Advances in aggregation induced emission materials in biosensing and imaging for biomedical applications. Part B /

Advances in Aggregation Induced Emission Materials in Biosensing and Imaging for Biomedical Applications - Part B, Volume 185 presents many aspects of AIE materials that can help future investigators, researchers, students and stakeholders perform research with ease.

Bibliographic Details
Corporate Author: ScienceDirect (Online service)
Other Authors: Bhosale, Rajesh (Editor), Singh, Vijai (Editor)
Format: eBook
Language:English
Published: Cambridge, MA : Academic Press, 2021.
Series:Progress in molecular biology and translational science ; volume 185.
Subjects:
Online Access:Connect to the full text of this electronic book
Table of Contents:
  • Intro
  • Advances in Aggregation Induced Emission Materials in Biosensing and Imaging for Biomedical Applications
  • Part B
  • Copyright
  • Contents
  • Contributors
  • Preface
  • Chapter One: Aggregation induced emission materials for tissue imaging
  • 1. Introduction
  • 2. Mass spectrometric techniques for tissue imaging
  • 3. Fluorescence spectroscopic techniques for tissue imaging
  • 4. AIE molecular probes for deep tissue imaging
  • 4.1. Detection and imaging of singlet oxygen in tissue during photodynamic therapy using 2-PM
  • 4.2. In vivo brain tissue imaging using 3-PM
  • 4.3. Barbituric acid-TPE as AIEgens for high-resolution tissue images of secondary growth tumor
  • 5. AIE nanoparticle probe for tissue imaging
  • 5.1. Near-infrared AIE nanodots for tissue imaging
  • 5.2. Photon fluorescence microscopy for tissue imaging using AIE dots
  • 6. AIE active conjugated polymer probe for tissue imaging
  • 6.1. AIE active conjugated polymeric micelle formation for tissue imaging
  • 7. Conclusions and future prospect
  • Acknowledgments
  • References
  • Chapter Two: AIE materials for cancer cell detection, bioimaging and theranostics
  • 1. Introduction
  • 2. AIE based materials in cancer cell detection
  • 3. AIE based materials in bioimaging
  • 4. AIE based materials in theranostics
  • 5. AIE based materials for anticancer application
  • 6. Conclusion, potential challenges, and future prospect
  • Acknowledgments
  • Conflict of interest
  • References
  • Chapter Three: AIE material for photodynamic therapy
  • 1. Introduction
  • 2. Small molecule-based organelle targeting AIEgens for PDT
  • 2.1. Mitochondria targeting AIEgens
  • 2.2. Lysosome targeting AIEgens
  • 2.3. Other organelles and multi-organelles targeting AIEgens
  • 3. Small-molecule based AIEgens for two-photon PDT
  • 4. Metal complexes as AIEgens for PDT.
  • 1.2.2. Step or condensation polymerization
  • 1.2.2.1. Suzuki reaction
  • 1.2.2.2. Knoevenagel reaction
  • 1.2.2.3. Stille reaction
  • 1.2.3. Post functionalization
  • 1.3. Classification of AIE active polymer
  • 1.3.1. Addition polymers
  • 1.3.2. Condensation polymers
  • 2. Diagnostics with AIE active polymer
  • 2.1. Detection of biomolecules
  • 2.2. Detection of diseases related biomarkers
  • 2.3. Detection of microbes and antibacterial application
  • 3. Imaging with AIE active polymer
  • 3.1. Imaging with polymer
  • 3.2. AIE active polymer for in-vitro imaging
  • 3.3. AIE active polymer for in-vivo imaging
  • 4. Biomedical application of AIE active polymer
  • 4.1. AIE active polymer for drug screening and drug delivery
  • 4.2. AIE active polymer for photodynamic therapy
  • 5. Conclusion and outlook
  • References
  • Chapter Seven: AIE-MOF materials for biological applications
  • 1. Metal organic frameworks
  • 2. Aggregation-induced emission of MOFs
  • 3. AIE of MOF materials for biological applications
  • 3.1. Cell imaging
  • 3.2. Heparin detection
  • 3.3. Drug delivery
  • 4. Summary and perspectives
  • Acknowledgments
  • References
  • Chapter Eight: Patented AIE materials for biomedical applications
  • 1. Introduction
  • 1.1. Mechanism of fluorescence spectroscopy
  • 1.2. Aggregation induced emission (AIE) properties
  • 1.3. Aggregation induced emission mechanism
  • 2. Biomedical applications
  • 2.1. Mitochondria imaging
  • 2.2. Biosensing
  • 2.3. Cellular imaging, cell tracking, bacterial imaging
  • 2.4. Image-guided therapy and visualization of treatment of cancer
  • 2.5. AIE nanoparticles for intracellular imaging and protein carrier
  • 2.6. Retardation of amyloid fibrillation of insulin
  • 2.7. Photoactivatable probe
  • 2.8. Method of detecting human serum albumin in biological fluids
  • 3. Future prospectus
  • Acknowledgments
  • References.