Table 2.
Comparison of various strategies for skin bioprinting
| Bioprinting strategy | Advantages | Disadvantages |
|---|---|---|
| Inkjet bioprinting | Widely used | Thermal and mechanical stress to cells |
| High printing speed | Limited printable materials | |
| High resolution | Low cell concentration | |
| High cell viability | ||
| Low cost | ||
| Laser-assisted bioprinting | Non-contacting process | Limited printable materials |
| Nozzle free | High cost | |
| High precision | Time-consuming | |
| High concentration and high viability of cells | ||
| Electrohydrodynamic jet printing | High precision | High cost |
| High structural integrity | Limited printable materials | |
| Extrusion-based bioprinting | Widely used | Limited printing accuracy |
| Good compatibility with materials | The need for gelation and shear thinning properties of materials | |
| Digital light processing bioprinting | High printing speed and consistency | The need for photocuring properties of materials |
| High structural integrity and mechanical property | ||
| High precision | ||
| In situ bioprinting | ||
| Automated | Automated fabrication process | Complicated scanning modality |
| In situ cross-linking | Sufficient room for operation | |
| Minimal invasion | Low degree of freedom | |
| Handheld | Low cost | Experience-dependence |
| Portability | Low resolution | |
| Convenient for sterilization | Non-uniform deposition | |
| Cell spheroid-laden bioprinting | Pre-aggregation of cells | Limited size of spheroids |
| Precise positioning and arrangement of cells | Complex steps for construction | |
| 4D bioprinting | Recreation of spatiotemporal factors | Limited printable materials |
| Bioprinted skin-on-a-chip | Presence of biochemical and biomechanical cues | Complex process for construction |
| Presence of multi-cell/multi-organ interactions | ||
| Microfluidics-assisted extrusion bioprinting | Precise deposition of hydrogels | Complex process for construction |
| Good repeatability | ||