Novel Hot Melt Extruded Matrices of Hydroxypropyl Cellulose and Amorphous Felodipine-Plasticized Hydroxypropyl Methylcellulose as Controlled Release Systems.

Hydroxypropyl methylcellulose (HPMC) is a hydrophilic retarding-release polymer with the limited application in hot melt extrusion (HME) due to its high glass transition temperature (Tg 181-191°C) and melt viscosity. The aim of this study is to develop hot melt extruded matrices using hydroxypropyl cellulose (HPC) and felodipine (FLDP) with HPMC for controlled release and explore the relations of their specialty, processability, and structure with the product properties. Results showed that FLDP/HPCEF/HPMC can be extruded at 160°C with torques not more than 0.5 N·m. The extruded matrices of FLDP/HPCEF/HPMCK15M (10:45:45 and 30:35:35) achieved the controlled release for 24 h. Rheological behaviors demonstrated that HPCEF and FLDP were miscible with HPMCK15M, attaining maximum 30% FLDP soluble in the molten mixtures. HPCEF and FLDP decreased the complex viscosity and plasticized HPMCK15M to improve the extrusion processing. DSC and FT-IR indicated that the molten soluble FLDP was amorphous in the extruded matrices by hydrogen bonding with HPCEF/HPMCK15M. SEM/energy-dispersive X-ray microanalysis illustrated that the microstructure of extrudates was surface dense and interior loose, and FLDP was homogenously dispersed. Three-point bending test revealed that the plasticizers of HPCEF and FLDP contributed differently to the mechanical properties. HPCEF decreased the flexural modulus of HPMCK15M while that of HPCEF/HPMCK15M was increased by FLDP. Besides controlled release, low moisture absorption and enhanced stability were also the correlated achievements. Therefore, HPCEF-combined poorly water-soluble drugs to plasticize HPMCK15M provide an alternative novel potential approach to realize the controlled-release delivery via HME.

Polyvinyl alcohol/collagen composite scaffold reinforced with biodegradable polyesters/gelatin nanofibers for adipose tissue engineering.

Breast cancer has become the most diagnosed cancer type, endangering the health of women. Patients with breast resection are likely to suffer serious physical and mental trauma. Therefore, breast reconstruction becomes an important means of postoperative patient rehabilitation. Polyvinyl alcohol hydrogel has great potential in adipose tissue engineering for breast reconstruction. However, its application is limited because of the lack of bioactive factors and poor structural stability. In this study, we prepared biodegradable polylactic acid-glycolic acid copolymer/polycaprolactone/gelatin (PPG) nanofibers. We then combined them with polyvinyl alcohol/collagen to create tissue engineering scaffolds to overcome limitations. We found that PPG fibers formed amide bonds with polyvinyl alcohol/collagen scaffolds. After chemical crosslinking, the number of amide bonds increased, leading to a significant improvement in their mechanical properties and thermal stability. The results showed that compared with pure PVA scaffolds, the maximum compressive stress of the scaffold doped with 0.9 g nanofibers increased by 500 %, and the stress loss rate decreased by 40.6 % after 10 cycles of compression. The presence of natural macromolecular gelatin and the changes in the pore structure caused by nanofibers provide cells with richer and more three-dimensional adsorption sites, allowing them to grow in three dimensions on the scaffold. So, the hydrogel scaffold by reinforcing polyvinyl alcohol hydrogel with PPG fibers is a promising breast reconstruction method.

Bile acid transporter mediated STC/Soluplus self-assembled hybrid nanoparticles for enhancing the oral drug bioavailability.

The nano-particulate system for oral delivery faces a big challenge across the gastrointestinal bio-barriers. The aim was to explore the potential applications of bile acid transporter mediated the self-assembled hybrid nanoparticles (SHNPs) of sodium taurocholate (STC) and polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol (Soluplus) for augmenting the oral delivery of poorly water-soluble drugs. Felodipine (FLDP) was chosen as a model drug. The self-assembly of STC with Soluplus to load FLDP and the microstructure of the SHNPs were confirmed using molecular simulation, STC determination by high performance liquid chromatography (HPLC) and transmission electron microscope. Results showed that STC was integrated with Soluplus on the surface of nanoparticles by hydrophobic interactions. The permeability of FLDP loaded STC/Soluplus SHNPs was STC dependent in the ileum, which was inhibited by the higher concentrations of STC and the inhibitor of apical sodium-dependent bile acid transporter (ASBT). STC/Soluplus (1:9) SHNPs significantly improved the drug loading of FLDP, achieved the highest permeability of FLDP and realized 1.6-fold of the area under the curve (AUC) of Soluplus self-assembled nanoparticles (SNPs). A water-quenching fluorescent probe P4 was loaded into the STC/Soluplus SHNPs, which verified that the SHNPs were transferred intactly across the ileum. In conclusion, STC/Soluplus SHNPs via ASBT are a potential strategy for enhancing the oral bioavailability of poorly water-soluble drugs.

Biocompatible nanocomposite of TiO2 incorporated bi-polymer for articular cartilage tissue regeneration: A facile material.

The development and design of polymeric hydrogels for articular cartilage tissue engineering have been a vital biomedical research for recent days. Organic/inorganic combined hydrogels with improved surface activity have shown potential for the repair and regeneration of hard tissues, but have not been broadly studied for articular cartilage tissue engineering applications. In this work, bi-polymeric hydrogel composite was designed with the incorporation some quantities of stick-like TiO2 nanostructures for favorable surface behavior and enhancement of osteoblast adhesions. The microscopic investigations clearly exhibited that the stick-like TiO2 nanostructured materials are highly inserted into the PVA/PVP bi-polymeric matrix, due to the long-chain PVA molecules are promoted to physical crosslinking density in hydrogel network. The results of improved surface topography of hydrogel matrixes show that more flatted cell morphologies and enhanced osteoblast attachment on the synthesized nanocomposites. The crystalline bone and stick-like TiO2 nanocomposites significantly improved the bioactivity via lamellipodia and filopodia extension of osteoblast cells, due to its excellent intercellular connection and regulated cell responses. Consequently, these hydrogel has been enhanced the antibacterial activity against Staphylococcus aureus and Escherichia coli bacterial pathogens. Hence it is concluded that these hydrogel nanocomposite with improved morphology, osteoblast behavior and bactericidal activity have highly potential candidates for articular cartilage tissue regeneration applications.

Increased expression of EphA7 in inflamed human dental pulp.

INTRODUCTION: Pulpitis has been associated with abundant inflammatory cells, dilated blood vessels, and thickening nerve fibers histopathologically with or without severe pain clinically. On the basis of EphA7 receptor expression in inflammatory cells, the developing mouse dental pulp, and trigeminal nerve system, EphA7 may possibly be involved in local inflammatory response and sensory innervation of adult dental pulp as well as odontogenic pain conducted through the trigeminal system. The purpose of the study was to analyze the expression of EphA7 gene in healthy and inflamed human dental pulps and to elucidate the roles of EphA7 gene in dental pulp inflammation response and odontogenic pain. METHODS: Twelve healthy controls, 5 acute pulpitis from dental trauma, 21 symptomatic, and 20 asymptomatic irreversible pulpitis human dental pulps were involved in the study. The protein expression, subcellular localization, and mRNA level of EphA7 gene were detected by immunohistochemistry and real-time reverse transcriptase-polymerase chain reaction, respectively. RESULTS: In healthy samples, immunohistochemical staining showed positive EphA7 expression only in vascular endothelial cells and odontoblasts with cytoplasm staining. Under inflammatory conditions, in addition to the above cells, EphA7 staining began to occur in fibroblasts, nerve fiber tissues, and inflammatory cells. Compared with healthy samples, EphA7 expressions at both mRNA and protein levels increased significantly in acute and irreversible pulpitis samples. In asymptomatic irreversible pulpitis samples, EphA7 expressions were significantly lower than those in symptomatic ones but still higher than those in healthy ones. There was no significant difference between acute and symptomatic irreversible pulpitis groups. CONCLUSIONS: The results suggest that EphA7 gene may be a marker reflecting inflammatory activity and pain state for human dental pulp.