Evidence of wall slip and magnitude of yield stress are examined for colloidal gels consisting of hydrophobic silica, polyether, and lithium salts using geometries with serrated, smooth, hydrophilic and hydrophobic surfaces. Serrated plates, which provide minimal wall slip, are used to compare different methods of measuring yield stress: conventional extrapolation of shear stress in steady shear experiments and dynamic experiments at large strain amplitudes. In the latter, the yield stress is denoted by the maximum in the elastic stress, the product of the elastic modulus and strain (G Ј ␥), when plotted as a function of strain amplitude. Although excellent agreement is observed in the yield stress values using both these techniques, the dynamic method seems preferable considering its experimental ease, accuracy, and lack of extrapolation. In the presence of smooth geometries, the silica gels show evidence of wall slip with a concomitant decrease in yield stress. Using underestimation of yield stress as a measure of wall slip, we find slip to be unaffected by changes in the gel modulus obtained through incorporation of additional silica or salts. The use of smooth surfaces compared to serrated surfaces leads to approximately a 60% reduction in yield stress for all such samples. Finally, control of wall slip is attempted using plates modified to have different surface energies. Hydrophobic plates reduce slip significantly and produce data comparable to those with the serrated plates. In contrast, hydrophilic plates have minimal effect on slip and produce data analogous to those obtained using smooth plates. These results can be explained based on the fact that the particle-lean layer, responsible for slip, remains so with hydrophilic plates as it repels the hydrophobic silica particles in favor of the polar solvent. In contrast, the hydrophobic silica interacts with the hydrophobic plates, thus reducing slip.
A bioinspired glucose-responsive insulin delivery system for self-regulation of blood glucose levels is desirable for improving health and quality of life outcomes for patients with type 1 and advanced type 2 diabetes. Here we describe a painless core–shell microneedle array patch consisting of degradable cross-linked gel for smart insulin delivery with rapid responsiveness and excellent biocompatibility. This gel-based device can partially dissociate and subsequently release insulin when triggered by hydrogen peroxide (H2O2) generated during the oxidation of glucose by a glucose-specific enzyme covalently attached inside the gel. Importantly, the H2O2-responsive microneedles are coated with a thin-layer embedding H2O2-scavenging enzyme, thus mimicking the complementary function of enzymes in peroxisomes to protect normal tissues from injury caused by oxidative stress. Utilizing a chemically induced type 1 diabetic mouse model, we demonstrated that this smart insulin patch with a bioresponsive core and protective shell could effectively regulate the blood glucose levels within a normal range with improved biocompatibility.
We report on the synthesis of poly(vinyl alcohol) (PVA)-silica hybrid nanofibers via sol-gel electrospinning. Silica is synthesized through acid catalysis of a silica precursor (tetraethyl orthosilicate (TEOS) in ethanol-water), and fibers are obtained by electrospinning a mixture of the silica precursor solution and aqueous PVA. A systematic investigation on how the amount of TEOS, the silica-PVA ratio, the aging time of the silica precursor mixture, and the solution rheology influence the fiber morphology is undertaken and reveals a composition window in which defect-free hybrid nanofibers with diameters as small as 150 nm are obtained. When soaked overnight in water, the hybrid fibers remain intact, essentially maintaining their morphology, even though PVA is soluble in water. We believe that mixing of the silica precursor and PVA in solution initiates the participation of the silica precursor in cross-linking of PVA so that its -OH group becomes unavailable for hydrogen bonding with water. FTIR analysis of the hybrids confirms the disappearance of the -OH peak typically shown by PVA, while formation of a bond between PVA and silica is indicated by the Si-O-C peak in the spectra of all the hybrids. The ability to form cross-linked nanofibers of PVA using thermally stable and relatively inert silica could broaden the scope of use of these materials in various technologies.
A dynamic rheological technique, Fourier transform mechanical
spectroscopy (FTMS), was
used to monitor in real time the evolving rheological properties during
UV cross-linking of two thiol−ene
systems. These systems comprised a trifunctional thiol
(trimethylolpropane tris(2-mercaptoacetate))
together with a trifunctional allyl monomer (triallyl isocyanurate) and
a tetrafunctional thiol (pentaerythritol tetrakis(2-mercaptoacetate)) with the same allyl monomer.
FTMS, in conjunction with specially
designed quartz plates, provided an in situ method to
elucidate the effects of temperature and monomer
functionality on the photoinitiated polymerization of these systems.
It was found that the tetrafunctional
thiol system cross-linked at a faster rate than the trifunctional thiol
system over the temperature range
(25−50 °C) studied. Moreover, increasing the temperature
increased the cross-linking rates for both
systems. The Winter−Chambon criterion was applied to determine
the gel point and the two parameters
which characterize the material at its gel point, the gel stiffness,
S, and the relaxation exponent, n.
The
gel stiffness was found to be greater for the trifunctional thiol
system, which was consistent with the
higher value of conversion calculated from the Flory−Stockmayer
theory of gelation. Relaxation exponents
of 0.80 and 0.81−0.82 were determined for the tri- and
tetrafunctional thiol systems, respectively,
indicating similar fractal structures at the gel point. These
relaxation exponents were also invariant
over the temperature ranges studied, suggesting that the cross-linking
mechanisms remained unchanged
with temperature. From the temperature dependence of the gel
times, apparent activation energies of
6.6 and 14 kcal/mol were calculated for the tri- and tetrafunctional
thiol systems, respectively.
Graphical abstract
A cellular protease-mediated graphene-based nanosystem is developed for co-delivery of a membrane-associated cytokine (TRAIL) and an intracellular-acting small-molecule drug (DOX). The nanocarrier realizes the intramembrane enzyme-mediated extracellular release of TRAIL and endocytotic acidity-responsive intracellular release of DOX, which enables them to target to their distinct sites of action. This formulation starts a new generation of 2D nanomaterials with programmed-release therapeutics capability for combination cancer treatment.
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