Time course of de novo adipogenesis in matrigel by gelatin microspheres incorporating basic fibroblast growth factor

Controlled release of basic fibroblast growth factor (bFGF) from gelatin microspheres achieved de novo adipogenesis at the implanted site of a basement membrane extract (Matrigel). Following subcutaneous co-implantation of Matrigel and gelatin microspheres incorporating 0.1 microg of bFGF into the back of mice, adipose tissue was formed at the implanted site after 4 weeks postoperatively although the extent increased with implantation time. Formation of adipose tissue was significantly faster than the co-implantation of Matrigel, and 0.1 microg of free bFGF while a larger volume of the adipose tissue formed was retained 15 weeks later. When measured in Matrigel co-implanted with the gelatin microspheres incorporating bFGF, the number of cells infiltrated into Matrigel increased to a significantly high extent compared with the bFGF co-implantation. Matrigel alone was much less effective in inducing formation of adipose tissue. We conclude that gelatin microspheres incorporating bFGF enable Matrigel to efficiently induce de novo adipogenesis at the implanted site in respect to the formation rate and volume of adipose tissue.     

In situ regeneration of adipose tissue in rat fat pad by combining a collagen scaffold with gelatin microspheres containing basic fibroblast growth factor

This study is an investigation to evaluate in situ adipose tissue regeneration in fat pads. Gelatin microspheres with different water contents were prepared for the controlled release of basic fibroblast growth factor (bFGF). After a collagen sponge scaffold was incorporated by the microspheres containing 0, 0.01, 0.1, 1, and 10 microg of bFGF with or without syngeneic rat preadipocytes (1 x 10(5) cells/site) into a defect of rat fat pad, adipogenesis at the implanted site of scaffold was evaluated histologically. in situ formation of adipose tissue accompanied with angiogenesis was observed in the scaffold implanted with the microspheres containing 1.0 microg of bFGF, although the extent was less at the lower and higher bFGF doses. The in situ formation induced by the microspheres containing bFGF was significantly higher than that induced by free bFGF of the same dose. Adipogenesis was enhanced with time after implantation up to 4 weeks and thereafter leveled off. Such in situ adipogenesis was reproducibly induced by implantation of collagen scaffold incorporating gelatin microspheres containing 1 microg of bFGF, whereas addition of rat syngeneic preadipocytes did not promote the adipogenesis. The degradation of microspheres and the consequent FGF release became faster with an increase in the water content of gelatin microspheres. Less in situ formation of adipose tissue was observed at the lower water content of microspheres, which showed longer-term bFGF release. We conclude that combination of scaffold collagen with an appropriate controlled release of bFGF was essential to achieve the in situ formation of adipose tissue even without preadipocytes.     

Adipose tissue engineering based on human preadipocytes combined with gelatin microspheres containing basic fibroblast growth factor

Gelatin microspheres containing basic fibroblast growth factor (bFGF) were prepared for the controlled release of bFGF. Co-implantation with the gelatin microspheres enabled preadipocytes to induce adipose tissue formation at the implanted site. Preadipocytes isolated from human fat tissue were suspended with the gelatin microspheres containing bFGF and incorporated into a collagen sponge of cell scaffold. Following subcutaneous implantation of the collagen sponge incorporating human preadipocytes, and gelatin microspheres containing 1 microg of bFGF into the back of nude mice, adipose tissue was formed at the implanted site of collagen sponge within 6 weeks postoperatively although the extent depended on the number of preadipocytes transplanted and the bFGF dose. The formation of adipose tissue was significant compared with the implantation of collagen sponge incorporating human preadipocytes and 1 microg of free bFGF. The area of adipose tissue newly formed was increased with the number of preadipocytes transplanted until to 1.0 x 10(5) cells/site and thereafter leveled off. The maximum area was observed at the bFGF dose of 1 microg/site. The area was significantly smaller at the bFGF dose of 0.5 microg/site or larger than 1 microg/site. Immunohistochemical examination indicated that the adipose tissue newly formed was composed of human matured adipocytes. No adipogenesis was observed at the implanted site of collagen sponge incorporating either gelatin microspheres containing bFGF or human preadipocytes and the mixed gelatin microspheres containing bFGF and human preadipocytes. We conclude that combination of gelatin microspheres containing bFGF and preadipocytes with the collagen sponge is essential to achieve tissue engineering of fat tissue.     

Adipose tissue engineering based on the controlled release of fibroblast growth factor-2 in a collagen matrix

Adipose tissue forms when basement membrane extract (Matrigel) and fibroblast growth factor-2 (FGF-2) are added to our mouse tissue engineering chamber model. A mouse tumor extract, Matrigel is unsuitable for human clinical application, and finding an alternative to Matrigel is essential. In this study we generated adipose tissue in the chamber model without using Matrigel by controlled release of FGF-2 in a type I collagen matrix. FGF-2 was impregnated into biodegradable gelatin microspheres for its slow release. The chambers were filled with these microspheres suspended in 60 microL collagen gel. Injection of collagen containing free FGF-2 or collagen containing gelatin microspheres with buffer alone served as controls. When chambers were harvested 6 weeks after implantation, the volume and weight of the tissue obtained were higher in the group that received collagen and FGF-2 impregnated microspheres than in controls. Histologic analysis of tissue constructs showed the formation of de novo adipose tissue accompanied by angiogenesis. In contrast, control groups did not show extensive adipose tissue formation. In conclusion, this study has shown that de novo formation of adipose tissue can be achieved through controlled release of FGF-2 in collagen type I in the absence of Matrigel.     

Photocured, styrenated gelatin-based microspheres for de novo adipogenesis through corelease of basic fibroblast growth factor, insulin, and insulin-like growth factor I

De novo adipose tissue formation appears to proceed via two different biological events: neovascularization and spontaneous accumulation of preadipocytes and subsequent differentiation to mature adipocytes. In this article, we perform accelerated de novo adipose tissue engineering using photocured, styrenated, gelatin-based microspheres (SGMs) with different drug release rates of immobilized angiogenic and adipogenic factors. The concept of this system is to induce neovascularization and migration of endogenous preadipocytes by the rapid delivery of the angiogenic factor basic fibroblast growth factor (bFGF), followed by the proliferation and differentiation of preadipocytes into adipocytes by the prolonged delivery of the adipogenic factors, insulin and insulin-like growth factor I (IGF-I). Bioactive substance-immobilized SGMs with different drug release rates were prepared with different gelatin concentrations. An in vitro study showed the prolonged release of an immobilized model protein and the dependence of drug release rate on gelatin concentration. After the subcutaneous injections of SGMs immobilized with these bioactive substances in different combinations, the formation of masses or clusters of adipocytes was observed in rats. Triglyceride content in the injection site for the group that received bFGF-, insulin-, and IGF-I-immobilized SGMs was significantly higher than that for the group that received insulin- and IGF-I-immobilized SGMs 4 weeks after the injection of microspheres. These results suggest that the system developed here is effective for the de novo formation of adipose tissue as it enables the induction of the two-step biological reaction by single injection.     

Adipogenesis induced by human adipose tissue-derived stem cells

Adipose tissue-derived stem cells (ASCs), including preadipocytes, may play an important role in de novo adipogenesis and are expected to be a useful external source of cells for adipose tissue engineering. In this study, we examined in vivo adipogenesis up to 24 weeks after implantation, induced by human ASCs that were isolated from adipose tissues and expanded in vitro. ASCs proliferated in vitro in the presence of basic fibroblast growth factor (bFGF), and the number of cells increased by more than 1000-fold at the fourth passage. The ability to differentiate into mature adipocytes was maintained up to the third passage. We incorporated designated numbers of third-passage-expanded cells into a type I collagen scaffold and implanted them into the back of nude mice with or without controlled-release bFGF. After the implantation of 2 x 10(6) ASCs with controlled-release bFGF, the greatest cross-sectional surface area of adipose tissue in the scaffold was 1.19 mm(2) at 12 weeks and 2.14 mm(2) at 24 weeks. About 2 x 10(6) ASCs with controlled-release bFGF was the best condition for total adipogenesis. Immunohistochemical analysis with antihuman vimentin antibody showed that the area of human-origin adipose tissue was maximum in the group with 8 x 10(6) ASCs incorporated in a scaffold at both 12 and 24 weeks. The amount of human-origin adipose tissue increased in all groups with implanted ASCs from 12 to 24 weeks. Only trace of human-origin adipose tissue was observed in other groups implanted ASCs. Our results show that human ASCs not only function as progenitor cells for in vivo adipogenesis, but also induce de novo adipogenesis for long period.     

Accelerated tissue regeneration through incorporation of basic fibroblast growth factor-impregnated gelatin microspheres into artificial dermis

The objective of this study was to evaluate the effect of incorporation of basic fibroblast growth factor (bFGF)-impregnated gelatin microspheres into an artificial dermis on the regeneration of dermis-like tissues. When used in the free form in vivo, bFGF cannot induce sufficient wound healing activity, because of its short half-life. Therefore, sustained release of bFGF was achieved by impregnation into biodegradable gelatin microspheres. A radioisotope study revealed that incorporation of bFGF-impregnated gelatin microspheres significantly prolonged in vivo retention of bFGF in the artificial dermis. Artificial dermis with incorporated bFGF-impregnated gelatin microspheres or bFGF in solution was implanted into full-thickness skin defects on the back of guinea pigs (1.5 cm x 1.5 cm) (n = 4). Incorporation of bFGF into the artificial dermis accelerated fibroblast proliferation and capillary formation in a dose-dependent manner. However, the accelerated effects were more significant with the incorporation of bFGF-impregnated gelatin microspheres than with free bFGF at doses of 50 microg or higher. We conclude that the gelatin microsphere is a promising tool to accelerate bFGF-induced tissue regeneration in artificial dermis.     

The role of adipose protein derived hydrogels in adipogenesis

Biomaterials that induce adipogenesis may ultimately serve as alternatives to traditional tissue reconstruction and regeneration techniques. In addition, these materials can provide environments for studying factors that regulate adipogenesis. The present study investigates the potential of adipose-derived matrices to induce adipogenesis in vitro and in vivo. Solutions containing basement membrane proteins and growth factors were extracted from subcutaneous adipose tissue. These extracts could be induced to form gels by either incubating the solutions at 37 degrees C or adjusting the pH to 4.0. The adipose extracts promoted rapid preadipocyte aggregation and formation of lipid-loaded colonies in vitro. Differentiation on adipose-derived gels was greater than tissue culture dishes and the tumor-derived product Matrigel (p < 0.05). Significant adipose formation was observed when adipose-derived gels were implanted around a rat epigastric pedicle bundle. Adipose levels in these gels were significantly greater than Matrigel (p < 0.05). The duration of adipose formation depended on the mechanism for gelling the solutions, with acid gelled matrices having greater adipose levels at 6 weeks than temperature gelled matrices. These adipose-derived hydrogels promote rapid adipogenesis in vitro and in vivo. They may lead to new materials for adipose tissue engineering, and provide an environment for studying cell-matrix interactions in adipogenesis.     

Vascularization into a porous sponge by sustained release of basic fibroblast growth factor

Vascularization into a poly(vinyl alcohol) (PVA) sponge was investigated using basic fibroblast growth factor (bFGF). This growth factor was impregnated into biodegradable gelatin microspheres for its sustained release and then the bFGF-containing microspheres or free bFGF were incorporated into PVA sponges. Following subcutaneous implantation into the back of mice, the bFGF-containing gelatin microspheres induced vascularization in and around the sponge to a significantly greater extent than that of free bFGF from 3 days after implantation. Significant ingrowth of fibrous tissue into the sponge was also observed when bFGF-containing microspheres were added to the sponge in contrast to free bFGF. Tissue ingrowth occurred into the deeper portion of the sponge over time while it accompanied formation of new capillaries. Empty gelatin microspheres had no effect on vascularization and the level of fibrous tissue ingrowth into the sponge was similar to that of the control group. It was concluded that incorporation of gelatin microspheres containing bFGF into the PVA sponge was effective in prevascularization of the sponge pores.     

Neovascularization and bone regeneration by implantation of autologous bone marrow mononuclear cells

We examined whether transplantation of autologous bone marrow mononuclear cells (BM-MNCs) can augment neovascularization and bone regeneration of bone marrow in femoral bone defects of rabbits. Gelatin microspheres containing basic fibroblast growth factor (bFGF) were prepared for the controlled release of bFGF. To evaluate the in vivo effect of implanted BM-MNCs, we created bone defects in the rabbit medial femoral condyle, and implanted into them 5 x 10(6) fluorescent-labeled autologous BM-MNCs together with gelatin microspheres containing 10 microg bFGF on an atelocollagen gel scaffold. The four experimental groups, which were Atelocollagen gel (Col), Col + 5 x 10(6) BM-MNCs, Col + 10 microg bFGF, and Col + 5 x 10(6) BM-MNCs + 10 microg bFGF, were implanted into the sites of the prepared defects using Atelocollagen gel as a scaffold. The autologous BM-MNCs expressed CD31, an endothelial lineage cell marker, and induced efficient neovascularization at the implanted site 2 weeks after implantation. Capillary density in Col + BM-MNCs + bFGF was significantly large compared with other groups. This combination also enhanced regeneration of the bone defect after 8 weeks to a significantly greater extent than either BM-MNCs or bFGF on their own. In summary, these findings demonstrate that a combination of BM-MNCs and bFGF gelatin hydrogel enhance the neovascularization and the osteoinductive ability, resulting in bone regeneration.     

Vascularization into a porous sponge by sustained release of basic fibroblast growth factor

Vascularization into a poly(vinyl alcohol) (PVA) sponge was investigated using basic fibroblast growth factor (bFGF). This growth factor was impregnated into biodegradable gelatin microspheres for its sustained release and then the bFGF-containing microspheres or free bFGF were incorporated into PVA sponges. Following subcutaneous implantation into the back of mice, the bFGF-containing gelatin microspheres induced vascularization in and around the sponge to a significantly greater extent than that of free bFGF from 3 days after implantation. Significant ingrowth of fibrous tissue into the sponge was also observed when bFGF-containing microspheres were added to the sponge in contrast to free bFGF. Tissue ingrowth occurred into the deeper portion of the sponge over time while it accompanied formation of new capillaries. Empty gelatin microspheres had no effect on vascularization and the level of fibrous tissue ingrowth into the sponge was similar to that of the control group. It was concluded that incorporation of gelatin microspheres containing bFGF into the PVA sponge was effective in prevascularization of the sponge pores.     

Contact with existing adipose tissue is inductive for adipogenesis in matrigel

The effect of adipose tissue on inductive adipogenesis within Matrigel (BD Biosciences) was assessed by using a murine chamber model containing a vascular pedicle. Three-chamber configurations that varied in the access to an adipose tissue source were used, including sealed- and open-chamber groups that had no access and limited access, respectively, to the surrounding adipose tissue, and a sealed-chamber group in which adipose tissue was placed as an autograft. All groups showed neovascularization, but varied in the amount of adipogenesis seen in direct relation to their access to preexisting adipose tissue: open chambers showed strong adipogenesis, whereas the sealed chambers had little or no adipose tissue; adipogenesis was restored in the autograft chamber group that contained 2- to 5-mg fat autografts. These showed significantly more adipogenesis than the sealed chambers with no autograft ( p < 0.01). Autografts with 1mg of fat were capable of producing adipogenesis but did so less consistently than the larger autografts. These findings have important implications for adipose tissue engineering strategies and for understanding de novo production of adipose tissue.     

Promoted growth of murine hair follicles through controlled release of basic fibroblast growth factor

This study is an investigation to evaluate how the controlled release of basic fibroblast growth factor (bFGF) affects the hair follicle growth of mice in different hair cycle stages: second anagen and second telogen. bFGF was incorporated into biodegradable gelatin hydrogels for its controlled release. After subcutaneous implantation of gelatin hydrogels incorporating 0, 0.7, 7, and 70 microg of bFGF or injection of 0 and 70 microg of free bFGF into the backs of mice, hair follicle growth was evaluated photometrically and histologically on the basis of three parameters: skin color of the reverse side of the implanted or injected site, skin thickness, and area occupied by hair follicle tissue. For mice in second anagen, the darkness of the reverse side of skin implanted with gelatin hydrogel incorporating 7 microg of bFGF was significantly higher than that of skin injected with 70 microg of bFGF 10 days after bFGF application. Implantation of gelatin hydrogel incorporating bFGF enabled the hair follicles to increase the area occupied in skin tissue to a significantly greater extent than in other groups, whereas no effect on skin thickness was observed. bFGF-free, empty gelatin hydrogels did not affect hair follicle growth. Moreover, hair shaft length was significantly elongated by gelatin hydrogel incorporating 7 microg of bFGF, in marked contrast to other agents. The skin of telogen mice receiving gelatin hydrogel incorporating 7 microg of bFGF did not show any change in darkness of reverse skin side or skin thickness, but a significant increase in the size of hair follicles 10 days later. These results indicate that the controlled release of bFGF positively affects the hair growth cycle of mice.     

Laser Doppler imaging evaluation of adipogenesis after adipose tissue-derived stem cell implantation

We need a better method of assessing adipose tissue formation non-invasively than the current one, which requires resecting tissue samples in vivo. The aim of this study was to establish a system to evaluate adipogenesis using laser Doppler imaging (LDI) to measure subcutaneous microcirculation. CGSs containing adipose stem cells with or without bFGF were implanted in the backs of 30 mice. Once per week after implantation, LDI was used to evaluate blood flow at the implantation site. The implantation sites were resected at 6 weeks, and the tissue was weighed. Six weeks after implantation, LDI showed that mice who received CGS with 1 μg/cm² bFGF had the greatest mean blood flow, and these mice had the heaviest resected specimens, which contained the most newly formed adipose tissue. The findings for LDI and the weight findings were compatible. This study indicates that LDI could be used to assess subcutaneous tissue regeneration in vivo in a real-time, non-invasive manner.     

Endogenous adipocyte precursor cells for regenerative soft-tissue engineering

Subcutaneous injection of reconstituted basement membrane (Matrigel) in combination with basic fibroblast growth factor induces de novo adipogenesis in which endogenous precursor cells invade the artificially formed Matrigel space, proliferate and differentiate to form adipose tissue. Since this adipogenesis offers us a novel approach for soft-tissue reconstruction without transplanting preadipocytes, the early process was examined by optical and electron microscopy. Formation of multiple layers of fibroblast-like cells at the surface of Matrigel implant was the first response of connective tissue. The cells within four to five layers proximal to Matrigel implant acquired a thick cytoplasm and an enlarged nucleus, and they invaded Matrigel space together with endothelial cells which caused neovascularization. Phagocytotic incorporation and digestion of Matrigel components by well-developed lysosomes appeared to be a stimulus of fibroblast-like cells to mature depending on proximity to Matrigel. The fibroblast-like cells often contacted to the outer surface of capillary over a large area and rapidly accumulated lipid droplets. Electron microscopy of the developing adipocytes showed a well-organized smooth endoplasmic reticulum and mitochondria. This investigation thus revealed the characteristics of adipocyte precursor cells, which can be recruited for regenerative engineering of soft tissues.     

Neovascularization effect of biodegradable gelatin microspheres incorporating basic fibroblast growth factor

Biodegradable microspheres were prepared through glutaraldehyde cross-linking of gelatin without using any surfactants as a carrier matrix of basic fibroblast growth factor (bFGF). In the in vitro system, bFGF was sorbed to microspheres of acidic gelatin with an isoelectric point (IEP) of 5.0, but not to those of basic gelatin with an IEP of 9.0. The rate of bFGF sorption to the acidic gelatin microsphere in phosphate-buffered saline solution (pH 7.4) was smaller than that in water. Following incorporation of bFGF into the microspheres at 4 degrees C for 12 h, bFGF release from the bFGF-incorporating microspheres was studied. Approximately 30% of incorporated bFGF was released from the acidic gelatin microsphere within the initial 3 h, followed by no substantial release, whereas the basic gelatin microsphere released almost completely the incorporated bFGF within 1 day. It is likely that when basic bFGF molecules were immobilized to the acidic gelatin constituting microspheres through polyion complexation, they were not readily released under the in vitro nondegradation condition of gelatin. Incorporation of anionic carboxylmethyl cellulose (CMC) into the acidic gelatin microspheres reduced the amount of bFGF desorbed initially. This indicates that the initial burst is ascribed to free bFGF which is not ionically interacted with the acidic gelatin. CMC will function as a bFGF sorbent to suppress the initial leakage from the microspheres. When injected subcutaneously into the mouse back, bFGF-incorporating acidic gelatin microspheres were degraded over time and induced neovascularization around the injection site, in marked contrast to bFGF in the solution form. CMC incorporation slowed down the biodegradation and vascularization effect of bFGF-incorporating gelatin microspheres. It was concluded that the gelatin microsphere was a promising carrier matrix of bFGF to enhance the vascularization effect.     

Vascularization effect of basic fibroblast growth factor released from gelatin hydrogels with different biodegradabilities.

Biodegradable gelatin hydrogels were prepared through the glutaraldehyde crosslinking of acidic gelatin with an isoelectric point (IEP) of 5.0 and the basic gelatin with an IEP of 9.0. The hydrogel water content was changed by the concentration of both gelatin and glutaraldehyde, used for hydrogel preparation. An aqueous solution of basic fibroblast growth factor (bFGF) was sorbed into the gelatin hydrogel freeze-dried to obtain a bFGF-incorporating gelatin hydrogel. Irrespective of the hydrogel water content, approximately 30% of the incorporated bFGF was released from the bFGF-incorporating acidic gelatin hydrogel, within the first day into phosphate-buffered saline solution at 37 degrees C, followed by no substantial release. Probably, the basic bFGF complexed with the acidic gelatin through poly-ion complexation would not be released under the in vitro non-degradation condition of gelatin. On the contrary, almost 100% of the incorporated bFGF was initially released from all types of basic gelatin hydrogels. This is due to the simple diffusion of bFGF because of no complexation between bFGF and the basic gelatin. When implanted subcutaneously into the mouse back, bFGF-incorporating acidic and basic gelatin hydrogels with higher water contents were degraded with time faster than those with lower water contents. Significant neovascularization was induced around the implanted site of the bFGF-incorporating acidic gelatin hydrogel. The induction period prolonged with the decrease in hydrogel water content. On the other hand, such a prolonged vascularization effect was not achieved by the bFGF-incorporating basic gelatin hydrogel and the hydrogel initially exhibited less enhanced effect, irrespective of the water content. These findings indicate that the controlled release of biologically active bFGF is caused by biodegradation of the acidic gelatin hydrogel, resulting in induction of vascularization effect dependent on the water content. It is possible that only the transient vascularization by the basic gelatin hydrogel is due to the initial large burst in bFGF release, probably because of the down regulation of bFGF receptor.     

Simple and longstanding adipose tissue engineering in rabbits

Adipose tissue engineering for breast reconstruction can be performed for patients who have undergone breast surgery. We have previously confirmed adipogenesis in mice implanted with type I collagen sponge with controlled release of fibroblast growth factor 2 (FGF2) and human adipose tissue-derived stem cells. However, in order to use this approach to treat breast cancer patients, a large amount of adipose tissue is needed, and FGF2 is not readily available. Thus, we aimed to regenerate large amounts of adipose tissue without FGF2 for a long period. Under general anesthesia, cages made of polypropylene mesh were implanted into the rabbits’ bilateral fat pads. Each cage was 10 mm in radius and 10 mm in height. Minced type I collagen sponge was injected as a scaffold into the cage. Regenerated tissue in the cage was examined with ultrasonography, and the cages were harvested 3, 6, and 12 months after the implantation. Ultrasonography revealed a gradually increasing homogeneous high-echo area in the cage. Histology of the specimen was assessed with hematoxylin and eosin staining. The percentages of regenerated adipose tissue area were 76.2 ± 13.0 and 92.8 ± 6.6 % at 6 and 12 months after the implantation, respectively. Our results showed de novo adipogenesis 12 months after the implantation of only type I collagen sponge inside the space. Ultrasonography is a noninvasive and useful method of assessing the growth of the tissue inside the cage. This simple method could be a promising clinical modality in breast reconstruction.     

Preparation of Gelatin Microspheres Encapsulated with bFGF for Therapeutic Angiogenesis in a Canine Ischemic Hind Limb

There is urgent need for the treatment of limb ischemia. In order to avoid the risk of genetic materials or injury in collection of implanted cells, a basic fibroblast growth factor (bFGF) sustained release system using cross-linked gelatin microspheres was developed for therapeutic angiogenesis. In this study, gelatin microspheres (MSs) and the complex of MSs and bFGF (MSs–bFGF) were prepared. MSs and MSs–bFGF were analyzed for morphology, particle size, in vitro bFGF release and the bioactivity of the released medium. MSs–bFGF was intramuscularly implanted into the ischemic hind limb of a dog and free bFGF, empty MSs and untreated animals were used as controls. Histological examination was performed for angiogenesis evaluation. After immersion in an aqueous solution, the un-cross-linked MSs became deformed and adhered together. The cross-linked MSs showed a more stable character both in vivo and in vitro. The bFGF released from MSs remained bioactive. The histological examination indicated that the densities of micro-vessels in the MSs–bFGF-treated hind limb muscle were significantly greater than that in the untreated control, free bFGF and empty MSs groups. The MSs–bFGF sustained release system was a simple, safe and effective way to achieve therapeutic angiogenesis in an ischemic limb.     

Synergistic effect of gelatin microspheres incorporating TGF-beta1 and a physical barrier for fibrous tissue infiltration on skull bone formation

The objective of this study is to examine whether or not bone formation at a skull bone defect induced by gelatin microspheres incorporating transforming growth factor (TGF)-beta1 is promoted by prevention of fibrous tissues into the defect. The 6-mm diameter bone defect of rabbit skulls was applied with gelatin microspheres incorporating TGF-beta1 or free TGF-beta1 and physically covered by a barrier membrane. When the bone formation at the defect was assessed 6 weeks postoperatively, combinational application of gelatin microspheres incorporating 0.1 microg of TGF-beta1 with the barrier membrane induced bone formation at the skull defect, in marked contrast to that of 0.1 microg of free TGF-beta1 and empty gelatin microspheres. Complete defect closure was histologically observed by the newly formed bone tissue. Without the barrier membrane, gelatin microspheres incorporating TGF-beta1 were less effective in inducing bone formation, whereas free TGF-beta1 and empty gelatin microspheres were ineffective. The skull defect was occupied by fibrous tissue infiltrated in place of bone tissue. The bone mineral density at the skull defect applied with gelatin microspheres incorporating TGF-beta1 plus the membrane was significantly higher than that of gelatin microspheres incorporating TGF-beta1 alone. The present data indicated that physical protection from the soft tissue infiltration enabled gelatin microspheres incorporating TGF-beta1 to synergistically enhance the osteoinductive ability at the skull defect.