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Near Infrared-Emitting Nanoparticles for Biomedical Applications

✍ Scribed by Antonio Benayas (editor), Eva Hemmer (editor), Guosong Hong (editor), Daniel Jaque (editor)

Publisher
Springer
Year
2020
Tongue
English
Leaves
391
Category
Library
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✦ Synopsis

​This book analyzes and evaluates the growing field of light-emitting nanoprobes as contrast agents for in vivo imaging and sensing. It is a comprehensive resource that critically analyzes the state of the art in an interdisciplinary manner, with a special focus on the shift of emission wavelengths into the near-infrared (NIR) spectral region (ranging from 0.7 to 2 microns), which has greatly contributed to the latest advances in biomedical imaging and sensing. This book discusses merits of different contrast agents at nanoscale, and how their unique chemical and structural properties lead to the emission and interaction of light within the NIR window. Both the NIR-emitting materials and various surface modification strategies governing their interactions with the biological system at the β€œnano” level are discussed. Furthermore, different experimental techniques and protocols for NIR-light-based in vivo imaging and sensing are addressed to shed light on further understanding of the advantages and limitations of each category of these nanoprobes.

  • Assembles the state of the art heretofore appearing in scientific literature into a comprehensive, multi-perspective guidebook on near infrared-emitting nanomaterials in an assortment of biomedical applications;
  • Explains the physical, chemical, and biological phenomena underlying near infrared-emitting nanomaterials for biomedical applications;
  • Presents conceptual and experimental approaches surrounding a unique spectral range of light emission from nanosized contrast agents, while offering a clear explanation of basic and general phenomena regarding the interaction between light and biological tissues, such as absorption, scattering and autofluorescence.

✦ Table of Contents

Preface and Summary
Acknowledgements
Contents
1 Optical Properties of Tissues in the Near Infrared: Their Relevance for Optical Bioimaging
1.1 Optical Properties of Tissues: Physical Origin and Statistical Approach
1.1.1 Basic Interactions Between Light and Matter
1.2 Light Propagation in Biological Tissues
1.3 Properties of Light in the Near Infrared
1.3.1 Blood
1.3.2 Water
1.3.3 Skin
1.3.4 Tissue Autofluorescence
1.4 Imaging in the II Near Infrared Window
1.5 Consequences of Near Infrared Light Propagation in Image Quality and Resolution
References
2 NIR Autofluorescence: Molecular Origins and Emerging Clinical Applications
2.1 Introduction
2.2 NIR Autofluorescence as a Problem
2.3 NIR Autofluorescence Sources
2.3.1 Autofluorescence in the Visible
2.3.2 In Vivo Autofluorescence in the NIR: Plant Sources
2.3.3 In Vivo Skin Autofluorescence in the NIR
2.3.4 Other Sources of In Vivo NIR Autofluorescence
2.4 NIR Autofluorescence as a Solution: Applications
2.4.1 Surgical Guidance and Diagnostics in Cancer
2.4.2 Monitoring Ophthalmological Diseases
2.4.3 Intra-Operative Parathyroid Gland Identification
2.4.4 Imaging Atherosclerotic Plaque in Coronary Artery Disease
2.5 Conclusion and Future Perspectives
References
3 Surface Modification of Near Infrared-Emitting Nanoparticles for Biomedical Applications
3.1 Introduction
3.2 Strategies for Surface Modification
3.3 Conclusion and Challenges in Surface Modification
References
4 Rare Earth-Doped Nanoparticles for Advanced In Vivo Near Infrared Imaging
4.1 Introduction
4.2 NIR Emissions from RENPs
4.2.1 NIR Upconversion Luminescence
4.2.2 NIR Downshifting Luminescence
4.3 In Vivo NIR Imaging Using RENPs
4.3.1 Bioimaging Using NIR UCL
4.3.2 Bioimaging Using NIR-II Downshifting Luminescence
4.4 Time-Gated Luminescence Imaging
4.4.1 Principle of Time-Gated Imaging
4.4.2 Time-Gated Imaging in NIR-II Window
4.4.3 Multiplexing Imaging with Tunable Lifetimes
4.5 Conclusions
References
5 Recent Advances in Development of NIR-II Fluorescent Agents
5.1 NIR-II Fluorophores with High Fluorescence Quantum Yields
5.2 NIR-II Fluorophores with Long Emission Wavelengths
5.3 Favorable Pharmacokinetics and Biocompatibility
5.4 Outlook
References
6 Near Infrared Spectral Imaging of Carbon Nanotubesfor Biomedicine
6.1 Introduction
6.2 Optophysical Properties of Single-Walled Carbon Nanotubes
6.2.1 Intrinsic Bandgap Photoluminescence
6.2.2 Isolation of Single-Nanotube Chiralities
6.2.3 Inherent Multiplicity of Nanotube Structures
6.2.4 Biocompatibility
6.3 Photoluminescent SWCNTs as Imaging and Sensing Agents
6.3.1 Structural Properties of Linear SWCNTs
6.3.2 Advantageous Optical Properties
6.3.3 Photoluminescence Modulation by Environment
6.3.4 Multimodal Functionalization of the Nanotube Structure
6.3.5 Comparison to Other NIR Agents
6.4 Instrumentation for Near Infrared Spectroscopy-Resolved Imaging
6.4.1 New Imaging Tools
6.4.2 NIR Imaging of SWCNTs in Biological Systems
6.5 Global NIR Hyperspectral Imaging
6.5.1 Hyperspectral Imaging of SWCNTs in Biological Systems
6.5.2 Applications for Characterizing Individual Carbon Nanotubes
6.6 Spectral Imaging in Live Cells
6.6.1 Applications in Live Cells
6.6.2 Spectral Imaging of a Sensor for Endolysosomal Lipids
6.7 Spectral Imaging in Vivo
6.7.1 Technical Challenges to NIR In Vivo Imaging
6.7.2 Spectral Imaging in Complex Biological Systems
6.7.3 Spectral Imaging of the Lipid Sensor in Live Animals
6.8 Conclusion
6.8.1 The Challenges of Molecular Identity, Standardization, and Biocompatibility
6.8.2 Crossroad for Nanotubes: Tool for Basic Research and Translational Biomedicine
References
7 Near Infrared-Emitting Carbon Nanomaterials for Biomedical Applications
7.1 Near Infrared-Emitting Carbon Nanomaterials
7.2 Carbon Nanomaterials
7.2.1 Carbon Nanotubes
7.2.2 Carbon Dots
7.2.3 Graphene Dots
7.3 Synthesis of Carbon Nanomaterials
7.3.1 Top-Down Synthesis of Nanomaterials
7.3.1.1 Using Arc-Discharge and Laser Ablation for the Synthesis of Carbon Nanomaterials
7.3.2 Bottom-Up Synthesis of Carbon Nanomaterials
7.3.2.1 Carbon Vapor Deposition Reactions
7.3.2.2 Solvothermal and Microwave Assisted Reactions
7.4 Biomedical Applications
7.4.1 NIR Bioimaging
7.4.2 Biosensors
7.5 Challenges and Perspectives
References
8 NIR-Persistent Luminescence Nanoparticles for Bioimaging, Principle and Perspectives
8.1 Introduction
8.2 Main Characteristics of the Persistent Luminescence Materials
8.3 Persistent Luminescence Mechanisms
8.4 Focus on One Developed Materials ZnGa2O4:Cr Nanoparticles for Persistent Luminescence Applications in the BW1 Range
8.5 Biocompatibility
8.6 Excitation Capabilities and Long-Term In Vivo Imaging
8.7 Strategies Developed to Perform Long-Time Imaging
8.8 Multimodal Imaging
8.9 Theranostics Nanoprobes
8.10 Photodynamic Therapy with PLNPs
8.11 Photothermal Therapy with PLNPs
8.12 Perspectives of the NIR-Persistent Luminescence Nanoparticles for Bioimaging
8.13 Conclusions
References
9 Near Infrared-Emitting Bioprobes for Low-Autofluorescence Imaging Techniques
9.1 Introduction
9.2 Autofluorescence Filtering Strategies
9.2.1 Spectral Filtering of the Autofluorescence: NIR-II-Emitting Nanoparticles
9.2.1.1 Carbon Nanotubes
9.2.1.2 Quantum Dots and Semiconducting Nanoparticles
9.2.1.3 Rare Earth-Doped Nanoparticles
9.2.1.4 Polymeric Nanoparticles
9.2.2 Time-Domain Filtering of Autofluorescence: Time-Gating Techniques
9.3 Excitation-Free Approaches
9.3.1 Long-Persistent-Luminescence Nanoparticles
9.3.1.1 Persistent Luminescence with Inorganic Nanoparticles
9.3.1.2 Persistent Luminescence with Organic Molecules
9.3.2 Bioluminescence
9.3.3 Chemiluminescence
9.4 Multiphoton Excitation in the NIR-II
9.5 Conclusions and Perspectives
References
10 Polymer-Functionalized NIR-Emitting Nanoparticles: Applications in Cancer Theranostics and Treatment of Bacterial Infections
Abbreviations
10.1 Introduction: Why Use Polymer Functionalization of Nanoparticles?
10.2 Types of NIR-Emitting Nanoparticles
10.2.1 Organic Dyes and Small-Molecule Probes
10.2.2 Inorganic Quantum Dots
10.2.3 Au Nanoparticles
10.2.4 Carbon Dots, Carbon Nanotubes, Graphene and their Derivatives
10.2.5 Upconversion or Downconversion Nanoparticles
10.3 Discussion and Future Prospects
References
11 Near Infrared Ag2S Quantum Dots: Synthesis, Functionalization, and In Vivo Stem Cell Tracking Applications
Abbreviations
11.1 Introduction
11.2 Synthesis of Ag2S QDs
11.2.1 Methods for Synthesizing Photoluminescent Ag2S QDs
11.2.2 Emission Wavelength Regulation of Ag2S QDs
11.2.3 Synthesis of Multifunctional Ag2S QDs
11.3 Surface Functionalization of Ag2S QDs
11.3.1 Preparing Water Soluble and Stable Ag2S QDs
11.3.2 Surface Functionalization and Biomedical Applications of Ag2S QDs
11.4 Biocompatibility of Ag2S QDs
11.4.1 In Vitro Toxicity Study of Ag2S QDs
11.4.2 In Vivo Toxicity of Ag2S QDs
11.5 In Vivo Stem Cell Tracking Applications of Ag2S QDs
11.5.1 Tracking Transplanted Stem Cells for Liver Therapy
11.5.2 Tracking Stem Cells for Cutaneous Regeneration
11.5.3 Tracking the Fate of Stem Cells by Ag2S QD-Based Multimodal Imaging
11.6 Future Prospects
References
12 Non-plasmonic NIR-Activated Photothermal Agentsfor Photothermal Therapy
12.1 Introduction
12.2 Graphene and Its Derivatives
12.2.1 Graphene
12.2.1.1 Graphene Oxide
12.2.1.2 Reduced Graphene Oxide
12.2.2 Carbon Quantum Nanodots (C-Dots, CQDs)
12.2.3 Carbon Nanotubes (CNT)
12.2.3.1 Single-Walled Nanotubes (SWNCTs)
12.2.3.2 Multi-Walled Carbon Nanotubes
12.2.4 Mesoporous Carbon Nanoframes
12.2.5 Carbonaceous Nanospheres
12.2.6 Single-Walled Carbon Nanohorns
12.3 Rare Earth-Doped Photothermal Agents
12.4 Polymeric Photothermal Agents
12.5 Silicon-Based Photothermal Agents
12.6 Titanium-Based Photothermal Agents
12.7 Iron-Based Photothermal Agents
12.8 Conclusions
References
13 NIR Fluorescent Nanoprobes and Techniques for Brain Imaging
13.1 Introduction
13.2 Optical Property of Brain Tissue
13.3 NIR Nanoprobes for In Vivo Fluorescence Imaging
13.3.1 Nanomaterial-Based NIR Nanoprobes
13.3.2 Organic Dye-Based NIR Nanoprobes
13.4 NIR Fluorescence Detection System for Brain Imaging
13.5 Non-invasive Brain Imaging Using NIR Nanoprobes
13.5.1 Cerebral Blood Vessels
13.5.1.1 SWNT Probes
13.5.1.2 QD Probes
13.5.1.3 Rare-Earth Nanoprobes
13.5.1.4 Organic Dye Nanoprobes
13.5.2 Brain Tumors
13.5.3 Cerebrovascular Disorders
13.6 Summary and Outlook
References
Index

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