Poly(lactide-co-glycotide) (PLGA)/gelatin composite microspheres were prepared by an emulsion solvent evaporation technique. RGDS peptides were further immobilized under the catalyzation of water soluble carbodiimide (EDAC). Confocal laser scanning microscopy and transmission electron microscopy revealed that the gelatin was entrapped in the PLGA/gelatin microspheres with a manner of separated domains. The contents of the entrapped gelatin and immobilized RGDS peptides were quantified as 0.9 mg/20 mg and approximately 2.1 microg/20 mg microspheres by hydroxyproline analysis and bicinchoninic acid protein assay, respectively. Moreover, difference in morphology of PLGA, PLGA/gelatin and RGDS modified PLGA/gelatin (PLGA/gelatin-RGDS) microspheres was observed by scanning electron microscopy. The PLGA/gelatin and PLGA/gelatin-RGDS microspheres lost their weight rapidly in PBS, but slowly in DMEM/fetal bovine serum. Rabbit auricular chondrocytes were seeded onto the microspheres in vitro to assess their biological performance and applicability as cell carriers. Results show that amongst the PLGA, PLGA/gelatin and PLGA/gelatin-RGDS microspheres, the latter ones have the best performance in terms of chondrocyte attachment, proliferation, viability and sulfated glycosaminoglycans secretion.
In
the present study, SWCNH–COOH and SWCNH–TETA were
fabricated using single-walled carbon nanohorns (SWCNHs) via carboxylation and grafting with triethylenetetramine (TETA) for
uranium (VI) ion [U(VI)] removal. The morpho-structural characterization
of as-prepared adsorbing materials was performed by transmission electron
microscopy, X-ray diffractometry, Raman spectroscopy, and X-ray photoelectron
spectroscopy (XPS). Several parameters including the pH value of the
aqueous solutions, contact time, temperature, and U(VI) concentration
were used to evaluate the sorption efficiency of SWCNH–COOH
and SWCNH–TETA. The Langmuir isotherm model could well represent
the as-obtained adsorption isotherms, and the kinetics was successfully
modeled by pseudo-second-order kinetics in the adsorption process.
The maximum adsorption capacity of SWCNH–TETA was calculated
as 333.13 mg/g considering the Langmuir isotherm model. Thermodynamic
studies showed that adsorption proved to be a spontaneous endothermic
process. Moreover, SWCNH–TETA exhibited excellent recycling
performance and selective adsorption of uranium. Furthermore, the
possible mechanism was investigated by XPS and density functional
theory calculations, indicating that the excellent adsorption was
attributed to the cooperation capability between uranium ions and
nitrogen atoms in SWCNH–TETA. This efficient approach can provide
a strategy for developing high-performance adsorbents for U(VI) removal
from wastewater.
PLLA microspheres were aminolyzed in hexanediamine/propanol solution to introduce free amino groups on their surface, which were further transferred into aldehyde groups by a treatment of glutaraldehyde. Chitosan-graft-lactose was then covalently coupled via Schiff base formation. Morphological variation and chitosan-graft-lactose immobilization were characterized. In vitro culture of rabbit auricular chondrocytes demonstrated that the PLLA microcarriers could effectively support the cell attachment and particularly induce cell aggregation on their surface. The formed cell aggregates/microcarriers composite showed higher viability and extracellular matrix production. Thus, the PLLA microcarriers can be potentially used as an injectable delivery system for cartilage repair.
A three-dimensionally
interconnected molybdenum trioxide (MoO
3
)/polypyrrole (PPy)/reduced
graphene oxide (rGO) composite
was synthesized via an eco-friendly three-step method. The as-obtained
electrode shows a high specific capacity of 412.3 F g
–1
at a current density of 0.5 A g
–1
and a good cycling
stability (85.1% of the initial specific capacitance after 6000 cycles
at 2 A g
–1
is retained), and these excellent electrochemical
performances can be attributed to the unique structure, remarkable
electrical conductivity, and the synergetic effects between MoO
3
, PPy, and rGO. Furthermore, a symmetric supercapacitor based
on a MoO
3
/PPy/rGO electrode was assembled to investigate
the practical application performance of this material. The results
demonstrate a high energy density of 19.8 W h kg
–1
at a power density of 301 W kg
–1
. These findings
shine a light on the rational design of electrode materials with multicomponents
for high-performance supercapacitors.
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