Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

170 Tissue Engineering and Nanotheranostics

rotational movement of anisotropic nanoparticles with a subdegree

uncertainty.106–108 By combination of defocused imaging and the rota

tion of the polarization direction of light incident upon the sample,

the 3D orientation of stationary AuNPs was resolved with a higher

precision in TIR scattering microscope. In another work, a dual color

TIR scattering microscope was used to track the orientation change

of AuNRs when interacting with synthetic lipid membranes by analyz

ing orientationdependent intensity fluctuations of surface plasmon

resonance enhancement along the long and short axis simultane

ously.^108 AuNR orientation changes in the sample plane can be tracked

in details using polarized light that propagates parallel to the prism

surface, while outofplane orientation changes can be tracked utiliz

ing the long axis of the AuNR and its interaction with polarized light

propagating perpendicularly to the prism surface.

5. Application based on Localized Surface

Plasmon Resonance

The typical LSPR sensing application of plasmonic nanoparticles is to

detect changes of their surrounding environment through shifts of

scattering profile.^109 This kind of a sensor has been designed to detect

bimolecular binding events110,111 close to the surface and molecular

adsorb on the surface,^112 to characterize carbohydrate–protein interac

tions^113 and measure the binding of a protein to DNA.^114 For instant,

a sensor^115 was designed to detect conformational changes in a surface

bound construct of the calciumsensitive protein calmodulin. Increases

in calcium concentration induce a 0.96 nm redshift in the spectral

position of the LSPR extinction maximum (λ max). Addition of a

calciumchelating agent forces the protein to return to its original

conformation and is detected as a reversal of the λ maxshift.

5.1. Localized Surface Plasmon Resonance Change to

Sensor Catalytic Reaction

Due to the quantum effects and free electrons on their surface,

AuNPs of small scale exhibit catalytic activity and attract many scien

tists to study its mechanism. It’s discovered that catalytic reactions

Tissue Engineering And Nanotheranostics

rotational movement of anisotropic nanoparticles with a subdegree

uncertainty.106–108 By combination of defocused imaging and the rota

tion of the polarization direction of light incident upon the sample,

the 3D orientation of stationary AuNPs was resolved with a higher

precision in TIR scattering microscope. In another work, a dual color

TIR scattering microscope was used to track the orientation change

of AuNRs when interacting with synthetic lipid membranes by analyz

ing orientationdependent intensity fluctuations of surface plasmon

resonance enhancement along the long and short axis simultane

ously.^108 AuNR orientation changes in the sample plane can be tracked

in details using polarized light that propagates parallel to the prism

surface, while outofplane orientation changes can be tracked utiliz

ing the long axis of the AuNR and its interaction with polarized light

propagating perpendicularly to the prism surface.

5. Application based on Localized Surface

Plasmon Resonance

The typical LSPR sensing application of plasmonic nanoparticles is to

detect changes of their surrounding environment through shifts of

scattering profile.^109 This kind of a sensor has been designed to detect

bimolecular binding events110,111 close to the surface and molecular

adsorb on the surface,^112 to characterize carbohydrate–protein interac

tions^113 and measure the binding of a protein to DNA.^114 For instant,

a sensor^115 was designed to detect conformational changes in a surface

bound construct of the calciumsensitive protein calmodulin. Increases

in calcium concentration induce a 0.96 nm redshift in the spectral

position of the LSPR extinction maximum (λ max). Addition of a

calciumchelating agent forces the protein to return to its original

conformation and is detected as a reversal of the λ maxshift.

5.1. Localized Surface Plasmon Resonance Change to

Sensor Catalytic Reaction

Due to the quantum effects and free electrons on their surface,

AuNPs of small scale exhibit catalytic activity and attract many scien

tists to study its mechanism. It’s discovered that catalytic reactions

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Tissue Engineering And Nanotheranostics

rotational movement of anisotropic nanoparticles with a subdegree

uncertainty.106–108 By combination of defocused imaging and the rota­

tion of the polarization direction of light incident upon the sample,

the 3D orientation of stationary AuNPs was resolved with a higher

precision in TIR scattering microscope. In another work, a dual color

TIR scattering microscope was used to track the orientation change

of AuNRs when interacting with synthetic lipid membranes by analyz­

ing orientation­dependent intensity fluctuations of surface plasmon

resonance enhancement along the long and short axis simultane­

ously.^108 AuNR orientation changes in the sample plane can be tracked

in details using polarized light that propagates parallel to the prism

surface, while out­of­plane orientation changes can be tracked utiliz­

ing the long axis of the AuNR and its interaction with polarized light

propagating perpendicularly to the prism surface.

5. Application based on Localized Surface

Plasmon Resonance

The typical LSPR sensing application of plasmonic nanoparticles is to

detect changes of their surrounding environment through shifts of

scattering profile.^109 This kind of a sensor has been designed to detect

bimolecular binding events110,111 close to the surface and molecular

adsorb on the surface,^112 to characterize carbohydrate–protein interac­

tions^113 and measure the binding of a protein to DNA.^114 For instant,

a sensor^115 was designed to detect conformational changes in a surface­

bound construct of the calcium­sensitive protein calmodulin. Increases

in calcium concentration induce a 0.96 nm red­shift in the spectral

position of the LSPR extinction maximum (λ max). Addition of a

calcium­chelating agent forces the protein to return to its original

conformation and is detected as a reversal of the λ max­shift.

5.1. Localized Surface Plasmon Resonance Change to

Sensor Catalytic Reaction

Due to the quantum effects and free electrons on their surface,

AuNPs of small scale exhibit catalytic activity and attract many scien­

tists to study its mechanism. It’s discovered that catalytic reactions

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Company

Features

Documentation

Resources

uncertainty.106–108 By combination of defocused imaging and the rota

of AuNRs when interacting with synthetic lipid membranes by analyz

ing orientationdependent intensity fluctuations of surface plasmon

resonance enhancement along the long and short axis simultane

surface, while outofplane orientation changes can be tracked utiliz

adsorb on the surface,^112 to characterize carbohydrate–protein interac

a sensor^115 was designed to detect conformational changes in a surface

bound construct of the calciumsensitive protein calmodulin. Increases

in calcium concentration induce a 0.96 nm redshift in the spectral

calciumchelating agent forces the protein to return to its original

conformation and is detected as a reversal of the λ maxshift.

AuNPs of small scale exhibit catalytic activity and attract many scien