Quadir M.A. Dendritic polymers as nanoscale delivery systems for metal ion and drugs: Diss. … Dr. rer. nat. / Berlin: Freie Universität, 2009. - iv, 160 p.: ill., graph. - Ref.: p.145-155.  Место хранения:   07 | Центральная библиотека Красноярского научного центра СО РАН | Красноярск

Оглавление / Contents

Abbreviations ................................................ I Nomenclature of Polymers and Dendritic Architectures ........ IV 1 General Introduction ......................................... 1 1.1 Concept of Nanoscale Drug Delivery System (Nano-DDS) .... 1 1.2 Modes/Mechanism of Drug Delivery from Nano-DDS: State- of-the-Art .............................................. 2 1.2.1 Supramolecular Drug-Polymer Complex .............. 3 1.2.2 Drug-Polymer Conjugates: The Covalent Approach ... 6 1.3 Specialized Polymers as Nano-DDS: Dendrimers ............ 8 1.4 Hyperbranched Polymers for Nano-DDS Application ........ 11 1.5 Hyperbranched Polyglycerol as Drug Delivery Platform ... 14 1.5.1 Synthesis of Well-defined Hyperbranched Polyglycerol .................................... 16 1.5.2 Core Variation and Diversification of Polyglycerol Scaffold ........................... 17 1.5.3 Biocompatibility Profile of Dendritic Polyglycerols ................................... 18 1.5.4 Biomedical Applications of Hyperbranched Polyglycerol .................................... 19 2 Objective of the Thesis ..................................... 24 3 Polyglycerol based Multivalent Ligand for Copper Ion Transport ................................................... 26 3.1 Copper in Physiology: Role, Deficiency Disorders and Homeostasis ............................................ 26 3.2 Objective of the Project ............................... 29 3.3 The Blood-brain Barrier (BBB) and Transporter Design ... 30 3.4 Synthesis of Polyglycerol Based Nanocarriers for Cu Ion Transport .......................................... 31 3.4.1 Synthesis of Dialkylamine Functionalized Polyglycerol .................................... 32 3.4.2 Synthesis of Core-aminated Polyglycerol ......... 34 3.4.3 Synthesis of Polyglycerol-bispicolylamide Derivatives ..................................... 36 3.4.4 Synthesis of Mono- and Oligosaccharide Modified Polyglycerolamine ...................... 39 3.4.5 Attaching N-α-BOC-Histidine to Polyglycerolamine: BBB Targeted Nanocarriers .... 40 3.4.6 Immobilizing Ascorbic Acid onto Polyglycerol .... 41 3.4.7 Synthesis of FTTC-Labeled PG10-TMEDA System ..... 43 3.5 Proof of Cu-encapsulation by Synthesized Constructs: UV-Vis Spectroscopy .................................... 43 3.6 Energetics of Cu-ion encapsulation: Isothermal Titration Calorimetry (ITC) ............................ 47 3.7 Surface Charge Determination ........................... 51 3.8 Interaction of Cu-ion Encapsulating Systems with Plasma Albumin ......................................... 54 3.9 Cellular Toxicity of the Synthesized Architectures ..... 57 3.10 Uptake of PG10-TMEDA system by Living Cells ............ 58 3.11 Discussion ............................................. 60 4 Core Single-shell and Core-multishell Architecture for Cellular Delivery of Copper Ions ............................ 64 4.1 Introduction ........................................... 64 4.2 Objective of the project ............................... 65 4.3 Synthesis of CS NPs and CMS NPs ........................ 65 4.4 Fluorescent Labelling and Biochemical Experiments ...... 66 4.5 In Vitro Encapsulation and Cellular Delivery Cu-ion by CS and CMS NPs ...................................... 67 4.5.1 Evidence and Stoichiometry of Encapsulation: UV-Vis Spectroscopy ............................. 67 4.5.2 Thermodynamics of Encapsulation: Isothermal Titration Calorimetry .......................... 68 4.5.3 Spontaneous Encapsulation of Cu by the Nanocarriers in Cellular Environment ............ 68 4.5.4 Accessibility of Carrier Cargo .................. 70 4.5.5 Toxicity of Nanocarriers in Higher Eukaryotic Cells ........................................... 71 4.5.6 Cellular Cu Localization, Possible Targets and Effect on Aß Production ......................... 72 4.5.7 Endocytosis of CMS NPs and CS NPs ............... 75 4.6 Discussion ............................................. 77 5 Non-covalent Encapsulation of Drugs in Dendritic Polymers ... 80 5.1 Introduction ........................................... 80 5.2 Objective of the Project ............................... 81 5.3 Interaction between Representative Dendritic Polymers and Model Drugs ........................................ 82 5.3.1 Model 1. Interaction between Ibandronate and Core-mutishell Nanoparticles .................... 82 5.3.2 Model 2. Interaction of ATP with Oligosaccharide Modified Hyperbranched PEI ...... 84 5.4 Calorimetric Protocol for the Model Interactions ....... 87 5.5 Results and Discussion of Interaction Experiments ...... 87 5.5.1 Ibn Encapsulation by CMS NPs .................... 87 5.5.2 ATP Encapsulation by Oligosaccharide-modified Hyperbranched PEI ............................... 90 6 Conjugation of Drugs to Hyperbranched Polyglycerol: Covalent Approach ........................................... 97 6.1 Covalent Conjugation of Morphine onto Polyglycerol ..... 97 6.1.1 Chemistry and Pharmacology of Morphine .......... 97 6.1.2 Objective of the Project ........................ 98 6.1.3 Reported Synthetic Strategies to Design Morphine Prodrugs/Delivery System .............. 100 6.1.4 Esterification of Morphine with Polyglycerol Carboxylate .................................... 101 6.1.5 Amidation of Succinylated Morphine to Polyglycerolamine .............................. 104 6.1.6 Biological Investigation in Rat Model .......... 106 6.2 Attachment of Coumarin onto Polyglycerol Architecture .......................................... 109 6.2.1 Attachment of Coumarin to Succinylated Polyglycerol ................................... 110 6.2.2 The "Click" Approach to Immobilize Coumarin onto Polyglycerol Backbone ..................... 111 6.2.3 Photoactivity of 4-methyl 7-hydroxy Coumarin Loaded Polyglycerol ............................ 113 6.3 Discussion ............................................ 116 7 Summary and Conclusion ..................................... 118 8 Outlook .................................................... 121 9 Experimental Part .......................................... 122 9.1 Materials ............................................. 122 9.1.1 Polymers ....................................... 122 9.1.2 Chemicals ...................................... 122 9.2 Analytical Methods .................................... 122 9.2.1 NMR Spectroscopy ............................... 122 9.2.2 Dialysis ....................................... 122 9.2.3 Size Exclusion Chromatography (SEC) ............ 123 9.2.4 TLC and Dry Flash Column Chromatography ........ 123 9.2.5 UV-Vis Spectrosocpy ............................ 123 9.2.6 Isothermal Titration Calorimetry (ГТС) ......... 123 9.2.7 Zeta Potential Measurement ..................... 124 9.2.8 Fluorescence Spectroscopy ...................... 124 9.3 Synthesis of Selected Polyglycerol Analogues and Intermediates ......................................... 125 10 References ................................................. 145 11 Zusammenfassung ............................................ 156 12 Appendix ................................................... 158 Curriculum Vitae ........................................... 159 List of publications ....................................... 160 Poster presentations ....................................... 160