Table 3.
Recent studies on CNMs for cancer therapy
| Type of materials | Loaded drug | Feature | Anti-cancer effect | References |
|---|---|---|---|---|
| rGO | PTX | Phosphorylcholine oligomer grafted perylene-modified | Cytotoxicity of PTX against SGC7901 tumor cell line was improved compared with free PTX | [166] |
| rGO | DOX | Folic acid-conjugated | Enhanced specificity and cytotoxicity of DOX to MBA-MB 231 human breast cancer cells | [167] |
| rGO | MTX | Gold NPs-coated | Activity of MTX on MCF-7 was improved compared to free MTX | [168] |
| GO | MTX | Dopamine-conjugated | Capacity of MTX targeting dopamine receptors expressing cancer cells was enhanced | [169] |
| GO | DOX | Carboxymethyl cellulose-functionalized | DOX was released pH-dependently and showed good antitumor activity and biocompatibility without no obvious cytotoxicity | [170] |
| Fullerene | C60 (OH)22 | Targeting at cancer stem cells | Biological communication of stem cells and tumor cells was inhibited | [171] |
| Fullerene | Gd@C82 (OH)22 | Angiogenesis | 10 proangiogenic factors were downregulated in mice model | [172] |
| CNT | Hydrazine–SWNT–DOX | pH-sensitive drug release | Great cytotoxicity toward HepG2 tumor cells with high weight loading | [173] |
| CNT | Chitosan–MWCNT–DOX | Used in photothermal/chemotherapy | Sustained release of DOX and significant hyperthermia exhibiting remarkably enhanced anti-tumor efficacy | [174] |
| CQD | CQD–mesoporous silica nanoparticle–DOX | pH-sensitive drug release | 80% DOX load released at pH 5.0 and a remarkably enhanced anti-tumor efficiency was exhibited | [175] |
CNTs, Carbon nanotubes; CQDs, Carbon quantum dots; DOX, Doxorubicin; GO, Graphene oxide; MTX, Methotrexate; MWCNTs, Multiwalled carbon nanotubes; PTX, Paclitaxel; rGO, Reduced graphene oxide