TABLE 1.
Nanomedicines constructed by cyclodextrin‐based host–guest interactions.
| CD‐based nanomedicines | Host/guest molecules | Cargoes | Purpose | Cancer cell type | Ref. |
|---|---|---|---|---|---|
| Poly(pseudo)rotaxane‐based nanocarriers | α‐CD/PEG | DOX | Targeted delivery and controlled release of DOX | 4T1 and NIH3T3 cells | [26] |
| MTX | To improve the anticancer activity of MTX | HepG2 cells | [27] | ||
| Ce6, 3BP | Relief of tumor hypoxia to improve PDT efficiency and conversion autophagy from pro‐survival to pro‐death | 4T1, HepG2, and KB cells | [28] | ||
| GEM | Enhanced cancer cellular uptake and selective GEM release within cancer cells | BxPC‐3 cells | [29] | ||
| NO, DOX | Mitochondria‐targeted delivery of NO and inhibition of drug resistance and cancer metastasis | MCF‐7 cells | [30] | ||
| Amphiphilic supramolecule‐based nanocarriers | β‐CD/BM | DOX | pH‐responsive release of DOX | HepG2 cells | [31] |
| β‐CD/PS | PTX | To encapsulate and transfer PTX with a high loading capacity | ‐ | [32] | |
| β‐CD/Azo | DOX, SN‐38, phenytoin, and aliskiren | Supramolecular prodrug systems | MDA‐MB‐231 cells | [33] | |
| β‐CD/Fc | Ce6 | Self‐amplified PDT to suppress primary breast cancer and bone metastases | 4T1 cells | [34] | |
| β‐CD/Fc | pDNA | ROS‐responsive release of pDNA | COS‐7 cells | [35] | |
| β‐CD/Ada | PTX, shRNA | Co‐delivery of chemotherapeutics and siRNAs to suppress cancer growth more effectively | SKOV‐3 cells | [36] | |
| Supramolecular hydrogels | α‐CD/PEG | DOX, ICG, CpG | Abundant tumor‐specific antigen storage in situ and combined immune therapy to inhibit primary tumor growth, tumor recurrence, and metastasis | B16F10 and B16‐OVA cells | [37] |
| β‐CD/Ada | ‐ | Thermo‐responsive hydrogel formation | ‐ | [38] | |
| β‐CD/Azo | ‐ | Photo‐reversible supramolecular hydrogels | ‐ | [39] | |
| β‐CD/Fc | GOX, HRP‐H2O2 | Fuel‐driven redox‐responsive hydrogel, a potential glucose sensor | ‐ | [40] | |
| Supramolecular cross‐linked networks | β‐CD/Ada | CPT, PTX | Reversible control over the size, positron emission tomography (PET) imaging | ‐ | [41] |
| β‐CD/PTX | PTX | Targeted delivery and responsive release of PTX | MCF‐7 cells | [42] | |
| Polycatenane‐based nanocarriers | α‐CD/PEG | ‐ | Reversible conversion of supramolecule from polyrotaxane to poly(polyrotaxane) | ‐ | [43] |
| β‐CD/PEG | ‐ | Simple synthesis and separation of polycatenanes | ‐ | [44] | |
| Supramolecular gatekeepers | β‐CD/Ada | DOX | Active targeting and redox‐responsive drug release | SKOV‐3 cells | [45] |
| β‐CD/BM | MXF | pH‐sensitive nanovalve systems | Tularemia | [46] | |
| β‐CD/Fc | R6G, DOX | pH/redox‐responsive nanovalve, drug size selectivity | ‐ | [47] | |
| β‐CD/Azo | FITC | Light‐responsive triggered system | ‐ | [48] | |
| Supramolecular‐responsive linkers | β‐CD/Ada | JQ1, PPa | Supramolecular prodrug nano‐system, enhance photoimmunotherapy | Panc02 cells | [49] |
| β‐CD/Fc | Pt, Ru | PTT, hypoxia relief, photoacoustic, PDT, and computed tomography imaging | 4T1 cells | [50] | |
| Supramolecular targeting ligands | β‐CD/Ada | siRNA, Tf | Translation from concept to the clinic for targeted delivery of siRNA | / | [51] |
| β‐CD/Ada | BODIPY | Targeted photodynamic killing | MCF‐10A, and MDA‐MB‐231 cells | [52] | |
| β‐CD/CPT | CPT, RGD, 64Cu | Targeted delivery of CPT, PET imaging | 4T1 cells | [16b] |