| Nome |
# |
|
Fabrication of 3D cell-laden hydrogel microstructures through photo-mold patterning, file e0c31c08-16fe-4599-e053-1705fe0aef77
|
550
|
|
Micro-electrode channel guide (µECG) technology: An online method for continuous electrical recording in a human beating heart-on-chip, file e0c31c11-4b4c-4599-e053-1705fe0aef77
|
482
|
|
Towards modeling limb development: high-throughput microfluidic platform for culturing mesenchymal stromal cell perfused micromasses, file e0c31c09-4bce-4599-e053-1705fe0aef77
|
452
|
|
Cardiac Meets Skeletal: What's New in Microfluidic Models for Muscle Tissue Engineering, file e0c31c09-c5d6-4599-e053-1705fe0aef77
|
414
|
|
Fabrication of multi-well chips for spheroid cultures and implantable constructs through rapid prototyping techniques, file e0c31c08-497f-4599-e053-1705fe0aef77
|
383
|
|
Microfabricated Physiological Models for In Vitro Drug Screening Applications, file e0c31c0a-4d0d-4599-e053-1705fe0aef77
|
323
|
|
VA-086 methacrylate gelatine photopolymerizable hydrogels: A parametric study for highly biocompatible 3D cell embedding, file e0c31c08-3183-4599-e053-1705fe0aef77
|
238
|
|
Recapitulating monocyte extravasation to the synovium in an organotypic microfluidic model of the articular joint, file e0c31c11-646f-4599-e053-1705fe0aef77
|
233
|
|
On-chip assessment of human primary cardiac fibroblasts proliferative responses to uniaxial cyclic mechanical strain, file e0c31c08-e26e-4599-e053-1705fe0aef77
|
215
|
|
High-throughput microfluidic platform for adherent single cells non-viral gene delivery, file e0c31c08-3184-4599-e053-1705fe0aef77
|
207
|
|
Bioprinting 3D microfibrous scaffolds for engineering endothelialized myocardium and heart-on-a-chip, file e0c31c0f-5016-4599-e053-1705fe0aef77
|
190
|
|
High-Throughput Microfluidic Platform for 3D Cultures of Mesenchymal Stem Cells, Towards Engineering Developmental Processes, file e0c31c07-bf11-4599-e053-1705fe0aef77
|
189
|
|
Integrating Biosensors in Organs-on-Chip Devices: A Perspective on Current Strategies to Monitor Microphysiological Systems, file e0c31c10-2c82-4599-e053-1705fe0aef77
|
185
|
|
A microfluidic device for studying drug transport through endothelial Blood Brain
Barrier cells monolayers, file e0c31c0d-117c-4599-e053-1705fe0aef77
|
179
|
|
Controlled electromechanical cell stimulation on-a-chip, file e0c31c08-4e39-4599-e053-1705fe0aef77
|
165
|
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Tailoring cardiac environment in microphysiological systems: an outlook on current and perspective heart-on-chip platforms, file e0c31c0b-2551-4599-e053-1705fe0aef77
|
155
|
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Short-term effects of microstructured surfaces: role in cell differentiation toward a contractile phenotype, file e0c31c08-535e-4599-e053-1705fe0aef77
|
154
|
|
A microscale biomimetic platform for generation and electro-mechanical stimulation of 3D cardiac microtissues, file e0c31c0d-ea66-4599-e053-1705fe0aef77
|
150
|
|
Reconstitution of the Human Nigro-striatal Pathway on-a-Chip Reveals OPA1-Dependent Mitochondrial Defects and Loss of Dopaminergic Synapses, file e0c31c0e-e7be-4599-e053-1705fe0aef77
|
150
|
|
Human cardiac fibroblasts adaptive responses to controlled combined mechanical strain and oxygen changes in vitro, file e0c31c0b-11f9-4599-e053-1705fe0aef77
|
133
|
|
Lab-on-Chip for testing myelotoxic effect of drugs and chemicals, file e0c31c08-7192-4599-e053-1705fe0aef77
|
123
|
|
Microfluidic flow-based platforms for induction and analysis of dynamic shear-mediated platelet activation - Initial validation versus the standardized hemodynamic shearing device, file e0c31c0c-8676-4599-e053-1705fe0aef77
|
121
|
|
Microfluidic emulation of mechanical circulatory support device shear-mediated platelet activation, file e0c31c09-a132-4599-e053-1705fe0aef77
|
117
|
|
Bioengineered tooth emulation systems for regenerative and pharmacological purposes, file e0c31c11-a2ad-4599-e053-1705fe0aef77
|
113
|
|
Physiologic flow-conditioning limits vascular dysfunction in engineered human capillaries, file e0c31c12-c424-4599-e053-1705fe0aef77
|
113
|
|
Young at Heart: Pioneering Approaches to Model Nonischaemic Cardiomyopathy with Induced Pluripotent Stem Cells, file e0c31c09-41fb-4599-e053-1705fe0aef77
|
111
|
|
Enhancing all-in-one bioreactors by combining interstitial perfusion, electrical stimulation, on-line monitoring and testing within a single chamber for cardiac constructs, file e0c31c0d-8f4c-4599-e053-1705fe0aef77
|
110
|
|
Generating Multicompartmental 3D Biological Constructs Interfaced through Sequential Injections in Microfluidic Devices, file e0c31c0b-002e-4599-e053-1705fe0aef77
|
101
|
|
Frataxin gene editing rescues Friedreich’s ataxia pathology in dorsal root ganglia organoid-derived sensory neurons, file e0c31c10-4a26-4599-e053-1705fe0aef77
|
94
|
|
Current strategies of mechanical stimulation for maturation of cardiac microtissues, file e0c31c12-0e3f-4599-e053-1705fe0aef77
|
81
|
|
Liver-Heart on chip models for drug safety, file e0c31c11-ae47-4599-e053-1705fe0aef77
|
74
|
|
METHODS , DEVICES , AND SYSTEMS FOR MICROFLUIDIC STRESS EMULATION, file e0c31c0e-d9af-4599-e053-1705fe0aef77
|
72
|
|
The MICELI (MICrofluidic, ELectrical, impedance): Prototyping a point-of-care impedance platelet aggregometer, file e0c31c10-0603-4599-e053-1705fe0aef77
|
71
|
|
Microfluidic Biofabrication of 3D Multicellular Spheroids by Modulation of Non-geometrical Parameters, file e0c31c10-0601-4599-e053-1705fe0aef77
|
70
|
|
Assessing the influence of perfusion on cardiac microtissue maturation: A heart-on-chip platform embedding peristaltic pump capabilities, file e0c31c11-6776-4599-e053-1705fe0aef77
|
51
|
|
A dynamic microscale mid-throughput fibrosis model to investigate the effects of different ratios of cardiomyocytes and fibroblasts, file e0c31c11-8011-4599-e053-1705fe0aef77
|
43
|
|
Modeling in vitro osteoarthritis phenotypes in a vascularized bone model based on a bone-marrow derived mesenchymal cell line and endothelial cells, file e0c31c11-b54c-4599-e053-1705fe0aef77
|
38
|
|
Predicting human cardiac QT alterations and pro-arrhythmic effects of compounds with a 3D beating heart-on-chip platform, file faac129d-2946-46b8-8904-ce8bdeeb4f26
|
33
|
|
LivHeart: A Multi Organ-on-Chip Platform to Study Off-Target Cardiotoxicity of Drugs Upon Liver Metabolism, file a4b93e4f-fa55-4013-bcd3-32235cb98879
|
28
|
|
A new microfluidic platform for the highly reproducible preparation of non-viral gene delivery complexes, file 5573c2ff-000d-47ea-a6ed-b7b807aa0882
|
20
|
|
Microfluidic facsimile of ventricular assist device shear stress patterns: towards point-of-care devices to monitor patient thrombotic risk, file e0c31c09-622e-4599-e053-1705fe0aef77
|
19
|
|
A Human Stem Cell-Derived Neurosensory-Epithelial Circuitry on a Chip to Model Herpes Simplex Virus Reactivation, file 72dd1ecc-f288-41dd-9c42-fb9832959890
|
14
|
|
GZMKhigh CD8+ T effector memory cells are associated with CD15high neutrophil abundance in non-metastatic colorectal tumors and predict poor clinical outcome., file 8b082849-9e03-43f3-8e89-5627b014b369
|
11
|
|
Normothermic Ex Vivo Liver Platform Using Porcine Slaughterhouse Livers for Disease Modeling, file fb7de1e4-4ab7-40a6-a749-4c07c7e32285
|
11
|
|
Cholangiocarcinoma-on-a-chip: A human 3D platform for personalised medicine, file b1e0a18a-e110-4ea5-af87-9c872e30ebc0
|
8
|
|
Functional microvascularization of human myocardium in vitro, file caff2fec-8030-47c8-8ac2-1c3dfd8e16f0
|
8
|
|
In Vitro Mechanical Stimulation to Reproduce the Pathological Hallmarks of Human Cardiac Fibrosis on a Beating Chip and Predict The Efficacy of Drugs and Advanced Therapies, file 1a712977-dfe2-4e7f-92fe-57abd52aa8fa
|
6
|
|
Microfluidic approaches for the assessment of blood cell trauma: a focus on thrombotic risk in mechanical circulatory support devices, file e0c31c09-5ef4-4599-e053-1705fe0aef77
|
5
|
|
Development of a microfluidic platform for high-throughput screening of non-viral gene delivery vectors, file e0c31c0b-73bd-4599-e053-1705fe0aef77
|
5
|
|
Cancer-on-chip: a 3D model for the study of the tumor microenvironment, file ade111b8-e3b8-498d-a4e7-ad833de063a5
|
4
|
|
Immunomodulatory biomimetic nanoparticles target articular cartilage trauma after systemic administration, file 5c9ff6da-c577-4e0f-8477-2339c07ea5d8
|
3
|
|
Design and validation of a microfluidic device for blood–brain barrier monitoring and transport studies, file e0c31c0b-9ea1-4599-e053-1705fe0aef77
|
3
|
|
Novel microfluidic protein patterning method for human-organs-on-chip: liver-tumor application, file e0c31c0f-072e-4599-e053-1705fe0aef77
|
3
|
|
Are slaughterhouse-obtained livers suitable for use in ex vivo perfusion research?, file 52e61fa6-5289-4c6e-811a-205a7b119195
|
2
|
|
null, file e0c31c08-e182-4599-e053-1705fe0aef77
|
2
|
|
A Simple Vacuum-Based Microfluidic Technique to Establish High-Throughput Organs-On-Chip and 3D Cell Cultures at the Microscale, file e0c31c0d-c79c-4599-e053-1705fe0aef77
|
2
|
|
Experimental liver models: From cell culture techniques to microfluidic organs-on-chip, file e0c31c11-b54d-4599-e053-1705fe0aef77
|
2
|
|
Physiologic flow-conditioning limits vascular dysfunction in engineered human capillaries, file e0c31c11-f465-4599-e053-1705fe0aef77
|
2
|
|
null, file e0c31c07-e791-4599-e053-1705fe0aef77
|
1
|
|
VA-086 methacrylate gelatine photopolymerizable hydrogels: A parametric study for highly biocompatible 3D cell embedding, file e0c31c08-3182-4599-e053-1705fe0aef77
|
1
|
|
'HyperShear in a channel': A microfluidic facsimile of ventricular assist devices to reduce thrombotic risk and enhance patient safety, file e0c31c09-85b1-4599-e053-1705fe0aef77
|
1
|
|
Hyperphysiological compression of articular cartilage induces an osteoarthritic phenotype in a cartilage-on-a-chip model, file e0c31c0e-ca70-4599-e053-1705fe0aef77
|
1
|
|
Developmentally inspired programming of adult human mesenchymal stromal cells towards stable chondrogenesis, file e0c31c10-cc92-4599-e053-1705fe0aef77
|
1
|
|
Plasma-enhanced protein patterning in a microfluidic compartmentalized platform for multi-organs-on-chip: A liver-tumor model, file e0c31c11-a2ab-4599-e053-1705fe0aef77
|
1
|
| Totale |
6.847 |