Table 2.
Summary of the representative ROS‐enhanced nanomedicines
| Representative ROS‐elevated nanomedicines | Therapeutic modalities | ROS types | Working mechanism | Strategies | Refs |
|---|---|---|---|---|---|
| Elevating ambient oxygen of nanomedicines | |||||
| PFC and IR780‐coencapsulated lipids NPs | PDT | 1O2 | PFC can improve the ambient oxygen photosensitizer IR780, and then accelerate generation of 1O2 to enhance photodynamic effect | Exogenous oxygen delivery | [ 150 ] |
| Hb conjugated polymeric micelles | PDT | 1O2 | Hb with oxygen‐binding capacity can enhance the 1O2 generation of photosensitizer zinc phthalocyanine | Exogenous oxygen delivery | [ 159 ] |
| human serum albumin (HSA)‐stabilized PFC nanodroplets | PDT and RT | 1O2 | PFC nanodroplets can adsorb oxygen in the lung and rapidly release oxygen in the tumor under US, which enhance PDT and RT | Exogenous oxygen delivery; US‐triggered rapid oxygen release | [ 153 ] |
| MOF (UiO‐66) conjugated with indocyanine green (ICG) | PDT | 1O2 | Photothermal property of ICG could facilitate the burst release of O2, which significantly improve the PDT effects of ICG | Exogenous oxygen delivery; NIR‐induced oxygen burst release | [ 149 ] |
| ATO/VER NPs | PDT | 1O2 | ATO can reduce cellular oxygen consumption by inhibition of mitochondria respiratory chain, and then enhance VER to generate 1O2 in hypoxic tumor. | Oxygen elevation by inhibiting cellular oxygen consumption | [ 173 ] |
| MnFe2O4 NPs‐anchored MSN | PDT | 1O2 | MnFe2O4 NPs catalyze H2O2 tumor microenvironment O2 generation, and then MFNs loaded with Ce6 under continuous oxygen supply can enhance ROS generation | In situ oxygen generation by decomposing cellular H2O2 | [ 181 ] |
| MnO2‐Ce6 NPs | PDT | 1O2 | MnO2 NPs with high reactivity toward H2O2 can increase O2 generation in tumor, and then promote 1O2 generation and enhance PDT effects | In situ oxygen generation by decomposing cellular H2O2 | [ 306 ] |
| Carbon‐dot‐decorated C3N4 nanocomposite (CNN) | PDT | 1O2 | A 630 nm laser was used to trigger CCN to split water to generate O2, meanwhile, 630 nm laser irradiation can activate the photosensitizer PpIX on CNN for 1O2 generation | Photocatalyst for splitting water to generate O2 | [ 187 ] |
| Ultrathin graphdiyne oxide (GDYO) nanosheets | PDT | 1O2 | GDYO under 660 nm laser irradiation are able to efficiently catalyze water oxidation to release O2 and induce blood perfusion, promoting 1O2 generation | Photocatalyst for splitting water to generate O2 | [ 188 ] |
| Enhancing O2‐free ROS generation | |||||
| Fe meta‐organic framework | Fenton cancer therapy | •OH | Iron present on the rMOF‐FA can release into solution, reacting with high levels of H2O2 to generate •OH | Catalyzing H2O2 for O2‐free ROS generation | [ 307 ] |
| GOD‐Fe3O4@DMSNs nanocatalysts | Fenton cancer therapy | •OH | GOD catalyze the glucose into abundant H2O2 in tumor region, and then the elevated H2O2 is catalyzed by the downstream Fe3O4 NPs | GOD for H2O2 elevation; catalyzing H2O2 for O2‐free ROS generation | [ 195 ] |
| Fe3O4@MSN encapsulating doxorubicin (DOX) | Fenton cancer therapy + chemotherapy | •OH | DOX can activate nicotinamide adenine dinucleotide phosphate oxidases (NOXs) for H2O2 elevation, and then the elevated H2O2 is catalyzed by the downstream Fe3O4 NPs | DOX for H2O2 elevation; catalyzing H2O2 for O2‐free ROS generation | [ 308 ] |
| Fe3O4 NPs loading cisplatin(IV) prodrugs | Fenton cancer therapy + chemotherapy | •OH | Cisplatin(IV) prodrugs can be activated by intracellular GSH, then Cisplatin(II) activate NOXs for H2O2 elevation, and then the elevated H2O2 is catalyzed by the downstream Fe3O4 NPs | GSH consumption; cisplatin for H2O2 elevation; Catalyzing H2O2 for O2‐free ROS generation | [ 309 ] |
| MnO2‐coated MSN NPs | Fenton cancer therapy | •OH | MnO2 shell can react with GSH to yield Mn2+, and then Mn2+‐trigger •OH production from H2O2 | GSH depletion; catalyzing H2O2 for O2‐free ROS generation | [ 194 ] |
| UCNPs@silica core‐shell NPs loaded with Fe2+ ion | Photo‐Fenton cancer therapy | •OH | UCNP cores can convert NIR light to UV or visible photons to catalyze photo‐Fenton reaction | Near infrared‐assisted Fenton reaction | [ 201 ] |
| Cu2− xSe NPs | Photo‐Fenton cancer therapy | •OH | NIR‐II irradiation can promote the conversion of Cu2+ and Cu+ | X‐ray‐driven Fenton reaction | [ 189 ] |
| Cu2(OH)PO4 nanocrystals | RT | •OH | X‐ray can trigger CuI sites generation on Cu2(OH)PO4 nanocrystals, serving as a catalyst to efficiently decomposing overexpressed H2O2 in the tumor | X‐ray‐induced Fenton reaction | [ 202 ] |
| Au–Bi2S3 NPs | RT | •OH | Schottky barrier in Au–Bi2S3 can remarkably improve the utilization of a large number of X‐ray‐induced low energy electrons for H2O2 decomposition | X‐ray‐induced H2O2 decomposition | [ 204 ] |
| Reduced graphene oxide (rGO) coupled with BiP5W30 | RT | •OH | rGO can BiP5W30 NPs can improve radiocatalytic activity through promoting e−–h+ separation to decomposing H2O2 into •OH. In addition, BiP5W30 NPs can deplete GSH to further enhance •OH generation | X‐ray‐induced H2O2 decomposition; GSH depletion | [ 205 ] |
| TiO2‐coated UCNPS | PDT | •OH,H+, •O2 − | UCNPs can efficiently convert NIR light to UV emission, then activate TiO2 for the formation of an e−–h+ pair and generation of intracellular ROS | NIR‐induced deep tissue penetration; catalyzing H2O for O2‐free ROS generation | [ 32 ] |
| SrAl2O4:Eu2+@MC540 | RT+PDT | 1O2 | Scintillator emits numerous photons of low energy that can trigger MC540 for 1O2 generation | X‐ray trigger deep PDT | [ 30 ] |
| CeIII‐doped LiYF4@SiO2@ZnO nanostructure | RT | •OH, •O2 − | Scintillator emits numerous photons of low energy that can trigger ZnO for the formation of an e−–h+ pair and free radicals | X‐ray‐induced deep tissue penetration; catalyzing H2O for O2‐free ROS generation | [ 222 ] |
| LiLuF4:Ce@SiO2@Ag3PO4@Pt(IV) | RT+ chemotherapy | •OH, •O2 − | Scintillator emits numerous photons of low energy that can trigger Ag3PO4 for the formation of an e−–h+ pair and free radicals. Meanwhile, cisplatin(IV) prodrugs as sacrificial agent can increase the yield of free radicals, thereby exerting chemotherapy effect | X‐ray‐induced deep tissue penetration; inhibiting e−–h+ pair recombination; catalyzing H2O for O2‐free ROS generation | [ 223 ] |
| Bi2WO6 nanoplates | RT | •OH, •O2 − | Under X‐ray irradiation, Bi2WO6 generate e−–h+ pair and subsequently promoting the generation of ROS | X‐ray‐induced deep tissue penetration; catalyzing H2O for O2‐free ROS generation | [ 224 ] |
| BiOI@Bi2S3 heterojunction NPs | RT | •OH, •O2 − | BiOI@Bi2S3 NPs inhibit rapid recombination of e−–h+ pair to promoting the generation of ROS under X‐ray irradiation | X‐ray‐induced deep tissue penetration; catalyzing H2O for O2‐free ROS generation | [ 225 ] |
| Au‐TiO2 nanocomposite | SDT | •OH, •O2 − | Au‐TiO2 nanocomposite can increase ROS generation by enhancing the energy absorption and reducing the e−–h+ pair recombination | US‐induced deep tissue penetration; inhibiting e−–h+ pair recombination; catalyzing H2O for O2‐free ROS generation | [ 228 ] |
| MnWOX NPs | SDT | •OH, 1O2 | MnWOX NPs can reduce the e−–h+ pair recombination for enhanced ROS generation and deplete intracellular GSH | US‐induced deep tissue penetration; inhibiting e−–h+ pair recombination; catalyzing H2O for O2‐free ROS generation | [ 229 ] |