28-36, 2012. Article
2011
[J35] K. Gupta, D.H. Kim, D. Beebe, and A. Levchenko, “Micro and nanoengineering for stem cell biology: the promise with a caution,” Trends in Biotechnology, Vol. 29, pp.399-408, 2011. (Selected as Top 25 Hottest Articles) Article
[J34] J. Kim, I. Hwang, D. Britain, T.D. Chung, Y. Sun, and D.H. Kim, "Microfluidic approaches for gene delivery and gene therapy," Lab on a Chip, vol. 11, pp. 3941 - 3948, 2011. Article
[J33] E. Hur*, I.H. Yang*, D.H. Kim*, J. Byun, W.-L. Xu, S. Jilafu, R. Cheong, A. Levchenko, N. Thakor, and F. Zhou, “Engineering neuronal growth cone to promote axon regeneration over inhibitory molecules,” Proceedings of the National Academy of Sciences USA, vol. 108, pp. 5057-5062, 2011. ( *Equal contribution). Article
[J32] D.H. Kim and Y. Sun, “Micro- and nanoengineered tools as emerging platforms for cell mechanobiology,” IET Micro and Nano Letters, vol. 6, pp. 289, Editorial, 2011.
2010~2003 (Before Tenure-Track Appointment)
[J31] D.H. Kim, H.J. Lee, Y.K. Lee, J.M. Nam, and A. Levchenko, "Biomimetic nanopatterns as enabling tools for analysis and control of live cells," Advanced Materials, vol. 22, pp.4551-4566, 2010. Pubmed, Hubmed
[J30] K. Gupta*, D.H. Kim*, D. Ellison, C. Smith, A. Kundu, K.Y. Suh, J. Tuan, and A. Levchenko, “Lab-on-a-chip devices as an emerging platform for stem cell biology,” Lab on a Chip, vol. 10, pp.2019-2031, 2010. (*Equal contribution) Pubmed, Hubmed (Selected as one of the ten most accessed Lab on a Chip articles in August)
[J29] M.H. You, M.K. Kwak, D.H. Kim, K. Kim, A. Levchenko, D.Y. Kim, and K.Y. Suh, “Synergistically enhanced osteogenic differentiation of human mesenchymal stem cells by culture on nanostructured surfaces with induction media,” Biomacromolecules, vol. 11, pp.1856-1862, 2010. Pubmed, Hubmed
[J28] J. Park*, D.H. Kim*, G. Kim, Y.H. Kim, E. Choi, and A. Levchenko, “Simple haptotactic gradient generation within a triangular microfluidic channel,” Lab on a Chip, vol. 10, pp.2130-2138, 2010. (*Equal contribution) Pubmed, Article
[J27] D.H. Kim, E. Lipke, P. Kim, R. Cheong, S. Edmonds, M. Delannoy, K.Y. Suh, L.Tung, and A. Levchenko, "Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs," Proceedings of National Academy of Sciences USA, vol.107, pp. 565-570, 2010. Pubmed, Hubmed (Highlighted in the National Institute of Biomedical Imaging and Bioengineering)
[J26] D.H. Kim, P. Wong, J.Y. Park, A. Levchenko, and Y. Sun#, "Microengineered platforms for cell mechanobiology," Annual Review of Biomedical Engineering, vol. 11, pp.203-233, 2009. (# denotes corresponding authors) Pubmed
[J25] D.H. Kim, C. Seo, K. Han, K. Kwon, A. Levchenko and K.Y. Suh, "Guided cell migration on microtextured substrates with variable local density and anisotropy," Advanced Functional Materials, vol.19, pp.1579-1586, 2009. (Featured as a Frontispiece) Pubmed, Hubmed
[J24] D.H. Kim, K. Han, K. Gupta, K. Kwon, K.Y. Suh, and A. Levchenko, "Mechanosensitivity of fibroblast cell shape and movement to anisotropic substratum topography gradients," Biomaterials, vol. 30, pp. 5433-5444, 2009. Pubmed, Hubmed
[J23] J. Kim, M. Junkin, D.H. Kim, S.L. Kwon, Y.S. Shin, P. K. Wong, and B. K. Gale, "Applications, techniques, and microfluidic interfacing for nanoscale biosensing," Microfluidics and Nanofluidics, vol. 7, pp. 149-167, 2009. http://dx.doi.org/10.1016/j.snb.2005.11.051
[J22] D.H. Kim, J.Y. Park, M.K. Kim, and K.S. Hong, "AFM-based identification of the dynamic properties of globular proteins: simulation study," Journal of Mechanical Science and Technology, vol. 22, no.11, pp. 2203-2212, 2008.
[J21] D.H. Kim, J.Y. Park, K.Y. Suh, P. Kim, S.K. Choi. S.C. Ryu, S.H. Park, S.H. Lee and B. Kim, "Fabrication of patterned micromuscles with high activity for powering biohybrid microdevices," Sensors and Actuators B, vol. 117, pp.391-400, 2006. http://dx.doi.org/10.1016/j.snb.2005.11.051
[J20] K.Y. Suh, H.E. Jeong, D.H. Kim, A.R. Singh, and E.S. Yoon, "Capillarity-assisted fabrication of nanostructures using less permeable mold for nanotribological applications," Journal of Applied Physics, vol.100, 2006. http://dx.doi.org/10.1063/1.2222071
[J19] S. Park, S. Ryu, S. Ryu, D.H. Kim, and B. Kim, “Contractile force measurements of cardiac myocytes using a micro-manipulation system,” Journal of Mechanical Science and Technology, vol.20, no.5, pp.668-674, 2006.
[J18] D.H. Kim, P. Kim, I.S. Song, J.M. Cha, S.H. Lee, B. Kim, and K.Y. Suh, "Guided three-dimensional growth of functional cardiomyocytes on polyethylene glycol nanostructures," Langmuir, vol.22, no.12, pp.5419-5426, 2006. > Pubmed, Hubmed
[J17] E.S. Yoon, R.A. Singh, H.S. Kong, B. Kim, D.H. Kim, H.E. Jeong, and K.Y. Suh, “Tribological properties of bio-mimetic nano-patterned polymeric surfaces on silicon wafer,” Tribology Letters, vol.21, pp.31-37, 034303, 2006. (the Society of Tribologists and Lubrication Engineers, Surface Engineering Best Paper Award) http://dx.doi.org/10.1007/s11249-005-9005-4
[J16] D.H. Kim, C.N. Hwang, Y. Sun, B. Kim, S.H. Lee, and B. Nelson, "Mechanical analysis of chorion softening in pre-hatching stages of zebrafish embryos," IEEE Transactions on Nanobioscience, vol.5, no.2, pp.89-94, 2006. Pubmed, Hubmed
[J15] D.H. Kim, K.S. Hong, and K.S. Yi, “Driving load estimation with the use of estimated turbine torque,” JSME International Journal Series C, vol.49, pp.163-171, 2006.
[J14] B. Kim, H.J. Kang, D.H. Kim, and J.O. Park, “A flexible microassembly system based on hybrid manipulation scheme for manufacturing photonics components," International Journal of Advanced
Manufacturing Technology, vol.28, pp.379-386, 2006.
[J13] J.Y. Park, S.M. Kim, D.H. Kim, B. Kim, S.J. Kwon, J.O. Park, and K.I. Lee, "Identification and control of a sensorized microgripper for micromanipulation," IEEE/ASME Transactions on Mechatronics, vol.10, no.5, pp.601-606, 2005. http://dx.doi.org/10.1109/TMECH.2005.856103
[J12] P.N. Kim, D.H. Kim, B. Kim, S.K. Choi, S.H. Lee, A. Khademhosseini, R. Langer, and K.Y. Suh, "Fabrication of nanostructures of poly(ethylene glycol) for application to protein adsorption and cell adhesion," Nanotechnology, vol.16, pp.2420-2426, 2005. http://dx.doi.org/10.1088/0957-4484/16/10/072
[J11] B. Kim, D.H. Kim, J.H. Jung, and J.O. Park, "A biomimetic undulatory tadpole robot using ionic polymer-metal composite actuators," Smart Materials and Structures, vol. 14, pp.1579-1585, 2005. http://dx.doi.org/10.1088/0964-1726/14/6/051
[J10] D.H. Kim, M.G. Lee, B. Kim, and Y. Sun, "A superelastic alloy microgripper with embedded electromagnetic actuators and piezoelectric sensors: a numerical and experimental study," Smart Materials and Structures, vol.14, pp.1265-1272, 2005. http://dx.doi.org/10.1088/0964-1726/14/6/019
[J9] D.H. Kim, Y. Sun, S. Yun, S.H. Lee, and B. Kim, "Investigating chorion softening of zebrafish embryos with a microrobotic force sensing system," Journal of Biomechanics, vol.38, no.6, pp.1359-1363, 2005. Pubmed, Hubmed
[J8] A. Haake, A. Neild, D.H. Kim, J.E. Ihm, Y. Sun, J. Dual, and B.K. Ju, "Manipulation of cells using an ultrasonic pressure field," Ultrasound in Medicine and Biology, vol.31, no.6, pp.857-864, 2005. Pubmed, Hubmed
[J7] D.H. Kim, B. Kim, B.K. Ju, and J.O. Park, “State of the art in nano-biomanipulation technologies,” Journal of Control, Automation and Systems Engineering, vol.11, no.4, pp.353-362, 2005.
[J6] D.H. Kim, B. Kim, and H.J. Kang, "Development of a piezoelectric polymer-based sensorized microgripper for micromanipulation and microassembly", Microsystem Technologies, vol.10, no.4, pp.275-280, 2004. http://dx.doi.org/10.1007/s00542-003-0330-y
[J5] D.H. Kim, B. Kim, and J.O. Park, “Implementation of a piezoresistive MEMS cantilever for nanoscale force
measurements in micro/nano robotic applications,” Journal of Mechanical Science and Technology, vol.18,
no.5, 789-797, 2004.
[J4] D.H. Kim, K.-J. Yang, K.S. Hong, J.O. Hahn, and K.I. Lee, “Smooth shift control of automatic transmissions
using a robust adaptive scheme with intelligent supervision,“ International Journal of Vehicle Design,
vol.32, no.3/4, pp.250-272, 2003.
[J3] J.Y. Park, D.H. Kim, T.S. Kim, B. Kim, and K.I. Lee “Design and performance evaluation of a 3-DOF
mobile microrobot for micro manipulation,” Journal of Mechanical Science and Technology, vol.17, no.9,
pp.1268-1275, 2003.
[J2] D.H. Kim, B. Kim, S. Youn, and H.J. Kang, “Cellular force sensing for force feedback-based biological cell
injection,” Transactions of the KSME, A, vol.27, no.12, pp.2079-2084, 2003.
[J1] D.H. Kim, B. Kim, H.J. Kang, and S.M. Kim, “Design, fabrication and performance evaluation of a
sensorized superelastic alloy microrobot gripper,” Transactions of the KSME, A, vol.27, no.10, pp.1772-
1777, 2003.
[B9] A. Blakney, J. Antetomaso W. Leung, and D.H. Kim#, “Extracellular matrix in vivo: components and behavior of cells on them,” Stem Cell NanoEngineering, H. Baharvand and N. Aghdami, invited chapter, 2014.
[B8] N. Trosper, P. Kerscher, J. Macadangdang, D. Carson, E. Lipke, and D.H. Kim#, "Micro- and nanofabrication approaches to cardiac tissue engineering," Tissue and Organ Regeneration: Advances in Micro and Nano Technology, invited chapter, 2014.
[B7] J. Antetomaso, A. Jiao, K. Gauthier-Bell, and D.H. Kim#, “Nanotopographically-defined in vitro cell culture models for stem cell and tissue engineering,” Handbook of Biomimetics and Bioinspiration, E. Jabbari, A. Khademhosseini, L.P. Lee, D.H. Kim, and A. Ghaemmaghami, (Eds.), invited chapter, 2014.
[B6] E. Jabbari, A. Khademhosseini, L.P. Lee, D.H. Kim, and A. Ghaemmaghami, Editors, “Handbook of
Biomimetics and Bioinspiration,” World Scientific Publishers, 2012
[B5] R. Singh, E.S. Yoon, K.Y. Suh, and D.H. Kim, “Biomimetic surfaces for tribological applications in
micro/nano-devices,” Nano-Tribology and Materials Issues in MEMS, S.S. Kumar, N. Satyanarayana, S.C.
Lim (Eds.), Springer-Verlag, invited chapter, 2011.
[B4] K. Gupta, D.H. Kim#, D. Allison, C. Smith, and A. Levchenko#, “Using lab-on-a-chip technologies for stem
cell biology,” Stem Cells and Regenerative Medicine, K. Appasani (Eds.), Springer Science (Humana) Press,
invited chapter, pp. 483-498, 2010. (# corresponding authors)
[B3] K.J. Chang, D.H. Kim, S.M. Kim, A. Levchenko, and K.Y. Suh, “Micropatterned polymer structures for cell
and tissue engineering,” Biological Responsive Hybrid Biomaterials, E. Jabbari and A. Khademhosseini
(Eds.), Artech House Publishers, invited chapter, pp. 101-120, 2010.
[B2] D.H. Kim, A. Levchenko, and K.Y. Suh, “Engineered surface nanotopography for controlling cell-substrate
interactions,” Micro- and Nanoengineering of the Cell Microenvironment: Technologies and Applications,
A. Khademhosseini, J. Borenstein, S. Takayama, and M. Toner (Eds.), Artech House Publishers, invited
chapter, pp. 185-208, 2008.
[B1] Y. Sun, D.H. Kim, and A. Hashemi, “Biological cell sorting automation,” Life Science Automation:
Fundamentals and Applications, M.J. Zhang, B.J. Nelson and R.A. Felder (Eds.), Artech House Publishers,
invited chapter, pp. 411-434, 2007.
[I54] University of Arizona, "Micro- and nanoscale engineering of cell and tissue function,” Tucson, AZ, USA, September 19, 2013.
[I53] International Nano and Micro Systems (NAMIS) Workshop, “BioMEMS Research Activities at University of Washington,” Seattle, WA, USA, July 8-10, 2013.
[I52] University of Washington, "Engineering biomimetic materials to direct cell function and tissue regeneration,” Seattle, WA, USA, June 4, 2013.
[I51] International Myocardial Ischemia Symposium, “Microenvironmental regulation of cardiac function by biophysical and material cues,” Seoul, Korea, March 28-29, 2013.
[I50] Kyunghee University, School of Dentistry, “Biomimetic approaches for engineering stem cells and tissues,” Seoul, Korea, March 28, 2013.
{I49] Seoul National University, School of Chemistry, “Biomimetic approaches for engineering cell function and tissue regeneration,” Seoul, Korea, March 27, 2013.
[I48] Samsung Medical Center, "Microenvironmental regulation of cell and tissue function by biophysical and material cues,” Seoul, Korea, March 26, 2013.
[I47] Benaroya Research Institute, “Microenvironmental regulation of muscle regeneration by biophysical stimulation, Seattle, WA, USA, February 25, 2013.
[I46] Seattle Korean-American Biomedical Science Symposium, “Nanoengineering cell biology and therapy,” Seattle, WA, USA, November 17, 2012.
[I45] IEEE NanoMedicine Conference, “Matrix nanotopography as a regulator of cell function and tissue regeneration,” Bangkok, Thailand, November 5, 2012.
[I44] Northwest Korean-American Scientist Association, “Nanotechnological strategies for engineering cells and tissue regeneration,” Seattle, WA, USA, August 23, 2012.
[I43] “Mechanobiological regulation of cell function and tissue regeneration with nanoengineered matrix cues,” Department of Mechanical Engineering, University of Washington, Seattle, WA, USA, November 22, 2011.
[I42] “Biomimetic nanopatterns as enabling tools for analysis and control of cell function and tissue regeneration,” Department of Chemistry and Nanoscience, Ewha Womans University, Seoul, Korea, Nov., 4, 2011.
[I41] “Biomimetic nanopatterns as enabling tools for analysis and control of cell function and muscle regeneration,” Department of Biochemistry and Cell Biology, Kyungbook National University, Daegu, Korea, Nov., 4, 2011.
[I40] “Controlling Cardiac Function on the Nano-Scale: A Biomimetic Approach and Intervention,” The 5th International Conference on Cell Therapy, Seoul, Korea, November 1, 2011.
[I39] “Biomimetic nanopatterns as enabling tools for analysis and control of cell function and tissue regeneration,” The 10th International Conference on Nanoimprint and Nanoprint Technology, JeJu, Korea, October 19-21, 2011.
[I38] “Nanotopographically-defined biomaterials for analysis and control of cell function and tissue regeneration,” Department of Chemical Engineering, University of Washington, Seattle, WA, USA, May 26, 2011.
[I37] “Micro and nanotechnologies for bioengineering regenerative medicine,” Department of Bioengineering, University of Washington, Seattle, WA, USA, May 17, 2011.
[I36] "Biomimetic nanopatterns as enabling tools for analysis and control of cell function and tissue regeneration,” Department of Bioengineering, University of Washington, Seattle, WA, USA, May 5, 2010.
[I35] "Analysis and control of cell function and tissue regeneration with nanoscale cues,” Department of Chemical Engineering and Materials Science, Chung Ang University, Seoul, Korea, December 9, 2010.
[I34] "Engineering cellular function and tissue regeneration with local matrix cues: implications for wound healing, cancer invasion, and stem cell therapy,” Department of Bioengineering, Hanyang University, Seoul, Korea, December 8, 2010.
[I33] "Analysis and control of cellular function and tissue regeneration with nanoscale matrix cues,” Department of Bionano Engineering, Hanyang University, An-San, Korea, December 7, 2010.
[I32] "Regulation of cell function and tissue regeneration with matrix cues: implications for wound healing, cancer invasion, and tissue engineering,” College of Bionano Technology, Kyungwon University, Sungnam, Korea, December 6, 2010.
[I31] "Nanoscale material cues regulate the structure and function of stem cells and macroscopic cardiac tissue construct,” School of Material Science and Engineering, Gwangju Institute of Science and Technology, Gwangju, Korea, December 3, 2010.
[I30] "Regulation of cellular and multicellular form and function with nanoscale cues: implications for wound healing, cancer metastasis, and tissue engineering,” College of Pharmacy, Kyung Hee University, Seoul, Korea, December 2, 2010.
[I29] "Controlling cellular function and tissue regeneration with nanoscale matrix cues,” Department of Mechanical Engineering, Sogang University, Seoul, Korea, December 1, 2010.
[I28] "Controlling cellular function and tissue regeneration with nanoscale material cues,” Department of Material Science and Engineering, KAIST, Daejon, Korea, November 30, 2010.
[I27] "Engineering cellular function and tissue regeneration with local matrix cues: implications for wound healing, cancer invasion, and stem cell therapy,” Samsung Medical Center, Seoul, Korea, November 29, 2010.
[I26] "Control of cellular and multicellular function with nanoscale matrix cues: implications for wound healing, cancer invasion, and tissue engineering,” Department of Biotechnology, Yonsei University, Seoul, Korea, November 25, 2010.
[I25] "Engineering cellular function and tissue regeneration with local matrix cues: implications for wound healing, cancer invasion, and stem cell therapy,” Division of Biomedical Science, Korea Institute of Science and Technology, Seoul, Korea, November 24, 2010.
[I24] "Nanoscale matrix cues regulates the structure and function of macroscopic cardiac tissue constructs,” Annual Bioscience and Engineering Symposium (ABES), Natcher Auditorium, National Institute of Health (NIH) Campus, Bethesda, MD, USA, November 6, 2010.
[I23] "Regulation of cellular and multicellular form and function with nanoscale cues: implications for wound healing, cancer metastasis, and tissue engineering,” Department of Bioengineering, University of Washington, Seattle, WA, USA, May 20, 2010.
[I22] "Mechanical control of cellular function and tissue regeneration,” Department of Mechanical Engineering, Stanford University, Stanford, CA, USA, May 13, 2010.
[I21] “Mechanochemical regulation of cellular and multicellular form and function using nanoengineered extracellular matrices: implications for wound repair, cancer metastasis, and tissue engineering”, 2010 Weintraub Award Symposium, Seattle, May 7, 2010.
[I20] "Regulation of cellular and multicellular form and function with nanoscale cues: implications for wound healing, cancer metastasis, and tissue engineering,” Department of Bio and Brain Engineering, KAIST, Daejeon, Korea, April 29, 2010.
[I19] "Nanotopographically-defined biomaterials for controlling cell function and tissue regeneration,” Department of Bioengineering, University of California at Riverside, Riverside, CA, USA, April 26, 2010.
[I18] "Mechanochemical regulation of cellular and multicellular form and function with nanoscale cues: implications for wound healing, cancer metastasis, and tissue engineering,” Department of Mechanical Science and Engineering, University of Illinois at Urbana-Champaign, Champaign, IL, USA, April 22, 2010.
[I17] "Mechanochemical regulation of cellular and multicellular form and function with nanoscale cues: implications for wound healing, cancer metastasis, and tissue engineering,” Department of Biomedical Engineering, The State University of New York at Buffalo, Buffalo, NY, USA, April 19, 2010.
[I16] "Mechanochemical regulation of cellular and multicellular form and function with nanoscale cues: implications for wound repair, cancer metastasis, and tissue engineering,” Johns Hopkins School of Medicine and the Whiting School of Engineering, Baltimore, MD, USA, March, 30, 2010.
[I15] "Mechanochemical regulation of multicellular form and function with nanoscale cues: implications for cancer metastasis, wound repair, and tissue engineering,” Baltimore Life Scientists Association, Baltimore, MD, USA, Feb., 23, 2010.
[I14] “Multi-scale mechanobiology for cell and tissue engineering using nano/micropatterned biomaterials,” Korea Institute of Machine and Materials, Daejeon, Korea, Feb., 6, 2009.
[I13] “Multi-scale mechanobiology for cell and tissue engineering using nano/micropatterned biomaterials,” Adult Stem Cell Research Center, College of Veterinary Medicine, Seoul National University, Seoul, Korea, Feb., 3, 2009.
[I12] “Analysis and engineering of cell function with nanoscale cues”, BME Student Seminar Series, Johns Hopkins University, Baltimore, January 23, 2009.
[I11] “Regulation of cell function by local force and geometry sensing: implications for biology and regenerative medicine,” Department of Chemistry and Nanoscience, Ewha Womans University, Seoul, Korea, Dec., 11, 2008.
[I10] “Regulation of cell function by local force and geometry sensing: implications for biology and regenerative medicine,” Department of Biomedical Engineering, Korea University, Seoul, Korea, Dec., 11, 2008.
[I9] “Regulation of cell function by local force and geometry sensing: implications for integrative biology and regenerative medicine,” Department of Mechanical Engineering, POSTECH, Pohang, Korea, Dec., 10, 2008.
[I8] “Sensing by touch in tumors, hearts, and stem cells: contact-mediated signaling and function of living cells on chips,” Nano-Bio Research Center, Korea Institute of Science and Technology, Seoul, Korea, Dec., 9, 2008.
[I7] “Regulation of cell function by local force and geometry sensing: implications for tissue engineering and biology,” Department of Mechanical Engineering, KAIST, Daejeon, Korea, Dec., 8, 2008.
[I6] “Sensing by touch: contact-mediated signaling and function of living cells on chips,” Interdisciplinary Graduate Program of Bioengineering and Micro Thermal System Research Center, Seoul National University, Seoul, Korea, Dec., 5, 2008.
[I5] “Nano-engineering the cell-matrix interface: implications for tissue engineering and cell-based regenerative therapies,” Baltimore Life Scientists Association, Baltimore, MD, USA, Nov., 15, 2008.
[I4] “Biomicrorobotics and BioMEMS for cell bioengineering: from single cell manipulation to cell separation,” Laboratoire d'Automatique de Besançon (LAB), UMR CNRS, France, April 15, 2004.
[I3] “Microrobotic devices and MEMS-based cell chips for biomedical applications,” Laboratoire de systèmes robotiques, Institut de Production et Robotique, Swiss Federal Institute of Technology (EPFL), Lausanne, Switzerland, Feb. 24, 2004.
[I2] “Micromechatronics for microassembly and biomanipulation,” Institute of Robotics and Intelligent Systems, Swiss Federal Institute of Technology – Zurich (ETH Zurich), Switzerland, Nov., 28, 2003.
[I1] “Robotic manipulation at the micro/nanoscale,” special workshop on “Paradigm Shift in Next Generation Robotic Technology in Industry: Micro-Nano Robot,” Korea Machine Tool Manufactures’ Association, Seoul, Korea, July 24, 2002.
