More and more evidence advises that circular RNAs (circRNAs) function critically in regulating different disease microenvironments. Our previous study found that autotransplantation of adipose-derived mesenchymal stem cells (ADSCs) promotes diabetes wound healing. Exosomes derived in ADSCs play an important regulatory role. This study aimed to characterize if mmu_circ_0000250 played a role in ADSC-exosome-mediated full-thickness skin wound repair in diabetic rats. Endothelial progenitor cells (EPCs) were selected to study the therapeutic mechanism of exosomes in high-glucose (HG)-induced cell damage and dysfunction. Analysis and luciferase reporter assay were utilized to explore the interaction among mmu_circ_0000250, miRNA (miR)-128-3p, and sirtuin (SIRT)1. The diabetic rats were used to confirm the therapeutic effect of mmu_circ_0000250 against exosome-mediated wound healing. Exosomes containing a high concentration of mmu_circ_0000250 had a greater therapeutic effect on restoration of the function of EPCs by promotion autophagy activation under HG conditions. Expression of mmu_circ_0000250 promoted SIRT1 expression by miR-128-3p adsorption, which was confirmed via luciferase reporter assay and bioinformatics analysis. In vivo, exosomes containing a high concentration of mmu_circ_0000250 had a more therapeutic effect on wound healing when compared with wild-type exosomes from ADSCs. Immunohistochemistry and immunofluorescence detection showed that mmu_circ_0000250 increased angiopoiesis with exosome treatment in wound skin and suppressed apoptosis by autophagy activation. In conclusion, we verified that mmu_circ_0000250 enhanced the therapeutic effect of ADSC-exosomes to promote wound healing in diabetes by absorption of miR-128-3p and upregulation of SIRT1. Therefore, these findings advocate targeting the mmu_circ_0000250/miR-128-3p/SIRT1 axis as a candidate therapeutic option for diabetic ulcers.
In this work, the lightweight and scalable organic macromolecule graphitic carbon nitride (g-C3N4) with enriched polysulfide adsorption sites of pyridinic-N was introduced to achieve the effective functionalization of separator at the molecular level. This simple method overcomes the difficulty of low doping content as well as the existence of an uncontrolled form of nitrogen heteroatom in the final product. Besides the conventional pyridinic-N-Li bond formed in the vacancies of g-C3N4, the C-S bond was interestingly observed between g-C3N4 and Li2S, which endowed g-C3N4 with an inherent adsorption capacity for polysulfides. In addition, the microsized g-C3N4 provided the coating layer with good mechanical strength to guarantee its restriction function for polysulfides during long cycling. As a result, an excellent reversible capacity of 840 mA h g(-1) was retained at 0.5 C after 400 cycles for a pure sulfur electrode, much better than that of the cell with an innocent carbon-coated separator. Even at a current density of 1 C, the cell still delivered a stable capacity of 732.7 mA h g(-1) after 500 cycles. Moreover, when further increasing the sulfur loading to 5 mg cm(-2), an excellent specific capacity of 1134.7 mA h g(-1) was acquired with the stable cycle stability, ensuring a high areal capacity of 5.11 mA h cm(-2). Besides the intrinsic adsorption ability for polysulfides, g-C3N4 is nontoxic and mass produced. Therefore, a scalable separator decorated with g-C3N4 and a commercial sulfur cathode promises high energy density for the practical application of Li-S batteries.
Metal–organic
frameworks (MOFs) and MOF-based composites
as luminescent sensors with excellent economic practicability and
handy operability have attracted much attention. Herein, we designed
and fabricated a porous Zn-based MOF, [Zn(OBA)2(L1)·2DMA]
n
[1; H2OBA = 4,4′-oxybis(benzoic acid), L1 = 2,4,6-tris(4-pyridyl)pyridine,
and DMA = N,N-dimethylacetamide],
with mixed nodes under solvothermal conditions, and the pore size
of 5.9 Å was calculated from N2 adsorption isotherms
by using a density functional theory model. The as-synthesized compound 1 is stable in different boiling organic solvents and water
solutions with a wide pH range of 2–12 and exhibits intense
luminescence emission at 360 nm under excitation of 290 nm. Significantly,
compound 1 shows high selective detection of Fe3+, CrO4
2–, and Cr2O7
2– in aqueous solution even under the interference
of other ions. Compound 1 can quickly sense these ions
in a short time and has a striking sensitivity toward Fe3+ with an ultralow limit of detection (LOD) of 1.06 μM. The
relatively low LODs for CrO4
2– and Cr2O7
2– are 3.87 and 2.37 μM,
respectively, compared to the reported works. Meanwhile, compound 1 can be reused to detect Fe3+, CrO4
2–, and Cr2O7
2– six times by simple regeneration. Considering the practicability,
a mixed-matrix membrane (MMM) incorporated compound 1 and poly(methyl methacrylate) has been constructed. This MMM displays
quick detection of Fe3+, CrO4
2–, and Cr2O7
2– and prompt
regeneration by lifting from the analyte. This useful MMM shows a
comparable LOD below 4.35 μM for these ions. This work presents
a cost-effective Zn-based MOF as a functional platform for simple
but useful sensing of Fe3+, CrO4
2–, and Cr2O7
2– in aqueous
solution.
This meta-analysis confirms that response to NAC is an indicator for PFS and OS, and suggests that patients-achieving response of NAC before surgery predicts favorable prognosis for cervical cancer patients.
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