Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

168 Tissue Engineering and Nanotheranostics

particle, leading to conversion of the nonpropagating nearfield

light into the conventional propagating scattered light. The scattered

light is detected by camera while the returning laser is stopped,

inducing darkfield effects. Taking advantage of the focus on a thin

layer by TIR illumination, background noise was decreased and

images with high SNR were acquired. In a study of the rotary mecha

nism of F 1 –ATPase 1–2 nm, spatial precision and 9.1 μs temporal

resolution were demonstrated by the successful application of this

homebuilt TIRDFM system. Later, to achieve higher sensitivity,

white light laser with average power output of 2.8 W was reported to

supply a strong light source to illuminate the particles in TIR geom

etry. With the help of the improved system, the dynamic evolution of

a single protein binding to a single AuNP was observed with milli

second time resolution.^102

Although TIR illumination can decrease the background noise,

this technique is limited to a thin region adjacent to the interface.

Baumberg et al. used a supercontinuum laser to perform DF spec

troscopy in a focused mode, they equipped a circular block in the

illumination beam path to focus the ringshaped laser on the sam

ple, and the illumination intensities yielded were up to 10 MW/

cm^2.^103 Under intense illumination, the growth of a single gold

nanorod was observed in real time with 8 ms time resolution. More

importantly, this method can be used to probe deeply into a

sample.

To reduce the toxicity of the illumination light to living cells, He

et al. developed quiet a different method. They utilized a new tech

nique that named dualwavelength difference (DWD) imaging to

remove noise in the living cell environment.^27 Briefly, the scattering

intensity of nanoparticle probe at resonance frequency is much higher

than noise signal from living cells, while at nonresonance frequency

scattering intensity of nanoparticle is similar with noise signals. Then,

noise free images could be obtained by subtracting the signal of refer

ence beam, of which wavelength is far away from the resonance fre

quency, from probe poem beam at the resonance. With this novel

strategy, the diffusion dynamics of nucleic acids functionalized AuNPs

on the cell membranes were explored.

Tissue Engineering And Nanotheranostics

particle, leading to conversion of the non­propagating near­field

light into the conventional propagating scattered light. The scattered

light is detected by camera while the returning laser is stopped,

inducing dark­field effects. Taking advantage of the focus on a thin

layer by TIR illumination, background noise was decreased and

images with high SNR were acquired. In a study of the rotary mecha­

nism of F 1 –ATPase 1–2 nm, spatial precision and 9.1 μs temporal

resolution were demonstrated by the successful application of this

home­built TIRDFM system. Later, to achieve higher sensitivity,

white light laser with average power output of 2.8 W was reported to

supply a strong light source to illuminate the particles in TIR geom­

etry. With the help of the improved system, the dynamic evolution of

a single protein binding to a single AuNP was observed with milli­