Cargo-loading capacity of polymeric micelles could be improved by reducing the core crystallinity and the improvement in the amount of loaded cargo was cargo-polymer affinity dependent. The effect of medium chain triglyceride (MCT) in inhibiting PCL crystallization was confirmed by DSC and polarized microscope. When incorporating MCT into polymeric micelles, the maximum drug loading of disulfiram (DSF), cabazitaxel (CTX), and TM-2 (a taxane derivative) increased from 2.61 ± 0.100%, 13.5 ± 0.316%, and 20.9 ± 1.57% to 8.34 ± 0.197%, 21.7 ± 0.951%, and 28.0 ± 1.47%, respectively. Moreover, the prepared oil-containing micelles (OCMs) showed well-controlled particle size, good stability, and decreased drug release rate. MCT incorporation showed little influence on the performances of micelles in cell studies or pharmacokinetics. These results indicated that MCT incorporation could be a core construction module applied in the delivery of hydrophobic drugs.
Anticancer
agents that present nonapoptotic cell death pathways
are required for treating apoptosis-resistant pancreatic cancer. Here,
we synthesized three fluorescent dithiocarbazate–copper complexes,
{[CuII(L)(Cl)] 1, [CuII
2(L)2(NO3)2] 2, and
[CuII
2CuI(L)2(Br)3] 3}, to assess their antipancreatic cancer activities.
Complexes 1–3 showed significantly greater cytotoxicity
toward several pancreatic cancer cell lines with better IC50 than those of the HL ligand and cisplatin. Confocal fluorescence
imaging showed that complex 3 was primarily localized
in the mitochondria. Primarily, compound 3 also can be
applied to in vivo imaging. Further studies revealed
that complex 3 kills pancreatic cancer cells by triggering
multiple mechanisms, including ferroptosis. Complex 3 is the first copper complex to evoke cellular events consistent
with ferroptosis in cancer cells. Finally, it significantly retarded
the ASPC-1 cells’ growth in a mouse xenograft model.
Here we report the development and evaluation of cysteine-modified nanostructured lipid carriers (NLCs) for oral delivery of docetaxel (DTX). The NLCs ensure high encapsulation efficiency of docetaxel, while the cysteine bound the NLCs with PEG2000-monostearate (PEG2000-MSA) as a linker, and allowed a specific interaction with mucin of the intestinal mucus layer and facilitated the intestinal transport of docetaxel. The cysteine-modified NLCs (cNLCs) had a small particle size (<100 nm) and a negative zeta potential (-13.72 ± 0.07 mV), which was lower than that of the unmodified NLCs (uNLCs) (-6.39 ± 0.07 mV). This correlates well with the location of the cysteine group on the surface of the NLCs obtained by X-ray photoelectron spectroscopy (XPS). The cNLCs significantly improved the mucoadhesion properties compared with uNLCs. The intestinal absorption of cNLCs in total intestinal segments was greatly improved in comparison with uNLCs and docetaxel solution (DTX-Sol), and the in vivo imaging system captured pictures also showed not only increased intestinal absorption but also improved accumulation in blood. The cNLCs could be absorbed into the enterocytes via both endocytosis and passive transport. The results of the in vivo pharmacokinetic study indicated that the AUC0-t of cNLCs (1533.00 ng/mL·h) was markedly increased 12.3-fold, and 1.64-fold compared with docetaxel solution and uNLCs, respectively. Overall, the cysteine modification makes nanostructured lipid carriers more suitable as nanocarriers for oral delivery of docetaxel.
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