2020
DOI: 10.1039/c9nr08127e
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Biocompatible iron(iii) carboxylate metal–organic frameworks as promising RNA nanocarriers

Abstract: Rapid cell-internalization of biocompatible RNA-loaded nanoMOFs leads to an effective in vitro gene activity while protects nucleic acids from degradation.

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Cited by 66 publications
(46 citation statements)
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“…Importantly, results obtained with SNs-Lpx were superior to those recently published with miRNA145-loaded PLGA/PEI/HA nanoparticles in HTC-116 cells (11-fold increase), miRNA-145-loaded magnetic nanoparticles in AsPC-1cells (19-fold increase) and HPAF-II cells (4-fold increase), miRNA145-loaded cationic liposomes in HepG2 cells (9-fold increase), miRNA145 associated to a lentiviral vector in SW620 cells (8.2-fold increase), and miRNA145-loaded protamine nanocapsules in SW480 cells (33-fold increase) [15][16][17]49,50]. In relation to nanometric porous metal-organic frameworks (nanoMOFs), they show a similar efficiency in SW480 cells, superior to lipofectamine, as recently published by our group [51].…”
Section: Transfection Efficiencysupporting
confidence: 60%
“…Importantly, results obtained with SNs-Lpx were superior to those recently published with miRNA145-loaded PLGA/PEI/HA nanoparticles in HTC-116 cells (11-fold increase), miRNA-145-loaded magnetic nanoparticles in AsPC-1cells (19-fold increase) and HPAF-II cells (4-fold increase), miRNA145-loaded cationic liposomes in HepG2 cells (9-fold increase), miRNA145 associated to a lentiviral vector in SW620 cells (8.2-fold increase), and miRNA145-loaded protamine nanocapsules in SW480 cells (33-fold increase) [15][16][17]49,50]. In relation to nanometric porous metal-organic frameworks (nanoMOFs), they show a similar efficiency in SW480 cells, superior to lipofectamine, as recently published by our group [51].…”
Section: Transfection Efficiencysupporting
confidence: 60%
“… 1 , 2 , 3 , 4 , 5 , 6 The ability to control particle size, 7 , 8 , 9 surface chemistry, 10 and internal porosity 11 , 12 has led to increasingly complex MOF-based materials. These have been designed to target specific cells 13 and organelles, 14 transport large specialized cargo such as oligonucleotides and proteins, 15 , 16 , 17 , 18 , 19 release these in response to specific stimuli, 20 , 21 and combine drug delivery with other techniques such as imaging 22 , 23 , 24 , 25 , 26 or photodynamic therapy. 27 , 28 Despite this diversification of material, the process of postsynthetic drug loading itself is often undercharacterized; cargo is often simply assumed to penetrate the porosity of the MOF despite potential competition from loading solvents.…”
Section: Introductionmentioning
confidence: 99%
“…Various other nucleotide@MOF delivery systems have been reported for other applications, such as the delivery of the gene‐editing tool CRISPR/CAS9, [ 129 ] siRNA@NCP, [ 127 ] ssDNA@IRMOF‐74(Ni), using a toxic metal, [ 130 ] , mRNA using UiO‐66(Zr), [ 131 ] and MIL‐100(Fe). [ 132 ] The delivery of mRNA using MIL‐100(Fe) in particular is promising due to its biocompatibility and its comparatively good stability in phosphate‐containing solutions.…”
Section: Mof Compositesmentioning
confidence: 99%