ABSTRACT
One–step preparation of electrospun bimodal fibrous membrane based on single nozzle is the key to the efficient fabrication of high–performance air filter. However, the preparation mechanism of electrospun bimodal fibers at low conductivity solution system is not clear, and there is a lack of evaluation methods for the quality of bimodal nanofibers, which limits the applicability of single nozzle electrospinning and the preparation efficiency of electrospun bimodal fibers. Here, three electrospinning processes at low conductivity solution systems of polyamide–6 (PA6), PA6 blended PVP (PA6/PVP), and PA6 blended polyethylene oxide (PA6/PEO) were studied according to the rheological properties and the fluid electrics (i.e., zeta potential), and the quality of the prepared bimodal fibrous membrane was creatively evaluated by R value. Inhomogeneous phase separations of the electrospinning jet along the direction parallel (x–axis) or perpendicular (y–axis) to the electric field were responsible for the formation of bimodal fibers. In addition, for the same solution system, the R value had a positive correlation with the air filtration performance. This work will greatly enhance the applicability of one–step single nozzle electrospinning for the preparation of bimodal nanofibers, improve the preparation efficiency, and promote the development of high–performance air filter. © 2022 Elsevier Ltd
ABSTRACT
Obesity is a metabolic condition that accounts for life-threatening disorders like cancer, cardiovascular diseases, and type-2 diabetes. There are several anti-obesity drugs currently available on the market, but many of them show poor bioavailability due to low water solubility. Several attempts have been made by researchers to improve the solubility of orally administered drugs, but many of them did not work properly. Herein, we introduced a block copolymer micelle consisting of poly (lactic acid)-co-poly (ethylene glycol) to improve the solubility of the anti-obesity drug "Fenofibrate”. The block copolymer was synthesized using the polycondensation method, while the micelle was formed when water was added dropwise to the copolymer. Finally, laser light scattering and DLS analysis were used to confirm the micelle formation. The size of the micelle increased from 158 nm to 249 nm after the fenofibrate drug loading inside the hydrophobic core. The polymer PLA-co-PEG can be used as a carrier for orally administered fenofibrate drugs in the future for better water solubility and efficiency. © The Electrochemical Society
ABSTRACT
Advancements in polymer science and engineering have helped the scientific community to shift its attention towards the use of environmentally benign materials for reducing the environmental impact of conventional synthetic plastics. Biopolymers are environmentally benign, chemically versatile, sustainable, biocompatible, biodegradable, inherently functional, and ecofriendly materials that exhibit tremendous potential for a wide range of applications including food, electronics, agriculture, textile, biomedical, and cosmetics. This review also inspires the researchers toward more consumption of biopolymer-based composite materials as an alternative to synthetic composite materials. Herein, an overview of the latest knowledge of different natural- and synthetic-based biodegradable polymers and their fiber-reinforced composites is presented. The review discusses different degradation mechanisms of biopolymer-based composites as well as their sustainability aspects. This review also elucidates current challenges, future opportunities, and emerging applications of biopolymeric sustainable composites in numerous engineering fields. Finally, this review proposes biopolymeric sustainable materials as a propitious solution to the contemporary environmental crisis. © 2022 Elsevier Ltd.