2 research outputs found
Dendritic Silica Nanomaterials (KCC-1) with Fibrous Pore Structure Possess High DNA Adsorption Capacity and Effectively Deliver Genes In Vitro
The
pore size and pore structure of nanoporous materials can affect
the materials’ physical properties, as well as potential applications
in different areas, including catalysis, drug delivery, and biomolecular
therapeutics. KCC-1, one of the newest members of silica nanomaterials,
possesses fibrous, large pore, dendritic pore networks with wide pore
entrances, large pore size distribution, spacious pore volume and
large surface areaî—¸structural features that are conducive for
adsorption and release of large guest molecules and biomacromolecules
(e.g., proteins and DNAs). Here, we report the results of our comparative
studies of adsorption of salmon DNA in a series of KCC-1-based nanomaterials
that are functionalized with different organoamine groups on different
parts of their surfaces (channel walls, external surfaces or both).
For comparison the results of our studies of adsorption of salmon
DNA in similarly functionalized, MCM-41 mesoporous silica nanomaterials
with cylindrical pores, some of the most studied silica nanomaterials
for drug/gene delivery, are also included. Our results indicate that,
despite their relatively lower specific surface area, the KCC-1-based
nanomaterials show high adsorption capacity for DNA than the corresponding
MCM-41-based nanomaterials, most likely because of KCC-1’s
large pores, wide pore mouths, fibrous pore network, and thereby more
accessible and amenable structure for DNA molecules to diffuse through.
Conversely, the MCM-41-based nanomaterials adsorb much less DNA, presumably
because their outer surfaces/cylindrical channel pore entrances can
get blocked by the DNA molecules, making the inner parts of the materials
inaccessible. Moreover, experiments involving fluorescent dye-tagged
DNAs suggest that the amine-grafted KCC-1 materials are better suited
for delivering the DNAs adsorbed on their surfaces into cellular environments
than their MCM-41 counterparts. Finally, cellular toxicity tests show
that the KCC-1-based materials are biocompatible. On the basis of
these results, the fibrous and porous KCC-1-based nanomaterials can
be said to be more suitable to carry, transport, and deliver DNAs
and genes than cylindrical porous nanomaterials such as MCM-41
Differences in Nanoparticle Uptake in Transplanted and Autochthonous Models of Pancreatic Cancer
Human pancreatic ductal adenocarcinoma
(PDAC) contains a distinctively
dense stroma that limits the accessibility of anticancer drugs, contributing
to its poor overall prognosis. Nanoparticles can enhance drug delivery
and retention in pancreatic tumors and have been utilized clinically
for their treatment. In preclinical studies, various mouse models
differentially recapitulate the microenvironmental features of human
PDAC. Here, we demonstrate that through utilization of different organic
cosolvents and by doping of a homopolymer of polyÂ(ε-caprolactone),
a diblock copolymer composition of polyÂ(ethylene oxide)-<i>block</i>-polyÂ(ε-caprolactone) may be utilized to generate biodegradable
and nanoscale micelles with different physical properties. Noninvasive
optical imaging was employed to examine the pharmacology and biodistribution
of these various nanoparticle formulations in both allografted and
autochthonous mouse models of PDAC. In contrast to the results reported
with transplanted tumors, spherical micelles as large as 300 nm in
diameter were found to extravasate in the autochthonous model, reaching
a distance of approximately 20 μm from the nearest tumor cell
clusters. A lipophilic platinumÂ(IV) prodrug of oxaliplatin was further
able to achieve a ∼7-fold higher peak accumulation and a ∼50-fold
increase in its retention half-life in pancreatic tumors when delivered
with 100 nm long worm-like micelles as when compared to the free drug
formulation of oxaliplatin. Through further engineering of nanoparticle
properties, as well as by widespread adoption of the autochthonous
tumor model for preclinical testing, future therapeutic formulations
may further enhance the targeting and penetration of anticancer agents
to improve survival outcomes in PDAC