Takashi Ushida

Development of biodegradable porous scaffolds for tissue engineering

Abstract Three-dimensional biodegradable porous scaffolds play an important role in tissue engineering. A new method of preparing porous scaffolds composed of synthetic biodegradable polymers was developed by combining porogen leaching and freeze-drying techniques using preprepared ice particulates as the porogen material. The pore structures of the polymer sponges could be manipulated by controlling processing variables such as the size and weight fraction of the ice particulates and the polymer concentration. The synthetic polymer sponges were further hybridized with collagen microsponges to prepare biodegradable hybrid porous sponges of synthetic polymer and collagen. The collagen microsponges were formed in the pores of synthetic polymer sponges. The hybrid sponges exhibited the advantages of both the synthetic polymers and collagen. Hybrid sponges of synthetic polymer, collagen, and inorganic hydroxyapatite were developed by depositing hydroxyapatite particulates on the surfaces of the collagen microsponges in the synthetic polymer–collagen sponges. The use of synthetic polymer sponge as a mechanical skeleton facilitated the formation of these hybrid sponges into desired shapes, contributed good mechanical strength and handling, while the collagen and hydroxyapatite facilitated cell seeding and promoted cell interaction.

A biodegradable hybrid sponge nested with collagen microsponges.

A biodegradable hybrid sponge of poly(DL-lactic-co-glycolic acid) (PLGA) and collagen was fabricated by forming microsponges of collagen in the pores of PLGA sponge. Observation of the PLGA-collagen hybrid sponge by scanning electron microscopy (SEM) showed that microsponges of collagen with interconnected pore structures were formed in the pores of PLGA sponge. The hybrid structure further was confirmed by scanning electron microscopy-electron probe microanalysis (SEM-EPMA), and elemental nitrogen was detected in the microsponges of collagen and on the pore surfaces of PLGA, but not in cross-sections of PLGA regions. The formation of collagen microsponges was dependent on collagen concentration, the effective range of which was from 0.1 to 1.5 (w/v) %. The mechanical strength of the hybrid sponge was higher than that of either PLGA or collagen sponges, in both dry and wet states. The wettability with water was improved by hybridization with collagen, which facilitated cell seeding in the hybrid sponge. Mouse fibroblast L929 cells attached well and spread on the surfaces of the microsponges of collagen in the hybrid sponge. The distribution of cells was spatially uniform throughout the hybrid sponge. Use of the PLGA sponge as a skeleton facilitated formation of the hybrid sponge into desired shapes with high mechanical strength while collagen microsponges contributed good cell interaction and hydrophilicity.

Hydrostatic fluid pressure enhances matrix synthesis and accumulation by bovine chondrocytes in three-dimensional culture

Monolayer cell cultures and cartilage tissue fragments have been used to examine the effects of hydrostatic fluid pressure (HFP) on the anabolic and catabolic functions of chondrocytes. In this study, bovine articular chondrocytes (bACs) were grown in porous three‐dimensional (3‐D) collagen sponges, to which constant or cyclic (0.015 Hz) HFP was applied at 2.8 MPa for up to 15 days. The effects of HFP were evaluated histologically, immunohistochemically, and by quantitative biochemical measures. Metachromatic matrix accumulated around the cells within the collagen sponges during the culture period. There was intense intracellular, pericellular, and extracellular immunoreactivity for collagen type II throughout the sponges in all groups. The incorporation of [35S]‐sulfate into glycosaminoglycans (GAGs) was 1.3‐fold greater with constant HFP and 1.4‐fold greater with cyclic HFP than in the control at day 5 (P < 0.05). At day 15, the accumulation of sulfated‐GAG was 3.1‐fold greater with constant HFP and 2.7‐fold with cyclic HFP than the control (0.01). Quantitative immunochemical analysis of the matrix showed significantly greater accumulation of chondroitin 4‐sulfate proteoglycan (C 4‐S PG), keratan sulfate proteoglycan (KS PG), and chondroitin proteoglycan (chondroitin PG) than the control (P < 0.01). With this novel HFP culture system, 2.8 MPa HFP stimulated synthesis of cartilage‐specific matrix components in chondrocytes cultured in porous 3‐D collagen sponges. J. Cell. Physiol. 193: 319–327, 2002.

TISSUE ENGINEERING OF CARTILAGE USING A HYBRID SCAFFOLD OF SYNTHETIC POLYMER AND COLLAGEN

A biodegradable hybrid scaffold of synthetic polymer, poly (DL-lactic-co-glycolic acid) (PLGA), and naturally derived polymer, collagen, was prepared by forming collagen microsponges in the pores of PLGA sponge. This was then used as the three-dimensional scaffold for tissue engineering of bovine articular cartilage, both in vitro and in vivo. In vitro studies show that hybridization with collagen facilitated cell seeding in the sponge and raised seeding efficiency. Chondrocytes adhered to the collagen microsponges, where they proliferated and secreted extracellular matrices with time, filling the space within the sponge. Hematoxylin and eosin staining revealed that most of the chondrocytes after 4 weeks of culture, and almost all cell types after 6 weeks of culture, maintained their phenotypically rounded morphology. While new tissue formed, the scaffold degraded and lost almost 36.9% of its original weight after 10 weeks. Subcutaneous implantation studies in nude mice demonstrated more homogeneous tissue formation in hybrid sponge than in PLGA sponge. The new tissue formed maintained the original shape of the hybrid sponge. The synthetic PLGA sponge, serving as a skeleton, facilitated easy formation into desired shapes and provided appropriate mechanical strength to define the ultimate shape of engineered tissue. Incorporation of collagen microsponges facilitated cell seeding and homogeneous cell distribution and created a favorable environment for cellular differentiation. The hybrid sponge could therefore represent a promising candidate as a three-dimensional scaffold for articular cartilage tissue engineering.

Preparation of poly(L-lactic acid) and poly(DL-lactic-co-glycolic acid) foams by use of ice microparticulates.

Biodegradable foams of poly(L-lactic acid) (PLLA) and poly(DL-lactic-co-glycolic acid) (PLGA) for tissue engineering were fabricated by a porogen-leaching technique using ice microparticulates as the porogen material. PLLA or PLGA solution in chloroform was mixed with ice microparticulates. The mixtures were frozen by being placed in molds in liquid nitrogen and freeze-dried to form the foams. Scanning electron microscopic observation of the PLLA and PLGA foams showed that evenly distributed and interconnected pore structures were formed in these foams. The porosity and surface area of the foams increased with an increase in the weight fraction of the ice microparticulates, while the median pore size remained unchanged. The pore structures of the foams could be manipulated by controlling processing variables such as the size and weight fraction of the ice microparticulates and polymer concentration.

Translational Suppression of Atrophic Regulators by MicroRNA-23a Integrates Resistance to Skeletal Muscle Atrophy

Muscle atrophy is caused by accelerated protein degradation and occurs in many pathological states. Two muscle-specific ubiquitin ligases, MAFbx/atrogin-1 and muscle RING-finger 1 (MuRF1), are prominently induced during muscle atrophy and mediate atrophy-associated protein degradation. Blocking the expression of these two ubiquitin ligases provides protection against muscle atrophy. Here we report that miR-23a suppresses the translation of both MAFbx/atrogin-1 and MuRF1 in a 3′-UTR-dependent manner. Ectopic expression of miR-23a is sufficient to protect muscles from atrophy in vitro and in vivo. Furthermore, miR-23a transgenic mice showed resistance against glucocorticoid-induced skeletal muscle atrophy. These data suggest that suppression of multiple regulators by a single miRNA can have significant consequences in adult tissues.

The effect of substrate microtopography on focal adhesion maturation and actin organization via the RhoA/ROCK pathway

Recently, a growing number of reports have reported that micro- or nanoscale topography enhances cellular functions such as cell adhesion and stem cell differentiation, but the mechanisms responsible for this topography-mediated cell behavior are not fully understood. In this study, we examine the underlying processes and mechanisms behind specific topography-mediated cellular functions. Formation of focal adhesions (FA) was studied by culturing cells on different kinds of topographies, including a flat surface and surfaces with a micropatterned topography (2 μm lattice pattern with 3 μm intervals). We found that the formation and maturation of focal adhesions were highly dependent on the topography of the substrate although the shape, morphology and spreading of cells on the different substrates were not significantly affected. Focal adhesion maturation and actin polymerization were also promoted in cells cultured on the micropatterned substrate. These differences in cell adhesion led us to focus on the Rho GTPases, RhoA and downstream pathways since a number of reports have demonstrated that RhoA-activated cells have highly enhanced focal adhesions and actin activation such as polymerization. By inhibiting the Rho-associated kinase (ROCK) and downstream myosin II, we found that the FA formation, actin organization, and FAK phosphorylation were dramatically decreased. The topographical dependency of FA formation was also highly decreased. These results show that the FA formation and actin cytoskeleton organization of cells on the microtopography is regulated by the RhoA/ROCK pathway.

Poly(DL‐lactic‐co‐glycolic acid) sponge hybridized with collagen microsponges and deposited apatite particulates

A novel three-dimensional porous scaffold has been developed for bone tissue engineering by hybridizing synthetic poly(DL-lactic-co-glycolic acid) (PLGA), naturally derived collagen, and inorganic apatite. First, a porous PLGA sponge was prepared. Then, collagen microsponges were formed in the pores of the PLGA sponge. Finally, apatite particulates were deposited on the surfaces of the collagen microsponges in the pores of PLGA sponge. The PLGA-collagen sponge served as a template for apatite deposition, and the deposition was accomplished by alternate immersion of PLGA-collagen sponge in CaCl(2) and Na(2)HPO(4) aqueous solutions and centrifugation. The deposited particulates were small and scarce after one cycle of alternate immersion. Their number and size increased with the number of alternate immersion cycles. The surfaces of collagen microsponges were completely covered with apatite after three cycles of alternate immersion. The porosity of the hybrid sponge decreased gradually as the number of alternate immersion increased. Energy-dispersive spectroscopy analysis and X-ray diffraction spectra showed that the calcium-to-phosphorus molar ratio of the deposited particulates and the level of crystallinity increased with the number of alternate immersion cycles, and became almost the same as that of hydroxyapatite after four cycles of alternate immersion. The deposition process was controllable. Use of the PLGA sponge as a mechanical skeleton facilitated formation of the PLGA-collagen-apatite hybrid sponge into desired shapes and collagen microsponges facilitated the uniform deposition of apatite particulates throughout the sponge. The PLGA-collagen-apatite hybrid sponge would serve as a useful three-dimensional porous scaffold for bone tissue engineering.

Redifferentiation of dedifferentiated bovine chondrocytes when cultured in vitro in a PLGA: collagen hybrid mesh

Bovine articular chondrocytes dedifferentiated and lost their ability to express articular cartilage‐specific extracellular matrices such as type II collagen and aggrecan when cultured in a culture flask during in vitro multiplication. A poly(DL‐lactic‐co‐glycolic acid) (PLGA)–collagen hybrid mesh was prepared and used to redifferentiate the dedifferentiated cells. The two passaged dedifferentiated chondrocytes were seeded in a PLGA–collagen hybrid mesh and cultured in vitro in Dulbeccos modified Eagles medium containing 10% fetal bovine serum. The cells adhered to the hybrid mesh, distributed evenly, and proliferated to fill the spaces in the scaffold. The gene expression of type I collagen, type II collagen, and aggrecan was analyzed after the cells were cultured in the hybrid mesh for 2–12 weeks. The expression of the gene encoding type I collagen was downregulated, whereas those of type II collagen and aggrecan were upregulated. Histological examination by hematoxylin–eosin and safranin O/fast green staining indicates that the cells regained their original round morphology. In addition, a homogeneous distribution of articular cartilage extracellular matrices was detected around the cells. These results suggest redifferentiation of the differentiated chondrocytes in the hybrid mesh. The hybrid mesh, which facilitated the redifferentiation of the dedifferentiated multiplied chondrocytes, would be an effective scaffold for the assembly of cells to regenerate three‐dimensional cartilaginous tissue.

Use of isolated mature osteoblasts in abundance acts as desired-shaped bone regeneration in combination with a modified poly-DL-lactic-co-glycolic acid (PLGA)-collagen sponge

Controlled regeneration of bone or cartilage has recently begun to facilitate a host of novel clinical treatments. An osteoblast line, which we isolated is able to form new bone matrix in vivo within 2 days and exhibits a mature osteoblast phenotype both in vitro and in vivo. Using these cells, we show that cuboidal bones can be generated into a predesigned shaped‐bone with high‐density bone trabeculae when used in combination with a modified poly‐DL‐lactic‐co‐glycolic acid (PLGA)‐collagen sponge. PLGA coated with collagen gel serves as a good scaffold for osteoblasts. These results indicate that mature osteoblasts, in combination with a scaffold such as PLGA‐collagen sponge, show promise for use in a custom‐shaped bone regeneration tool for both basic research into osteogenesis and for development of therapeutic applications.