Table 2.
Different techniques for loading cargos in EVs with advantages and disadvantages.
| Loading Methods | Steps Involved | Advantages | Disadvantages | Ref. |
|---|---|---|---|---|
| Electroporation | Phospholipid bilayer of EVs are disorganized by an electric field, creating pores in the membrane which allow the passage of drug to vesicle. | Loading with large molecules is possible | Disrupts integrity of EVs; Low loading efficiency | [101,149,150,151] |
| Sonication | Exosomes derived from donor cells are mixed with drug and sonicated through probe sonicator which permits the drug to flow into exosome | Increased loading efficiency; applicable for small RNAs | Potential deformation of membrane of EVs; Not efficient for hydrophobic drugs. |
[60,152] |
| Extrusion | Exosomes are mixed with drug and loaded into syringe-based lipid extruder and extruded through membrane with 100–400 nm pore size at controlled temperature. | High drug loading efficiency | Potential deformation of membrane. |
[60] |
| Freeze/Thaw Method | Exosome are mixed with drug and incubated, subsequently frozen at −80 °C or in liquid nitrogen and are thawed at room temperature. | Medium loading;Fusion of membranespossible | Exosomes may aggregate; Low loading efficiency |
[60] |
| Saponin-Assisted Loading | Saponin is incubated with exosomes to generate pores in their membrane by interacting with cholesterol which leads to increased membrane permeability | High drug loading compared to the other methods used in early reports | Generates pores in exosomes; Saponin can cause haemolysis; Toxicity concerns; Saponin concentration control & washing required |
[119,147,148] |
| Dialysis | Exosomes mixed with drug are dialyzed by stirring to obtain drug loaded exosome. | Promotes loading efficiency | Poor cellular uptake; No substantial impact on photodynamic effect |
[153] |