10 research outputs found
Glyco-Nanovesicles with Activatable Near-Infrared Probes for Real-Time Monitoring of Drug Release and Targeted Delivery
A glyco-nanovesicle
(Lac-SS-DCM) is self-assembled by a rationally
designed amphiphilic lactose derivative (<b>1</b>), which features
a surface lactose corona, a disulfide linkage, and an activatable
DCM near-infrared (NIR) probe moiety. Taking advantage of the disulfide
linkage, Lac-SS-DCM can be triggered to disassemble by glutathione
(GSH) and simultaneously activate the dormant NIR, which allows for
a drug-loaded vesicle capable of both therapies in cancer cells where
a higher GSH concentration exists and real-time monitoring of drug
release. Furthermore, Lac-SS-DCM demonstrates excellent HepG2 target
ability as well as higher anticancer efficacy and reduced side effects
compared to those of free DOX through lactose-mediated endocytosis
resulting from the surface lactose corona, which acts as a multivalent
galectin-targeting ligand. As a multifunctional drug delivery compound
with perfect synchronization of targeting, imaging, monitoring, and
controllable drug release, we believe this activatable glyco-nanovesicle,
readily modulated for imaging of different tumors by incorporation
of unique targeting entities on the vesicle surface, would be of broad
interest for cancer diagnosis and therapy
Feedback-Induced Temporal Control of “Breathing” Polymersomes To Create Self-Adaptive Nanoreactors
Here
we present the development of self-regulated “breathing”
polymersome nanoreactors that show temporally programmable biocatalysis
induced by a chemical fuel. pH-sensitive polymersomes loaded with
horseradish peroxidase (HRP) and urease were developed. Addition of
an acidic urea solution (“fuel”) endowed the polymersomes
with a transient size increase and permeability enhancement, driving
a temporal “ON” state of the HRP enzymatic catalysis;
subsequent depletion of fuel led to shrinking of the polymersomes,
resulting in the catalytic “OFF” state. Moreover, the
nonequilibrium nanoreactors could be reinitiated several cycles as
long as fuel was supplied. This feedback-induced temporal control
of catalytic activity in polymersome nanoreactors provides a platform
for functional nonequilibrium systems as well as for artificial organelles
with precisely controlled adaptivity
Erythrocyte Membrane Modified Janus Polymeric Motors for Thrombus Therapy
We report the construction
of erythrocyte membrane-cloaked Janus
polymeric motors (EM-JPMs) which are propelled by near-infrared (NIR)
laser irradiation and are successfully applied in thrombus ablation.
Chitosan (a natural polysaccharide with positive charge, CHI) and
heparin (glycosaminoglycan with negative charge, Hep) were selected
as wall materials to construct biodegradable and biocompatible capsules
through the layer-by-layer self-assembly technique. By partially coating
the capsule with a gold (Au) layer through sputter coating, a NIR-responsive
Janus structure was obtained. Due to the asymmetric distribution of
Au, a local thermal gradient was generated upon NIR irradiation, resulting
in the movement of the JPMs through the self-thermophoresis effect.
The reversible “on/off” motion of the JPMs and their
motile behavior were easily tuned by the incident NIR laser intensity.
After biointerfacing the Janus capsules with an erythrocyte membrane,
the EM-JPMs displayed red blood cell related properties, which enabled
them to move efficiently in relevant biological environments (cell
culture, serum, and blood). Furthermore, this therapeutic platform
exhibited excellent performance in ablation of thrombus through photothermal
therapy. As man-made micromotors, these biohybrid EM-JPMs hold great
promise of navigating <i>in vivo</i> for active delivery
while overcoming the drawbacks of existing synthetic therapeutic platforms.
We expect that this biohybrid motor has considerable potential to
be widely used in the biomedical field
One-Step Synthesis of Dual Clickable Nanospheres via Ultrasonic-Assisted Click Polymerization for Biological Applications
Dual clickable nanospheres (DCNSs)
were synthesized in one step using an efficient approach of ultrasonic-assisted
azide–alkyne click polymerization, avoiding the need of surfactants.
This novel approach presents a direct clickable monomer-to-nanosphere
synthesis. Field emission scanning electron microscopy (FESEM), Fourier
transform infrared spectroscopy (FTIR), and dynamic laser scattering
(DLS) were used to characterize the synthesized DCNSs. Numerous terminal
alkynyl and azide groups on the surface of DCNSs facilitate effective
conjugation of multiple molecules or ligands onto a single nanocarrier
platform under mild conditions. To exemplify the potential of DCNSs
in biological applications, (1) multivalent glyconanoparticles (GNPs)
were prepared by clicking DCNSs with azide-functionalized and alkyne-functionalized
lactose sequentially for the determination of carbohydrate-galectin
interactions with quartz crystal microbalance (QCM) biosensor. Using
protein chip (purified galectin-3 coated on chip) and cell chip (Jurkat
cells immobilized on chip), the QCM sensorgrams showed excellent binding
activity of GNPs for galectins; (2) fluorescent GNPs were prepared
by clicking DCNSs with azide-functionalized Rhodamine B and alkyne-functionalized
lactose sequentially in order to target galectin, which is overexpressed
on the surface of Jurkat cells. The fluorescent images obtained clearly
showed the cellular internalization of fluorescent GNPs. This fluorescent
probe could be easily adapted to drugs to construct lectin-targeted
drug delivery systems. Thus, DCNSs prepared with our method may provide
a wide range of potential applications in glycobiology and biomedicine
Erythrocyte Membrane Modified Janus Polymeric Motors for Thrombus Therapy
We report the construction
of erythrocyte membrane-cloaked Janus
polymeric motors (EM-JPMs) which are propelled by near-infrared (NIR)
laser irradiation and are successfully applied in thrombus ablation.
Chitosan (a natural polysaccharide with positive charge, CHI) and
heparin (glycosaminoglycan with negative charge, Hep) were selected
as wall materials to construct biodegradable and biocompatible capsules
through the layer-by-layer self-assembly technique. By partially coating
the capsule with a gold (Au) layer through sputter coating, a NIR-responsive
Janus structure was obtained. Due to the asymmetric distribution of
Au, a local thermal gradient was generated upon NIR irradiation, resulting
in the movement of the JPMs through the self-thermophoresis effect.
The reversible “on/off” motion of the JPMs and their
motile behavior were easily tuned by the incident NIR laser intensity.
After biointerfacing the Janus capsules with an erythrocyte membrane,
the EM-JPMs displayed red blood cell related properties, which enabled
them to move efficiently in relevant biological environments (cell
culture, serum, and blood). Furthermore, this therapeutic platform
exhibited excellent performance in ablation of thrombus through photothermal
therapy. As man-made micromotors, these biohybrid EM-JPMs hold great
promise of navigating <i>in vivo</i> for active delivery
while overcoming the drawbacks of existing synthetic therapeutic platforms.
We expect that this biohybrid motor has considerable potential to
be widely used in the biomedical field
Erythrocyte Membrane Modified Janus Polymeric Motors for Thrombus Therapy
We report the construction
of erythrocyte membrane-cloaked Janus
polymeric motors (EM-JPMs) which are propelled by near-infrared (NIR)
laser irradiation and are successfully applied in thrombus ablation.
Chitosan (a natural polysaccharide with positive charge, CHI) and
heparin (glycosaminoglycan with negative charge, Hep) were selected
as wall materials to construct biodegradable and biocompatible capsules
through the layer-by-layer self-assembly technique. By partially coating
the capsule with a gold (Au) layer through sputter coating, a NIR-responsive
Janus structure was obtained. Due to the asymmetric distribution of
Au, a local thermal gradient was generated upon NIR irradiation, resulting
in the movement of the JPMs through the self-thermophoresis effect.
The reversible “on/off” motion of the JPMs and their
motile behavior were easily tuned by the incident NIR laser intensity.
After biointerfacing the Janus capsules with an erythrocyte membrane,
the EM-JPMs displayed red blood cell related properties, which enabled
them to move efficiently in relevant biological environments (cell
culture, serum, and blood). Furthermore, this therapeutic platform
exhibited excellent performance in ablation of thrombus through photothermal
therapy. As man-made micromotors, these biohybrid EM-JPMs hold great
promise of navigating <i>in vivo</i> for active delivery
while overcoming the drawbacks of existing synthetic therapeutic platforms.
We expect that this biohybrid motor has considerable potential to
be widely used in the biomedical field
Erythrocyte Membrane Modified Janus Polymeric Motors for Thrombus Therapy
We report the construction
of erythrocyte membrane-cloaked Janus
polymeric motors (EM-JPMs) which are propelled by near-infrared (NIR)
laser irradiation and are successfully applied in thrombus ablation.
Chitosan (a natural polysaccharide with positive charge, CHI) and
heparin (glycosaminoglycan with negative charge, Hep) were selected
as wall materials to construct biodegradable and biocompatible capsules
through the layer-by-layer self-assembly technique. By partially coating
the capsule with a gold (Au) layer through sputter coating, a NIR-responsive
Janus structure was obtained. Due to the asymmetric distribution of
Au, a local thermal gradient was generated upon NIR irradiation, resulting
in the movement of the JPMs through the self-thermophoresis effect.
The reversible “on/off” motion of the JPMs and their
motile behavior were easily tuned by the incident NIR laser intensity.
After biointerfacing the Janus capsules with an erythrocyte membrane,
the EM-JPMs displayed red blood cell related properties, which enabled
them to move efficiently in relevant biological environments (cell
culture, serum, and blood). Furthermore, this therapeutic platform
exhibited excellent performance in ablation of thrombus through photothermal
therapy. As man-made micromotors, these biohybrid EM-JPMs hold great
promise of navigating <i>in vivo</i> for active delivery
while overcoming the drawbacks of existing synthetic therapeutic platforms.
We expect that this biohybrid motor has considerable potential to
be widely used in the biomedical field
Erythrocyte Membrane Modified Janus Polymeric Motors for Thrombus Therapy
We report the construction
of erythrocyte membrane-cloaked Janus
polymeric motors (EM-JPMs) which are propelled by near-infrared (NIR)
laser irradiation and are successfully applied in thrombus ablation.
Chitosan (a natural polysaccharide with positive charge, CHI) and
heparin (glycosaminoglycan with negative charge, Hep) were selected
as wall materials to construct biodegradable and biocompatible capsules
through the layer-by-layer self-assembly technique. By partially coating
the capsule with a gold (Au) layer through sputter coating, a NIR-responsive
Janus structure was obtained. Due to the asymmetric distribution of
Au, a local thermal gradient was generated upon NIR irradiation, resulting
in the movement of the JPMs through the self-thermophoresis effect.
The reversible “on/off” motion of the JPMs and their
motile behavior were easily tuned by the incident NIR laser intensity.
After biointerfacing the Janus capsules with an erythrocyte membrane,
the EM-JPMs displayed red blood cell related properties, which enabled
them to move efficiently in relevant biological environments (cell
culture, serum, and blood). Furthermore, this therapeutic platform
exhibited excellent performance in ablation of thrombus through photothermal
therapy. As man-made micromotors, these biohybrid EM-JPMs hold great
promise of navigating <i>in vivo</i> for active delivery
while overcoming the drawbacks of existing synthetic therapeutic platforms.
We expect that this biohybrid motor has considerable potential to
be widely used in the biomedical field
Supramolecular Vesicles Based on Complex of Trp-Modified Pillar[5]arene and Galactose Derivative for Synergistic and Targeted Drug Delivery
Supramolecular Vesicles Based on Complex of Trp-Modified
Pillar[5]arene and Galactose Derivative for Synergistic and Targeted
Drug Deliver
Positively Charged Biodegradable Polymersomes with Structure Inherent Fluorescence as Artificial Organelles
Polymersomes, nanosized
polymeric vesicles, have attracted
significant
interest in the areas of artificial cells and nanomedicine. Given
their size, their visualization via confocal microscopy techniques
is often achieved through the physical incorporation of fluorescent
dyes, which however present challenges due to potential leaching.
A promising alternative is the incorporation of molecules with aggregation-induced
emission (AIE) behavior that are capable of fluorescing exclusively
in their assembled state. Here, we report on the use of AIE polymersomes
as artificial organelles, which are capable of undertaking enzymatic
reactions in vitro. The ability of our polymersome-based artificial
organelles to provide additional functionality to living cells was
evaluated by encapsulating catalytic enzymes such as a combination
of glucose oxidase/horseradish peroxidase (GOx/HRP)
or β-galactosidase (β-gal). Via the additional incorporation
of a pyridinium functionality, not only the cellular uptake is improved
at low concentrations but also our platform’s potential to
specifically target mitochondria expands