Chemotherapy is still an important and effective clinical treatment for cancer. However, individual drugs hardly achieve precise controlled release and targeted therapy, thus resulting in unavoidable side effects. Fortunately, the emergence of drug carriers is expected to solve the above problems. In this work, the MOF-on-MOF strategy was adopted to encapsulate DOX into double-layer NH 2 -MIL-88B to fabricate a core−shell-structured DOX@NH 2 -MIL-88B-On-NH 2 -MIL-88B (DMM) and then realize the pH and GSH dual-responsive controlled DOX release. Because of the core−shell structure, the drug-loading capacity of DMM reached 14.4 wt %, which was nearly twice that of DOX@ NH 2 -MIL-88B (DM), and the controlled release performance of DMM was also improved at the same time, greatly improving the kinetics equilibrium time of DOX from 2 h (DM) to 16 h (DMM) at pH 5.0. Moreover, we found that DMM also possessed peroxidase-like catalytic activity under acidic conditions, which could catalyze H 2 O 2 to produce • OH, exhibiting the potential chemodynamical treatment of cancer. Cell experiments showed that DMM had a significant inhibitory effect against 4T1 cancer cells, and the survival rate of 4T1 cells was less than 20% at 100 ppm.
Cancer nanovaccines have been widely explored to enhance immunotherapy efficiency, in which the significant irritation of antigen-specific cytotoxic T cells (CTLs) is the critical point. In this study, we developed a pH and reduction dualsensitive nanovaccine (PMSN@OVA-MPN) composed of two parts. The inner part was made up of polyethyleneimine (PEI)modified mesoporous silica nanoparticles (MSNs) loaded with model antigen ovalbumin (OVA) and the outer part was made up of disulfide bond-involved metal−phenolic networks (MPNs) as a protective corona. In vitro release experiments proved that PMSN@OVA-MPN could intelligently release OVA in the presence of reductive glutathione, but not in neutral phosphatebuffered saline (PBS). Moreover, in vitro cell assays indicated that the nanovaccine promoted not only the OVA uptake efficiency by DC2.4 cells but also antigen lysosome escape due to the proton sponge effect of PEI. Furthermore, in vivo animal experiments indicated that PMSN@OVA-MPN induced a large tumor-specific cellular immune response so as to effectively inhibit the growth of an existing tumor. Finally, the immune memory effect caused by the nanovaccine afforded conspicuous prophylaxis efficacy in neonatal tumors. Hence, the multifunctional vaccine delivery system prepared in this work exhibits a great application potential in cancer immunotherapy and offers a platform for the development of nanovaccines.
Effective treatments for patients suffering from heat hypersensitivity are lacking, mostly due to our limited understanding of the pathogenic mechanisms underlying this disorder. In the nervous system, activating transcription factor 4 (ATF4) is involved in the regulation of synaptic plasticity and memory formation. Here, we show that ATF4 plays an important role in heat nociception. Indeed, loss of ATF4 in mouse dorsal root ganglion (DRG) neurons selectively impairs heat sensitivity. Mechanistically, we show that ATF4 interacts with transient receptor potential cation channel subfamily M member-3 (TRPM3) and mediates the membrane trafficking of TRPM3 in DRG neurons in response to heat. Loss of ATF4 also significantly decreases the current and KIF17-mediated trafficking of TRPM3, suggesting that the KIF17/ATF4/TRPM3 complex is required for the neuronal response to heat stimuli. Our findings unveil the non-transcriptional role of ATF4 in the response to heat stimuli in DRG neurons.
Controlling the crystal size and surface chemistry of MOF materials, and understanding their multifunctional effect are of great significance for the biomedical applications of MOF systems. Herein, we designed and synthesized a new anionic MOF, ZJU-64-NSN, which features 1D channels decorated with highly polarized thiadiazole groups, and its crystal size could be systematically tuned from 200 μm to 300 nm through a green and simple approach. As a result, the optimal nanosized ZJU-64-NSN is found to enable an ultrafast loading of cationic drug procainamide (PA) (21.2 wt% within 1 min). Moreover, the undesirable chemical stability of PA@ZJU-64-NSN is greatly improved by the surface coating of polyethylene glycol (PEG) biopolymer. The final drug delivery system PEG/PA@ZJU-64-NSN is found to effectively prevent PA from premature release under the harsh stomach environments due to the intense host-guest interaction, and mainly release PA to the targeted intestinal surroundings. Such controlled drug delivery is proved to be triggered by endogenic Na
+
ions instead of H
+
ions, well revealed by the study on the dynamics behavior of drug release and UV–Vis absorption spectrum. Good biocompatibility of ZJU-64-NSN and PEG-coated ZJU-64-NSN has been fully demonstrated by MTT assay as well as confocal microscopy imaging.
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