Comparison of different silica microporous structures as drug delivery systems for in vitro models of solid tumors
authors Vilaca, N; Machado, AF; Morais-Santos, F; Amorim, R; Neto, AP; Logodin, E; Pereira, MFR; Sardo, M; Rocha, J; Parpot, P; Fonseca, AM; Baltazar, F; Neves, IC
nationality International
journal RSC ADVANCES
keywords SQUAMOUS-CELL CARCINOMA; TITANOSILICATE ETS-10; MESOPOROUS SILICA; ZEOLITE-Y; SULFONAMIDE ANTIBIOTICS; CONTROLLED-RELEASE; CONTRAST AGENTS; SALICYLIC-ACID; SLOW-RELEASE; NITRIC-OXIDE
abstract Several silica microporous structures have been studied for their potential as drug delivery systems (DDS) over the last years. However, systematic studies comparing host structures with different topologies and particle sizes, and toxicity studies to human cancer cells, are scarce. In the present work, 3D crystalline structures, three different zeolites (large, medium and small pore size) and one titanosilicate (large pore size) were used as hosts for loading 5-fluorouracil (5-FU), an anticancer drug currently used to treat several malignant tumors. Here, we (i) compared the loading capacity and drug release profiles of the different hosts in simulated body fluid conditions, including host structure stability studies; (ii) established the kinetic parameters for the release of 5-FU and (iii) studied the effect of 5-FU encapsulation in the viability of human breast and colon cancer cells, with determination of the potentiation factor. The loading capacity and the release profile of the DDS were revealed to be dependent on the porous framework of the host structures. Decrease in pH to 2.0 (simulation of gastro-intestinal fluid), showed stability of the host structures, with minimal leaching of Al3+ and no Ti4+ for long periods of time (up to 72 h). All DDS drug release profiles fitted the Weibull model. These silica microporous structures were revealed to be non-toxic to the cancer cells, while all DDS endorsed the important 5-FU potentiation effect on cell viability.
publisher ROYAL SOC CHEMISTRY
issn 2046-2069
year published 2017
volume 7
issue 22
beginning page 13104
ending page 13111
digital object identifier (doi) 10.1039/c7ra01028a
web of science category Chemistry, Multidisciplinary
subject category Chemistry
unique article identifier WOS:000395935300010
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journal analysis (jcr 2017):
journal impact factor 2.936
5 year journal impact factor 3.096
category normalized journal impact factor percentile 58.772
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