More than half of
diabetic wounds demonstrate clinical signs of infection at presentation
and lead to poor outcomes. This work develops coaxial sheath-core
nanofibrous poly(lactide-co-glycolide) (PLGA) scaffolds
that are loaded with bioactive antibiotics and platelet-derived growth
factor (PDGF) for the repair of diabetic infectious wounds. PDGF and
PLGA/antibiotic solutions were pumped, respectively, into two independent
capillary tubings for coaxial electrospinning to prepare biodegradable
sheath-core nanofibers. Spun nanofibrous scaffolds sustainably released
PDGF, vancomycin, and gentamicin for 3 weeks. The scaffolds also reduced
the phosphatase and tensin homologue content, enhanced the amount
of angiogenesis marker (CD31) around the wound area, and accelerated
healing in the early stage of infected diabetic wound repair. Antibiotic/biomolecule-loaded
PLGA nanofibers may provide a very effective way to aid tissue regeneration
at the sites of infected diabetic wounds.
Overall, the water extract of M. rubra fruit is a safe and effective melanin inhibitor and anti-oxidant and can be applied widely in the fields of cosmetics and medicine.
Human safety, health management, and disease transmission prevention have become crucial tasks in the present COVID-19 pandemic situation. Masks are widely available and create a safer and disease transmission–free environment. This study presents a facile method of fabricating masks through electrospinning nontoxic polyvinyl butyral (PVB) polymeric matrix with the antibacterial component Thymol, a natural phenol monoterpene. Based on the results of Japanese Industrial Standards and American Association of Textile Chemists and Colorists methods, the maximum antibacterial value of the mask against Gram-positive and Gram-negative bacteria was 5.6 and 6.4, respectively. Moreover, vertical electrospinning was performed to prepare Thymol/PVB nanofiber masks, and the effects of parameters on the submicron particulate filtration efficiency (PFE), differential pressure, and bacterial filtration efficiency (BFE) were determined. Thorough optimization of the small-diameter nanofiber–based antibacterial mask led to denser accumulation and improved PFE and pressure difference; the mask was thus noted to meet the present pandemic requirements. The as-developed nanofibrous masks have the antibacterial activity suggested by the National Standard of the Republic of China (CNS 14774) for general medical masks. Their BFE reaches 99.4%, with a pressure difference of <5 mmH2O/cm2. The mask can safeguard human health and promote a healthy environment.
Wearable
skin-inspired electronic skins present remarkable outgrowth
in recent years because their promising comfort device integration,
lightweight, and mechanically robust durable characteristics led to
significant progresses in wearable sensors and optoelectronics. Wearable
electronic devices demand real-time applicability and factors such
as complex fabrication steps, manufacturing cost, and reliable and
durable performances, severely limiting the utilization. Herein, we
nominate a scalable solution-processable electrospun patterned candidate
capable of forming ultralong mechanically robust nano–microdimensional
fibers with higher uniformity. Nanofibrous patterned substrates present
surface energy and silver nanoparticle crystallization shifts, contributing
to strain-sensitive and -insensitive conductive electrodes (10 000
cycles of 50% strain). Synergistic robust stress releasing and durable
electromechanical behavior engenders stretchable durable health sensors,
strain-insensitive pressure sensors (sensitivity of ∼83 kPa–1 and 5000 durable cycles), robust alternating current
electroluminescent displays, and flexible organic light-emitting diodes
(20% improved luminescence and 300 flex endurance of 2 mm bend radius).
BackgroundThe high lifetime risk of vascular disease is one of the important issues that plague patients with diabetes mellitus. Systemic oral vildagliptin administration favors endothelial recovery and inhibits smooth muscle cell (SMC) proliferation. However, the localized release of vildagliptin in the diabetic vessel damage has seldom been investigated.Research design and methodsIn this work, nanofiber-eluting stents that loaded with vildagliptin, a dipeptidyl peptidase-4 enzyme (DPP-4) inhibitor, was fabricated to treat diabetic vascular disease. To prepare nanofibers, the poly (D,L)-lactide-co-glycolide (PLGA) and vildagliptin were mixed using hexafluoroisopropanol and electrospinning process. In vitro and in vivo release rates of the vildagliptin were characterized using high-performance liquid chromatography.ResultsEffective vildagliptin concentrations were delivered for more than 28 days from the nanofibrous membranes coating on the surface of the stents in vitro and in vivo. The vildagliptin-eluting PLGA membranes greatly accelerated the recovery of diabetic endothelia and reduced SMC hyperplasia. The type I collagen content of the diabetic vascular intimal area that was treated by vildagliptin-eluting stents was lower than that of the non-vildagliptin-eluting group.ConclusionThe experimental results revealed that stenting with vildagliptin-eluting PLGA membranes could potentially promote healing for diabetic arterial diseases.
Starch-based biodegradable foams with a high starch content are developed using industrial starch as the base material and supercritical CO2 as blowing or foaming agents. The superior cushioning properties of these foams can lead to competitiveness in the market. Despite this, a weak melting strength property of starch is not sufficient to hold the foaming agents within it. Due to the rapid diffusion of foaming gas into the environment, it is difficult for starch to maintain pore structure in starch foams. Therefore, producing starch foam by using supercritical CO2 foaming gas faces severe challenges. To overcome this, we have synthesized thermoplastic starch (TPS) by dispersing starch into water or glycerin. Consecutively, the TPS surface was modified by compatibilizer silane A (SA) to improve the dispersion with poly(butylene adipate-co-terephthalate) (PBAT) to become (TPS with SA)/PBAT composite foam. Furthermore, the foam-forming process was optimized by varying the ratios of TPS and PBAT under different forming temperatures of 85 °C to 105 °C, and two different pressures, 17 Mpa and 23 Mpa were studied in detail. The obtained results indicate that the SA surface modification on TPS can influence the great compatibility with PBAT blended foams (foam density: 0.16 g/cm3); whereas unmodified TPS and PBAT (foam density: 0.349 g/cm3) exhibit high foam density, rigid foam structure, and poor tensile properties. In addition, we have found that the 80% TPS/20% PBAT foam can be achieved with good flexible properties. Because of this flexibility, lightweight and environment-friendly nature, we have the opportunity to resolve the strong demands from the packing market.
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