Hyaluronan microenvironment enhances cartilage regeneration of human adipose-derived stem cells in a chondral defect model.

Hyaluronan (HA) is an important extracellular matrix component in the early stage of chondrogenesis. This study aimed to investigate the application of an HA microenvironment for human adipose-derived stem cells (hADSCs)-based articular cartilage regeneration. HA-enriched fibrin (HA/Fibrin) hydrogels were synthesized and characterized for use as HA microenvironments. The cell viability and chondrogenic gene expression of hADSCs cultured in HA/Fibrin (HA/Fibrin/hADSC) and Fibrin (Fibrin/hADSC) hydrogels were tested in vitro. A chondral defect created in osteochondral core explants ex vivo was used to test chondral defect regeneration by HA/Fibrin/hADSC or Fibrin/hADSC hydrogels. The results showed that HA/Fibrin hydrogels exhibited an increased swelling ratio and matrix stiffness and a smoother surface with more interconnected pores than in Fibrin hydrogels. The viability of hADSCs in HA/Fibrin/hADSC hydrogels was not altered, but they exhibited higher chondrogenic gene expression than those in Fibrin/hADSC hydrogels. For chondral defect regeneration, the HA/Fibrin/hADSC hydrogels exhibited the most cartilaginous tissue neo-formation, chondral integration and sGAG content in the surrounding tissue. This study demonstrated that an HA microenvironment enhances hADSC-mediated cartilage regeneration in chondral defects and thus may be used for ADSC-based articular cartilage tissue engineering.

The stiffness of a crosslinked hyaluronan hydrogel affects its chondro-induction activity on hADSCs.

Matrix stiffness plays an important role in stem cell differentiation. This study reports the synthesis of methacrylated hyaluronan (MeHA) with different degrees of methacrylation, ranging from 15 to 140% per disaccharide unit, which corresponds to a matrix stiffness ranging from 1.5 to 8 KPa. The swelling ratio was inversely proportional to the matrix stiffness, but the water content remained constant at >97% of the hydrogel mass. A fibril-like surface morphology and larger pore size were observed in lyophilized MeHA hydrogel with a lower stiffness. The matrix stiffness also affected the degradability of the MeHA hydrogel, where softer MeHA hydrogels (MeHA15 and MeHA30 ) were completely degraded within 6 days and a stiffer MeHA hydrogel (MeHA140 ) was able to retain ∼25% of its initial mass after 30 days. Subsequently, the crosslinked MeHA hydrogel was used as a scaffold to encapsulate human adipose-derived stem cells (hADSCs). The embedded cells remained viable and expressed ∼11-fold higher levels of aggrecan and 42-fold higher levels of collagen type II in MeHA140 compared with ADSCs cultured in HA-coated wells. In addition, cells grown in MeHA140 exhibited the highest rates of glycosaminoglycan and collagen type II synthesis of ∼5 ng/DNA and 0.4 ng/DNA, respectively. Immunofluorescence staining showed an increase of collagen type II synthesis in MeHA65 , MeHA85 and MeHA140 . This study showed that the matrix stiffness of a hydrogel can be modulated by the degree of methacrylation, thus affecting the efficacy of chondrogenesis in hADSCs. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 808-816, 2018.

Liposomal Encapsulation for Systemic Delivery of Propranolol via Transdermal Iontophoresis Improves Bone Microarchitecture in Ovariectomized Rats.

The stimulatory effects of liposomal propranolol (PRP) on proliferation and differentiation of human osteoblastic cells suggested that the prepared liposomes-encapsulated PRP exerts anabolic effects on bone in vivo. Iontophoresis provides merits such as sustained release of drugs and circumvention of first pass metabolism. This study further investigated and evaluated the anti-osteoporotic effects of liposomal PRP in ovariectomized (OVX) rats via iontophoresis. Rats subjected to OVX were administered with pure or liposomal PRP via iontophoresis or subcutaneous injection twice a week for 12 weeks. Changes in the microarchitecture at the proximal tibia and the fourth lumbar spine were assessed between pure or liposomal PRP treated and non-treated groups using micro-computed tomography. Administration of liposomal PRP at low dose (0.05 mg/kg) via iontophoresis over 2-fold elevated ratio between bone volume and total tissue volume (BV/TV) in proximal tibia to 9.0% whereas treatment with liposomal PRP at low and high (0.5 mg/kg) doses via subcutaneous injection resulted in smaller increases in BV/TV. Significant improvement of BV/TV and bone mineral density (BMD) was also found in the fourth lumbar spine when low-dose liposomal PRP was iontophoretically administered. Iontophoretic low-dose liposomal PRP also elevated trabecular numbers in tibia and trabecular thickness in spine. Enhancement of bone microarchitecture volumes has highlighted that liposomal formulation with transdermal iontophoresis is promising for PRP treatment at the lower dose and with longer duration than its clinical therapeutic range and duration to exhibit optimal effects against bone loss in vivo.

Alternative approach of cell encapsulation by Volvox spheres.

Volvox sphere is a bio-mimicking concept of a biomaterial structure design able to encapsulate chemicals, drugs and/or cells. The aim of this study was to prepare Volvox spheres encapsulating AML12 liver cells and mesenchymal stem cells (MSCs) via a high voltage electrostatic field system. The results demonstrated that AML12 liver cells and MSCs could be successfully encapsulated into the inner spheres and the outer sphere of the Volvox spheres. The improved cell viability of MSCs was achieved by the addition of collagen and polyethylene glycol into the preparation components of the Volvox spheres. Collagen material potentially provides extracellular matrix-like structure for cell adhesion while polyethylene glycol provides a void/loose space for permeability of metabolites. The encapsulated MSCs were able to differentiate into hepatocytes or hepatocyte-like cells and express liver cell markers including albumin, alpha feto-protein and cytokeratin 18. The encapsulated cells secreted albumin to about 140 ng on day 14. Based on these observations, we conclude that Volvox spheres can be used as an alternative approach to encapsulate multiple types of cells, here AML12 hepatocyte cell line and MSCs. Nevertheless, efforts are still needed to improve the viability of the encapsulated cells and increase the differentiation of MSCs into functional liver cells.

Effects of culturing media on hepatocytes differentiation using Volvox sphere as co-culturing vehicle.

Volvox sphere is a unique design to mimic natural volvox consists of a large outer-sphere that contains smaller inner-spheres, which provide three-dimensional (3D) environment to culture cells. The purpose of this study is to co-culture mesenchymal stem cells (MSCs) and AML12 liver cells in Volvox spheres and to evaluate the effects of two media, DMEM and DMEM/F12 on the cultured cells. The results of this study shows that the 3D Volvox sphere can successfully be applied for co-culture of MSCs and AML12 liver cells, and the MSCs are able to differentiate into hepatocyte-like cells expressing hepatocyte-specific markers including albumin (ALB), alpha feto-protein (AFP) and cytokeratin 18 (CK18) mRNA expressions and producing CK18 and ALB proteins. Interestingly, the MSCs expressed higher ALB, AFP and CK18 mRNA expression at the initial 7-day culture by using DMEM, whereas, the MSCs expressed more mRNA expressions from 7-day to 14-day by the usage of DMEM/F12. The result demonstrated that DMEM and DMEM/F12 media could affect MSCs behaviors during a 14-day culture.

Enhanced anti-cancer activity by curcumin-loaded hydrogel nanoparticle derived aggregates on A549 lung adenocarcinoma cells.

To investigate the anti-cancer activity of curcumin-loaded hydrogel nanoparticle derived aggregates on A549 lung adenocarcinoma cells. Curcumin was incorporated with biopolymeric chitosan, gelatin, and hyaluronan nanoparticles using an electrostatic field system. Characteristics of curcumin-loaded aggregates were examined including size and morphology, incorporation efficiency, stability and in vitro release. Treatment effect on A549 cells were assessed with cell viability assay, apoptosis assay, cell cycle analysis, reactive oxygen species detection, and Western blot. Observation from transmission electron microscopy show that the prepared biopolymeric nanoparticles were approximately 3-4 nm in diameter and that the size of the aggregates increased to approximately 26-55 nm after the incorporation of curcumin with the nanoparticles. The incorporation efficiency of curcumin into the chitosan, gelatin, and hyaluronan nanoparticles was 81, 67, and 78 % respectively. The formation of hyaluronan/curcumin and gelatin/curcumin aggregates seems to improve the stability of curcumin drug. The chitosan/curcumin aggregate has a faster release of curcumin than gelatin/curcumin and hyaluronan/curcumin aggregates. Treatment with chitosan/curcumin, gelatin/curcumin and hyaluronan/curcumin aggregates resulted in higher apoptosis rates of 45, 40 and 32 %, respectively, as compared to pure curcumin (less than 20 %) via Annexin V-FITC/PI analysis. Chitosan/curcumin aggregates induce the highest apoptosis effect (indicated by sub-G1 phase). In summary, chitosan/curcumin, gelatin/curcumin, and hyaluronan/curcumin aggregates represent higher anticancer proliferation properties in A549 cells than curcumin alone that exhibit great potential enhancement by either using fewer drugs or a decreased duration.

Characterization and human osteoblastic proliferation- and differentiation-stimulatory effects of phosphatidylcholine liposomes-encapsulated propranolol hydrochloride.

DMPC and DSPC liposomes were prepared via thin film hydration method followed by sonication. Propranolol solution was incorporated into liposomes at hydration stage. TEM images showed the sizes of DSPC and DMPC were around 88 and 137 nm, respectively. The highest encapsulation ratio of propranolol was approximately 70% using DSPC/CHO/OCT liposomes, which release the drug over 60% in 24 h and reached 100% in 48 h. Both propranolol (10⁻8-10⁻6 M) and DSCP liposomes-encapsulated propranolol showed over 1.5-fold increases in the proliferation of human osteoblastic cells hFOB1.19 while differentiation of the cells was approximately doubled by plain and liposomal propranolol, indicating that the stimulatory effects of liposomal propranolol are similar with those of propranolol on human osteoblastic hFOB1.19 cells. The phosphatidylcholine liposomes-encapsulated propranolol prepared in this study potentially possesses anabolic effects in vivo and is also a promising anti-osteoporotic agent in future.

Enhanced apoptotic effects of dihydroartemisinin-aggregated gelatin and hyaluronan nanoparticles on human lung cancer cells.

Recent studies suggest that dihydroartemisinin (DHA), a derivative of artemisinin isolated from the traditional Chinese herb Artemisia annua L., has anticancer properties. Due to poor water solubility, poor oral activity, and a short plasma half-life, large doses of DHA have to be injected to achieve the necessary bioavailability. This study examined increasing DHA bioavailability by encapsulating DHA within gelatin (GEL) or hyaluronan (HA) nanoparticles via an electrostatic field system. Observations from transmission electron microscopy show that DHA in GEL and HA nanoparticles formed GEL/DHA and HA/DHA aggregates that were approximately 30-40 nm in diameter. The entrapment efficiencies for DHA were approximately 13 and 35% for the GEL/DHA and HA/DHA aggregates, respectively. The proliferation of A549 cells was inhibited by the GEL/DHA and HA/DHA aggregates. Fluorescent annexin V-fluorescein isothiocyanate (FITC) and propidium iodide (PI) staining displayed low background staining with annexin V-FITC or PI on DHA-untreated cells. In contrast, annexin V-FITC and PI stains dramatically increased when the cells were incubated with GEL/DHA and HA/DHA aggregates. These results suggest that DHA-aggregated GEL and HA nanoparticles exhibit higher anticancer proliferation activities than DHA alone in A549 cells most likely due to the greater aqueous dispersion after hydrophilic GEL or HA nanoparticles aggregation. These results demonstrate that DHA can aggregate with nanoparticles in an electrostatic field environment to form DHA nanosized aggregates.

The production of volvox spheres and their potential application in multi-drugs encapsulation and release.

Volvox sphere is a bio-mimicking concept of an innovative biomaterial structure of a sphere that contains smaller microspheres which then encapsulate chemicals, drugs and/or cells. The volvox spheres were produced via a high-voltage electrostatic field system, using alginate as the primary material. Encapsulated materials tested in this study include staining dyes, nuclear fast red and trypan blue, and model drugs, bovine serum albumin (BSA) and cytochrome c (CytC). The external morphology of the volvox spheres was observed via electron microscopy whereas the internal structure of the volvox spheres was observed via an optical microscope with the aid of the staining dyes, since alginate is colorless and transparent. The diameter of the microspheres was about 200 to 300 µm, whereas the diameter of the volvox spheres was about 1500 µm. Volvox spheres were durable, retaining about 95% of their mass after 4 weeks. Factors affecting entrapment efficiency, such as temperature and concentration of the bivalent cross-linker, were compared followed by a 7-day in vitro release study. The encapsulation efficiency of CytC within the microspheres was higher at cold (~4°C) and warm (~50°C) temperatures whereas temperature has no obvious effect on the BSA encapsulation. High crosslinking concentration (25% w/v) of calcium chloride has resulted higher entrapment efficiency for BSA but not for CytC. Furthermore, volvox spheres showed a different release pattern of BSA and CytC when compared to microspheres encapsulating BSA and CytC. Despite the fact that the mechanisms behind remain unclear and further investigation is required, this study demonstrates the potential of the volvox spheres for drug delivery.