12 research outputs found
Flow-Driven Translocation of Strung Micelles Formed by Core–Shell Bottle-Brush Copolymers and the Accompanying Morphological Transformation through a Nanochannel
Herein, the flow-driven translocation of strung micelles
formed
by core–shell bottle-brush copolymers was investigated through
hybrid lattice-Boltzmann molecular dynamics simulations. Results reveal
that despite the submicelle size in two uniformly strung micelles
being approximately the same as that of a single micelle, they exhibited
a higher critical flow flux. Furthermore, two nonuniformly strung
micelles exhibited a slightly higher critical flow flux compared to
two uniformly strung micelles, which is mainly determined by the larger
submicelle. Interestingly, most strung micelles transformed into cylindrical
micelles after they crossed the nanochannel. These cylindrical micelles
exhibited a lower critical flow flux compared with strung micelles
because they were thinner than equivalent strung micelles. This study
clarifies the transformations between various micelle structures during
flow-driven translocation, emphasizing that spherical and cylindrical
micelles are more easily generated when subjected to the constraints
of a nanochannel. Additionally, it provides insights into the stability
of strung micelles, contributing to the valuation of different micelle
performances
Flow-Driven Translocation of Strung Micelles Formed by Core–Shell Bottle-Brush Copolymers and the Accompanying Morphological Transformation through a Nanochannel
Herein, the flow-driven translocation of strung micelles
formed
by core–shell bottle-brush copolymers was investigated through
hybrid lattice-Boltzmann molecular dynamics simulations. Results reveal
that despite the submicelle size in two uniformly strung micelles
being approximately the same as that of a single micelle, they exhibited
a higher critical flow flux. Furthermore, two nonuniformly strung
micelles exhibited a slightly higher critical flow flux compared to
two uniformly strung micelles, which is mainly determined by the larger
submicelle. Interestingly, most strung micelles transformed into cylindrical
micelles after they crossed the nanochannel. These cylindrical micelles
exhibited a lower critical flow flux compared with strung micelles
because they were thinner than equivalent strung micelles. This study
clarifies the transformations between various micelle structures during
flow-driven translocation, emphasizing that spherical and cylindrical
micelles are more easily generated when subjected to the constraints
of a nanochannel. Additionally, it provides insights into the stability
of strung micelles, contributing to the valuation of different micelle
performances
Molecular Dynamics Simulation of Salt Diffusion in Polyelectrolyte Assemblies
The
diffusion of salt ions and charged probe molecules in polyelectrolyte
(PE) assemblies is often assumed to follow a theoretical hopping model,
in which the diffusing ion hops between charged sites of chains based
on electroneutrality. However, experimental verification of diffusing
pathway at such microscales is difficult, and the corresponding molecular
mechanisms remain elusive. In this study, we perform all-atom molecular
dynamics simulations of salt diffusion in the PE assembly of polyÂ(sodium-4-styrenesulfonate)
(PSS) and polyÂ(diallyldimethylammonium chloride) (PDAC). Besides the
ion hopping mode, the diffusing trajectories are found to present
common features of a jump process, that is, subjecting to PE relaxation,
water pockets in the structure open and close; thus, the ion can move
from one pocket to another. Anomalous subdiffusion of ions and water
is observed because of the trapping scenarios in these water pockets.
The jump events are much rarer compared with ion hopping but significantly
increases salt diffusion with increasing temperature. Our result strongly
indicates that salt diffusion in hydrated PDAC/PSS is a combined process
of ion hopping and jump motion. This provides a new molecular explanation
for the coupling of salt motion with chain motion and the nonlinear
increase of salt diffusion at glass-transition temperature
An Approach for the Sphere-to-Rod Transition of Multiblock Copolymer Micelles
The shape of polymer micelles is important for pharmaceutical
applications
as drug delivery. In this article, an approach inducing sphere-to-rod
transition of multiblock polyurethane micelles has been developed
through introducing a second hydrophilic component phosphatidylcholine
group into the polymer chains. Time-resolved dynamic light scattering
(DLS), combined with transmission electron microscopy (TEM), was employed
to investigate the kinetics of morphology transition. Moreover, a
dissipative particle dynamics (DPD) simulation method was applied
to study the mechanism of sphere-to-rod transition. These experimental
and simulation studies revealed that the hydrophilic phosphatidylcholine
groups can create defects on the surfaces of spherical polyurethane
micelles, thus, making positive contribution to adhesive collisions
and leading to the fusion of spherical micelles into rod-like micelles.
This finding provides new insight into the origins of rod-like polymer
micelles, which is valuable for the design and preparation of novel
polymeric drug carriers with tailored properties
Cell Internalizable and Intracellularly Degradable Cationic Polyurethane Micelles as a Potential Platform for Efficient Imaging and Drug Delivery
A cell internalizable and intracellularly
degradable micellar system, assembled from multiblock polyurethanes
bearing cell-penetrating gemini quaternary ammonium pendent groups
in the side chain and redox-responsive disulfide linkages throughout
the backbone, was developed for potential magnetic resonance imaging
(MRI) and drug delivery. The nanocarrier is featured as a typical
“cleavable core–internalizable shell–protective
corona” architecture, which exhibits small size, positive surface
charge, high loading capacity, and reduction-triggered destabilization.
Furthermore, it can rapidly enter tumor cells and release its cargo
in response to an intracellular level of glutathione, resulting in
enhanced drug efficacy <i>in vitro</i>. The magnetic micelles
loaded with superparamagnetic iron oxide (SPIO) nanoparticles demonstrate
excellent MRI contrast enhancement, with <i>T</i><sub>2</sub> relaxivity found to be affected by the morphology of SPIO-clustering
inside the micelle core. The multifunctional carrier with good cytocompatibility
and nontoxic degradation products can serve as a promising theranostic
candidate for efficient intracellular delivery of anticancer drugs
and real-time monitoring of therapeutic effect
Antibacterial and Biocompatible Cross-Linked Waterborne Polyurethanes Containing Gemini Quaternary Ammonium Salts
A cross-linked
waterborne polyurethane (CPTMGPU) with long-term
stability was developed from polyÂ(ethylene glycol) (PEG), polyoxytetramethylene
glycol (PTMG), isophorone diisocyanate (IPDI), l-lysine,
and its derivative diamine consisting of gemini quaternary ammonium
salt (GQAS), using ethylene glycol diglycidyl ether (EGDE) as a cross-linker.
Weight loss test, X-ray photoelectron spectroscopy (XPS) measurements,
and attenuated total reflectance-Fourier transform infrared spectroscopy
(ATR-FTIR) were performed to prove the surface structure and stability
of these CPTMGPU films. Furthermore, the GQAS-bearing CPTMGPUs show
repeatable contact-active antibacterial efficacy against both Gram-positive Staphylococcus aureus (S. aureus) and Gram-negative Escherichia coli (E. coli) bacteria and do not show
any inhibition effect against fibroblasts in vitro. After subcutaneous
implantation in rats, the CPTMGPU films manifest good biocompatibility
in vivo, despite the presence of a typical foreign body reaction toward
surrounding tissues and mild systematic inflammation reaction that
could be eliminated after a short implantation period, as demonstrated
by histology and immunohistochemistry combined with interleukin (IL)-1β,
IL-4, IL-6, IL-10, and TNF-α analysis though enzyme-linked immunosorbent
assay (ELISA) and real-time quantitative polymerase chain reaction
(qRT-PCR). Therefore, these cross-linked waterborne polyurethanes
hold great promise for antibacterial applications in vivo
Effects of Chain Rigidity on the Adsorption of a Polyelectrolyte Chain on Mixed Lipid Monolayer: A Monte Carlo Study
We
apply Monte Carlo simulation to explore the adsorption of a
positively charged polyelectrolyte on a lipid monolayer membrane,
composed of electronically neutral, monovalent anionic and mulvitalent
anionic phospholipids. We systematically assess the influence of various
factors, including the intrinsic rigidity of the polyelectrolyte chain,
the bead charge density of the polyelectrolyte, and the ionic strength
of the saline solution, on the interfacial structural properties of
the polyelectrolyte/monolayer complex. The enhancement of the polyelectrolyte
chain intrinsic rigidity reduces the polyelectrolyte conformational
entropy loss and the energy gains in electrostatic interaction, but
elevates the segregated anionic lipid demixing entropy loss. This
energy-entropy competition results in a nonmonotonic dependence of
the polyelectrolyte/monolayer association strength on the degree of
chain rigidity. The semiflexible polyelectrolyte, i.e., the one with
an intermediate degree of chain rigidity, is shown to associate onto
the ternary membane below a higher critical ionic concentration. In
this ionic concentration regime, the semiflexible polyelectrolyte
binds onto the monolayer more firmly than the pancake-like flexible
one and exhibits a stretched conformation. When the chain is very
rigid, the polyelectrolyte with bead charge density <i>Z</i><sub>b</sub> = +1 exhibits a larger tail and tends to dissociate
from the membrane, whereas the one with <i>Z</i><sub>b </sub>= +2 can still bind onto the membrane in a bridge-like conformation.
Our results imply that chain intrinsic rigidity serves as an efficient
molecular factor for tailoring the adsorption/desorption transition
and interfacial structure of the polyelectrolyte/monolayer complex
Toward the Next-Generation Nanomedicines: Design of Multifunctional Multiblock Polyurethanes for Effective Cancer Treatment
Specific accumulation of therapeutics at tumor sites to improve <i>in vivo</i> biodistribution and therapeutic efficacy of anticancer drugs is a major challenge for cancer therapy. Herein, we demonstrate a new generation of intelligent nanosystem integrating multiple functionalities in a single carrier based on multifunctional multiblock polyurethane (MMPU). The smart nanocarriers equipped with stealth, active targeting, and internalizable properties can ferry paclitaxel selectively into tumor tissue, rapidly enter cancer cells, and controllably release their payload in response to an intracellular acidic environment, thus resulting in an improved biodistribution and excellent antitumor activity <i>in vivo</i>. Our work provides a facile and versatile approach for the design and fabrication of smart intracellular targeted nanovehicles for effective cancer treatment, and opens a new era in the development of biodegradable polyurethanes for next-generation nanodelivery systems
Simultaneous Improvement of Oxidative and Hydrolytic Resistance of Polycarbonate Urethanes Based on Polydimethylsiloxane/Poly(hexamethylene carbonate) Mixed Macrodiols
The degradation behaviors
including oxidation and hydrolysis of
silicone modified polycarbonate urethanes were thoroughly investigated.
These polyurethanes were based on polyhexamethylene carbonate (PHMC)/polydimethylsiloxane
(PDMS) mixed macrodiols with molar ratio of PDMS ranging from 5% to
30%. It was proved that PDMS tended to migrate toward surface and
even a small amount of PDMS could form a silicone-like surface. Macrophages-mediated
oxidation process indicated that the PDMS surface layer was desirable
to protect the fragile soft PHMC from the attack of degradative species.
Hydrolysis process was probed in detail after immersing in boiling
buffered water using combined analytical tools. Hydrolytically stable
PDMS could act as protective shields for the bulk to hinder the chain
scission of polycarbonate carbonyls whereas the hydrolysis of urethane
linkages was less affected. Although the promoted phase separation
at higher PDMS fractions lead to possible physical defects and mechanical
compromise after degradation, simultaneously enhanced oxidation and
hydrolysis resistance could be achieved for the polyurethanes with
proper PDMS incorporation
Effects of Concentration and Ionization Degree of Anchoring Cationic Polymers on the Lateral Heterogeneity of Anionic Lipid Monolayers
We employed coarse-grained
Monte Carlo simulations to investigate a system composed of cationic
polymers and a phosphatidyl-choline membrane monolayer, doped with
univalent anionic phosphatidylserine (PS) and tetravalent anionic
phosphatidylinositol 4,5-bisphosphate (PIP<sub>2</sub>) lipid molecules.
For this system, we consider the conditions under which multiple cationic
polymers can anchor onto the monolayer and explore how the concentration
and ionization degree of the polymers affect the lateral rearrangement
and fluidity of the negatively charged lipids. Our work shows that
the anchoring cationic polymers predominantly bind the tetravalent
anionic PIP<sub>2</sub> lipids and drag the PIP<sub>2</sub> clusters
to migrate on the monolayer. The polymer/PIP<sub>2</sub> binding is
found to be drastically enhanced by increasing the polymer ionization
fraction, which causes the PIP<sub>2</sub> lipids to form into larger
clusters and reduces the mobility of the polymer/PIP<sub>2</sub> complexes.
As expected, stronger competition effects between anchoring polymers
occur at higher polymer concentrations, for which each anchoring polymer
partially dissociates from the monolayer and hence sequesters a smaller
PIP<sub>2</sub> cluster. The desorbed segments of the anchored polymers
exhibit a faster mobility on the membrane, whereas the PIP<sub>2</sub> clusters are closely restrained by the limited adhering cationic
segments of anchoring polymers. We further demonstrate that the PIP<sub>2</sub> molecules display a hierarchical mobility in the PIP<sub>2</sub> clusters, which is regulated by the synergistic effect between
the cationic segments of the polymers. The PS lipids sequester in
the vicinity of the polymer/PIP<sub>2</sub> complexes if the tetravalent
PIP<sub>2</sub> lipids cannot sufficiently neutralize the cationic
polymers. Finally, we illustrate that the increase in the ionic concentration
of the solution weakens the lateral clustering and the mobility heterogeneity
of the charged lipids. Our work thus provides a better understanding
of the fundamental biophysical mechanism of the concentration gradients
and the hierarchical mobility of the anionic lipids in the membrane
caused by the cationic polymer anchoring on length and time scales
that are generally inaccessible by atomistic models. It also offers
insight into the development and design of novel biological applications
on the basis of the modulation of signaling lipids