Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

180 Tissue Engineering and Nanotheranostics

apoptosis. Following that, a detailed work on concentrationdependent

has been done. They found that cancer cell communities have cellular

attraction, clustering, and bystander killing at low concentrations,

while the degree of attraction and clustering is diminished and most

cells in community died at high nanoparticle concentrations.

6. Other Application

Besides the nanoparticle’s plasmic property, its optical property, such

as Förster resonance energy transfer (FRET), surface enhanced Raman

scattering (SERs) and nonlinear optical properties, also have been

applied to construct biosensors for biosensing and bioimaging. For

example, with the help of its high surface area to volume ratio, a serial

of biomolecules and biomarkers can be conjugated to a nanoparticle,

constructing a multifunction probe for detecting various material,

ranging from small organic molecules to proteins.

6.1. Energy Transfer

FRET technology is widely applied in detecting dynamic changes at

single molecule level. The nonradiative transfer of excitation energy

between donor and acceptor interacts by dipole–dipole when dis

tance between them is smaller than the Förster distance (typically

less than 10 nm).159,160 To trigger FRET, the emission frequency of

the donor should match the absorption frequency of the

acceptor.161–163 Due to their large molar extinction coefficients,

AuNPs can be used as acceptors to quench the donors.^164 When

metal nanoparticles are used as acceptors, the energy transfer phe

nomenon is named NSET. While AuNPs also can be used as a donor

to be quenched by absorbed molecular acceptors this energy transfer

form is named as PRET.^165

6.1.1. Plasmon resonance energy transfer

When the plasmon resonance spectrum of a plasmon sensor inten

tionally matches the absorption spectrum of chemical or biological

Tissue Engineering And Nanotheranostics

apoptosis. Following that, a detailed work on concentrationdependent

has been done. They found that cancer cell communities have cellular

attraction, clustering, and bystander killing at low concentrations,

while the degree of attraction and clustering is diminished and most

cells in community died at high nanoparticle concentrations.

6. Other Application

Besides the nanoparticle’s plasmic property, its optical property, such

as Förster resonance energy transfer (FRET), surface enhanced Raman

scattering (SERs) and nonlinear optical properties, also have been

applied to construct biosensors for biosensing and bioimaging. For

example, with the help of its high surface area to volume ratio, a serial

of biomolecules and biomarkers can be conjugated to a nanoparticle,

constructing a multifunction probe for detecting various material,

ranging from small organic molecules to proteins.

6.1. Energy Transfer

FRET technology is widely applied in detecting dynamic changes at

single molecule level. The nonradiative transfer of excitation energy

between donor and acceptor interacts by dipole–dipole when dis

tance between them is smaller than the Förster distance (typically

less than 10 nm).159,160 To trigger FRET, the emission frequency of

the donor should match the absorption frequency of the

acceptor.161–163 Due to their large molar extinction coefficients,

AuNPs can be used as acceptors to quench the donors.^164 When

metal nanoparticles are used as acceptors, the energy transfer phe

nomenon is named NSET. While AuNPs also can be used as a donor

to be quenched by absorbed molecular acceptors this energy transfer

form is named as PRET.^165

6.1.1. Plasmon resonance energy transfer

When the plasmon resonance spectrum of a plasmon sensor inten

tionally matches the absorption spectrum of chemical or biological

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Tissue Engineering And Nanotheranostics

apoptosis. Following that, a detailed work on concentration­dependent

has been done. They found that cancer cell communities have cellular

attraction, clustering, and bystander killing at low concentrations,

while the degree of attraction and clustering is diminished and most

cells in community died at high nanoparticle concentrations.

6. Other Application

Besides the nanoparticle’s plasmic property, its optical property, such

as Förster resonance energy transfer (FRET), surface enhanced Raman

scattering (SERs) and nonlinear optical properties, also have been

applied to construct biosensors for biosensing and bioimaging. For

example, with the help of its high surface area to volume ratio, a serial

of biomolecules and biomarkers can be conjugated to a nanoparticle,

constructing a multifunction probe for detecting various material,

ranging from small organic molecules to proteins.

6.1. Energy Transfer

FRET technology is widely applied in detecting dynamic changes at

single molecule level. The non­radiative transfer of excitation energy

between donor and acceptor interacts by dipole–dipole when dis­

tance between them is smaller than the Förster distance (typically

less than 10 nm).159,160 To trigger FRET, the emission frequency of

the donor should match the absorption frequency of the

acceptor.161–163 Due to their large molar extinction coefficients,

AuNPs can be used as acceptors to quench the donors.^164 When

metal nanoparticles are used as acceptors, the energy transfer phe­

nomenon is named NSET. While AuNPs also can be used as a donor

to be quenched by absorbed molecular acceptors this energy transfer

form is named as PRET.^165

6.1.1. Plasmon resonance energy transfer

When the plasmon resonance spectrum of a plasmon sensor inten­

tionally matches the absorption spectrum of chemical or biological

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Company

Features

Documentation

Resources

apoptosis. Following that, a detailed work on concentrationdependent

single molecule level. The nonradiative transfer of excitation energy

between donor and acceptor interacts by dipole–dipole when dis

metal nanoparticles are used as acceptors, the energy transfer phe

When the plasmon resonance spectrum of a plasmon sensor inten