Linked e-resources
Details
Table of Contents
Intro; Foreword; Contents; Contributors; 1 Supramolecular Self-assembled Nanomaterials for Fluorescence Bioimaging; Abstract; 1.1 Introduction; 1.2 Ex-Situ Construction; 1.2.1 Dye-Dispersed Nanoparticles; 1.2.2 Semiconducting Polymer Nanoparticles; 1.2.3 AIE Nanoparticles; 1.2.4 J-Aggregates; 1.2.5 In situ Construction; 1.2.5.1 Disassembly; 1.2.5.2 Assembly; 1.2.5.3 Reassembly; 1.3 Summary and Outlook; References; 2 The Self-assembly of Cyanine Dyes for Biomedical Application In Vivo; Abstract; 2.1 Introduction; 2.2 Characterizations of Cyanine Dyes
2.2.1 Chemical Structure and Fluorescence Characteristic of Cyanine Dyes2.2.2 Aggregates of Cyanine Dyes; 2.3 Biomedical Applications of Cyanine Dyes; 2.3.1 Biosensors for Bioactive Molecules; 2.3.2 Bioimaging and Diagnosis for Diseases; 2.3.2.1 Cyanine Dye Nanovesicles for Tumor Bioimaging; 2.3.2.2 Cyanine Dye Nanoemitters for Cancer Diagnosis; 2.3.2.3 Cyanine Dye Nanopaticles for Bacterial Bioimaging; 2.4 Summary and Outlook; References; 3 Self-assembled Nanomaterials for Bacterial Infection Diagnosis and Therapy; Abstract; 3.1 Introductions
3.2 Self-assembled Peptides for Antimicrobial Therapy3.2.1 Design and Antimicrobial Mechanism of the Peptide-Based Nanomaterials; 3.2.2 Supramolecular Peptide Amphiphilic Self-assembles as Antimicrobial Agents; 3.2.3 Multilayer Self-assembly of Hybrid Peptides for Surface Antimicrobial Defense; 3.3 Polymer Assemblies with Antimicrobial Activity; 3.3.1 Self-assembled Polymers as Antibacterial Agents; 3.3.1.1 Structural Design of Cationic Polymers; 3.3.1.2 Nanosized Self-assembly Architectures; 3.3.2 Polymer Self-assemblies Coating As Infection-Resistant Surfaces
3.4 Hybrid Metal/Inorganic Nanomaterials as Bactericide3.4.1 Ag Nanoparticles Dispersive into Self-assembled Nanostructures for Synergistic Bacterial Inactivation; 3.4.2 Others Hybrid Nanoassembles as Antibacterial Agents; 3.5 Photodynamic Antibacterial Agent Assembled Nanomaterials; 3.6 Antibiotic Assembly with Enhanced Antibacterial Efficiency; 3.7 Self-assembled Nanomaterials for Bacterial Detection; 3.7.1 Polymer-Based Assemblies to Detect Bacteria; 3.7.2 Metal/Inorganic Hybrid Assemblies as Bacterial Sensor; 3.7.3 Others Self-assembled Probes
3.7.4 In Vivo Self-assembly Strategy for Bacterial Infection Diagnosis3.8 Conclusion Remarks; References; 4 Enzyme-Instructed Self-assembly of Small Peptides In Vivo for Biomedical Application; Abstract; 4.1 Introduction; 4.2 The Development of Small Molecular Gels; 4.2.1 The Development and Characteristic of Organogels; 4.2.2 The Development and Characteristic of Hydrogels; 4.2.3 The Development of Enzyme-Instructed Self-assembly; 4.3 The Characteristic and Advantages of EISA on Cancer Theranostics; 4.4 The Application of EISA Strategy in Cancer Theranostics; 4.4.1 Hydrolysis of Esters
2.2.1 Chemical Structure and Fluorescence Characteristic of Cyanine Dyes2.2.2 Aggregates of Cyanine Dyes; 2.3 Biomedical Applications of Cyanine Dyes; 2.3.1 Biosensors for Bioactive Molecules; 2.3.2 Bioimaging and Diagnosis for Diseases; 2.3.2.1 Cyanine Dye Nanovesicles for Tumor Bioimaging; 2.3.2.2 Cyanine Dye Nanoemitters for Cancer Diagnosis; 2.3.2.3 Cyanine Dye Nanopaticles for Bacterial Bioimaging; 2.4 Summary and Outlook; References; 3 Self-assembled Nanomaterials for Bacterial Infection Diagnosis and Therapy; Abstract; 3.1 Introductions
3.2 Self-assembled Peptides for Antimicrobial Therapy3.2.1 Design and Antimicrobial Mechanism of the Peptide-Based Nanomaterials; 3.2.2 Supramolecular Peptide Amphiphilic Self-assembles as Antimicrobial Agents; 3.2.3 Multilayer Self-assembly of Hybrid Peptides for Surface Antimicrobial Defense; 3.3 Polymer Assemblies with Antimicrobial Activity; 3.3.1 Self-assembled Polymers as Antibacterial Agents; 3.3.1.1 Structural Design of Cationic Polymers; 3.3.1.2 Nanosized Self-assembly Architectures; 3.3.2 Polymer Self-assemblies Coating As Infection-Resistant Surfaces
3.4 Hybrid Metal/Inorganic Nanomaterials as Bactericide3.4.1 Ag Nanoparticles Dispersive into Self-assembled Nanostructures for Synergistic Bacterial Inactivation; 3.4.2 Others Hybrid Nanoassembles as Antibacterial Agents; 3.5 Photodynamic Antibacterial Agent Assembled Nanomaterials; 3.6 Antibiotic Assembly with Enhanced Antibacterial Efficiency; 3.7 Self-assembled Nanomaterials for Bacterial Detection; 3.7.1 Polymer-Based Assemblies to Detect Bacteria; 3.7.2 Metal/Inorganic Hybrid Assemblies as Bacterial Sensor; 3.7.3 Others Self-assembled Probes
3.7.4 In Vivo Self-assembly Strategy for Bacterial Infection Diagnosis3.8 Conclusion Remarks; References; 4 Enzyme-Instructed Self-assembly of Small Peptides In Vivo for Biomedical Application; Abstract; 4.1 Introduction; 4.2 The Development of Small Molecular Gels; 4.2.1 The Development and Characteristic of Organogels; 4.2.2 The Development and Characteristic of Hydrogels; 4.2.3 The Development of Enzyme-Instructed Self-assembly; 4.3 The Characteristic and Advantages of EISA on Cancer Theranostics; 4.4 The Application of EISA Strategy in Cancer Theranostics; 4.4.1 Hydrolysis of Esters