The
extractive membrane bioreactor (EMBR) system combining a membrane
process and a biological process has been developed to extract and
biodegrade recalcitrant organic pollutants in wastewater. Removal
of the organics such as phenol by EMBR requires an effective membrane
to selectively extract the organic compounds while rejecting water
and other harsh inorganic components. In this work, novel composite
membranes consisting of a highly porous substrate, made by tiered
polyvinylidene fluoride (PVDF) nanofibers with ultrafine nanofibers
on top (61 ± 12 nm in diameter), and a dense polydimethylsiloxane
(PDMS) selective layer have been fabricated. We have investigated
(1) the effect of the pore size of PVDF nanofibrous substrates, (2)
the effect of PDMS preparation method, and (3) the effect of prewetting
agent on the resultant composite membranes’ morphologies, mechanical
properties, and phenol removal performance. Compared with the symmetric
substrate with a nanofiber diameter of 129 ± 13 nm, the tiered
substrate can effectively support a uniform and defect-free PDMS coating.
This is attributed to the smaller surface pore size of the tiered
substrate as a result of its top ultrafine nanofibers. Besides, the
use of partially precross-linked PDMS coating solution with increased
viscosity and 50 wt % glycerol aqueous solution as the prewetting
agent to fill the substrate pores is preferred in order to mitigate
PDMS intrusion. On the basis of the resistance model, the overall
membrane resistance decreases with the decrease of the PDMS intrusion
level, giving rise to a higher overall mass transfer coefficient, k
0, for phenol removal. With the above-mentioned
factors being taken into account, the first PDMS-coated PVDF nanofibrous
composite membrane has been developed to remove phenol with a high k
0 (over 4 times higher than the existing commercial
PDMS tubular membrane) for EMBR. This study provides insights and
guidelines for fabricating highly efficient membranes for organic
removal in the EMBR process.
Corneal transplantation is currently the major solution in the treatment of severe corneal diseases. However, it is restricted due to the limited number of corneal donors. A tissue-engineered cornea is a potential substitute which could help overcome this limitation. This research envisages the development of a novel tissue-engineered corneal stroma consisting of bacterial cellulose (BC)/poly(vinyl alcohol) (PVA) hydrogel composites for reconstructing the cornea. It was found that the properties of BC/PVA were better suited for use as a corneal stroma material than the BC hydrogel. The human corneal stromal cells (hCSCs) were used to evaluate the cytotoxicity of the materials, wherein BC/PVA displayed excellent biocompatibility with these cells. Furthermore, in the in vivo studies, the BC/PVA was transplanted intrastromally in rabbits. After four weeks, the cornea remained almost transparent, and without obvious inflammation, sensitization or neovascularization, as confirmed by the clinical and histological examinations. Our results demonstrate that BC/PVA was well-tolerated in the rabbit cornea, and may be a potential substitute for corneal stroma.
Corneal endothelial disease is a global sight-threatening disease, and corneal transplantation using donor corneas remains the sole therapeutic option. A previous work demonstrated that N (2)-alanyl-glutamine (Ala-Gln) protected against apoptosis and cellular stress, and maintained intestinal tissue integrity. In this pursuit, the present study aimed to examine the effect of Ala-Gln in the protection of the corneal endothelium and expand its range of potential clinical applications. Mice in the control group were intracamerally irrigated with Ringers lactate injection, whereas those in the experimental group were irrigated with Ringers lactate injection containing Ala-Gln. The mean intraocular pressure increased to 44 ± 3.5 mm Hg during intracameral irrigation (normal range 10.2 ± 0.4 mmHg). In vivo confocal microscopy results showed that the addition of Ala-Gln protected the morphology, structure, and density of the corneal endothelial cells. Optical Coherence Tomography (OCT) measurements showed that corneal thickness was not significantly different between the two groups, because of the immediate corneal edema after irrigation, but the addition of Ala-Gln obviously promoted the recovery of the corneal edema. Scanning electron microscopy indicated that the corneal endothelial cells were severely ruptured and exfoliated in the Ringer's group accompanied with cellular edema, when compared with the Ala-Gln group. The intracameral irrigation using Ala-Gln protected the structure and expression of cytoskeleton and Na-K-ATPase, which exhibited a regular distribution and significantly increased expression in comparison to Ringer's group. Furthermore, Ala-Gln maintained the mitochondrial morphology and increased the activity of mitochondria. Moreover, transmission electron microscopy showed that intracameral irrigation of Ala-Gln reversed the ultrastructural changes induced by the acute ocular hypertension in mice. Our study demonstrates that the intracameral irrigation of Ala-Gln effectively maintained the corneal endothelial pump function and barrier function by protecting the mitochondrial function and preventing the rearrangement of cytoskeleton in acute ocular hypertension in mice.
It has been a long-standing challenge to obtain from cell cultures adequate amounts of mouse corneal epithelial cells (mCEC) to perform transplantation surgery. This limitation is attributable to the passage dependent declines in their proliferative activity. We describe here development of a novel 6C medium that contains six different modulators of different signaling pathways, which control proliferative mCEC activity. Its usage shortens the time and effort required to obtain epithelial sheets for hastening healing of an epithelial wound in an experimental animal model. This serum-free 6C medium contains:Y27632, forskolin, SB431542, DAPT, IWP-2, LDN-193189 and also DermaLife K keratinocyte calcium. Their inclusion inhibits rises in four specific markers of epithelial mesenchymal transdifferentiation:ZEB1/2, Snail, β-catenin and α-SMA. This medium is applied in a feeder-free air-lifted system to obtain sufficient populations of epithelial progenitor cells whose procurement is facilitated due to suppression of progenitor epithelial cell transdifferentiation into epithelial-mesenchymal cells. Diminution of this decline in transdifferentiation was confirmed based on the invariance of P63, K14, Pax6, and K12 gene expression levels. This cell culture technique is expected to facilitate ex vivo characterization of mechanisms underlying cell fate determination. Furthermore, its implementation will improve yields of progenitor mouse corneal epithelial cells, which increases the likelihood of using these cells as a source to generate epithelial sheets for performing transplantation surgery to treat limbal stem cell deficiency in a clinical setting. In addition, the novel insight obtainable from such studies is expected to improve the outcomes of corneal regenerative medicine.
An ultrasensitive and selective method for Bisphenol A (BPA) detection using aptamer-BPA and real-time quantitative polymerase chain reaction (RT-qPCR) technology is reported, in which biotin-modified aptamer DNA (BPA) is fixed on the inner wall of a streptavidin-coated PCR tube via biotin-avidin interactions and the template is fixed through the complementary base pairing with aptamer DNA. Upon the addition of BPA, the template DNA could be off from the inner wall of PCR tube, which results from aptamer DNA interacted specifically with BPA. Thus, the number of template DNA change result from the BPA concentration is readily seen by cycle threshold (Ct) values. The sensor exhibited an excellent linear response between Ct values and BPA concentration in the range of 1-500 nM and the detection limit of this method for aqueous BPA was as low as 0.7 nM. In addition, this method showed good selectivity for BPA over its analogues.
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