Tissue Engineering And Nanotheranostics

“9.61x6.69” b2815 Tissue Engineering and Nanotheranostics

Plasmonic Nanoparticles Application in Biosensor and Bioimaging 201

157. Oyelere AK, et al. Peptide­conjugated gold nanorods for nuclear tar­
     geting. Bioconjugate Chem. 18 (5), 1490–1497 (2007).


158. Kang B, Mackey MA, and El­Sayed MA. Nuclear targeting of gold
     nanoparticles in cancer cells induces DNA damage, causing cytokinesis
     arrest and apoptosis. J. Am. Chem. Soc. 132 (5), 1517–1519 (2010).


159. Yeh HC, et al. Single­molecule detection and probe strategies for
     rapid and ultrasensitive genomic detection. Current Pharmaceutical
     Biotechnol. 6 (6), 453–461 (2005).


160. Radwan SH and Azzazy HM. Gold nanoparticles for molecular diagnos­
     tics. Expert Review of Molecular Diagnostics. 9 (5), 511–524 (2009).


161. Qu W­G, et al. Plasmonic resonance energy transfer­based nanospec­
     troscopy for sensitive and selective detection of 2,4,6­trinitrotoluene
     (TNT). Chem. Comm. 47 (4), 1237–1239 (2011).


162. Choi Y, et al. Selective and sensitive detection of metal ions by plas­
     monic resonance energy transfer­based nanospectroscopy. Nat.
     Nanotechnol. 4 (11), 742–746 (2009).


163. Choi Y, Kang T, and Lee LP. Plasmon resonance energy transfer
     (PRET)­based molecular imaging of cytochrome c in living cells.
     Nano Lett. 9 (1), 85–90 (2009).


164. Ray PC, Fortner A, and Darbha GK. Gold nanoparticle based FRET
     assay for the detection of DNA cleavage. J. Phys. Chem. B. 110 (42),
     20745–20748 (2006).


165. Gao MX, et al. Insight into a reversible energy transfer system.
     Nanoscale. 8 (36) (2016).


166. Lee SE, and Lee LP. Biomolecular plasmonics for quantitative biology
     and nanomedicine. Current Opinion in Biotechno. 21 (4), 489–497
     (2010).


167. Liu GL, et al. Quantized plasmon quenching dips nanospectros copy
     via plasmon resonance energy transfer. Nat. Methods. 4 (12), 1015–
     1017 (2007).


168. Nakayama N, et al. Ethanol­induced apoptosis in hepatoma cells pro­
     ceeds via intracellular Ca(2+) elevation, activation of TLCK­sensitive
     proteases, and cytochrome c release. Experimental Cell Res. 269 (2),
     202–213 (2001).


169. Waldeck DH, Alivisatos AP, and Harris CB. Nonradiative damping of
     molecular electronic excited states by metal surfaces. Surface Science
     158 (1–3), 103–125 (1985).


170. Prigogine I, and Rice SA. Molecular Fluorescence and Energy
     Transfer Near Interfaces 1589–1595 (1975).