Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

184 Tissue Engineering and Nanotheranostics

the fluorescence was bright like a flare.^173 Later, this system was

extended for multiplexed detection of different targets simultaneously

in living cells.174–176 Besides nanoflare, NEST sensor based on molecu

lar beacon, composed of a loop structure and a stem structure,177,178 has

been employed. In the hairpin structure, the nucleotides at each termi

nus, where the fluorophore and quencher are anchored respectively,

are complementary to each other, resulting in the quenched fluoro

phore. Once the target nucleic acid hybridize with molecular beacon,

the stem structure opens and the fluorescence recovers. AuNPs behave

excellently in molecular beacons due to their high quenching effi

ciency. Dubetret et al. used AuNPs to assist molecular beacon to detect

DNA targets, they found that sensitivity had improved 100 times

compared to conventional molecular beacon.^179 Fan et al.180,181

reported a similar probe to detect three different tumorsuppressor

genes (Fig. 7(b)). Additionally, the AuNPsassisted molecular beacon

demonstrate a singlebase mismatch selectivity of 25:1, so they hold

great potential in multiplexed detection of singlebase mismatch.

Generally, small AuNPs (with size less than 20 nm) are more often

used in NEST, as absorption is dominant over scattering. While large

AuNPs are more often used in PRET as scattering is dominant above

600 nm.^182

6.2. Surface-Enhanced Raman Scattering

Raman effect originates from the inelastic scattering when light inter

acts with matter, and it means that an energy exchange occurs

between the incident photons and the scattering substance. Like NIR

spectrum, the Raman spectrum of different molecules is so unique

that it has also been called a “Raman fingerprint”.^183 A major limita

tion of traditional Raman spectroscopy is that its SNR ratio is too low,

especially in in vivo imaging with short acquisition time. SERs is the

most crucial solution to amplify Raman intensity.^184 SERs is a plas

monic effect in which the Raman intensity of a molecule is enhanced

enormously (up to 10^14 fold) when adsorbed on a rough metal (e.g.

Ag or Au) surface with high curvature, such as a nanoparticle.185,186

Both electromagnetic (EM) enhancement and chemical enhancement

Tissue Engineering And Nanotheranostics

the fluorescence was bright like a flare.^173 Later, this system was

extended for multiplexed detection of different targets simultaneously

in living cells.174–176 Besides nanoflare, NEST sensor based on molecu

lar beacon, composed of a loop structure and a stem structure,177,178 has

been employed. In the hairpin structure, the nucleotides at each termi

nus, where the fluorophore and quencher are anchored respectively,

are complementary to each other, resulting in the quenched fluoro

phore. Once the target nucleic acid hybridize with molecular beacon,

the stem structure opens and the fluorescence recovers. AuNPs behave

excellently in molecular beacons due to their high quenching effi

ciency. Dubetret et al. used AuNPs to assist molecular beacon to detect

DNA targets, they found that sensitivity had improved 100 times

compared to conventional molecular beacon.^179 Fan et al.180,181

reported a similar probe to detect three different tumorsuppressor

genes (Fig. 7(b)). Additionally, the AuNPsassisted molecular beacon

demonstrate a singlebase mismatch selectivity of 25:1, so they hold

great potential in multiplexed detection of singlebase mismatch.

Generally, small AuNPs (with size less than 20 nm) are more often

used in NEST, as absorption is dominant over scattering. While large

AuNPs are more often used in PRET as scattering is dominant above

600 nm.^182

6.2. Surface-Enhanced Raman Scattering

Raman effect originates from the inelastic scattering when light inter

acts with matter, and it means that an energy exchange occurs

between the incident photons and the scattering substance. Like NIR

spectrum, the Raman spectrum of different molecules is so unique

that it has also been called a “Raman fingerprint”.^183 A major limita

tion of traditional Raman spectroscopy is that its SNR ratio is too low,

especially in in vivo imaging with short acquisition time. SERs is the

most crucial solution to amplify Raman intensity.^184 SERs is a plas

monic effect in which the Raman intensity of a molecule is enhanced

enormously (up to 10^14 fold) when adsorbed on a rough metal (e.g.

Ag or Au) surface with high curvature, such as a nanoparticle.185,186

Both electromagnetic (EM) enhancement and chemical enhancement

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Tissue Engineering And Nanotheranostics

the fluorescence was bright like a flare.^173 Later, this system was

extended for multiplexed detection of different targets simultaneously

in living cells.174–176 Besides nanoflare, NEST sensor based on molecu­

lar beacon, composed of a loop structure and a stem structure,177,178 has

been employed. In the hairpin structure, the nucleotides at each termi­

nus, where the fluorophore and quencher are anchored respectively,

are complementary to each other, resulting in the quenched fluoro­

phore. Once the target nucleic acid hybridize with molecular beacon,

the stem structure opens and the fluorescence recovers. AuNPs behave

excellently in molecular beacons due to their high quenching effi­

ciency. Dubetret et al. used AuNPs to assist molecular beacon to detect

DNA targets, they found that sensitivity had improved 100 times

compared to conventional molecular beacon.^179 Fan et al.180,181

reported a similar probe to detect three different tumor­suppressor

genes (Fig. 7(b)). Additionally, the AuNPs­assisted molecular beacon

demonstrate a single­base mismatch selectivity of 25:1, so they hold

great potential in multiplexed detection of single­base mismatch.

Generally, small AuNPs (with size less than 20 nm) are more often

used in NEST, as absorption is dominant over scattering. While large

AuNPs are more often used in PRET as scattering is dominant above

600 nm.^182

6.2. Surface-Enhanced Raman Scattering

Raman effect originates from the inelastic scattering when light inter­

acts with matter, and it means that an energy exchange occurs

between the incident photons and the scattering substance. Like NIR

spectrum, the Raman spectrum of different molecules is so unique

that it has also been called a “Raman fingerprint”.^183 A major limita­

tion of traditional Raman spectroscopy is that its SNR ratio is too low,

especially in in vivo imaging with short acquisition time. SERs is the

most crucial solution to amplify Raman intensity.^184 SERs is a plas­

monic effect in which the Raman intensity of a molecule is enhanced

enormously (up to 10^14 ­fold) when adsorbed on a rough metal (e.g.

Ag or Au) surface with high curvature, such as a nanoparticle.185,186

Both electromagnetic (EM) enhancement and chemical enhancement

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Features

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Resources

in living cells.174–176 Besides nanoflare, NEST sensor based on molecu

been employed. In the hairpin structure, the nucleotides at each termi

are complementary to each other, resulting in the quenched fluoro

excellently in molecular beacons due to their high quenching effi

reported a similar probe to detect three different tumorsuppressor

genes (Fig. 7(b)). Additionally, the AuNPsassisted molecular beacon

demonstrate a singlebase mismatch selectivity of 25:1, so they hold

great potential in multiplexed detection of singlebase mismatch.

Raman effect originates from the inelastic scattering when light inter

that it has also been called a “Raman fingerprint”.^183 A major limita

most crucial solution to amplify Raman intensity.^184 SERs is a plas

enormously (up to 10^14 fold) when adsorbed on a rough metal (e.g.