• CO2 and Compressive Immobilization of C. elegans on-chip.
Chokshi T.V., Ben-Yakar A. and Chronis N., Lab-on-chip (in press)
• Femtosecond laser nanoaxotomy lab-on-a-chip for in vivo nerve regeneration studies.
Guo S.X., Bourgeois F., Chokshi T., Durr N.J., Hilliard M.A., Chronis N. & Adela Ben-Yakar, Nature Methods - 5, 531 - 533 (2008).
• Artificial dirt: Microfluidic substrates for nematode neurobiology and behavior.
Lockery S.R., Lawton K.J., Doll J.C., Faumont S., Coulthard S.M., Thiele T.R., Chronis N., McCormick K.E., Goodman M.B., Pruitt B., Journal of Neurophysiology 99: 3136-3143, (2008).
• Dissecting a circuit for olfactory behaviour in Caenorhabditis Elegans.
Chalasani S.H., Chronis N., Tsunozaki M., M. Gray J.M., Ramot D., Goodman M.B. & Cornelia I. Bargmann C.I, Nature 450, 63-70 (1 November 2007).
• Microfluidics for in vivo imaging of neuronal and behavioral activity in Caenorhabditis elegans.
Chronis N., Zimmer M., Bargmann C.I., Nature Methods. 2007 Sep;4(9):727-31.
• A Distributed Chemosensory Circuit for Oxygen Preference in C. Elegans.
Chang A.J., Chronis N., Karow D.S., Marletta M.A., Bargmann C.I., PLoS Biology Vol. 4, No. 9, (2006).
• Electrothermally activated SU-8 Microgripper for Single Cell Manipulation.
Chronis N. and Lee L.P, Journal of MicroelectroMechanical Systems, Volume 14, Issue 4, p.857- 863 (2005).
• Tunable Microdoublet Lens Array.
Jeong K.H., Liu G.L, Chronis N. and Lee L.P., Optics Express, Volume 12,p. 2494-2500, (2004).
• Total-Internal Reflection based-Biochip utilizing a polymer-filled cavity with a micromirror sidewall.
Chronis N. and Lee L.P, Lab on a Chip, 2004, 4, p.125 – 130, (2004).
• Tunable liquid-filled microlens array integrated with microfluidic network.
Chronis N., Liu G.L, Jeong K.H, and Lee L.P. Optics Express, Volume 11, p. 2370-78, (2003). |
|
• An opto-fluidic sensor for monitoring intracranial pressure.
Kodandaramaiah S.B. and Chronis N., 12th International Conference on Micro Total Analysis Systems (µTAS), San Diego, (2008).
• Worm-on-chip technology for studying aging of the nervous system in C. elegans.
Tripathi A., Chokshi T.V. and Chronis N., 12th International Conference on Micro Total Analysis Systems (µTAS), San Diego, (2008).
• A 2-D Adjustable Pinhole Formed by Two Orthogonally Moving Micro-slits.
Chronis N. and Lee L.P., 13th international conference on solid-state sensors and actuators (TRANSDUCERS), p. 1022-1025, (2005).
• A polymer-based microrobotic workstation for single cell manipulation.
Chronis N. and Lee L.P. 8th International Conference on Micro Total Analysis Systems (µTAS), Sweden, p. 407-409, (2004).
• Polymer MEMS-Based Microgripper for Single Cell Manipulation.
Chronis N. and Lee L.P, 17th International Conference on MicroElectroMechanical Systems, p.17-20, (2004).
• Tunable Microboublet Lens Array.
Jeong K.H., Liu G.L., Chronis N. and Lee L.P.,17th International Conference on
MicroElectroMechanical Systems, p.37-40 (2004).
• Total Internal Reflection-based Biochip for High Throughput Bioassays.
Chronis, N. and Lee L.P., 7th International Conference on Micro Total Analysis Systems (µTAS), California, p.1323-6, (2003).
• Polymer-based Actuators Integrated Into Microfluidic Systems.
Chronis N. and Lee L.P., 6th International Conference on Micro Total Analysis Systems (µTAS), Japan, p.754-7, (2002).
• A Microfabricated Bio-magnetic Separator Based On Continuous Hydrodynamic Parallel Flow.
Chronis, N., Lam W. and Lee L.P., 5th International Conference on Micro Total Analysis Systems (µTAS), California, p.345-6, (2001) |
