Table 2.
Different types of bioreactors for cardiac tissue engineering.
| Bioreactors | Culture type | Advantages | Examples | Ref. |
|---|---|---|---|---|
| Perfusion | Scaffolds | Enhances mass transfer of oxygen through the engineered patch |
Vascular cells reveal changes in their metabolic and functional properties after exposure to increased levels of shear stress, as well as increased cell distribution and lower diffusion gradients |
[120,143] |
| Creates frictional shear stress on the cells which enhances cell proliferation |
||||
|
Multi-shear perfusion |
Scaffolds | Delivers different shear stresses at the same time |
DNA content of cultured cells increases by 91% after exposure to the bioreactor |
[120] |
| Can be used on 3D tissues | ||||
| Pulsatile fow | Cell-Sheets | Enhances vascularization of stacked cell sheets |
Stacking of six layers of rat cardiac cell sheets resulted in a thicker and denser grafts, which contracts regularly after implantation into host rat |
[120] |
|
Uniaxial cyclic stress |
Scaffolds | Increases cardiomyocyte size | Human cardiac constructs implanted into rats after exposure to uniaxial loading displayed increased active force and enhanced graft perfusion into host tissue |
[120] |
| Aligns fibers in the ECM | ||||
| Increases angiogenesis | ||||
|
Rotational wall vessel |
Cell-culture vessels |
Creates laminar fluid flow | Cardiomyocytes cultured in these bioreactors have a constant pH, %CO2, and %O2, compared to an increasing amount of DNA in the culture. |
[143] |
| Enhances mass transfer rate | ||||
|
Electrical stimulation |
Scaffolds and hydrogels |
Ensures impulse propagation | Cardiac constructs propagate continuous pulses and a rate of 400 beats min−1 after inserting in an electrical stimulation bioreactor |
[144] |
| Increased conduction velocities to mimic in vitro conditions |
||||
| Caused synchronous macroscopic pulses |