Müller et al., 2013 - Google Patents
Printing thermoresponsive reverse molds for the creation of patterned two-component hydrogels for 3D cell cultureMüller et al., 2013
View HTML- Document ID
- 678920165900155927
- Author
- Müller M
- Becher J
- Schnabelrauch M
- Zenobi-Wong M
- Publication year
- Publication venue
- Journal of visualized experiments: JoVE
External Links
Snippet
Bioprinting is an emerging technology that has its origins in the rapid prototyping industry. The different printing processes can be divided into contact bioprinting1-4 (extrusion, dip pen and soft lithography), contactless bioprinting5-7 (laser forward transfer, ink-jet …
- 238000007639 printing 0 title abstract description 44
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Müller et al. | Printing thermoresponsive reverse molds for the creation of patterned two-component hydrogels for 3D cell culture | |
| Tolabi et al. | Progress of microfluidic hydrogel‐based scaffolds and organ‐on‐chips for the cartilage tissue engineering | |
| Daly | Granular hydrogels in biofabrication: recent advances and future perspectives | |
| Yu et al. | 3D printing and bioprinting nerve conduits for neural tissue engineering | |
| Hakim Khalili et al. | Additive manufacturing and physicomechanical characteristics of PEGDA hydrogels: recent advances and perspective for tissue engineering | |
| Yanagawa et al. | Hydrogel microfabrication technology toward three dimensional tissue engineering | |
| Tan et al. | Hybrid microscaffold-based 3D bioprinting of multi-cellular constructs with high compressive strength: A new biofabrication strategy | |
| Savoji et al. | 3D printing of vascular tubes using bioelastomer prepolymers by freeform reversible embedding | |
| Sasmal et al. | 3D bioprinting for modelling vasculature | |
| Jose et al. | Evolution of bioinks and additive manufacturing technologies for 3D bioprinting | |
| Jafarkhani et al. | Bioprinting in vascularization strategies | |
| Zorlutuna et al. | Microfabricated biomaterials for engineering 3D tissues | |
| Murphy et al. | 3D bioprinting of tissues and organs | |
| Wüst et al. | Controlled positioning of cells in biomaterials—approaches towards 3D tissue printing | |
| Tan et al. | Layer-by-layer microfluidics for biomimetic three-dimensional structures | |
| Liang et al. | Hybrid hydrogels based on methacrylate-functionalized gelatin (GelMA) and synthetic polymers | |
| Nadine et al. | Advances in microfabrication technologies in tissue engineering and regenerative medicine | |
| Fuentes-Caparrós et al. | Mechanical characterization of multilayered hydrogels: A rheological study for 3D-printed systems | |
| Bin Rashid et al. | 3D bioprinting in the era of 4th industrial revolution–insights, advanced applications, and future prospects | |
| Sardelli et al. | Engineering biological gradients | |
| US20160068385A1 (en) | Microfluidic devices and methods for the extrusion of tubular structures | |
| Mierke | Bioprinting of cells, organoids and organs-on-a-chip together with hydrogels improves structural and mechanical cues | |
| Li et al. | Promising new horizons in medicine: medical advancements with nanocomposite manufacturing via 3D printing | |
| Kim et al. | Advanced strategies in 3D bioprinting for vascular tissue engineering and disease modelling using smart bioinks | |
| Gerdes et al. | Extrusion-based 3D (bio) printed tissue engineering scaffolds: Process–structure–quality relationships |