Nome |
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Progress in Conductive Polyaniline-Based Nanocomposites for Biomedical Applications: A Review, file e0c31c0e-fe88-4599-e053-1705fe0aef77
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1.538
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Spinal cord injury (SCI) repair strategies, file e0c31c0e-4740-4599-e053-1705fe0aef77
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1.523
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Nanomaterials for Theranostics and Tissue Engineering: Techniques, Trends and Applications, file e0c31c0f-9fd3-4599-e053-1705fe0aef77
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915
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Soft Robotics, file e0c31c11-8113-4599-e053-1705fe0aef77
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803
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Nanogel functionalization: a versatile approach to meet the challenges of drug and gene delivery, file e0c31c0c-d412-4599-e053-1705fe0aef77
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798
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Selective Modulation of A1 Astrocytes by Drug-Loaded Nano-Structured Gel In Spinal Cord Injury, file e0c31c0e-d60b-4599-e053-1705fe0aef77
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767
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Progress in hydrogels for sensing applications: a review, file e0c31c0f-fe50-4599-e053-1705fe0aef77
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747
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Simple and efficient strategy to synthesize PEG-aldehyde derivatives for hydrazone orthogonal chemistry, file e0c31c0e-8da3-4599-e053-1705fe0aef77
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709
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Regenerative medicine for spinal cord injury: focus on stem cells and biomaterials, file e0c31c0f-ebbd-4599-e053-1705fe0aef77
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633
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Polymer-based thermoresponsive hydrogels for controlled drug delivery, file 29829c91-e087-4fe0-a598-c0bb1082fd1f
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629
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Advances in Functionalization of Polymers and Nanomaterials: Water Treatment, Food Packaging, Textile, and Biomedical Applications, file e0c31c10-cf5a-4599-e053-1705fe0aef77
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628
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Bone grafts: which is the ideal biomaterial?, file e0c31c0d-b251-4599-e053-1705fe0aef77
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601
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Drug delivery (nano)platforms for oral and dental applications: Tissue regeneration, infection control and cancer management, file e0c31c11-274f-4599-e053-1705fe0aef77
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458
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Evidence of superdiffusive nanoscale motion in anionic polymeric hydrogels: Analysis of PGSE-NMR data and comparison with drug release properties, file e0c31c0d-615e-4599-e053-1705fe0aef77
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368
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Functionalized Nanogel for Treating Activated Astrocytes in Spinal Cord Injury, file e0c31c10-26ae-4599-e053-1705fe0aef77
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367
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Design of polymer-based antimicrobial hydrogels through physico-chemical transition, file e0c31c0d-fd85-4599-e053-1705fe0aef77
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342
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Current options for cell therapy in spinal cord injury, file e0c31c11-be65-4599-e053-1705fe0aef77
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316
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Functionalization of Polymers and Nanomaterials for Biomedical Applications: Antimicrobial Platforms and Drug Carriers, file e0c31c0f-f73a-4599-e053-1705fe0aef77
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291
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A Kinetic Analysis of the Growth and Doping Kinetics of the SiC Chemical Vapor Deposition Process, file e0c31c0d-f3ae-4599-e053-1705fe0aef77
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280
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Hybrid nanogels: stealth and biocompatible structures for drug delivery applications, file e0c31c0c-d560-4599-e053-1705fe0aef77
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278
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Ester coupling of ibuprofen in hydrogel matrix: A facile one-step strategy for controlled anti-inflammatory drug release, file e0c31c0e-d0e0-4599-e053-1705fe0aef77
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259
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Introduction to spinal cord injury as clinical pathology, file e0c31c11-51ae-4599-e053-1705fe0aef77
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215
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Synthesis and applications of nanogels via covalent cross-linking strategies, file b2ce137f-9e28-4e55-b125-34f06a4daafc
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211
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Can nanostructures improve hydrogel-based biosensors performance?, file e0c31c11-352c-4599-e053-1705fe0aef77
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211
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Sensing materials: hydrogels, file cbcd404f-7535-4162-ab07-648828641759
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202
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Advances in bio-based polymers for colorectal cancer treatment: hydrogels and nanoplatforms, file e0c31c10-b6f4-4599-e053-1705fe0aef77
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201
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Nanovector-mediated drug delivery in spinal cord injury, file e0c31c0c-d415-4599-e053-1705fe0aef77
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197
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Biomaterials, spinal cord injury, and rehabilitation: A new narrative, file e0c31c12-b779-4599-e053-1705fe0aef77
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195
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Composite Polymer Coated Mineral Scaffolds for Bone Regeneration: from Material Characterization to Human Studies, file e0c31c0e-92c8-4599-e053-1705fe0aef77
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190
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A new three dimensional biomimetic hydrogel to deliver factors secreted by human mesenchymal stem cells in spinal cord injury, file e0c31c10-8b98-4599-e053-1705fe0aef77
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186
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Poly(phenylenediamine)s-decorated Cu-Al layered double hydroxide nanohexagonal: A potential non-viral vector for photothermal therapy and co-delivery of DOX/pCRISPR, file 1c2e62f7-4f05-4da4-b300-0a6bd8f85328
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183
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Polymer Functionalization as a Powerful Tool to Improve Scaffold Performances, file e0c31c08-1aad-4599-e053-1705fe0aef77
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177
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Polysaccharide-based scaffolds for tissue regeneration, file e0c31c0d-7566-4599-e053-1705fe0aef77
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171
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Is nanoparticle functionalization a versatile approach to meet challenges of drug and gene delivery?, file e0c31c0f-fb7d-4599-e053-1705fe0aef77
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171
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A mathematical model of a slurry reactor for the direct synthesis of hydrogen peroxide, file e0c31c0f-1cdd-4599-e053-1705fe0aef77
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166
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On the ability of chromatographic mass balance to predict solute diffusivity in drug delivery systems, file e0c31c0e-0577-4599-e053-1705fe0aef77
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163
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Drug-Polymer Interactions in Hydrogel-based Drug Delivery Systems: Experimental and Theoretical Study, file e0c31c0e-8f23-4599-e053-1705fe0aef77
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159
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Optimized Design and Development of a Bioresorbable High Rotational Stability Fixation System for Small Bone Fragments, file e0c31c0f-6ff9-4599-e053-1705fe0aef77
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158
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Polymer Hydrogel Functionalized with Biodegradable Nanoparticles as Composite System for Controlled Drug Delivery, file e0c31c0e-8f22-4599-e053-1705fe0aef77
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155
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Droplet-based microfluidic synthesis of polyethyleneimine/hyaluronan nanogels for controlled drug delivery: tailoring nanomaterial properties via pressure-actuated tunable flow focusing junction, file 855e0626-fdba-4874-bd96-52f714d9f460
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154
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Nano-encapsulation of hydroxytyrosol into formulated nanogels improves therapeutic effects against hepatic steatosis: an in vitro study, file e0c31c11-0c0c-4599-e053-1705fe0aef77
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147
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A perspective on graphene based aerogels and their environmental applications, file d6373928-7d28-4bbf-a01c-adeac760ce47
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145
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A Perspective on Polylactic Acid-Based Polymers Use for Nanoparticles Synthesis and Applications, file e0c31c0f-121f-4599-e053-1705fe0aef77
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139
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Functionalization of nylon 6,6 with polyetheramine improves wettability and antibacterial properties, file e0c31c11-8107-4599-e053-1705fe0aef77
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138
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Can gold nanoparticles improve delivery performance of polymeric drug delivery systems?, file e0c31c11-c1ff-4599-e053-1705fe0aef77
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136
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Hydrogel-nanoparticles composite system for controlled drug delivery, file e0c31c0c-d411-4599-e053-1705fe0aef77
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135
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Zinc electrodeposition from a chloride-free non-aqueous solution based on ethylene glycol and acetate salts, file e0c31c12-5e6b-4599-e053-1705fe0aef77
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134
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Mesenchymal stem cells encapsulated into biomimetic hydrogel scaffold gradually release CCL2 chemokine in situ preserving cytoarchitecture and promoting functional recovery in spinal cord injury, file e0c31c11-b62f-4599-e053-1705fe0aef77
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132
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Nanosized Drug Delivery Systems: Colloids and Gels for Site Specific Targeting, file e0c31c0f-fe52-4599-e053-1705fe0aef77
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121
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Non-invasive in vitro and in vivo monitoring of degradation of fluorescently labeled hyaluronan hydrogels for tissue engineering applications, file e0c31c11-8787-4599-e053-1705fe0aef77
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114
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β-Cyclodextrin Nanosponge Hydrogels as Drug Delivery Nanoarchitectonics for Multistep Drug Release Kinetics, file e0c31c11-da00-4599-e053-1705fe0aef77
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110
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On the influence of polyethyleneimine modification in nanogel-driven drug delivery, file d9f44264-48bb-4f0c-a2f1-635ac6b1a7d1
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109
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Scaffolds as structural tools for bone targeted drug delivery, file e0c31c0c-9552-4599-e053-1705fe0aef77
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107
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3D integration of pH-cleavable drug-hydrogel conjugates on magnetically driven smart microtransporters, file e0c31c0f-a91e-4599-e053-1705fe0aef77
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104
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A perspective on the applications of functionalized nanogels: promises and challenges, file e0c31c12-9344-4599-e053-1705fe0aef77
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104
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Nanovector-mediated drug delivery for spinal cord injury treatment, file e0c31c0d-e8a8-4599-e053-1705fe0aef77
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102
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Plasmonic control of drug release efficiency in agarose gel loaded with gold nanoparticle assemblies, file e0c31c10-24ba-4599-e053-1705fe0aef77
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98
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Trends in regenerative therapies, combination approaches, and clinical highlights for spinal cord injury (SCI) regeneration, file e0c31c11-51b0-4599-e053-1705fe0aef77
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90
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Double conjugated nanogels for selective intracellular drug delivery, file e0c31c0b-0664-4599-e053-1705fe0aef77
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84
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Evaluation of RGD functionalization in hybrid hydrogels as 3D neural stem cell culture systems, file e0c31c10-d6e6-4599-e053-1705fe0aef77
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84
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Coating and Functionalization Strategies for Nanogels and Nanoparticles for Selective Drug Delivery, file e0c31c0f-8367-4599-e053-1705fe0aef77
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83
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Modulation of electrostatic interactions to improve controlled drug delivery from nanogels, file e0c31c10-d88f-4599-e053-1705fe0aef77
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82
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Graphene nanoplatelets can improve the performances of graphene oxide – polyaniline composite gas sensing aerogels, file e0c31c11-f939-4599-e053-1705fe0aef77
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82
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The addition of hyaluronic acid in chemical hydrogels can tune the physical properties and degradability, file e0c31c12-1b73-4599-e053-1705fe0aef77
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78
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Biphasic porous structures formed by monomer/water interface stabilization with colloidal nanoparticles, file e0c31c11-c2a0-4599-e053-1705fe0aef77
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77
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Influence of the Core Formulation on Features and Drug Delivery Ability of Carbamate-Based Nanogels, file e0c31c0f-fa07-4599-e053-1705fe0aef77
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76
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Inorganic–organic core/shell nanoparticles: progress and applications, file e0c31c10-5e23-4599-e053-1705fe0aef77
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76
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How can nanovectors be used to treat spinal cord injury?, file e0c31c0e-d4fb-4599-e053-1705fe0aef77
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74
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Biohybrid Bovine Bone Matrix for Controlled Release of Mesenchymal Stem/Stromal Cell Lyosecretome: A Device for Bone Regeneration, file e0c31c11-04ab-4599-e053-1705fe0aef77
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65
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Computational fluid dynamic models as tools to predict aerosol distribution in tracheobronchial airways, file e0c31c10-98de-4599-e053-1705fe0aef77
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61
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Electroconductive multi-functional polypyrrole composites for biomedical applications, file e0c31c11-8125-4599-e053-1705fe0aef77
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59
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Polymer Functionalization as a Powerful Tool to Improve Scaffold Performances, file e0c31c0d-f1e9-4599-e053-1705fe0aef77
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55
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Effects of primary amine-based coatings on microglia internalization of nanogels, file e0c31c0e-e4ce-4599-e053-1705fe0aef77
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55
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b-Cyclodextrin functionalized agarose-based hydrogels for multiple controlled drug delivery of ibuprofen, file 3659538a-be46-4e2f-a959-4f076696e239
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54
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Layer-by layer fabrication of hydrogels microsystems for controlled drug delivery from untethered microrobots, file e0c31c12-195e-4599-e053-1705fe0aef77
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53
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Design and clinical application of injectable hydrogels for musculoskeletal therapy, file e0c31c12-b6b5-4599-e053-1705fe0aef77
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48
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A Methodologic Approach for the Selection of Bio-Resorbable Polymers in the Development of Medical Devices: The Case of Poly(L-lactide-co-epsilon-caprolactone), file e0c31c0c-5bee-4599-e053-1705fe0aef77
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40
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Effect of different physical cross-linkers on drug release from hydrogel layers coated on magnetically steerable 3D printed microdevices, file e0c31c11-625c-4599-e053-1705fe0aef77
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39
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Biobased Materials as Promising Tools for the Slow-Release of Urea, file aad5639d-b1d0-4cdd-a647-20d663e81bb6
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37
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Injectable Smart Hydrogels for Spinal Cord Regeneration, file 74375950-614e-4b0b-84bf-8b11d3b5ab69
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36
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A facile surfactant-free strategy to construct porous structures with hydrophobic and hydrophilic domains from polymer/water mixtures, file 008cedb7-c7c8-44fd-adbd-26ce19c044a8
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35
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On the influence of linear and branched polyethylenimine on properties and drug release ability of nanogels, file e0c31c10-ef47-4599-e053-1705fe0aef77
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33
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Current options for cell therapy in spinal cord injury, file e0c31c0b-3055-4599-e053-1705fe0aef77
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32
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Graphene oxide-chitosan aerogels: synthesis, characterization and use as adsorbent material for water contaminants, file e0c31c11-7bc8-4599-e053-1705fe0aef77
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32
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Bijels as a Fluid Labyrinth for Drugs: The Effect of Nanoparticles on the Release Kinetics of Ethosuximide and Dimethyl Fumarate, file 5418ffba-1217-4cdc-9e10-f9cae010c9cb
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31
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Layer-by-layer Polymeric Deposition as an Efficient Strategy to Sustain Drug Release, file abe01f32-9895-452a-8406-b61ffc6ce11f
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30
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Antimicrobial ionic liquid-based materials for biomedical applications, file e0c31c11-9d9a-4599-e053-1705fe0aef77
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29
|
Non-invasive in vitro and in vivo monitoring of degradation of fluorescently labeled hyaluronan hydrogels for tissue engineering applications, file e0c31c08-ea59-4599-e053-1705fe0aef77
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28
|
Mesenchymal stem cells encapsulated into biomimetic hydrogel scaffold gradually release CCL2 chemokine in situ preserving cytoarchitecture and promoting functional recovery in spinal cord injury, file e0c31c0b-c15e-4599-e053-1705fe0aef77
|
26
|
Drug Delivery, file d47cf88c-4605-44bb-a73f-05d955ebacdd
|
23
|
The Role of Drug-Drug Interactions in Hydrogel-based Drug Delivery Systems: Experimental and Theoretical Study, file e0c31c11-5f5a-4599-e053-1705fe0aef77
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22
|
Towards Bone Regeneration: Understanding the Nucleating Ability of Proline-rich peptides in Biomineralisation, file 36132cae-d7a8-4ede-bcab-340545109ae7
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21
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Effects of primary amine-based coatings on microglia internalization of nanogels, file 7bb94b80-0fa8-49a9-8776-da3feb90b9a1
|
19
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In vivo drug delivery applications of nanogels: a review, file e0c31c10-3994-4599-e053-1705fe0aef77
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18
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Biomaterial-mediated factor delivery for spinal cord injury treatment, file 283f30af-02b5-4de2-81a9-2f06fc744b89
|
15
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Can nanoparticles enhance delivery performances of hydrogels?, file 6e82c36a-32cd-4b30-a14c-b7fab3b0961a
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15
|
Multidrug encapsulation within self-assembled 3D structures formed by biodegradable nanoparticles, file e0c31c0e-8f71-4599-e053-1705fe0aef77
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15
|
Review on the strategies to improve the mechanical strength of highly porous bone bioceramic scaffolds, file b42158fd-4faa-4a4f-a091-b4e1969b86da
|
14
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Click chemistry as efficient strategy to improve nanoparticles performances in drug delivery, file d47e50ef-5122-4d35-ae6d-7417164a096f
|
14
|
Zinc electrodeposition from a chloride-free non-aqueous solution based on ethylene glycol and acetate salts, file e0c31c0c-fdd4-4599-e053-1705fe0aef77
|
14
|
Totale |
20.744 |