Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

160 Tissue Engineering and Nanotheranostics

incident light at the nanoscale.2,24,25 As the electric field of nanoparti

cle depends on its size, shape, structure and surrounding environ

ment,5,19,26 its plasmon property, corresponding with its LSPR, the

wavelength of the exciting light are tunable. Today, advances in col

loidal synthesis methods enable nanoparticle with tunable shape,27,28

such as nanosphere, nanorods, nanostars, varied sizes29–32 and there

fore wide range of applications in catalysis, optics, chemical and bio

logical sensing, and medical therapeutics to be obtained.

During the last two decades, to acquire nanoparticle with certain

plasmonic property and strong LSPR effect, considerable effort has

been focused on improving the methods of synthesizing and organ

izing nanoparticles with certain shape, structure, solubility, stability,

and functionality. Although numerous preparative methods have been

reported, these methods generally can be divided into two approaches,

“topdown”33–37 (physical manipulation) and “bottomup” (chemical

transformation). In the following section, I would like to briefly

introduce several popular methods of synthesizing and modifying

plasmonic nanoparticles from these approaches.

3.1. Bottom-Up Approach (Chemical Methods)

Bottomup approach, mainly based on chemical methods by reducing

metalsalt in the presence of surface stabilizers,38,39 provides us a serial

of metal nanoparticles with controllable size, morphology, coupled

structure and plasmonic property. We will briefly introduce some

chemical methods to synthesize gold nanoparticle (AuNP) and silver

nanoparticle (AgNP), which show strong LSPR effect and are widely

applied in biosensor and bioimaging.

3.1.1. Gold nanoparticles

Among the conventional methods of AuNPs synthesis by reduction

of gold (III) derivatives, the most popular method is reducing

HAuCl 4 with citrate in water, which was proposed by Turkevitch in

1951.^40 In this method, citric acid acts as both reducing and stabiliz

ing agents and provides AuNPs with diameters of 20 nm. G. Frens’

Tissue Engineering And Nanotheranostics

incident light at the nanoscale.2,24,25 As the electric field of nanoparti

cle depends on its size, shape, structure and surrounding environ

ment,5,19,26 its plasmon property, corresponding with its LSPR, the

wavelength of the exciting light are tunable. Today, advances in col

loidal synthesis methods enable nanoparticle with tunable shape,27,28

such as nanosphere, nanorods, nanostars, varied sizes29–32 and there

fore wide range of applications in catalysis, optics, chemical and bio

logical sensing, and medical therapeutics to be obtained.

During the last two decades, to acquire nanoparticle with certain

plasmonic property and strong LSPR effect, considerable effort has

been focused on improving the methods of synthesizing and organ

izing nanoparticles with certain shape, structure, solubility, stability,

and functionality. Although numerous preparative methods have been

reported, these methods generally can be divided into two approaches,

“topdown”33–37 (physical manipulation) and “bottomup” (chemical

transformation). In the following section, I would like to briefly

introduce several popular methods of synthesizing and modifying

plasmonic nanoparticles from these approaches.

3.1. Bottom-Up Approach (Chemical Methods)

Bottomup approach, mainly based on chemical methods by reducing

metalsalt in the presence of surface stabilizers,38,39 provides us a serial

of metal nanoparticles with controllable size, morphology, coupled

structure and plasmonic property. We will briefly introduce some

chemical methods to synthesize gold nanoparticle (AuNP) and silver

nanoparticle (AgNP), which show strong LSPR effect and are widely

applied in biosensor and bioimaging.

3.1.1. Gold nanoparticles

Among the conventional methods of AuNPs synthesis by reduction

of gold (III) derivatives, the most popular method is reducing

HAuCl 4 with citrate in water, which was proposed by Turkevitch in

1951.^40 In this method, citric acid acts as both reducing and stabiliz

ing agents and provides AuNPs with diameters of 20 nm. G. Frens’

Get our desktop app

Company

Features

Documentation

Resources

Tissue Engineering And Nanotheranostics

incident light at the nanoscale.2,24,25 As the electric field of nanoparti­

cle depends on its size, shape, structure and surrounding environ­

ment,5,19,26 its plasmon property, corresponding with its LSPR, the

wavelength of the exciting light are tunable. Today, advances in col­

loidal synthesis methods enable nanoparticle with tunable shape,27,28

such as nanosphere, nanorods, nanostars, varied sizes29–32 and there­

fore wide range of applications in catalysis, optics, chemical and bio­

logical sensing, and medical therapeutics to be obtained.

During the last two decades, to acquire nanoparticle with certain

plasmonic property and strong LSPR effect, considerable effort has

been focused on improving the methods of synthesizing and organ­

izing nanoparticles with certain shape, structure, solubility, stability,

and functionality. Although numerous preparative methods have been

reported, these methods generally can be divided into two approaches,

“top­down”33–37 (physical manipulation) and “bottom­up” (chemical

transformation). In the following section, I would like to briefly

introduce several popular methods of synthesizing and modifying

plasmonic nanoparticles from these approaches.

3.1. Bottom-Up Approach (Chemical Methods)

Bottom­up approach, mainly based on chemical methods by reducing

metal­salt in the presence of surface stabilizers,38,39 provides us a serial

of metal nanoparticles with controllable size, morphology, coupled

structure and plasmonic property. We will briefly introduce some

chemical methods to synthesize gold nanoparticle (AuNP) and silver

nanoparticle (AgNP), which show strong LSPR effect and are widely

applied in biosensor and bioimaging.

3.1.1. Gold nanoparticles

Among the conventional methods of AuNPs synthesis by reduction

of gold (III) derivatives, the most popular method is reducing

HAuCl 4 with citrate in water, which was proposed by Turkevitch in

1951.^40 In this method, citric acid acts as both reducing and stabiliz­

ing agents and provides AuNPs with diameters of 20 nm. G. Frens’

Get our desktop app

Company

Features

Documentation

Resources

incident light at the nanoscale.2,24,25 As the electric field of nanoparti

cle depends on its size, shape, structure and surrounding environ

wavelength of the exciting light are tunable. Today, advances in col

such as nanosphere, nanorods, nanostars, varied sizes29–32 and there

fore wide range of applications in catalysis, optics, chemical and bio

been focused on improving the methods of synthesizing and organ

“topdown”33–37 (physical manipulation) and “bottomup” (chemical

Bottomup approach, mainly based on chemical methods by reducing

metalsalt in the presence of surface stabilizers,38,39 provides us a serial

1951.^40 In this method, citric acid acts as both reducing and stabiliz