ABSTRACT
This study screened excellent carriers for co-loading tanshinone Ⅱ_A(TSA) and astragaloside Ⅳ(As) to construct antitumor nano-drug delivery systems for TSA and As. TSA-As microemulsions(TSA-As-MEs) were prepared by water titration. TSA-As metal-organic framework(MOF) nano-delivery system was prepared by loading TSA and As in MOF by the hydrothermal method. Dynamic light scattering(DLS), transmission electron microscopy(TEM), and scanning electron microscopy(SEM) were used to characterize the physicochemical properties of the two preparations. Drug loading was determined by HPLC and the effects of the two preparations on the proliferation of vascular endothelial cells, T lymphocytes, and hepatocellular carcinoma cells were detected by the CCK-8 method. The results showed that the particle size, Zeta potential, and drug loading of TSA-As-MEs were(47.69±0.71) nm,(-14.70±0.49) mV, and(0.22±0.01)%, while those of TSA-As-MOF were(258.3±25.2) nm,(-42.30 ± 1.27) mV, and 15.35%±0.01%. TSA-As-MOF was superior to TSA-As-MEs in drug loading, which could inhibit the proliferation of bEnd.3 cells at a lower concentration and improve the proliferation ability of CTLL-2 cells significantly. Therefore, MOF was preferred as an excellent carrier for TSA and As co-loading.
Subject(s)
Mice , Animals , Endothelial Cells , Abietanes , Cell LineABSTRACT
The α-amino acid ester acyltransferase (SAET) from Sphingobacterium siyangensis is one of the enzymes with the highest catalytic ability for the biosynthesis of l-alanyl-l-glutamine (Ala-Gln) with unprotected l-alanine methylester and l-glutamine. To improve the catalytic performance of SAET, a one-step method was used to rapidly prepare the immobilized cells (SAET@ZIF-8) in the aqueous system. The engineered Escherichia coli (E. coli) expressing SAET was encapsulated into the imidazole framework structure of metal organic zeolite (ZIF-8). Subsequently, the obtained SAET@ZIF-8 was characterized, and the catalytic activity, reusability and storage stability were also investigated. Results showed that the morphology of the prepared SAET@ZIF-8 nanoparticles was basically the same as that of the standard ZIF-8 materials reported in literature, and the introduction of cells did not significantly change the morphology of ZIF-8. After repeated use for 7 times, SAET@ZIF-8 could still retain 67% of the initial catalytic activity. Maintained at room temperature for 4 days, 50% of the original catalytic activity of SAET@ZIF-8 could be retained, indicating that SAET@ZIF-8 has good stability for reuse and storage. When used in the biosynthesis of Ala-Gln, the final concentration of Ala-Gln reached 62.83 mmol/L (13.65 g/L) after 30 min, the yield reached 0.455 g/(L·min), and the conversion rate relative to glutamine was 62.83%. All these results suggested that the preparation of SAET@ZIF-8 is an efficient strategy for the biosynthesis of Ala-Gln.
Subject(s)
Escherichia coli/genetics , Glutamine , Zeolites/chemistry , Amino AcidsABSTRACT
As an excellent hosting matrices for enzyme immobilization, metal-organic framework (MOFs) provides superior physical and chemical protection for biocatalytic reactions. In recent years, the hierarchical porous metal-organic frameworks (HP-MOFs) have shown great potential in enzyme immobilization due to their flexible structural advantages. To date, a variety of HP-MOFs with intrinsic or defective porous have been developed for the immobilization of enzymes. The catalytic activity, stability and reusability of enzyme@HP-MOFs composites are significantly enhanced. This review systematically summarized the strategies for developing enzyme@HP-MOFs composites. In addition, the latest applications of enzyme@HP-MOFs composites in catalytic synthesis, biosensing and biomedicine were described. Moreover, the challenges and opportunities in this field were discussed and envisioned.
Subject(s)
Metal-Organic Frameworks/chemistry , Porosity , Enzymes, Immobilized/chemistry , Biocatalysis , CatalysisABSTRACT
@#In recent years, bio-metal organic frameworks (Bio-MOFs) synthesized with biocompatible ligands have been widely investigated as a potential drug delivery carrier due to their large specific surface area and porosity, rich host-guest intermolecular interactions, and good biocompatibility.In this review, we summarized the design methods of Bio-MOFs including structural and toxic factors, as well as a variety of drug loading methods including click chemistry, with particular focus on recent research advances in Bio-MOFs for pulmonary drug delivery systems, improving pharmaceutical properties of drugs, sustained and controlled drug release, stimulation response and targeted drug delivery systems.Finally, we summarized the bottlenecks that constrain the development of Bio-MOFs in clinical studies of actual pharmaceutical formulations and their future directions for approved formulations, aiming to provide some theoretical reference for promoting the application of Bio-MOFs in drug delivery systems.
ABSTRACT
Metal-organic frameworks (MOFs) are mixed porous materials which are composed of metal clusters or ions and organic pillars. Given their channel tunability, high porosity, large specific surface area, and good biocompatibility, MOFs can be combined with various biological macromolecules. In recent years, they have been widely studied in the field of biomedicine, especially in the loading of anti-tumor drugs, showing great application prospects. Multifunctional anti-tumor MOF combined with different therapeutic methods provides a new idea and method for tumor treatment. On the basis of the structure of MOF, this paper introduces the advantages of using MOF to load anti-tumor drugs and reviews the application of MOF in tumor therapy.
ABSTRACT
Metal-organic frameworks (MOFs) are special materials formed by self-assembly of metal ions and organic ligands, with special physical and chemical properties, such as large specific surface area, excellent biocompatibility and strong pH sensitivity, etc. Through modification, they have synthesized nanomaterials with excellent performance, which have huge application prospects in treating tumors. This paper mainly reviews the properties of MOFs and their derived materials, and the application progress of MOFs in tumor drug-loaded therapy, photodynamic therapy and immunotherapy.
ABSTRACT
Metal-organic frameworks (MOFs) are formed by self-assembly of metal ions or clusters with organic ligands, and are widely used in the fields of catalysis, sensing, energy and biomedicine. Recently, biological composites based on MOFs have attracted increasing attention. MOFs can be used as a platform for encapsulating bioactive substances due to the advantages such as large pore capacity, large specific surface area and diverse structure composition. These features can protect bioactive substances from adverse conditions, e.g. high temperature, high pressure, and organic solvents, thus improving the anti-adversity of bioactive substances. This review summarizes the advances of using MOFs as protective coatings to improve the anti-adversity of different bioactive substances, and introduces the synthesis strategy of MOFs-based biological composites, with the aim to promote the practical application of MOFs-based biological composites.
Subject(s)
Catalysis , Ions , Metal-Organic Frameworks , MetalsABSTRACT
Metal-organic frameworks (MOFs), comprised of organic ligands and metal ions/metal clusters
ABSTRACT
Ferroptosis, as a newly discovered cell death form, has become an attractive target for precision cancer therapy. Several ferroptosis therapy strategies based on nanotechnology have been reported by either increasing intracellular iron levels or by inhibition of glutathione (GSH)-dependent lipid hydroperoxidase glutathione peroxidase 4 (GPX4). However, the strategy by simultaneous iron delivery and GPX4 inhibition has rarely been reported. Herein, novel tumor microenvironments (TME)-activated metal-organic frameworks involving Fe & Cu ions bridged by disulfide bonds with PEGylation (FCSP MOFs) were developed, which would be degraded specifically under the redox TME, simultaneously achieving GSH-depletion induced GPX4 inactivation and releasing Fe ions to produce ROS
ABSTRACT
Malignant tumor has become an urgent threat to global public healthcare. Because of the heterogeneity of tumor, single therapy presents great limitations while synergistic therapy is arousing much attention, which shows desperate need of intelligent carrier for co-delivery. A core‒shell dual metal-organic frameworks (MOFs) system was delicately designed in this study, which not only possessed the unique properties of both materials, but also provided two individual specific functional zones for co-drug delivery. Photosensitizer indocyanine green (ICG) and chemotherapeutic agent doxorubicin (DOX) were stepwisely encapsulated into the nanopores of MIL-88 core and ZIF-8 shell to construct a synergistic photothermal/photodynamic/chemotherapy nanoplatform. Except for efficient drug delivery, the MIL-88 could be functioned as a nanomotor to convert the excessive hydrogen peroxide at tumor microenvironment into adequate oxygen for photodynamic therapy. The DOX release from MIL-88-ICG@ZIF-8-DOX nanoparticles was triggered at tumor acidic microenvironment and further accelerated by near-infrared (NIR) light irradiation. The