| 3D printing of hydrogel composite systems: Recent advances in technology for tissue engineering |
35 |
| 3D bioprinting processes: A perspective on classification and terminology |
30 |
| Additive manufacturing of bone scaffolds |
27 |
| The arrival of commercial bioprinters - Towards 3D bioprinting revolution! |
14 |
| 3D printing for drug manufacturing: A perspective on the future of pharmaceuticals |
12 |
| A multi-scale porous scaffold fabricated by a combined additive manufacturing and chemical etching process for bone tissue engineering |
12 |
| Conductive collagen/polypyrrole-b-polycaprolactone hydrogel for bioprinting of neural tissue constructs |
12 |
| Extrusion-based 3D food printing - Materials and machines |
10 |
| Fabrication of biomimetic placental barrier structures within a microfluidic device utilizing two-photon polymerization |
9 |
| Progress in organ 3D bioprinting |
9 |
| Development and characterization of a photocurable alginate bioink for three-dimensional bioprinting |
8 |
| Physical stimulations and their osteogenesis-inducing mechanisms |
8 |
| The future of skin toxicology testing - Three-dimensional bioprinting meets microfluidics |
8 |
| Mechanism for corrosion protection of beta-TCP reinforced ZK60 via laser rapid solidification |
7 |
| Biofabrication offers future hope for tackling various obstacles and challenges in tissue engineering and regenerative medicine: A Perspective |
7 |
| Designs and applications of electrohydrodynamic 3D printing |
7 |
| Near-field electrospinning of a polymer/bioactive glass composite to fabricate 3D biomimetic structures |
6 |
| Mechanisms and modeling of electrohydrodynamic phenomena |
6 |
| A continuous net-like eutectic structure enhances the corrosion resistance of Mg alloys |
6 |
| Optimized vascular network by stereolithography for tissue engineered skin |
5 |
| Application of piezoelectric cells printing on three-dimensional porous bioceramic scaffold for bone regeneration |
5 |
| Three-dimensional-printing for microfluidics or the other way around? |
5 |
| Hybrid polycaprolactone/hydrogel scaffold fabrication and in-process plasma treatment using PABS |
5 |
| Electrohydrodynamic printing process monitoring by microscopic image identification |
4 |
| Of balls, inks and cages: Hybrid biofabrication of 3D tissue analogs |
4 |
| Coaxial nozzle-assisted electrohydrodynamic printing for microscale 3D cell-laden constructs |
4 |
| Bioprinting with human stem cell-laden alginate-gelatin bioink and bioactive glass for tissue engineering |
4 |
| High-precision three-dimensional inkjet technology for live cell bioprinting |
4 |
| Novel ultrashort self-assembling peptide bioinks for 3D culture of muscle myoblast cells |
4 |
| Rapid and efficient in vivo angiogenesis directed by electro-assisted bioprinting of alginate/collagen microspheres with human umbilical vein endothelial cell coating layer |
4 |
| Uncovering 3D bioprinting research trends: A keyword network mapping analysis |
3 |
| Personalized anesthetic patches for dental applications |
3 |
| An nMgO containing scaffold: Antibacterial activity, degradation properties and cell responses |
3 |
| New microorganism isolation techniques with emphasis on laser printing |
3 |
| Formation of cell spheroids using Standing Surface Acoustic Wave (SSAW) |
2 |
| The mussel-inspired assisted apatite mineralized on PolyJet material for artificial bone scaffold |
2 |
| Discovering new 3D bioprinting applications: Analyzing the case of optical tissue phantoms |
2 |
| Bioprinting of artificial blood vessels |
1 |
| Pre-clinical evaluation of advanced nerve guide conduits using a novel 3D in vitro testing model |
1 |
| Analysis of the knowledge landscape of three-dimensional bioprinting in Latin America |
1 |
| Multicomponent bioprinting of heterogeneous hydrogel constructs based on microfluidic printheads |
1 |
| Exploring nanofibrous self-assembling peptide hydrogels using mouse myoblast cells for three-dimensional bioprinting and tissue engineering applications |
1 |
| Preparation and printability of ultrashort self-assembling peptide nanoparticles |
1 |
| Optimization of a 3D bioprinting process using ultrashort peptide bioinks |
1 |
| Revealing emerging science and technology research for dentistry applications of 3D bioprinting |
1 |
| In vitro model of the glial scar |
0 |
| A methodology to develop a vascular geometry for in vitro cell culture using additive manufacturing |
0 |
