19. "Secondary structure of corona proteins determines the cell surface receptors used by nanoparticles," C.C. Fleischer and C.K. Payne, J. Phys. Chem. B., Special Issue: Spectroscopy of Nano- and Biomaterials Symposium, ASAP (2014). Link
18. "Tuning PEDOT:PSS conductivity with iron oxidants," J.D. Morris and C.K. Payne, Organic Electronics, 15, 1707-1710 (2014). Link
17. "Lysosome transport as a function of lysosome diameter," D. Bandyopadhyay, A. Cyphersmith, J.A. Zapata, Y.J. Kim, and C.K. Payne, PLoS One, 9, e86847 (2014). Link
16. "Cellular binding of anionic nanoparticles is inhibited by serum proteins independent of nanoparticle composition," C.C. Fleischer, U. Kumar, and C.K. Payne, Biomaterials Science, 1, 975-982 (2013).
15. "Protein-mediated synthesis of the conducting polymer PEDOT:PSS," S.M. Hira and C.K. Payne, Synthetic Metals, 176, 104-107 (2013).
14. "Membrane potential mediates the cellular binding of nanoparticles," E.H. Shin, Y. Li, U. Kumar, H.V. Sureka, X. Zhang, and C.K. Payne, Nanoscale, 5, 5879-5886 (2013). Link
13. "Conditioned media downregulates nuclear expression of Nrf2," S. Sarkar, C.K. Payne, and M.L. Kemp, Cellular and Molecular Bioengineering, 6, 130-137 (2013).
12. "Imaging intracellular quantum dots: Fluorescence microscopy and transmission electron microscopy," C.J. Szymanski, H. Yi, J.L. Liu, E.R. Wright, C.K. Payne, Nanobiotechnology Protocols, Eds. S.J. Rosenthal and D.W. Wright (Humana Press, New York, 2013).
11. "Nanoparticle surface charge mediates the cellular receptors used by protein-nanoparticle complexes," C.C. Fleischer and C.K. Payne, J. Phys. Chem. B, 116, 8901-8907 (2012).
10. "Imaging lysosomal enzyme activity in live cells using self-quenched substrates," W.H. Humphries and C.K. Payne, Analytical Biochemistry, 424, 178-183 (2012).
9. "Fluorescent coumarin thiols measure biological redox couples," K.G. Reddie, W.H. Humphries, C.P. Bain, C.K. Payne, M.L. Kemp, and N. Murthy, Organic Letters, 14, 680-683 (2012).
8. "Nanoparticles act as protein carriers during cellular internalization," G.W. Doorley and C.K. Payne, Chem. Commun., 48, 2961-2963 (2012).
7. "Endo-lysosomal vesicles positive for Rab7 and LAMP1 are terminal vesicles for the transport of dextran," W.H. Humphries IV, C.J. Szymanski, and C.K. Payne, PLoS ONE 6, e26626 (2011). doi:10.1371/journal.pone.0026626. Link
6. "Single particle tracking as a method to resolve differences in highly colocalized proteins," C.J. Szymanski, W.H. Humphries IV, C.K. Payne, Analyst, 136, 3527-3533 (2011).
5. "Cellular binding of nanoparticles in the presence of serum proteins," G.W. Doorley and C.K. Payne, Chem. Commun., 47, 466-468 (2011). PDF
4. "Intracellular degradation of low-density lipoprotein probed with two-color fluorescence microscopy," W.H. Humphries IV, N.C. Fay, C.K. Payne, Integr. Biol., 2, 536 - 544 (2010). PDF
3. "Pyrenebutyrate leads to cellular binding, not intracellular delivery, of polyarginine quantum dots," A.E. Jablonski, T. Kawakami, A.Y. Ting, C.K. Payne, J. Phys. Chem. Lett., 1, 1312–1315 (2010). PDF
x. "Pyrenebutyrate-Mediated Delivery of Quantum Dots across the Plasma Membrane of Living Cells," A.E. Jablonski, W.H. Humphries, C.K. Payne, J. Phys. Chem. B, 113 (2), 405-408 (2009), pmid:19099434, withdrawn.
The conclusions drawn from the data in this manuscript were incorrect. A full discussion can be found in, "Pyrenebutyrate Leads to Cellular Binding, Not Intracellular Delivery, of Polyarginine Quantum Dots," A.E. Jablonski, T. Kawakami, A.Y. Ting, C.K. Payne, J. Phys. Chem. Lett., 1, 1312–1315 (2010).
2. "Imaging gene delivery with fluorescence microscopy," C.K. Payne, Nanomedicine, 2, 847-860 (2007). pmid:18095850.
1. "Cellular binding, motion, and internalization of synthetic gene delivery polymers," G.T. Hess, W.H. Humphries IV, N.C. Fay, and C.K. Payne, Biochim. Biophys. Acta, Mol. Cell Res., 1773, 1583-1588 (2007). pmid:17888530. PDF
C.K. Payne publications prior to Georgia Tech