Claudia Moia scite author profile

Dacarbazine (Dac) is one of the most commonly used chemotherapy drugs for treating various cancers. However, its poor water solubility, short half-life in blood circulation, low response rate and high side effect limit its application. This study aimed to improve the drug solubility and prolong drug release by developing nanostructured lipid carriers (NLCs) for Dac delivery. The NLC and Dac-encapsulated NLC were synthesized with precirol ATO 5 and isopropyl myristate as lipids, tocopheryl polyethylene glycol succinate, soybean lecithin and Kolliphor P 188 as co-surfactants. The NLCs with controlled size were achieved using high shear dispersion following solidification of oil-in-water emulsion. For Dac encapsulation, the smallest NLC with 155 ± 10 nm in size, 0.2 ± 0.01 polydispersion index and -43.4 ± 2 mV zeta potential was selected. The resultant DLC-Dac possessed size, polydispersion index and zeta potential of 190 ± 10, 0.2 ± 0.01, and -43.5 ± 1.2, respectively. The drug encapsulation efficiency and drug loading were 98.5 % and 14 %, respectively. In vitro drug release study showed a biphasic pattern, with 50 % released in the first 2 h, and the remaining released sustainably for up to 30 h. This is the first report on the development of NLC for Dac delivery, implying that NLC could be a new potential candidate as drug carrier to improve the therapeutic profile of Dac.

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In vitro evaluation of the internalization and toxicological profile of silica nanoparticles and submicroparticles for the design of dermal drug delivery strategies

Vicente

Moia

Zhu

et al. 2017

J of Applied Toxicology

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The use of colloidal silica nanoparticles and sub-microparticles (SiPs) have been considered a very interesting strategy for drug delivery applications. In the present study, we have focused our attention on the suitability of these nanomaterials as potential carriers for dermal drug delivery, thus studying their toxicological profile in vitro, cellular uptake and intracellular localization in both human keratinocytes (K17) and human dermal fibroblasts (HDF) as a function of their particle size (SiPs of 20, 70, 200 and 500 nm). Full characterization of these aspects enabled us to observe a strong cell-type dependency in terms of cytotoxicity and cell internalization, whereas particle size was only relevant for ultra-small SiPs (20 nm), being the most toxic SiPs. For 70, 200 and 500 nm SiPs, the differences in uptake and intracellular trafficking determined the different toxicological profiles in K17 and HDF. In addition, these characteristics can further define different drug delivery strategies. Hence, phagocytosis has been identified as the main internalization mechanism for K17, and caveolae-mediated endocytosis for HDF. This relevant information led us to conclude that fibroblasts would be optimal targets for delivering delicate therapeutic molecules such as proteins or genetic material using SiPs while maintaining a low toxicity profile, whereas keratinocytes could enable accelerated drug release therapies based on SiPs.

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Nanomaterials for Skin Regeneration

Zhu¹,

Moia²,

Vilela³

2014

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Claudia Moia

PLGA nanoparticles loaded with host defense peptide LL37 promote wound healing

Combined effects of PLGA and vascular endothelial growth factor promote the healing of non-diabetic and diabetic wounds

Development of nanostructured lipid carrier for dacarbazine delivery

In vitro evaluation of the internalization and toxicological profile of silica nanoparticles and submicroparticles for the design of dermal drug delivery strategies

Nanomaterials for Skin Regeneration

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