Nanoparticle Functionalization and Its Potentials for Molecular Imaging

Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast t...

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Published inAdvanced science Vol. 4; no. 3; pp. 1600279 - n/a
Main Authors Thiruppathi, Rukmani, Mishra, Sachin, Ganapathy, Mathangi, Padmanabhan, Parasuraman, Gulyás, Balázs
Format Journal Article
LanguageEnglish
Published Germany John Wiley & Sons, Inc 01.03.2017
John Wiley and Sons Inc
Subjects
Biocompatibility
Cadmium telluride
Chemistry
conjugation
Efficiency
functionalization
imaging
Ligands
microscopy
Nanoparticles
NMR
Nuclear magnetic resonance
Quantum dots
Regulatory approval
Review
Reviews
functionalization
microscopy
nanoparticles
conjugation
imaging
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Abstract Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast to obtain viable information. This review article discusses how functionalization enhances molecular imaging and enables multimodal imaging by which images with combination of functions particular to each modality can be obtained. This also explains how nanoparticles interacting at molecular level, when functionalized with molecules can target the cells of interest or substances with high specificity, reducing background signal and allowing simultaneous therapies to be carried out while imaging. Functionalization allows imaging for a prolonged period and enables to track the cells over a period of time. Recent researches and progress in functionalizing the nanoparticles to specifically enhance bioimaging with different modalities and their applications are reviewed in this article. Recent approaches and methods of specifically functionalizing nanoparticles to better equip the molecular imaging techniques like confocal and fluorescence microscopy, magnetic resonance imaging, positron emission tomography, and computed tomography are reviewed while providing an overview of chemistry behind functionalization and development of various advanced probe models including theranostics, multimodal imaging, and intraoperative therapies through functionalization.
AbstractList Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast to obtain viable information. This review article discusses how functionalization enhances molecular imaging and enables multimodal imaging by which images with combination of functions particular to each modality can be obtained. This also explains how nanoparticles interacting at molecular level, when functionalized with molecules can target the cells of interest or substances with high specificity, reducing background signal and allowing simultaneous therapies to be carried out while imaging. Functionalization allows imaging for a prolonged period and enables to track the cells over a period of time. Recent researches and progress in functionalizing the nanoparticles to specifically enhance bioimaging with different modalities and their applications are reviewed in this article.Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast to obtain viable information. This review article discusses how functionalization enhances molecular imaging and enables multimodal imaging by which images with combination of functions particular to each modality can be obtained. This also explains how nanoparticles interacting at molecular level, when functionalized with molecules can target the cells of interest or substances with high specificity, reducing background signal and allowing simultaneous therapies to be carried out while imaging. Functionalization allows imaging for a prolonged period and enables to track the cells over a period of time. Recent researches and progress in functionalizing the nanoparticles to specifically enhance bioimaging with different modalities and their applications are reviewed in this article.
Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast to obtain viable information. This review article discusses how functionalization enhances molecular imaging and enables multimodal imaging by which images with combination of functions particular to each modality can be obtained. This also explains how nanoparticles interacting at molecular level, when functionalized with molecules can target the cells of interest or substances with high specificity, reducing background signal and allowing simultaneous therapies to be carried out while imaging. Functionalization allows imaging for a prolonged period and enables to track the cells over a period of time. Recent researches and progress in functionalizing the nanoparticles to specifically enhance bioimaging with different modalities and their applications are reviewed in this article.
Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field of medicine. In molecular imaging, quality functional images are required with proper differentiation which can be seen with high contrast to obtain viable information. This review article discusses how functionalization enhances molecular imaging and enables multimodal imaging by which images with combination of functions particular to each modality can be obtained. This also explains how nanoparticles interacting at molecular level, when functionalized with molecules can target the cells of interest or substances with high specificity, reducing background signal and allowing simultaneous therapies to be carried out while imaging. Functionalization allows imaging for a prolonged period and enables to track the cells over a period of time. Recent researches and progress in functionalizing the nanoparticles to specifically enhance bioimaging with different modalities and their applications are reviewed in this article. Recent approaches and methods of specifically functionalizing nanoparticles to better equip the molecular imaging techniques like confocal and fluorescence microscopy, magnetic resonance imaging, positron emission tomography, and computed tomography are reviewed while providing an overview of chemistry behind functionalization and development of various advanced probe models including theranostics, multimodal imaging, and intraoperative therapies through functionalization.
Author Ganapathy, Mathangi
Thiruppathi, Rukmani
Gulyás, Balázs
Mishra, Sachin
Padmanabhan, Parasuraman
AuthorAffiliation 2 Center for Biotechnology Alagappa College of Technology Anna University Sardar Patel Road Chennai Tamil Nadu 600025 India
1 Lee Kong Chian School of Medicine Nanyang Technological University 59 Nanyang Drive 636921 Singapore
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  surname: Padmanabhan
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  surname: Gulyás
  fullname: Gulyás, Balázs
  email: balazs.gulyas@ntu.edu.sg
  organization: Nanyang Technological University
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Issue 3
Keywords functionalization
microscopy
nanoparticles
conjugation
imaging
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Snippet Functionalization enhances the properties and characteristics of nanoparticles through surface modification, and enables them to play a major role in the field...
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StartPage 1600279
SubjectTerms Biocompatibility
Cadmium telluride
Chemistry
conjugation
Efficiency
functionalization
imaging
Ligands
microscopy
Nanoparticles
NMR
Nuclear magnetic resonance
Quantum dots
Regulatory approval
Review
Reviews
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Title Nanoparticle Functionalization and Its Potentials for Molecular Imaging
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fadvs.201600279
https://www.ncbi.nlm.nih.gov/pubmed/28331783
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Volume 4
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