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Index
Cover image Title page Table of Contents Copyright List of Contributors 1: Self-assembling biomaterials: Beginnings, recent progress, and the future Part One: Molecular building blocks
2: Designing self-assembling biomaterials with controlled mechanical and biological performance
Abstract 2.1 Introduction 2.2 Molecular design 2.3 Applications in biology 2.4 Conclusion and future trends
3: Self-assembling hydrogels from reverse-engineered silk
Abstract 3.1 Introduction 3.2 Silk structure-function relationships 3.3 Reverse engineering the silk cocoon 3.4 Rationale for using self-assembling silk hydrogels for biomedical applications 3.5 Self-assembling silk hydrogels and their applications 3.6 Conclusion and future trends Acknowledgments
4: Elastin-like proteins: Molecular design for self-assembling
Abstract 4.1 Introduction 4.2 Coacervates 4.3 Nanoparticles 4.4 Hybrid elastin-like recombinamer nanoparticles 4.5 Self-assembly into fibrillar structures 4.6 Self-assembled hydrogels 4.7 Other structures 4.8 Conclusion and future trends
5: Sweet building blocks for self-assembling biomaterials with molecular recognition
Abstract 5.1 Introduction 5.2 Supramolecular systems using unmodified sugars 5.3 Supramolecular systems with glycopolymers and carbohydrate amphiphiles 5.4 Systems responsive to targeted external stimuli 5.5 Conclusion and future trends
6: Peptoid self-assembly and opportunities for creating protein-mimetic biomaterials and biointerfaces
Abstract 6.1 Introduction 6.2 “Conventional” peptoid secondary and tertiary structures 6.3 Therapeutic and diagnostic applications 6.4 Peptoid biointerfaces and self-assembled materials 6.5 Enzymatic recognition and biocompatibility of peptoids 6.6 Conclusion and future trends
7: Lipid bolaamphiphiles for fabricating membrane-mimetic biomaterials
Abstract 7.1 Introduction 7.2 Different classes of bolaamphiphiles 7.3 Biomimetic membranes 7.4 Translocation across vesicle membranes, membrane dynamics, flip-flop 7.5 Self-assembly of bolaamphiphiles into nanostructures 7.6 Structural analysis and experimental techniques for characterizing bolaamphiphiles 7.7 Conception of some original bolaamphiphiles 7.8 Applications of bolaamphiphiles in recognition, encapsulation, drug, and gene delivery 7.9 Conclusion and future trends
8: DNA-based materials as self-assembling scaffolds for interfacing with cells
Abstract Acknowledgments 8.1 Introduction 8.2 Three-dimensional hydrogels 8.3 Functional two-dimensional surfaces 8.4 Conclusion and future trends
9: Supramolecular biomaterials based on ureidopyrimidinone and benzene-1,3,5-tricarboxamide moieties
Abstract 9.1 Introduction 9.2 Solid biomaterials based on ureidopyrimidinone moieties 9.3 Supramolecular hydrogels 9.4 Supramolecular fibers in solution 9.5 Conclusion and future trends
10: Self-assembled biomaterials using host-guest interactions
Abstract 10.1 Introduction to host-guest interactions 10.2 Building biomaterials with host-guest interactions 10.3 Applications 10.4 Conclusion and future trends
Part Two: Nanostructure in time and space
11: Unique properties of supramolecular biomaterials through nonequilibrium self-assembly
Abstract 11.1 Introduction 11.2 The free energy landscapes of self-assembly 11.3 In-equilibrium self-assembly 11.4 Nondissipative nonequilibrium self-assembly: Metastable assemblies and kinetic traps 11.5 Dissipative nonequilibrium assembly 11.6 Conclusion and future trends
12: Unveiling complex structure and dynamics in supramolecular biomaterials using super-resolution microscopy
Abstract 12.1 Super resolution microscopy for biomaterials 12.2 Why super resolution microscopy for self-assembling biomaterials? 12.3 Polypeptides fibrillar assemblies 12.4 Supramolecular fibers and hydrogels 12.5 Block copolymers & polymer nanoparticles 12.6 Deoxyribonucleic acid (DNA) origami 12.7 Liposomes and lipidic assemblies 12.8 Conclusion and future trends
13: Probing local molecular properties of self-assembled systems with electron paramagnetic resonance (EPR)
Abstract 13.1 Introduction 13.2 Principles of electron paramagnetic resonance spectroscopy 13.3 Dynamics measurements by electron paramagnetic resonance 13.4 Measurement of electrostatic properties 13.5 Perspective on the future of electron paramagnetic resonance for self-assembly
14: Using small-angle X-ray scattering (SAXS) to study the structure of self-assembling biomaterials
Abstract 14.1 General description of small angle scattering techniques 14.2 Analysis of small-angle X-ray scattering data 14.3 Conclusion and future trends
15: Molecular simulation of self-assembly
Abstract 15.1 Introduction 15.2 The molecular dynamics method 15.3 Simulations of molecular self-assembly 15.4 Conclusion and future trends
Part Three: Driving forces and boundaries
16: Magnetic fields to align natural and synthetic fibers
Abstract 16.1 Introduction 16.2 Magnetism 16.3 Diamagnetism 16.4 Alignment of natural fibers 16.5 Applications of aligned protein fibers 16.6 Alignment of peptide based fibers 16.7 Alignment of synthetic polymers 16.8 Conclusion and future trends
17: Displaying biofunctionality on materials through templated self-assembly
Abstract Acknowledgments 17.1 Introduction 17.2 Surface-induced self-assembly 17.3 Applications of templated self-assembly in biomaterials engineering 17.4 Conclusion and future trends
18: Multicomponent self-assembly: Supramolecular design of complex hydrogels for biomedical applications
Abstract 18.1 Introduction 18.2 Principles of multicomponent self-assembly and hydrogelation 18.3 Advantages of multicomponent hydrogels over single-molecule hydrogels 18.4 Prediction of multicomponent self-assemblies and forces driving them 18.5 Molecular design of multicomponent self-assembling hydrogels 18.6 Conclusion and future trends
19: Enzyme-mediated self-assembly
Abstract 19.1 Introduction 19.2 Enzyme-mediated self-assembly in vitro 19.3 Enzyme-mediated self-assembly in vivo 19.4 Conclusion and future trends
Part Four: Applications
20: Recreating stem-cell niches using self-assembling biomaterials
Abstract 20.1 Introduction 20.2 Stem-cell niches in the body 20.3 General principles for creating biomaterials mimics of extracellular matrix 20.4 Basic design principles of self-assembling peptide and protein materials 20.5 Self-assembling peptides and proteins as regulatory microenvironment for stem cells 20.6 Conclusion and future trends
21: Self-assembled peptide nanostructures and their gels for regenerative medicine applications
Abstract 21.1 Introduction 21.2 Physical and chemical properties of the extracellular matrix 21.3 Conclusion and future trends
22: Functionalization of self-assembling peptides for neural tissue engineering
Abstract 22.1 Introduction 22.2 Self-assembling of functionalized peptides: Design principles and pitfalls 22.3 Biomimetics and mechanical properties functionalized-self-assembling peptides scaffolds 22.4 Screening of functional motifs via phage display libraries and protein docking analysis 22.5 Progresses and opportunities for applications in tissue engineering 22.6 Conclusion and future trends
23: Self-assembling biomaterials as nanocarriers for the targeted delivery of drugs for cancer
Abstract 23.1 Introduction 23.2 Nanostructures that target key receptors/transporters 23.3 Miscellaneous 23.4 Conclusion and future trends
24: Self-assembling biomaterials for theranostic applications
Abstract 24.1 Introduction 24.2 Diagnostics and imaging modalities 24.3 Current theranostic applications 24.4 Conclusion and future trends
25: Single-chain polymeric nanoparticles: Toward in vivo imaging and catalysis in complex media
Abstract 25.1 Introduction 25.2 Collapsing/folding single polymer chains into single chain polymeric nanoparticles 25.3 Controlling intramolecular versus intermolecular assembly/crosslinking processes to obtain polymer nanoparticles 25.4 Compatibility of folded/collapsed amphiphilic polymer nanoparticles with complex cellular environments 25.5 Applying folded/collapsed single-chain polymeric nanoparticles in imaging and diagnostics 25.6 Applying folded/collapsed amphiphilic polymer nanoparticles as drug delivery systems and for photodynamic therapy systems 25.7 Applying folded/collapsed amphiphilic polymer nanoparticles in bio-orthogonal chemistry and catalysis 25.8 Conclusion and future trends
Index
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