The use of sonication treatment to decellularize aortic tissues for preparation of bioscaffolds.

A novel decellularization method using sonication treatment is described. Sonication treatment is the combination of physical and chemical agents. These methods will disrupt cell membrane and release cell contents to external environments. The cell removal was facilitated by subsequent rinsing of sodium dodecyl sulfate detergents. Sonication treatment is used in the preparation of complete decellularized bioscaffolds. The aim of this study is to confirm the usefulness of sonication treatment for preparation of biological scaffolds. In this study, samples of aortic tissues are decellularized by sonication treatment at frequency of 170 kHz in 0.1% and 2% sodium dodecyl sulfate detergents for 10-h treatment time. The relation between decellularization and sonication parameters such as dissolved oxygen concentration, conductivity, and pH is investigated. Histological analysis and biomechanical testing is performed to evaluate cell removal efficiency as well as changes in biomechanical properties. Minimal inflammation response elicit by bioscaffolds is confirmed by xenogeneic implantation and immunohistochemistry. Sonication treatment is able to produce complete decellularized tissue suggesting that these treatments could be applied widely as one of the decellularization method.

Fabrication of microstructures in photosensitive biodegradable polymers for tissue engineering applications.

Combining the MEMS technology and biology requirements for tissue engineering, the fabrication processes of microstructured chambers and microchannels made in biodegradable photosensitive polymers are presented. The fabrication processes, based on softlithography are very fast and flexible. Various single and multistepwise microstructures could be achieved using the biodegradable polymers. Microstructures down to 50microm, which are suitable for liver reconstructs, could be fabricated. As the pCLLA acrylate photosensitive polymer has interesting property for implantable bioreactors, that is, its softness, we examined the ability of various mammalian cells to grow and spread on it. With Hep G2 cells, human umbilical blood vessel endothelial cells (HUVEC), 3T3-L1 mouse fibroblasts, static cultures could be successfully performed on single stepwise microstructures. Then, by using this photosensitive biodegradable polymer, a microstructure with simple fluidic channels is fabricated and a perfusion experiment could be carried out. Both cell cultures and perfusion experiments suggested the possibility to use the present photosensitive polymer as microfluidic supports for biodegradable bioreactors for implantation applications.

Development of cone and plate-type rheometer for quantitative analysis of endothelial cell detachment by shear stress.

We developed an apparatus, which has a structure based on a cone and plate-type rheometer, to facilitate quantitative analysis of the detachment process of endothelial cells (EC) from diverse materials including 3-dimensional scaffolds such as plate, membrane and porous-shaped materials. As an artificial vascular model, a material inoculated with EC to a polycarbonate membrane coated with laminin was prepared. In consequence, reduced cell number, medium volume, and material size was enough to evaluate cell detachment from various materials by shear stress in our system. When shear stress was loaded to a material with EC, the ratio retained of initially inoculated cells decreased with time. Increase of magnitude of shear stress also decreased the ratio. We conclude that our apparatus could analyze quantitatively detachment of EC with ease for screenings to find materials that enhance adhesive force of EC. To produce artificial blood vessels with small diameter, our apparatus could become a useful instrument.

Formation of human fibroblast aggregates (spheroids) by rotational culture.

In the current study, we attempted to form aggregates of fibroblasts by rotationally shaking, declining fibroblast-material interactions, and augmenting cell-cell interactions. In addition, to promote cell-cell interactions, the medium was supplemented with insulin, dexamethasone, and basic fibroblast growth. Under such improved culture conditions, normal neonatal human dermal fibroblasts formed spheroidal aggregates within 1 day of rotation on a rotational shaker. The aggregates that formed had irregular shapes and were composed from only several cells after 12 h. However, they became nearly spheroidal after 24 h of shaking. The aggregates were approximately 240 microm in diameter. After 36 h of shaking, their shape became more rounded and their surfaces became smoother. No evidence of necrosis in the center of the aggregates was observed, although a small number of dead cells was scattered throughout the aggregates. After 24-36 h, aggregates of normal human fibroblasts were collected and reinoculated onto a scaffold composed of polyglycolic acid. which is used commercially as a scaffold for artificial skin, coated with collagen. The aggregates were successfully trapped to the mesh of polyglycolic acid and became attached within 24 h. Therefore, the aggregates could provide an alternative method for seeding fibroblasts to scaffold for an artificial skin, such as a mesh of polyglycolic acid.

Effect of shear stress on platelet adhesion to expanded polytetrafluoroethylene, a silicone sheet, and an endothelial cell monolayer.

We visualized in real-time platelets adhering to the surface of three representative biomaterials, by using an apparatus consisting of a modified cone and plate rheometer combined with an upright epifluorescence microscope under two shear flows (0.1 and 5.0 dyne/cm2). The materials were expanded polytetrafluoroethylene (ePTFE), silicone sheet, and a monolayer of bovine endothelial cells (ECs) formed on glass, all of which are opaque materials used for artificial blood vessels and medical devices. According to quantitative analysis, the monolayer of ECs formed on glass had better blood compatibility than did either the ePTFE or the silicone sheet under shear flow conditions. Under a shear flow condition of 0.1 dyne/cm2, platelet adhesion was silicone sheet > ePTFE. In contrast, under a shear flow condition of 5.0 dyne/cm2, ePTFE > silicone sheet. These results indicate that the intensity of shear stress could modify the order of hemocompatibility of the materials. Therefore, direct observation of platelet adhesion under shear flow conditions is indispensable for testing and screening biomaterials and for providing a precise quantitative evaluation of platelet adhesion.

Evaluation of cytotoxicity of UHMWPE wear debris.

We established a novel method to investigate the phagocytosis of ultra high molecular weight polyethylene using primary macrophage cells by an inverted cell culture method. Abundant wear debris derived from implant materials are generated in aseptic loosening and are deposited in periprosthetic tissues in which they are phagocytized by mono- and multi-nucleated macrophage like cells. Ultra-high-molecular-weight-polyethylene wear debris generated from different sources namely, from laboratory test wear machine, in vivo methods and from knee and hip simulator were mainly used in this investigation. The cytotoxicity index of the different UHMWPE particles obtained from various sources were compared with that of the PE beads and the control without particles by Alamar Blue and Neutral Red assays. The results showed that the cytotoxicity index was significantly lower for the wear debris from the in vivo experiments than that for other particles. SEM analysis were also done to understand the morphology of the wear debris and polyethylene beads and to confirm the phagocytosis process. The mean diameter of the wear debris obtained from the in vivo experiments as estimated from the imaging analysis of the SEM photographs was found to be the least. The inverted cell culture method may be regarded as one of the good methods to study the phagocytosis of UHMWPE by macrophage cells.

A unique antigenic epitope of human melanoma is carried on the common melanoma glycoprotein gp95/p97.

Analysis of antibodies present in the serum of melanoma patient FD has shown that they detect a unique tumor epitope present only on the autologous melanoma cell line SK-MEL-131. Previous results had shown that the unique FD epitope is carried on a common glycoprotein of approximately 90 kD, widely expressed on melanoma and a few other cell types. We now show by sequential radioimmunoprecipitation and partial amino acid sequencing that this common molecule is a previously recognized melanoma antigen, originally identified by mouse mAbs, designated gp95 or p97 (and also known as melanotransferrin). Thus, FD is the first of the class I (unique) melanoma antigens that has been characterized and related to a known cell surface molecule.

Class 1 (unique) tumor antigens of human melanoma: identification of unique and common epitopes on a 90-kDa glycoprotein.

Antibodies present in the serum of melanoma patient FD detect an antigenic determinant (FD) restricted to the autologous melanoma cell line SK-MEL-131. This cell-surface determinant is carried on a glycoprotein of 90 kDa, designated gp90. Mice were immunized with a partially purified preparation of gp90 derived from SK-MEL-131 clone 1.5, and three murine hybridomas (KF23, KF26, and KF104) secreting monoclonal antibodies (mAbs) detecting this antigen have been generated. Sequential immunoprecipitation experiments demonstrate that the three mAbs and human FD serum react with the same gp90 species. The mAbs, in contrast to FD serum, react with a broad range of cultured cells in assays for cell-surface antigens and immunoprecipitate a gp90 component from radiolabeled extracts of these cells, including autologous FD B cells. We conclude that gp90 from SK-MEL-131 has two types of determinants: restricted (detected by FD serum) and common (detected by the mouse mAbs). gp90 molecules from cell lines other than SK-MEL-131 carry only the common determinant(s). Immunoperoxidase analysis of frozen tissue sections with mAb KF23 demonstrated a restricted gp90 expression in normal tissues (capillary endothelial cells, duct epithelium in sweat glands, breast, and pancreas). Melanomas and sarcomas showed strong gp90 expression, suggesting up-regulation of gp90 synthesis in certain human cancers.