9 research outputs found
Facile Fabrication of Superhydrophobic Sponge with Selective Absorption and Collection of Oil from Water
A simple vapor-phase
deposition process has been developed to fabricate
a superhydrophobic and superoleophilic sponge using ordinary commercial
polyurethane sponges. The simultaneous properties of superhydrophobicity
and superoleophilicity enable the sponge to float on the water surface
and selectively absorb oil from water. Its uptake capacities of different
oils (motor oil, lubricating oil, pump oil, silicone oil, and soybean
oil) in the oil–water mixtures were all above 20 g/g. The absorbed
oil could be collected by squeezing the sponge, and the recovered
sponge could be reused in oil–water separation for many cycles
while still maintaining a high capacity. This is helpful for realizing
the proper disposal of the oil and avoiding secondary pollution. A
similar experiment was performed using the as-prepared sponge to remove
petroleum from contaminated water. The results suggest that our material
might find practical applications in the cleanup of oil spills and
the removal of organic pollutants from water surfaces
Facile Fabrication of Superhydrophobic Sponge with Selective Absorption and Collection of Oil from Water
A simple vapor-phase
deposition process has been developed to fabricate
a superhydrophobic and superoleophilic sponge using ordinary commercial
polyurethane sponges. The simultaneous properties of superhydrophobicity
and superoleophilicity enable the sponge to float on the water surface
and selectively absorb oil from water. Its uptake capacities of different
oils (motor oil, lubricating oil, pump oil, silicone oil, and soybean
oil) in the oil–water mixtures were all above 20 g/g. The absorbed
oil could be collected by squeezing the sponge, and the recovered
sponge could be reused in oil–water separation for many cycles
while still maintaining a high capacity. This is helpful for realizing
the proper disposal of the oil and avoiding secondary pollution. A
similar experiment was performed using the as-prepared sponge to remove
petroleum from contaminated water. The results suggest that our material
might find practical applications in the cleanup of oil spills and
the removal of organic pollutants from water surfaces
Bio-Inspired Supramolecular Hybrid Dendrimers Self-Assembled from Low-Generation Peptide Dendrons for Highly Efficient Gene Delivery and Biological Tracking
Currently, supramolecular self-assembly of dendrons and dendrimers emerges as a powerful and challenging strategy for developing sophisticated nanostructures with excellent performances. Here we report a supramolecular hybrid strategy to fabricate a bio-inspired dendritic system as a versatile delivery nanoplatform. With a rational design, dual-functionalized low-generation peptide dendrons (PDs) self-assemble onto inorganic nanoparticles <i>via</i> coordination interactions to generate multifunctional supramolecular hybrid dendrimers (SHDs). These SHDs exhibit well-defined nanostructure, arginine-rich peptide corona, and fluorescent signaling properties. As expected, our bio-inspired supramolecular hybrid strategy largely enhances the gene transfection efficiency of SHDs approximately 50 000-fold as compared to single PDs at the same R/P ratio. Meanwhile the bio-inspired SHDs also (i) provide low cytotoxicity and serum resistance in gene delivery; (ii) provide inherent fluorescence for tracking intracellular pathways including cellular uptake, endosomal escape, and gene release; and (iii) work as an alternative reference for monitoring desired protein expression. More importantly, <i>in vivo</i> animal experiments demonstrate that SHDs offer considerable gene transfection efficiency (in muscular tissue and in HepG2 tumor xenografts) and real-time bioimaging capabilities. These SHDs will likely stimulate studies on bio-inspired supramolecular hybrid dendritic systems for biomedical applications both <i>in vitro</i> and <i>in vivo</i>
Bioreducible Peptide-Dendrimeric Nanogels with Abundant Expanded Voids for Efficient Drug Entrapment and Delivery
Dendrimer-based nanoplatforms have
exhibited wide prospects in
the field of nanomedicine for drug delivery, without great success
due to many predicaments of cytotoxicity, high cost, and low yield.
In this work, we report a feasible strategy on dynamic cross-linkings
of low-generation peptide dendrimers into bioreducible nanogels for
efficient drug controlled release. With a facile fabrication, the
disulfide cross-linking of biocompatible peptide dendrimers successfully
possess well-defined and stable nanostructures with abundant expanded
voids for efficient molecular encapsulation. More importantly, high
reducing condition is capable of triggering the cleavage of disulfide
bonds, the disintegration of peptide-dendrimeric nanogels, and stimuli-responsive
release of guest molecules. The bioreducible nanogels improve antitumor
drug internalization, contribute to endosomal escape, and realize
intracellular drug controlled release. The doxorubicin-loaded nanogels
afford high antitumor efficiency and reduce the side effects to BALB/c
mice bearing 4T1 tumor. Therefore, dynamic cross-linkings of low-generation
dendrimers into smart nanogels will be an alternative and promising
strategy to resolve the dilemmas of current dendrimer-based nanocarriers
as well as develop innovative nanoplatforms
Bioinspired Design of Stereospecific d‑Protein Nanomimics for High-Efficiency Autophagy Induction
Bioinspired Design of Stereospecific d‑Protein
Nanomimics for High-Efficiency Autophagy Inductio
Robust and Durable Superhydrophobic Cotton Fabrics for Oil/Water Separation
By
introducing the incorporation of polyaniline and fluorinated
alkyl silane to the cotton fabric via a facile vapor phase deposition
process, the fabric surface possessed superhydrophobicity with the
water contact angle of 156° and superoleophilicity with the oil
contact angle of 0°. The as-prepared fabric can be applied as
effective materials for the separation of water and oil mixture with
separation efficiency as high as 97.8%. Compared with other materials
for oil/water separation, the reported process was simple, time-saving,
and repeatable for at least 30 times. Moreover, the obtained fabric
kept stable superhydrophobicity and high separation efficiency under
extreme environment conditions of high temperature, high humidity,
strong acidic or alkaline solutions, and mechanical forces. Therefore,
this reported fabric has the advantages of scalable fabrication, high
separation efficiency, stable recyclability, and excellent durability,
exhibiting the strong potential for industrial production
Robust and Durable Superhydrophobic Cotton Fabrics for Oil/Water Separation
By
introducing the incorporation of polyaniline and fluorinated
alkyl silane to the cotton fabric via a facile vapor phase deposition
process, the fabric surface possessed superhydrophobicity with the
water contact angle of 156° and superoleophilicity with the oil
contact angle of 0°. The as-prepared fabric can be applied as
effective materials for the separation of water and oil mixture with
separation efficiency as high as 97.8%. Compared with other materials
for oil/water separation, the reported process was simple, time-saving,
and repeatable for at least 30 times. Moreover, the obtained fabric
kept stable superhydrophobicity and high separation efficiency under
extreme environment conditions of high temperature, high humidity,
strong acidic or alkaline solutions, and mechanical forces. Therefore,
this reported fabric has the advantages of scalable fabrication, high
separation efficiency, stable recyclability, and excellent durability,
exhibiting the strong potential for industrial production
Specially-Made Lipid-Based Assemblies for Improving Transmembrane Gene Delivery: Comparison of Basic Amino Acid Residue Rich Periphery
Cationic lipid based
assemblies provide a promising platform for
effective gene condensation into nanosized particles, and the peripheral
properties of the assemblies are vital for complexation and interaction
with physical barriers. Here, we report three cationic twin head lipids,
and each of them contains a dioleoyl-glutamate hydrophobic tail and
a twin polar head of lysine, arginine, or histidine. Such lipids were
proven to self-assemble in aqueous solution with well-defined nanostructures
and residual amino-, guanidine-, or imidazole-rich periphery, showing
strong buffering capacity and good liquidity. The assemblies with
arginine (RL) or lysine (KL) periphery exhibited positive charges
(∼+35 mV) and complete condensation of pDNA into nanosized
complexes (∼120 nm). In contrast, assemblies composed of histidine-rich
lipids (HL) showed relatively low cationic electric potential (∼+10
mV) and poor DNA binding ability. As expected, the designed RL assemblies
with guanidine-rich periphery enhanced the <i>in vitro</i> gene transfection up to 190-fold as compared with the golden standard
PEI<sub>25k</sub> and Lipofectamine 2000, especially in the presence
of serum. Meanwhile, interaction with cell and endo/lysosome membrane
also revealed the superiority of RL complexes, that the guanidine-rich
surface efficiently promoted transmembrane process in cellular internalization
and endosomal disruption. More importantly, RL complexes also succeeded
beyond others <i>in vivo</i> with significantly (∼7-fold)
enhanced expression in HepG2 tumor xenografts in mice, as well as
stronger green fluorescence protein imaging in isolated tumors and
tumor frozen sections
Highly Stable Fluorinated Nanocarriers with iRGD for Overcoming the Stability Dilemma and Enhancing Tumor Penetration in an Orthotopic Breast Cancer
The
stability dilemma and limited tumor penetration of nanocarriers
in cancer chemotherapy remain two predominant challenges for their
successful clinical translation. Herein, the pH-sensitive fluorocarbon-functionalized
nanocarriers (SFNs) with a tumor-homing and penetrating peptide iRGD
are reported to overcome the stability dilemma and enhance tumor accumulation
and penetration in an orthotopic breast cancer. The highly stable
SFNs with a low critical association concentration provide a safe
and spacious harbor for hydrophobic drugs. Furthermore, the stimulus-responsive
evaluation and <i>in vitro</i> drug release study show that
the SFNs can balance intracellular dissociation for drug release and
extracellular stability in the blood circulation. Additionally, the
tumor penetration capacity has been dramatically enhanced in 3D multicellular
spheroids, effectively affecting cells far from the periphery. This
can be ascribed to the coadministration of iRGD having tumor-penetrating
ability and fluorocarbon chains having good cell membrane permeability.
The combination of SFNs and iRGD is a viable approach to assist drugs’
effective accumulation in primary and metastasized tumor sites, significantly
inhibiting the breast tumor growth and curbing lung and liver metastases
in an orthotopic-tumor-bearing mouse model. Taken together, this pH-sensitive
fluorinated nanosystem having excellent stability and tumor accumulation
and penetration properties paves the way to combat cancer