Table 1.
Known advantages and problems associated with the possible therapeutic use of different myogenic cell types
| Cell type | Advantages | Major problems | Ref. |
|---|---|---|---|
| Myoblasts | • Pure populations can be isolated and readily expanded and transduced in vitro | • Limited engraftment and migration in host muscle | 8, 24, 100 |
| • High number of cells required for transplantation | |||
| • Immediate immune response after grafting due to high number of cells | |||
| • Poor ability to populate the host satellite cell niche | |||
| Satellite cells | • Low numbers required for transplantation | • Limited migration | 21, 22, 101, 102 |
| • Efficient engraftment | • Only small numbers can be isolated | ||
| • Efficient population of the satellite cell niche of the recipient | • Cannot be cultured/maintained ex vivo | ||
| Satellite stem cells | • Very efficient engraftment | • No definitive markers available for the enrichment of viable cells | 65, 68, 73 |
| • Few cells required for transplantation | |||
| • Highly efficient population of the satellite cell niche of the recipient | • Not investigated in species other than mouse | ||
| • Extensive migration | |||
| Satellite cells on fibers | • Maximal engraftment | • Very difficult to apply in a clinical setting | 25, 36, 65 |
| • Minimal number of cells required | |||
| • Maximal population of the satellite cell niche | |||
| Muscle side population cells | • Certain SP cells can home into muscle from the blood stream (systemic delivery possible) | • Contact with myoblasts required for differentiation | 90, 103, 104 |
| • Population of the satellite cell niche of the recipient | • Low engraftment | ||
| Mesoangioblasts/pericytes | • Homing from the blood stream into the muscle (systemic delivery possible) | • Undergo senescence after a certain number of population doublings | 81, 82, 105–107 |
| • Can be cultivated ex vivo | |||
| • Readily transducible | |||
| • Sufficient engraftment | |||
| • Engraftment as satellite cells | |||
| CD133 positive cells | • Homing from the blood stream into the muscle (systemic delivery possible) | • Engraftment only shown in animal models with severely compromised immune system | 85, 86 |
| • Increased vasculogenesis | |||
| • Engraftment as satellite cells | |||
| Myoendothelial cells | • Can be cultured for a long period retaining myogenic potential | • Engraftment only shown in animal models with severely compromised immune system | 87 |
| • Tolerance for oxidative stress | |||
| Muscle resident ALDH positive CD34 negative cells | • High proliferative potential upon transplantation | • Engraftment only shown in animal models with severely compromised immune system | 88 |
| PW1+ interstitial cells | • Engraftment as satellite cells | • Only shown in a mouse model with severely compromised immune system | 89 |
| Bone marrow derived stem cells | • Homing from the blood stream into the muscle (systemic delivery possible) | • Low engraftment | 91, 108 |
| Mesenchymal stem cells | • Inhibition of inflammation | • Low engraftment | 93, 94 |
| hMAD: human mesenchymal stem cell from adipose tissue | • Easy to access from adipose tissue | • Low engraftment potential without forced expression of MyoD | 109, 110 |
| • Engraftment only shown in animal models with severely compromised immune system | |||
| ES cells | • Engraftment as satellite cells | • Risk of teratoma formation | 97, 111 |
| • Pax3/7 overexpression required for reprogramming | |||
| iPS cells | • Engraftment as satellite cells | • Risk of teratoma formation | 112 |
| • Autologous transplantations possible | • Reprogramming and purification required | ||
| • Differentiation may be impaired by epigenetic memory of the donor tissue |