Size and surface controllable metal–organic frameworks (MOFs) for fluorescence imaging and cancer therapy

Gao, Xuechuan; Cui, Ruixue; Ji, Guanfeng; Liu, Zhiliang

doi:10.1039/c7nr08892b

Cited by 107 publications

(73 citation statements)

References 37 publications

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“…The anticancer activity was assessed using HepG2 cells, in which incubation with 5-FU@UiO-66-NH 2 -5-FAM-FA had a slightly lesser effect than the same mass of the free drug (cell proliferation 57% vs 40%, respectively, at a concentration of 0.2 mgmL -1 ) despite the targeting effect. This is likely due to the maximum 5-FU loading being reported as 26% w/w for UiO-66-NH 2 , although no loading value for 5-FU@UiO-66-NH 2 -5-FAM-FA is given in the paper[94].The potential of Zr-fum as a delivery vector for biomolecules was investigated by attaching various pro-apoptotic peptides (Bak, Bad, KLK) and a cytochrome c protein (CytC) which, due to their membrane impermeability, are not able to efficiently cross the cell membrane by themselves, to the NMOF surface using His-tags[85]. The authors observed a 20-fold increase in the mean cell internal fluorescence of HeLa cells when incubated with Zr-fum-H 6 CF (H 6 CF = carboxyfluorescein with six histidine residues) and a 30-fold increase for Zrfum-H 6 GFP (H 6 GFP = green fluorescent protein modified with six histidine residues) compared to when cells were incubated with solutions of the same concentration of the respective free peptides in growth media, highlighting the efficiency of Zr-fum in internalising biomolecules not able to do so efficiently themselves.…”

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confidence: 91%

Application of zirconium MOFs in drug delivery and biomedicine

Lázaro

Forgan

2019

Coordination Chemistry Reviews

490

172

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Nanoparticulate metal-organic frameworks (MOFs) have the requisite high storage capacities, tailorable structures, ease of functionalisation, and excellent biocompatibilities for application as nanoscale drug delivery devices (DDSs). Zirconium MOFs in particular combine optimal stability towards hydrolysis and postsynthetic modification with low toxicity, and so are particularly suited for biological applications. This review covers the use of Zr MOFs as DDSs with focus on the different physical properties that makes them attractive for use. The various methods for modifying the surfaces of Zr MOFs are described with pertinent examples of the resulting enhancements in aqueous stability, colloidal dispersion, and stimuli-responsive drug release. The in vitro and in vivo application of Zr MOFs for photodynamic therapy and drug delivery are discussed with respect to the structural features of the MOFs and their surface functionality, and perspectives on their future applications and analogous hafnium MOFs are given.

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mentioning

confidence: 91%

Application of zirconium MOFs in drug delivery and biomedicine

Lázaro

Forgan

2019

Coordination Chemistry Reviews

490

172

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“…They concluded that the lower the concentration of the reactants, the larger the particle size of Fe-MIL-53-NH 2 . Additionally, Gao et al studied the effects of benzoic acid on the particle size of UIO-66-NH 2 and synthesized it by a hydrothermal method [38]. Unlike the above, the lower the benzoic acid, the smaller the particle size.…”

Section: Particle Size Control To Achieve Functional Transfer Of Mofsmentioning

confidence: 99%

Metal Organic Frameworks as Drug Targeting Delivery Vehicles in the Treatment of Cancer

et al. 2020

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In recent years, metal organic frameworks (MOFs) have been widely developed as vehicles for the effective delivery of drugs to tumor tissues. Due to the high loading capacity and excellent biocompatibility of MOFs, they provide an unprecedented opportunity for the treatment of cancer. However, drugs which are commonly used to treat cancer often cause side effects in normal tissue accumulation. Therefore, the strategy of drug targeting delivery based on MOFs has excellent research significance. Here, we introduce several intelligent targeted drug delivery systems based on MOFs and their characteristics as drug-loading systems, and the challenges of MOFs are discussed. This article covers the following types of MOFs: Isoreticular Metal Organic Frameworks (IRMOFs), Materials of Institute Lavoisier (MILs), Zeolitic Imidazolate Frameworks (ZIFs), University of Oslo (UiOs), and MOFs-based core-shell structures. Generally, MOFs can be reasonably controlled at the nanometer size to effectively achieve passive targeting. In addition, different ligands can be modified on MOFs for active or physicochemical targeting. On the one hand, the targeting strategy can improve the concentration of the drugs at the tumor site to improve the efficacy, on the other hand, it can avoid the release of the drugs in normal tissues to improve safety. Despite the challenges of clinical application of MOFs, MOFs have a number of advantages as a kind of smart delivery vehicle, which offer possibilities for clinical applications.

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“…Compared with other MOF-based drug carriers, UiO-66-NH 2 has a high degree of connectivity of the metal clusters in the crystal structure, generating exceptional mechanical stability and chemical stability in a broad range of pH values. In addition, the amino group on the UIO-66-NH 2 opens up the possibility of post-modification of UiO-66-NH 2 with multiple properties [64][65][66][67][68]. Meanwhile, polysilsesquioxanes (PSQs), an organosilica with organic/inorganic hybrid structure, have high stability, biocompatibility, and easy functionalization [40,48].…”

Section: Stability Testmentioning

confidence: 99%

Metal Organic Framework@Polysilsesequioxane Core/Shell-Structured Nanoplatform for Drug Delivery

Gao

et al. 2020

Pharmaceutics

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Modern pharmaceutics requires novel drug loading platforms with high drug loading capacity, controlled release, high stability, and good biocompacity. Metal–organic frameworks (MOFs) show promising applications in biomedicine owing to their extraordinarily high surface area, tunable pore size, and adjustable internal surface properties. However, MOFs have low stability due to weak coordinate bonding and limited biocompatibility, limiting their bioapplication. In this study, we fabricated MOFs/polysilsesquioxane (PSQ) nanocomposites and utilized them as drug carriers. Amine-functionalized MOF (UiO-66-NH2) nanoparticles were synthesized and encapsulated with epoxy-functionalized polysilsesquioxane layer on the surface via a facile process. MOFs possessed high surface area and regular micropores, and PSQs offered stability, inertness, and functionality. The obtained UiO-66-NH2@EPSQ nanocomposites were utilized as carriers for ibuprofen, a drug with carboxylic groups on the surface, and demonstrated high drug loading capacity and well-controlled release property. The UiO-66-NH2@EPSQ nanocomposite exhibited low cytotoxicity to HeLa cells within a wide concentration range of 10–100 µg/mL, as estimated by the MTT method. The UiO-66-NH2@EPSQ drug release system could be a potential platform in the field of controlled drug delivery.

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Size and surface controllable metal–organic frameworks (MOFs) for fluorescence imaging and cancer therapy

Cited by 107 publications

References 37 publications

Application of zirconium MOFs in drug delivery and biomedicine

Application of zirconium MOFs in drug delivery and biomedicine

Metal Organic Frameworks as Drug Targeting Delivery Vehicles in the Treatment of Cancer

Metal Organic Framework@Polysilsesequioxane Core/Shell-Structured Nanoplatform for Drug Delivery

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