Nome |
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Biofabrication: A Guide to Technology and Terminology, file e0d6c930-8496-fcf8-e053-d805fe0aa794
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412
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Age-related macular degeneration: Current knowledge of zinc metalloproteinases involvement, file e0d6c92e-c96e-fcf8-e053-d805fe0aa794
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365
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Finite element modelling and design of a concentration gradient generating bioreactor: application to biological pattern formation and toxicology, file e0d6c92c-d4ae-fcf8-e053-d805fe0aa794
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334
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Design and Validation of an Open-Hardware Print-Head for Bioprinting Application, file e0d6c926-c32a-fcf8-e053-d805fe0aa794
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329
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Fabrication and characterization of gelatin/carbon black–based scaffolds for neural tissue engineering applications, file e0d6c92d-70ae-fcf8-e053-d805fe0aa794
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268
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CREPE: Mathematical model for crosstalking of endothelial cells and hepatocyte metabolism, file e0d6c92d-1b7d-fcf8-e053-d805fe0aa794
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244
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Pressure-activated microsyringe (PAM) fabrication of bioactive glass-poly(lactic-co-glycolic acid) composite scaffolds for bone tissue regeneration, file e0d6c930-aca7-fcf8-e053-d805fe0aa794
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217
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Genipin diffusion and reaction into a gelatin matrix for tissue engineering applications, file e0d6c930-893b-fcf8-e053-d805fe0aa794
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214
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Touch sensor for social robots and interactive objects affective interaction, file e0d6c92e-f81e-fcf8-e053-d805fe0aa794
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211
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Cardiac tissue regeneration: A preliminary study on carbon-based nanotubes gelatin scaffold, file e0d6c929-f69b-fcf8-e053-d805fe0aa794
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200
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Bone scaffolds with homogeneous and discrete gradient mechanical properties, file e0d6c92c-d663-fcf8-e053-d805fe0aa794
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179
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Reconstruction of medial patello-femoral ligament: Comparison of two surgical techniques, file e0d6c92d-28f9-fcf8-e053-d805fe0aa794
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179
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CFD modelling of a mixing chamber for the realisation of functionally graded scaffolds, file e0d6c92d-0f7a-fcf8-e053-d805fe0aa794
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148
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Design, fabrication and perivascular implantation of bioactive scaffolds engineered with human adventitial progenitor cells for stimulation of arteriogenesis in peripheral ischemia, file e0d6c930-951f-fcf8-e053-d805fe0aa794
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136
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Electrospun Structures Made of a Hydrolyzed Keratin-Based Biomaterial for Development of in vitro Tissue Models, file e0d6c92d-7b63-fcf8-e053-d805fe0aa794
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133
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Chemico-physical characterization and evaluation of coating properties of two commercial organosilicons: Hydrophase® and Disboxan 450®, file e0d6c92d-cd4a-fcf8-e053-d805fe0aa794
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116
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A new 3D concentration gradient maker and its application in building hydrogels with a 3D stiffness gradient, file e0d6c930-76d4-fcf8-e053-d805fe0aa794
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111
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4D printing of polymeric materials for tissue and organ regeneration, file e0d6c930-655d-fcf8-e053-d805fe0aa794
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110
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Rational design and fabrication of multiphasic soft network composites for tissue engineering articular cartilage: A numerical model-based approach, file e0d6c930-9370-fcf8-e053-d805fe0aa794
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109
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Le colture cellulari da brushing nasale: un nuovo metodo per semplificare l’iter diagnostico nei casi dubbi di discinesia ciliare primaria, file e0d6c92c-644b-fcf8-e053-d805fe0aa794
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106
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Phantoms in medicine: the case of ophthalmology, file e0d6c92e-a5cf-fcf8-e053-d805fe0aa794
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103
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In silico models for dynamic connected cell cultures mimicking hepatocyte-endothelial cell-adipocyte interaction circle, file e0d6c926-8e3a-fcf8-e053-d805fe0aa794
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102
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Integration of Biomechanical and Biological Characterization in the Development of Porous Poly(Caprolactone)-Based Membranes for Abdominal Wall Hernia Treatment., file e0d6c92b-783b-fcf8-e053-d805fe0aa794
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99
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A new path to platelet production through matrix sensing, file e0d6c92d-1d55-fcf8-e053-d805fe0aa794
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85
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Biomechanical, Topological and Chemical Features That Influence the Implant Success of an Urogynecological Mesh: A Review, file e0d6c92d-2900-fcf8-e053-d805fe0aa794
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84
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Ultrasonic mixing chamber as an effective tool for the biofabrication of fully graded scaffolds for interface tissue engineering, file e0d6c930-c072-fcf8-e053-d805fe0aa794
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84
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Gelatin-genipin-based biomaterials for skeletal muscle tissue engineering, file e0d6c930-88ea-fcf8-e053-d805fe0aa794
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82
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Valorization of not soluble byproducts deriving from green keratin extraction from poultry feathers as filler for biocomposites, file e0d6c931-847f-fcf8-e053-d805fe0aa794
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73
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Material and structural tensile properties of the human medial patello-femoral ligament, file e0d6c930-9291-fcf8-e053-d805fe0aa794
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72
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Cell-free demineralized bone matrix for mesenchymal stem cells survival and colonization, file e0d6c92f-08cd-fcf8-e053-d805fe0aa794
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70
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Triphasic scaffolds for the regeneration of the bone-ligament interface, file e0d6c930-9ed0-fcf8-e053-d805fe0aa794
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62
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Soft-molecular imprinted electrospun scaffolds to mimic specific biological tissues, file e0d6c930-b3bb-fcf8-e053-d805fe0aa794
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50
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3D screening device for the evaluation of cell response to different electrospun microtopographies, file e0d6c930-7138-fcf8-e053-d805fe0aa794
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43
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Study of the Adhesion of the Human Gut Microbiota on Electrospun Structures, file e0d6c931-d5d0-fcf8-e053-d805fe0aa794
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34
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Endothelial cells support osteogenesis in an in vitro vascularized bone model developed by 3D bioprinting, file e0d6c92e-e22d-fcf8-e053-d805fe0aa794
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27
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Biofabrication: reappraising the definition of an evolving field, file e0d6c930-936e-fcf8-e053-d805fe0aa794
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23
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Bioreactor chamber, file e0d6c927-fbc8-fcf8-e053-d805fe0aa794
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16
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Development of an In Vitro Model of the Gut Microbiota Enriched in Mucus-Adhering Bacteria, file 93b31e56-4527-458d-97a8-170742d9fe40
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14
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One-pot process: Microwave-assisted keratin extraction and direct electrospinning to obtain keratin-based bioplastic, file e0d6c931-9a66-fcf8-e053-d805fe0aa794
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14
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Valorization of not soluble byproducts deriving from green keratin extraction from poultry feathers as filler for biocomposites, file e0d6c931-5248-fcf8-e053-d805fe0aa794
|
13
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A novel 3D in vitro model of the human gut microbiota, file e0d6c92f-ee5d-fcf8-e053-d805fe0aa794
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12
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Bone and gut microbiota crosstalk: A novel 3D in vitro approach, file e0d6c931-4865-fcf8-e053-d805fe0aa794
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11
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Impact of Bacillus cereus on the Human Gut Microbiota in a 3D In Vitro Model, file ce48db88-a6d9-4256-8e18-c564f09c489c
|
8
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3D screening device for the evaluation of cell response to different electrospun microtopographies, file e0d6c930-7139-fcf8-e053-d805fe0aa794
|
8
|
Valorization of not soluble byproducts deriving from green keratin extraction from poultry feathers as filler for biocomposites, file e0d6c931-879f-fcf8-e053-d805fe0aa794
|
7
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Designs and methodologies to recreate in vitro human gut microbiota models, file 9d685911-4cbf-45d1-a5cb-d790fd3562a1
|
6
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Role of IGF1 and IGF1/VEGF on Human Mesenchymal Stromal Cells in Bone Healing: Two Sources and Two Fates., file e0d6c926-f436-fcf8-e053-d805fe0aa794
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6
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Biofabrication: reappraising the definition of an evolving field, file e0d6c927-128c-fcf8-e053-d805fe0aa794
|
6
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Soft-molecular imprinted electrospun scaffolds to mimic specific biological tissues, file e0d6c92b-7335-fcf8-e053-d805fe0aa794
|
6
|
3D screening device for the evaluation of cell response to different electrospun microtopographies, file e0d6c930-713a-fcf8-e053-d805fe0aa794
|
6
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Triphasic scaffolds for the regeneration of the bone-ligament interface, file e0d6c927-11c6-fcf8-e053-d805fe0aa794
|
5
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An autologously generated platelet-rich plasma suturable membrane may enhance peripheral nerve regeneration after neurorraphy in an acute injury model of sciatic nerve neurotmesis, file e0d6c92d-1b83-fcf8-e053-d805fe0aa794
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5
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Combining inkjet printing and sol-gel chemistry for making pH-sensitive surfaces, file e0d6c92d-1d4d-fcf8-e053-d805fe0aa794
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5
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4D Bioprinting as New Tissue Engineering Perspective, file e0d6c92d-5098-fcf8-e053-d805fe0aa794
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5
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Microfabricated and multilayered PLGA structure for the development of co-cultured in vitro liver models, file e0d6c92f-8ca3-fcf8-e053-d805fe0aa794
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5
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Genipin diffusion and reaction into a gelatin matrix for tissue engineering applications, file e0d6c930-8058-fcf8-e053-d805fe0aa794
|
5
|
Pectin as rheology modifier of a gelatin-based biomaterial ink, file e0d6c931-a22c-fcf8-e053-d805fe0aa794
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5
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A Millifluidic Chamber for Controlled Shear Stress Testing: Application to Microbial Cultures, file 5a5c0199-eec3-41a7-824a-a83fb218cde8
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4
|
Material and structural tensile properties of the human medial patello-femoral ligament, file e0d6c926-c22d-fcf8-e053-d805fe0aa794
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4
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Gelatin-genipin-based biomaterials for skeletal muscle tissue engineering, file e0d6c92a-5ff1-fcf8-e053-d805fe0aa794
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4
|
null, file e0d6c92d-0f8d-fcf8-e053-d805fe0aa794
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4
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European regulatory framework for the clinical translation of bioprinted scaffolds and tissues, file e0d6c92f-9505-fcf8-e053-d805fe0aa794
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4
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Pressure-activated microsyringe (PAM) fabrication of bioactive glass-poly(lactic-co-glycolic acid) composite scaffolds for bone tissue regeneration, file e0d6c930-c4ed-fcf8-e053-d805fe0aa794
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4
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The control of stem cell morphology and differentiation using three-dimensional printed scaffold architecture, file e0d6c929-d6ca-fcf8-e053-d805fe0aa794
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3
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null, file e0d6c92b-2789-fcf8-e053-d805fe0aa794
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3
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null, file e0d6c92d-410b-fcf8-e053-d805fe0aa794
|
3
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Molecular Imprinting Strategies for Tissue Engineering Applications: A Review, file e0d6c930-7a0b-fcf8-e053-d805fe0aa794
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3
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Genipin diffusion and reaction into a gelatin matrix for tissue engineering applications, file e0d6c930-9a6b-fcf8-e053-d805fe0aa794
|
3
|
Physicochemical Characterization of Pectin-Gelatin Biomaterial Formulations for 3D Bioprinting, file e0d6c931-6be9-fcf8-e053-d805fe0aa794
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3
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4D Printing: A Snapshot on an Evolving Field, file e0d6c931-6da6-fcf8-e053-d805fe0aa794
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3
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null, file e0d6c925-f411-fcf8-e053-d805fe0aa794
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2
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AN AUTOLOGOUS PLATELET-RICH PLASMA MEMBRANE TO IMPROVE RAT SCIATIC NERVE REGENERATION, file e0d6c926-42f7-fcf8-e053-d805fe0aa794
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2
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Magnetic-driven pointing system: A feasibility study, file e0d6c926-8cf3-fcf8-e053-d805fe0aa794
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2
|
Smart Sensing Scaffolds, file e0d6c926-8e83-fcf8-e053-d805fe0aa794
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2
|
null, file e0d6c928-bf79-fcf8-e053-d805fe0aa794
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2
|
Multimaterial, heterogeneous, and multicellular three-dimensional bioprinting, file e0d6c929-99e2-fcf8-e053-d805fe0aa794
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2
|
In vitro development of engineered muscle using a scaffold based on the pressure-activated-microsyringe (PAM) technique, file e0d6c92d-1f12-fcf8-e053-d805fe0aa794
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2
|
Realisation and characterization of conductive hollow fibers for neuronal tissue engineering, file e0d6c92d-410d-fcf8-e053-d805fe0aa794
|
2
|
Disordered protein-graphene oxide co-assembly and supramolecular biofabrication of functional fluidic devices, file e0d6c92f-8ca0-fcf8-e053-d805fe0aa794
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2
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Modeling the Three-Dimensional Bioprinting Process of β-Sheet Self-Assembling Peptide Hydrogel Scaffolds, file e0d6c92f-9f3a-fcf8-e053-d805fe0aa794
|
2
|
A combined electrospinning and microestrusion apparatus, file e0d6c92f-e248-fcf8-e053-d805fe0aa794
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2
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Fabrication of New Hybrid Scaffolds for in vivo Perivascular Application to Treat Limb Ischemia, file e0d6c92f-ee55-fcf8-e053-d805fe0aa794
|
2
|
Osteogenic differentiation of hBMSCs on porous photo-crosslinked poly(trimethylene carbonate) and nano-hydroxyapatite composites, file e0d6c930-6b5a-fcf8-e053-d805fe0aa794
|
2
|
4D printing of polymeric materials for tissue and organ regeneration, file e0d6c930-788e-fcf8-e053-d805fe0aa794
|
2
|
3D screening device for the evaluation of cell response to different electrospun microtopographies, file e0d6c930-9bca-fcf8-e053-d805fe0aa794
|
2
|
Ultrasonic mixing chamber as an effective tool for the biofabrication of fully graded scaffolds for interface tissue engineering, file e0d6c930-a91d-fcf8-e053-d805fe0aa794
|
2
|
Design, fabrication and perivascular implantation of bioactive scaffolds engineered with human adventitial progenitor cells for stimulation of arteriogenesis in peripheral ischemia, file e0d6c930-bd32-fcf8-e053-d805fe0aa794
|
2
|
Electrical and Mechanical Characterisation of Single Wall Carbon Nanotubes Based Composites for Tissue Engineering Applications, file e0d6c926-17a9-fcf8-e053-d805fe0aa794
|
1
|
A phase diagram for microfabrication of geometrically controlled hydrogel scaffolds, file e0d6c926-223e-fcf8-e053-d805fe0aa794
|
1
|
null, file e0d6c926-35dd-fcf8-e053-d805fe0aa794
|
1
|
Collagen-gelatin-genipin-hydroxyapatite composite scaffolds colonized by human primary osteoblasts are suitable for bone tissue engineering applications: In vitro evidences., file e0d6c926-3a39-fcf8-e053-d805fe0aa794
|
1
|
A new approach to fabricate agarose microstructures, file e0d6c926-4263-fcf8-e053-d805fe0aa794
|
1
|
Utilizzo di phantom in oftalmologia, file e0d6c926-8cf9-fcf8-e053-d805fe0aa794
|
1
|
Development of a novel micro-ablation system to realise micrometric and well-defined hydrogel structures for tissue engineering applications, file e0d6c926-8cfb-fcf8-e053-d805fe0aa794
|
1
|
Role of IGF1 and IGF1/VEGF on human mesenchymal stromal cells in bone healing: Two sources and two fates, file e0d6c926-8e87-fcf8-e053-d805fe0aa794
|
1
|
A new 3D concentration gradient maker and its application in building hydrogels with a 3D stiffness gradient, file e0d6c926-8e8b-fcf8-e053-d805fe0aa794
|
1
|
New eye phantom for ophthalmic surgery, file e0d6c926-8e8d-fcf8-e053-d805fe0aa794
|
1
|
Indirect Rapid Prototyping for Tissue Engineering, file e0d6c926-c29f-fcf8-e053-d805fe0aa794
|
1
|
Quasi-linear viscoelastic properties of the human medial patello-femoral ligament, file e0d6c926-c32e-fcf8-e053-d805fe0aa794
|
1
|
Blends of poly-(epsilon-caprolactone) and polysaccharides in tissue engineering applications, file e0d6c927-781e-fcf8-e053-d805fe0aa794
|
1
|
Totale |
5.474 |