A comprehensive review on methods for promotion of mechanical features and biodegradation rate in amniotic membrane scaffolds.

Amniotic membrane (AM) is a biological tissue that surrounds the fetus in the mother's womb. It has pluripotent cells, immune modulators, collagen, cytokines with anti-fibrotic and anti-inflammatory effect, matrix proteins, and growth factors. In spite of the biological characteristics, some results have been released in preventing the adhesion on traumatized surfaces. Application of the AM as a scaffold is limited due to its low biomechanical resistance and rapid biodegradation. Therefore, for using the AM during surgery, its modification by different methods such as cross-linking of the membrane collagen is necessary, because the cross-linking is an effective way to reduce the rate of biodegradation of the biological materials. In addition, their cross-linking is likely an efficient way to increase the tensile properties of the material, so that they can be easily handled or sutured. In this regard, various methods related to cross-linking of the AM subsuming the composite materials, physical cross-linking, and chemical cross-linking with the glutraldehyde, carbodiimide, genipin, aluminum sulfate, etc. are reviewed along with its advantages and disadvantages in the current work.

Comparing various protocols of human and bovine ovarian tissue decellularization to prepare extracellular matrix-alginate scaffold for better follicle development in vitro.

BACKGROUND: Nowadays, the number of cancer survivors is significantly increasing as a result of efficient chemo/radio therapeutic treatments. Female cancer survivors may suffer from decreased fertility. In this regard, different fertility preservation techniques were developed. Artificial ovary is one of these methods suggested by several scientific groups. Decellularized ovarian cortex has been introduced as a scaffold in the field of human fertility preservation. This study was carried out to compare decellularization of the ovarian scaffold by various protocols and evaluate the follicle survival in extracellular matrix (ECM)-alginate scaffold. RESULTS: The micrographs of H&E and DAPI staining confirmed successful decellularization of the ovarian cortex in all experimental groups, but residual DNA content in SDS-Triton group was significantly higher than other groups (P < 0.05). SEM images demonstrated that complex fiber network and porosity structure were maintained in all groups. Furthermore, elastin and collagen fibers were observed in all groups after decellularization process. MTT test revealed higher cytobiocompatibility of the SDS-Triton-Ammonium and SDS-Triton decellularized scaffolds compared with SDS groups. Compared to the transferred follicles into the sodium alginate (81%), 85.9% of the transferred follicles into the decellularized scaffold were viable after 7 days of cultivation (P = 0.04). CONCLUSION: Although all the decellularization procedures was effective in removal of cells from ovarian cortex, SDS-Triton-Ammonium group showed less residual DNA content with higher cytobiocompatibility for follicles when compared with other groups. In addition, the scaffold made from ovarian tissues decellularized using SDS-Triton-Ammonium and sodium alginate is suggested as a potential 3D substrate for in vitro culture of follicles for fertility preservation.

Culture of rabbit bone marrow mesenchymal stem cells on polyurethane/pyrrole surface promoted differentiation into endothelial lineage.

Due to the electrical conductivity, pyrrole-based scaffolds are one of the attractive biomaterials in the regeneration of electrically active tissues like the heart and brain. Here, we investigated the impact of polyurethane/pyrrole scaffold on the angiogenesis differentiation of rabbit mesenchymal stem cells toward endothelial lineage in vitro. Nanoelectrospun polyurethane/pyrrole fibers were synthesized and characterized using attenuated total reflection-Fourier transform infrared (ATR-FTIR) spectrum analysis, scanning electron microscope (SEM) imaging. Mechanical properties, electroconductivity, and hydrophobicity were also measured. The viability of cells was monitored 72 hours after being plated on the polyurethane/pyrrole surface. The endothelial differentiation of stem cells was explored using western blotting. ATR-FTIR revealed that the pyrrole was successfully polymerized to polypyrrole and blend with polyurethane fibers. The addition of pyrrole to polyurethane increased the tensile strength compared to the polyurethane group. These features coincided with the reduction of the hydrophilic properties of polyurethane. Based on our data, the electro-conductivity of polyurethane/pyrrole was superior compared to the polyurethane group. SEM imaging showed an appropriate cell attachment to the surface of polyurethane/pyrrole and polyurethane groups synthesized membranes. MTT assay revealed a significantly increased survival rate in the polyurethane/pyrrole group compared to the polyurethane group (P < .05). We noted a statistically significant increase of endothelial-associated proteins, CD31, von Willebrand factor, and CD34, in cells expanded on polyurethane/pyrrole compared to the polyurethane group (P < .05). As a more general note, it could be hypothesized that the polyurethane/pyrrole blend could improve the angiogenesis potency of rabbit bone marrow mesenchymal stem cells for regenerative purposes.

Electrospun nanofibers based on carboxymethyl cellulose/polyvinyl alcohol as a potential antimicrobial wound dressing.

In this work, citric acid-based quantum dots (CA-QDs) as a novel and safe crosslinked agent was applied in different feeding ratios (5-15 wt%) to synthesize carboxymethyl cellulose/polyvinyl alcohol (CMC/PVA) nanofibers (NFs) for the first time. Colistin (CL) as an antibacterial agent was also loaded (2 w/w%) during the synthesizing process of CMC/PVA electrospun NFs to trigger antimicrobial properties. The morphological, hydrophilic, and mechanical properties of the prepared NFs were fully investigated with different techniques. The electrospun NFs with crosslinking ratios of 10 wt% CA-QDs revealed appropriate mechanical properties. According to cell culture data, the prepared NFs demonstrated good cytocompatibility against HFF-1 cells (over 80% cell viability). Remarkably, CL-loaded NFs showed desired antibacterial efficacy against S. aureus, E. coli, K. pneumoniae, and P. aeruginosa with 1.0-1.4, 1.3-1.4, 0.8-1.0, and 1.3-1.5 cm inhibition zones, respectively. These outcomes suggested that the fabricated NFs can be useful as wound healing scaffolds.

Sildenafil citrate-loaded targeted nanostructured lipid carrier enhances receptivity potential of endometrial cells via LIF and VEGF upregulation.

The main objective of this research is to prepare sildenafil citrate (SC)-loaded arginyl-glycyl-aspartic acid (RGD)-containing nanostructured lipid carrier (SC-loaded NLC-RGD) and evaluate their effects on the receptivity potential of endometrial cells. Hot homogenization method was used to prepare SC-loaded NLC-RGD. Then, size, drug encapsulation, and morphology of prepared nanoparticles were studied by photon correlation spectroscopy technic, ultrafiltration method, and scanning electron microscopy, respectively. Subsequently, the influence of SC-loaded NLC-RGD on endometrial receptivity was evaluated by in vitro implantation assay. Finally, expression of vascular endothelial growth factor (VEGF), leukemia inhibitory factor (LIF), and integrin beta 3 (as endometrial receptivity markers) was assessed in SC-loaded NLC-RGD-treated endometrial cells by reverse transcription polymerase chain reaction (RT-PCR). Particles with a nano-size diameter (92.7 nm), appropriate polydispersity index (0.21), spherical morphology, and acceptable loading efficiency were prepared. In vitro implantation assay showed that SC, SC-loaded NLC, and SC-loaded NLC-RGD improve the rate of endometrial attachment potential by 1.6 ± 0.4, 1.7 ± 0.3, and 2.3 ± 0.3 times, respectively. Analysis of RT-PCR results showed the enhancing mRNA of LIF and VEGF in SC-treated endometrial cells. Results also confirmed the higher influence of SC-loaded NLC-RGD on gene expression patterns in comparison to SC. Using NLC-RGD as a carrier to deliver SC to endometrial cells is an effective approach to improve endometrial receptivity. Upregulation of LIF and VEGF is the probable mechanism by which SC enhances the endometrial receptivity potential.

Tissue-specific defense and thermo-adaptive mechanisms of soybean seedlings under heat stress revealed by proteomic approach.

A comparative proteomic approach was employed to explore tissue-specific protein expression patterns in soybean seedlings under heat stress. The changes in the protein expression profiles of soybean seedling leaves, stems, and roots were analyzed after exposure to high temperatures. A total of 54, 35, and 61 differentially expressed proteins were identified from heat-treated leaves, stems, and roots, respectively. Differentially expressed heat shock proteins (HSPs) and proteins involved in antioxidant defense were mostly up-regulated, whereas proteins associated with photosynthesis, secondary metabolism, and amino acid and protein biosynthesis were down-regulated in response to heat stress. A group of proteins, specifically low molecular weight HSPs and HSP70, were up-regulated and expressed in a similar manner in all tissues. Proteomic analysis indicated that the responses of HSP70, CPN-60 beta, and ChsHSP were tissue specific, and this observation was validated by immunoblot analysis. The heat-responsive sHSPs were not induced by other stresses such as cold and hydrogen peroxide. Taken together, these results suggest that to cope with heat stress soybean seedlings operate tissue-specific defenses and adaptive mechanisms, whereas a common defense mechanism associated with the induction of several HSPs was employed in all three tissues. In addition, tissue-specific proteins may play a crucial role in defending each type of tissues against thermal stress.

Cancer stem cells-emanated therapy resistance: Implications for liposomal drug delivery systems.

It is verified that failure in cancer therapy by conventional chemotherapeutic agents arise from cancer heterogeneity. That, a small subpopulation of cancer cells known as "cancer stem cells" (CSCs) are shown to be responsible for deriving clonal heterogeneity/diversity in tumors, which render them resistant to conventional treatment regimes. So far, efficient targeted cancer therapy by nanotechnology-based drug delivery approaches is well established. Among various introduced nanocarriers, the non-toxic nature and biocompatibility of liposome make it highly desirable for human studies. In addition, liposomal nanocarriers can be used to protect entrapped therapeutic agents against chemical and biological degradation, improve solubility of the encapsulated drugs, provide sustained drug release, extend in vivo half-life, reduce side effects, improve drug pharmacokinetic and pharmacodynamic profiles, reduce drug dosage and administration frequency. Further, multifunctional liposomes can be envisioned that are simultaneously loaded with different theranostics and chemically-modified with different tumor-specific surface ligands for targeted therapy. Such versatile nanocarrier can influence the physicochemical characteristics, immunological mechanisms, and uptake mechanisms following systemic delivery. Other strategies to improve tumor-specific tropism include delivery systems involving immune cells or their modulators. Here, we describe mechanisms by which CSC can promote drug resistance to impair the efficacy of cancer therapies. Then, we summarize the implication of each of these mechanisms as potential therapeutics ways to overcome the therapeutically-resistant CSCs. Further, we discuss the status, therapeutic potential and prospect of different liposomal drug delivery systems in overcoming CSC drug resistance in the clinic.

Chrysin-nanoencapsulated PLGA-PEG for macrophage repolarization: Possible application in tissue regeneration.

The purpose of this study was to investigate the efficiency of a natural flavonoid, Chrysin (Chr), encapsulated in PLGA-PEG nanoparticles (NPs) for the modulation of macrophage polarity from the pro-inflammatory M1 to anti-inflammatory M2 phenotype. The synthetized NPs were characterized using FTIR, DLS and FE-SEM. MTT assay was used to assess the toxicity of different concentration of Chr-encapsulated NPs on LPS/IFN-γ stimulated peritoneal exudate macrophages. To investigate the repolarization efficiency of Chr-encapsulated NPs, real-time PCR was applied to measure M1 (iNOS and SOCS3) and M2 (Arg1 and Fizz) markers expression. Also, the relative mRNA and protein expression levels of pro-inflammatory cytokines including IL-6, IL-1ß and TNF-α were investigated in M1 macrophages treated with Chr-encapsulated NPs. Findings revealed that the Chr-encapsulated NPs with spherical shape and an average diameter of 235 nm were considerably less toxic to the macrophages. Additionally, the nano-formulated Chr efficiently showed a reduction in M1 markers and an increase in M2 markers levels than free Chr. Furthermore, macrophage phenotype switching by PLGA-PEG encapsulated Chr NPs significantly suppressed LPS/IFN-γ induced inflammation by a remarkable reduction in pro-inflammatory cytokine levels, TNF-α, IL-1ß, and IL-6. Convincingly, the results revealed that PLGA-PEG encapsulated Chr based drug delivery system might be introduced into biomaterials to fabricate bioactive smart multifunctional nanocomposites with macrophage repolarization activities for regenerative medicine purposes.

Characterization of calnexin in soybean roots and hypocotyls under osmotic stress.

Calnexin is an endoplasmic reticulum-localized molecular chaperone protein which is involved in folding and quality control of proteins. To evaluate the expression of calnexin in soybean seedlings under osmotic stress, immunoblot analysis was performed using a total membrane protein fraction. Calnexin constantly accumulated at an early growth stage of soybean under normal growth conditions. Expression of this protein decreased in 14-day-old soybean roots when treated with 10% polyethylene glycol for 2 days. Other abiotic stresses such as drought, salinity, cold as well as abscisic acid treatment, similarly reduced accumulation of calnexin and this reduction was correlated with reduction in root length in soybean seedlings under abiotic stresses. When compared between soybean and rice, calnexin expression was not changed in rice under abiotic stresses. Using Flag-tagged calnexin, a 70 kDa heat shock cognate protein was identified as an interacting protein. These results suggest that osmotic or other abiotic stresses highly reduce accumulation of the calnexin protein in developing soybean roots. It is also suggested that calnexin interacts with a 70 kDa heat shock cognate protein and probably functions as molecular chaperone in soybean.

Proteomics approach for identifying osmotic-stress-related proteins in soybean roots.

Osmotic stress can endanger the survival of plants. To investigate the mechanisms by which plants respond to osmotic stress, protein profiles from soybean plants treated with polyethylene glycol (PEG) were monitored by a proteomics approach. Treatment with 10% aqueous PEG reduced the lengths of roots and hypocotyls of soybean seedlings. Proteins from soybean roots were separated by two-dimensional polyacrylamide gel electrophoresis, and 415 proteins were detected by Coomassie brilliant blue staining. Thirty-seven proteins changed by PEG treatment were analyzed using Edman sequencing and peptide-mass fingerprinting method and this group included proteins involved in disease/defense. Seven proteins were selected for further experiments using the results of cluster analysis and statistical analysis of the abundance change. A comparison with the effects of other abiotic stresses showed that caffeoyl-CoA-O-methyltransferase and 20S proteasome alpha subunit A were decreased and increased by abiotic stresses, respectively. Expression analyses of these transcripts were also changed by PEG treatment. Caffeoyl-CoA-O-methyltransferase and 20S proteasome alpha subunit A may control the sensitivity of several regulatory genes specific to short exposure to osmotic stress.