Bacterial cellulose (BC) is cellulose produced by a few limited species of bacteria in given conditions. BC has many remarkable properties such as its high mechanical properties, water uptake ability and biocompatibility which makes it a very desirable material to be used for wound healing. Inherently due to these important properties, the material is very resistant to easy processing and thus difficult to produce into useful entities. Additionally, being rate limited by the dependency on bacterial production, high yield is difficult to obtain and thus secondary material processing is sought after. In this review, BC is explained in terms of synthesis, structure and properties. These beneficial properties are directly related to the material's great potential in wound healing where it has also been trialled commercially but ultimately failed due to processing issues. However, more recently there has been increased frequency in scientific work relating to BC processing into hybrid polymeric fibres using common laboratory fibre forming techniques such as electrospinning and pressurised gyration. This paper summarises current progress in BC fibre manufacturing, its downfalls and also gives a future perspective on how the landscape should change to allow BC to be utilised in wound care in the current environment.
Alzheimer's disease (AD) is a progressive and irreversible neurodegenerative disease. Cholinesterase inhibitors (ChEIs) are commonly used for symptomatic treatment of neural transmission improvement in AD. Donepezil is a reversible and non-competitive ChEI which is clinically used for palliative treatment of AD. The aim of the present study was to investigate the destabilizing effect of donepezil loaded poly(lactic-co-glycolic acid)-block-poly (ethylene glycol) [PLGA-b-PEG] nanoparticles on fibril formation in vitro and the ability of these nanoparticles to cross blood brain barrier (BBB) using in vitro BBB model and the neuroprotective effects of free donepezil and donepezil loaded PLGA-b-PEG nanoparticles. Donepezil loaded PLGA-b-PEG nanoparticles were prepared with double emulsion method. Destabilizing effect of these donepezil loaded particles on the amyloid-beta fibril (Aβ and Aβ) formation was determined in vitro. Nanoparticles were found to have small particle size and have destabilizing effect on fibril formation. In vitro BBB model was successfully prepared. Nanoparticles showed the ability to cross the BBB and showed a controlled release profile in this system. IL-1β, IL-6, GM-CSF, TGF-β, MCP-1 and TNF-α levels were found to be increased in both gene and protein expression levels in astrocytes incubated with amyloid fibrils in in vitro BBB model suggesting an increased inflammation. Free donepezil and donepezil loaded nanoparticle administration caused a significant dose-dependent decrease in both gene and protein expression levels of IL-1β, IL-6, GM-CSF and TNF-α. No significant changes were observed for TGF-β and MCP-1.
Poly(glycerol sebacate) (PGS) was discovered in the previous decade and is a promising bioelastomer with tuneable mechanical, biodegradable and biocompatible properties.Despite of these superiorities, PGS possesses solubility and processability disadvantages. To overcome these drawbacks of PGS, blends could be formed with a polymer which is soluble in a common solvent with PGS prepolymer, having a melting temperature above the crosslinking temperature and which can be removed from the structure after crosslinking. In this study, PGS fibers were fabricated for the first time using pressurized gyration as scaffolds. Fibers were obtained through blending the synthesized PGS prepolymer with poly(vinyl alcohol) (PVA) to overcome solubility/melting drawbacks of crosslinked PGS polymer. Obtained fiber diameters have a narrow size distribution which did not change after thermal crosslinking. After the washing procedure, ~ 25% decrease in the average fiber diameter was observed due to the PVA removal. Resulting PGS fibers were characterized in terms of chemical structure, morphology, and cell viability. Fibroblast cell adhesion and spreading on three-dimensional fiber networks were determined by microscopy. PGS fibers supported cell adhesion and proliferation. After 7 days of cell-PGS fiber interactions, cell proliferation and spreading increased without any toxicity.
Conventional administration of antibacterial drugs to the human body can cause vital problems such as dose dependent systemic toxicity and bacterial resistance which prevent the healing process. In this regard, recent studies have been devoted to producing nanofiber based antibacterial drug delivery approaches which surpass bacterial resistance and toxicological issues. Areas covered: This review summarizes latest developments in the production of antibacterial nanofibers, nanofiber based antibacterial action mechanisms and release profiles of nanofibers. In the first section, key challenges of antibacterial nanofibers and release and non-release antibacterial action mechanisms of nanofibers are highlighted. In the second section, routes of antibacterial nanofiber design have been given. Factors affecting drug release mechanisms have been discussed elaborately in the final section. Literature was surveyed from research articles, standard sources (WOS and Scopus) and clinical trials. Expert opinion: New generation nanofibers provide high drug loading capacity and efficiency with their high surface area and tunable pore size. They also enable sustained and controlled release of antibacterial drugs with basic (direct incorporation, physically adsorption or chemically surface modification of antibacterial drugs), advanced (core-shell structure, nanoparticle decorated and multidrug loaded) and smart (stimuli responsive) antibacterial nanofiber design strategies.
Neurite outgrowth and elongation of neural cells is the most important subject that is considered in nerve tissue engineering. In this regard, aligned nanofibers have taken much attention in terms of providing guidance for newly outgrown neurites. The main objective of this study was to fabricate aligned polyurethane nanofibers by electrospinning process and decorate them with gold nanoparticles to further investigate the synergistic effects of nanotopography, biological nerve growth factor (NGF) and electrical stimulations on neurite outgrowth and elongation of pheochromocytoma (PC-12) model cells. In this regard, smooth and uniform aligned polyurethane nanofibers with the average diameter of 519 ± 56 nm were fabricated and decorated with the gold nanoparticles with the average diameter of ∼50 nm. PC-12 cells were cultured on the various nanofiber surfaces inside the bio-mimetic bioreactor system and exposed either to NGF alone or combination of NGF and electrical stimulation. It was found that 50 ng/mL NGF concentration is an optimal value for the stimulation of neurite outgrowth. After 4 days of culture under 100 mV, 10 ms electrical stimulation in 1 h/day period it was found that the gold nanoparticle decorated aligned polyurethane nanofibers increased the neurite outgrowth and elongation more with the combinational NGF and electrical stimulation. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 1604-1613, 2018.
Amphiphilic block copolymers are widely used in science owing to their versatile properties. In this study, amphiphilic block copolymer poly(lactic- co-glycolic acid)- block-poly(ethylene glycol) (PLGA- b-PEG) was used to create microdroplets in a T-junction microfluidic device with a well-defined geometry. To compare interfacial characteristics of microdroplets, dichloromethane (DCM) and chloroform were used to prepare PLGA- b-PEG solution as an oil phase. In the T-junction device, water and oil phases were manipulated at variable flow rates from 50 to 300 μL/min by increments of 50 μL/min. Fabricated microdroplets were directly collected on a glass slide. After a drying period, porous two-dimensional and three-dimensional structures were obtained as honeycomb-like structure. Pore sizes were increased according to increased water/oil flow rate for both DCM and chloroform solutions. Also, it was shown that increasing polymer concentration decreased the pore size of honeycomb-like structures at a constant water/oil flow rate (50:50 μL/min). Additionally, PLGA- b-PEG nanoparticles were also obtained on the struts of honeycomb-like structures according to the water solubility, volatility, and viscosity properties of oil phases, by the aid of Marangoni flow. The resulting structures have a great potential to be used in biomedical applications, especially in drug delivery-related studies, with nanoparticle forming ability and cellular responses in different surface morphologies.
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