Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

178 Tissue Engineering and Nanotheranostics

field in the gap between L– and S–AuNPs allows indirect and

sensitive monitoring of the catalytic reaction, which provides ready

extraction of physicochemical parameters for quantitative under

standing of AuNPbased catalysis.143,144

5.3. Localized Surface Plasmon Resonance Imaging in Cells

The distancedependent electromagnetic coupling of nanoparticles

provides a unique approach for realtime monitoring nanoparticles

assembly and subsequent trafficking during nanoparticles ternaliza

tion. Reinhard et al. used this method to investigate the interactions

of negatively charged AuNPs with J774A.1 muring macrophages.^14

They demonstrated that AuNPs uptake is mediated by scavenger

receptors, and this internalization is associated with a time and con

centrationdependent nanoparticles assembling process. Detailed

study showed that both caveolin and clathrindependent endocytosis

domain this uptake process. The clathrindependent endocytosis leads

to nonagglomerated nanoparticles uptake within the cells while

caveolindependent endocytosis induces the formation of compact

nanoparticles clusters. Sokolov et al. applied DFM to track anti

EGFR AuNPs, and found a progressive redshift greater than 100 nm

in the nanoparticle plasmon resonance wavelength over a time period

of 60 min.^145 They demonstrated that changes in the scattering peak

are associated with EGFR trapped by the cell membrane, early

endosomes, and late endosomes. Combining these experiment data

with statistical analysis of RGBchannel, they create a realtime map

of EGFR regulatory states in living cells.

In addition, there are many other works on the determination of

noble nanoparticle interacting with cellular, for example, a micro

scopic method was developed to quantify the number of nanoparticle

and the degree of their aggregation in the cells.146,147 The major

advantage of this method is to eliminate the influence of nanoparticles

binding to the outer surface of the cells. Fan et al. also reported some

work on the interaction between AuNPs and cells, such as the uptake

methods, the transport pathways and the regulation by DNA

nanotechnology.^148

Tissue Engineering And Nanotheranostics

field in the gap between L– and S–AuNPs allows indirect and

sensitive monitoring of the catalytic reaction, which provides ready

extraction of physicochemical parameters for quantitative under

standing of AuNPbased catalysis.143,144

5.3. Localized Surface Plasmon Resonance Imaging in Cells

The distancedependent electromagnetic coupling of nanoparticles

provides a unique approach for realtime monitoring nanoparticles

assembly and subsequent trafficking during nanoparticles ternaliza

tion. Reinhard et al. used this method to investigate the interactions

of negatively charged AuNPs with J774A.1 muring macrophages.^14

They demonstrated that AuNPs uptake is mediated by scavenger

receptors, and this internalization is associated with a time and con

centrationdependent nanoparticles assembling process. Detailed

study showed that both caveolin and clathrindependent endocytosis

domain this uptake process. The clathrindependent endocytosis leads

to nonagglomerated nanoparticles uptake within the cells while

caveolindependent endocytosis induces the formation of compact

nanoparticles clusters. Sokolov et al. applied DFM to track anti

EGFR AuNPs, and found a progressive redshift greater than 100 nm

in the nanoparticle plasmon resonance wavelength over a time period

of 60 min.^145 They demonstrated that changes in the scattering peak

are associated with EGFR trapped by the cell membrane, early

endosomes, and late endosomes. Combining these experiment data

with statistical analysis of RGBchannel, they create a realtime map

of EGFR regulatory states in living cells.

In addition, there are many other works on the determination of

noble nanoparticle interacting with cellular, for example, a micro

scopic method was developed to quantify the number of nanoparticle

and the degree of their aggregation in the cells.146,147 The major

advantage of this method is to eliminate the influence of nanoparticles

binding to the outer surface of the cells. Fan et al. also reported some

work on the interaction between AuNPs and cells, such as the uptake

methods, the transport pathways and the regulation by DNA

nanotechnology.^148

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Tissue Engineering And Nanotheranostics

field in the gap between L– and S–AuNPs allows indirect and

sensitive monitoring of the catalytic reaction, which provides ready

extraction of physicochemical parameters for quantitative under­

standing of AuNP­based catalysis.143,144

5.3. Localized Surface Plasmon Resonance Imaging in Cells

The distance­dependent electromagnetic coupling of nanoparticles

provides a unique approach for real­time monitoring nanoparticles

assembly and subsequent trafficking during nanoparticles ternaliza­

tion. Reinhard et al. used this method to investigate the interactions

of negatively charged AuNPs with J774A.1 muring macrophages.^14

They demonstrated that AuNPs uptake is mediated by scavenger

receptors, and this internalization is associated with a time­ and con­

centration­dependent nanoparticles assembling process. Detailed

study showed that both caveolin­ and clathrin­dependent endocytosis

domain this uptake process. The clathrin­dependent endocytosis leads

to non­agglomerated nanoparticles uptake within the cells while

caveolin­dependent endocytosis induces the formation of compact

nanoparticles clusters. Sokolov et al. applied DFM to track anti­

EGFR AuNPs, and found a progressive red­shift greater than 100 nm

in the nanoparticle plasmon resonance wavelength over a time period

of 60 min.^145 They demonstrated that changes in the scattering peak

are associated with EGFR trapped by the cell membrane, early

endosomes, and late endosomes. Combining these experiment data

with statistical analysis of RGB­channel, they create a real­time map

of EGFR regulatory states in living cells.

In addition, there are many other works on the determination of

noble nanoparticle interacting with cellular, for example, a micro­

scopic method was developed to quantify the number of nanoparticle

and the degree of their aggregation in the cells.146,147 The major

advantage of this method is to eliminate the influence of nanoparticles

binding to the outer surface of the cells. Fan et al. also reported some

work on the interaction between AuNPs and cells, such as the uptake

methods, the transport pathways and the regulation by DNA

nanotechnology.^148

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Company

Features

Documentation

Resources

extraction of physicochemical parameters for quantitative under

standing of AuNPbased catalysis.143,144

The distancedependent electromagnetic coupling of nanoparticles

provides a unique approach for realtime monitoring nanoparticles

assembly and subsequent trafficking during nanoparticles ternaliza

receptors, and this internalization is associated with a time and con

centrationdependent nanoparticles assembling process. Detailed

study showed that both caveolin and clathrindependent endocytosis

domain this uptake process. The clathrindependent endocytosis leads

to nonagglomerated nanoparticles uptake within the cells while

caveolindependent endocytosis induces the formation of compact

nanoparticles clusters. Sokolov et al. applied DFM to track anti

EGFR AuNPs, and found a progressive redshift greater than 100 nm

with statistical analysis of RGBchannel, they create a realtime map

noble nanoparticle interacting with cellular, for example, a micro