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Preface | xi | |
1. | Biopolyesters and Biocatalysis Introduction | 1 |
Poly([beta]-hydroxyalkanoates) | ||
2. | Interesting Carbon Sources for Biotechnological Production of Biodegradable Polyesters: The Use of Rape Seed Oil Methyl Ester (Biodiesel) | 14 |
3. | Biosynthesis and Properties of Medium-Chain-Length Polyhydroxyalkanoates from Pseudomonas resinovorans | 25 |
4. | The Structural Organization of Polyhydroxyalkanoate Inclusion Bodies | 42 |
5. | Microbial Synthesis, Physical Properties, and Biodegradability of Ultra-High-Molecular-Weight Poly[(R)-3-hydroxybutyrate] | 67 |
6. | Polyhydroxyalkanoate Production by Recombinant Escherichia coli: New Genes and New Strains | 77 |
Biodegradable Polyesters: Synthesis and Characterization | ||
Enzymatic Synthesis | ||
7. | Introduction to Enzyme Technology in Polymer Science | 90 |
8. | Lipase-Catalyzed Ring-Opening Polymerization of [omega]-Pentadecalactone: Kinetic and Mechanistic Investigations | 100 |
9. | Enzymatic Polymerization of Natural Phenol Derivatives and Enzymatic Synthesis of Polyesters from Vinyl Esters | 113 |
Chemical Synthesis | ||
10. | High-Molecular-Weight [L]-Polylactides Containing Pendant Functional Groups | 129 |
11. | Macrocyclic Polymerizations of Lactones: A New Approach to Molecular Engineering | 135 |
12. | Polymerization and Copolymerization of Lactides and Lactones Using Some Lanthanide Initiators | 146 |
13. | Thermodynamics, Kinetics, and Mechanisms of Cyclic Esters Polymerization | 160 |
Polymer Evaluation | ||
14. | Can the Glass Transition Temperature of PLA Polymers Be Increased? | 200 |
15. | Solid-State Structure of Poly(lactide) Copolymers | 221 |
16. | Degradation Kinetics of Poly(hydroxy) Acids: PLA and PCL | 230 |
Biodegradability and Recycling | ||
17. | Broad-Based Screening of Polymer Biodegradability | 254 |
18. | Methacrylic Group Functionalized Poly(lactic acid) Macromonomers from Chemical Recycling of Poly(lactic acid) | 281 |
Biomedical Application of Polyesters | ||
19. | In Vitro Cellular Adhesion and Proliferation on Novel Bioresorbable Matrices for Use in Bone Regeneration Applications | 294 |
20. | Novel Approaches for the Construction of Functionalized PEG Layer on Surfaces Using Heterobifunctional PEG-PLA Block Copolymers and Their Micelles | 311 |
21. | Poly([beta]-hydroxyalkanoates) as Potential Biomedical Materials: An Overview | 328 |
Author Index | 335 | |
Subject Index | 336 |
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Add Polymers from Renewable Resources: Biopolyesters and Biocatalysis, This book is part two of a 3-volume series on polymers from renewable resources. The entire set focuses on gathering contributions from the leading workers in specific areas of research pertaining to this field, such as agroproteins, modification of n, Polymers from Renewable Resources: Biopolyesters and Biocatalysis to the inventory that you are selling on WonderClubX
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Add Polymers from Renewable Resources: Biopolyesters and Biocatalysis, This book is part two of a 3-volume series on polymers from renewable resources. The entire set focuses on gathering contributions from the leading workers in specific areas of research pertaining to this field, such as agroproteins, modification of n, Polymers from Renewable Resources: Biopolyesters and Biocatalysis to your collection on WonderClub |