Table 1.
Comparison of different methods for conjugation of DNA to quantum dots.
| s.no | approach | modification on QD | modification on DNA | advantages | disadvantages | references |
|---|---|---|---|---|---|---|
| 1 | phospholipid encapsulation | organic ligands | amine/thiol | — one step procedure — compatible with range of synthesis — DNA retains hybridizability |
— stability issues — large size of particles — random fusion with membranes — low QY |
[7,8] |
| 2 | electrostatic attraction with polymer on QDs | positively charged hydrophilic ligands | unmodified; interaction with phosphate backbone | — rapid — high DNA loading efficiency — reversible |
— difficult to control stoichiometry of DNA — issues with stability and aggregation |
[65,68] |
| 3 | affinity for cationic shell of QDs | positively charged or neutral | thiol/polyhistidine/phosphorothioate | — rapid assembly — high yield — compact |
— unstable in high dilutions — loss of DNA by photo-oxidation — pH sensitive — interactions with DNA backbone can cause conformational change — low QY due to charge transfer |
[44–46,49,56] |
| 4 | affinity for specific ligand | streptavidin conjugation | biotinylated DNA | — fast and easy — conjugation of DNA independent of length — stoichiometric control — High QY |
— increase in conjugate size due to presence of protein | [3,35,45,72,73,79] |
| Ni-NTA modified | polyhistidine modified | — one step — efficient — high QY |
— pH sensitive stability | [70] | ||
| 5 | covalent conjugation with ligands on QDs | QDs with carboxylic acids | amine modified | — highly stable — pH insensitive — DNA hybridization preserved — moderate-high QY |
— multistep — low yield — nanoparticle size increases |
[80–82] |
| QDs with amines | thiol modified | [83] | ||||
| QDs with thiols | amine modified cyclooctyne | [84] | ||||
| QDs with azide | — reactants are not prone to hydrolysis | — loss of QY | [85] |