Enhanced angiogenesis through controlled release of basic fibroblast growth factor from peptide amphiphile for tissue regeneration

In the present study, we hypothesized that a novel approach to promote vascularization would be to create injectable three-dimensional (3-D) scaffolds with encapsulated growth factor that enhance the sustained release of growth factor and induce the angiogenesis. We demonstrate that a 3-D scaffold can be formed by mixing of peptide-amphiphile (PA) aqueous solution with basic fibroblast growth factor (bFGF) suspension. PA was synthesized by standard solid phase chemistry that ends with the alkylation of the NH(2) terminus of the peptide. A 3-D network of nanofibers was formed by mixing bFGF suspensions with dilute aqueous solutions of PA. Scanning electron microscopy (SEM) observation revealed the formation of fibrous assemblies with an extremely high aspect ratio and high surface areas. In vitro and in vivo release profile of bFGF from 3-D network of nanofibers was investigated while angiogenesis induced by the released bFGF was assessed. When aqueous solution of PA was subcutaneously injected together with bFGF suspension into the back of mice, a transparent 3-D hydrogel was formed at the injected site and induced significant angiogenesis around the injected site, in marked contrast to bFGF injection alone or PA injection alone. The combination of bFGF-induced angiogenesis is a promising procedure to improve tissue regeneration.     

Injectable glycosaminoglycan hydrogels for controlled release of human basic fibroblast growth factor

Synthetic hydrogel mimics of the extracellular matrix (ECM) were created by crosslinking a thiol-modified analog of heparin with thiol-modified hyaluronan (HA) or chondroitin sulfate (CS) with poly(ethylene glycol) diacrylate (PEGDA). The covalently bound heparin provided a crosslinkable analog of a heparan sulfate proteoglycan, thus providing a multivalent biomaterial capable of controlled release of basic fibroblast growth factor (bFGF). Hydrogels contained >97% water and formed rapidly in <10min. With as little as 1% (w/w) covalently bound heparin (relative to total glycosaminoglycan content), the rate of release of bFGF in vitro was substantially reduced. Total bFGF released increased with lower percentages of heparin; essentially quantitative release of bFGF was observed from heparin-free hydrogels. Moreover, the hydrogel-released bFGF retained 55% of its biological activity for up to 28 days as determined by a cell proliferation assay. Finally, when these hydrogels were implanted into subcutaneous pockets in Balb/c mice, neovascularization increased dramatically with HA and CS hydrogels that contained both bFGF and crosslinked heparin. In contrast, hydrogels lacking bFGF or crosslinked heparin showed little increase in neovascularization. Thus, covalently linked, heparin-containing glycosaminoglycan hydrogels that can be injected and crosslinked in situ constitute highly promising new materials for controlled release of heparin-binding growth factors in vivo.     

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.     

Enhancing the vascularization of three-dimensional porous alginate scaffolds by incorporating controlled release basic fibroblast growth factor microspheres

Site-specific delivery of angiogenic growth factors from tissue-engineered devices should provide an efficient means of stimulating localized vessel recruitment to the cell transplants and would ensure cell survival and function. In the present article, we describe the construction of a novel porous alginate scaffold that incorporates tiny poly (lactic-co-glycolic acid) microspheres capable of controlling the release of angiogenic factors, such as basic fibroblast growth factor (bFGF). The microspheres are an integral part of the solid alginate matrix, and their incorporation does not affect the scaffold porosity or pore size. In vitro, bFGF was released from the porous composite scaffolds in a controlled manner and it was biologically active as assessed by its ability to induce the proliferation of cardiac fibroblasts. The controlled delivery of bFGF from the three-dimensional scaffolds accelerated the matrix vascularization after implantation on the mesenteric membrane in rat peritoneum. The number of penetrating capillaries into the bFGF-releasing scaffolds was nearly fourfold higher than into the control scaffolds (those incorporating microspheric BSA and heparin but not bFGF). At day 10 posttransplantation, capillary density in the composite scaffolds was 45 +/- 3/mm(2) and it increased to 70 +/- 7/mm(2) by day 21. The released bFGF induced the formation of large and matured blood vessels, as judged by the massive layer of mural cells surrounding the endothelial cells. The control over bFGF delivery and localizing its effects to areas of need, may aid in the wider application of bFGF in therapeutic angiogenesis as well as in tissue engineering.     

Controlled and modulated release of basic fibroblast growth factor.

Basic fibroblast growth factor has multivariate effects in stimulating cell growth and the processes that surround tissue repair. Pathophysiologic studies have been hampered by the stability of the compound. Though very potent, basic fibroblast growth factor is rapidly degraded when injected or ingested. Controlled release of basic fibroblast growth factor would allow for examination of the chronic effects of this compound. Conventional matrix polymer-based release devices were fabricated and basic fibroblast growth factor released in a sustained fashion, but 99% of basic fibroblast growth factor mitogenic activity was lost. The source of these losses was identified and preventative measures examined. Preservation and stabilization of basic fibroblast growth factor was accomplished by binding the factor to heparin-Sepharose beads. This permitted prolonged storage, repeated handling, and the encapsulation of basic fibroblast growth factor within a microspherical controlled-release device using a naturally occurring polymer material, alginate. Encapsulation was accomplished with 77% efficiency and 87.5 +/- 12% of the basic fibroblast growth factor was released in a biologically active form. Release activation and regulation was achieved when cleavage of the basic fibroblast growth factor-heparin bonds was enhanced (e.g. by enzymatic bond cleavage with heparinase). Kinetic profiles were identified for a variety of experimental conditions and the effects of the controlled release of basic fibroblast growth factor on BALBc/3T3 fibroblasts examined.     

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.     

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.     

Sustained release and activation of the growth factor basic fibroblast growth factor from loaded scaffolds in heart valve tissue engineering

Objectives. Loading of biological matrices offers an opportunity to induce specific cell behaviour. We previously reported the use of growth factors to promote cell invasion and proliferation in tissue valve engineering.

We investigated biological matrices preloaded with heparin as an ionically attractive template for the binding, activation and sustained release of basic fibroblast growth factor (bFGF).

Methods. Heparin loading concentrations were evaluated and different incubation times were tested. Heparin and heparin-bound bFGF uptake and release were evaluated by ¹²³I radio-labelling. Biological activity of bFGF was evaluated in vitro.

Results. Maximum heparin uptake was observed for 2000 μg/ml at 2 h and stabilized thereafter. bFGF-loaded matrices showed an initial burst release of 15% within 4 h and thereafter sustained release reaching 21% at 24 h. Released bFGF was bioactive.

Conclusions. This model would be useful in tissue engineering using porcine aortic matrices and could be applied using other growth factors or combinations.     

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.     

Requirement of fibroblast growth factor 10 in development of white adipose tissue

Fibroblast growth factors (FGFs) are important intercellular signaling molecules in developmental processes. Here, we show that FGF10 is secreted by cultured preadipocytes and that prevention of FGF10 signaling inhibits the expression of C/EBPbeta and the subsequent differentiation of these cells. An active form of C/EBPbeta rescued differentiation of the cells in which FGF10 signaling was blocked. Development of white adipose tissue and the expression of C/EBPbeta in this tissue of FGF10 knockout mice were markedly reduced, and the ability of embryonic fibroblasts derived from FGF10 knockout mice to differentiate into adipocytes was impaired. Therefore, FGF10 plays an important role in adipogenesis, at least partly by contributing to the expression of C/EBPbeta through an autocrine/paracrine mechanism.     

Regeneration of anterior cruciate ligament by biodegradable scaffold combined with local controlled release of basic fibroblast growth factor and collagen wrapping

The objective of this study was to increase the therapeutic efficacy of anterior cruciate ligament (ACL) surgery using an artificial ligament material developed through a combination of tissue engineering technologies. A poly-L-lactic acid (PLLA) scaffold of plain-woven braid was incorporated with a gelatin hydrogel for controlled release of basic fibroblast growth factor (bFGF) and wrapped with a collagen membrane to allow space for ligament regeneration. For the ACL reconstruction surgery, the PLLA braid scaffold combined with the gelatin hydrogel incorporating bFGF and the collagen wrapping was applied to a tunnel prepared in the femur and tibia of rabbits. The hydrogel was placed in the bone, whereas the portion of the braid inside the joint cavity was wrapped with the membrane. As controls, the PLLA scaffold was applied with the hydrogel or the membrane, or without either material. Bone regeneration in the tunnel and ACL tissue regeneration in the joint cavity were histologically evaluated, and the mechanical strength and collagen content of the regenerated ACL were assessed. When the PLLA scaffold was integrated with both the hydrogel and the membrane, bone and ACL tissues were regenerated in the corresponding sites, in marked contrast to the control groups. Combination of bFGF-controlled release resulted in enhanced mechanical strength of the regenerated ACL tissue. In the joint cavity, it is possible that the local bFGF release inside the membrane enhanced the cell migration and collagen production, and that the surrounding PLLA scaffold results in the biological regeneration of ligament-like tissue. Additionally, significant bone regeneration around the scaffold was observed in the bone tunnel. It is therefore possible that the local controlled release of bFGF near the PLLA braid induced both osseointegration and intrascaffold cell migration in the bone tunnel and joint cavity, respectively, resulting in an overall increase in the mechanical strength of the regenerated ACL.     

大鼠脂肪干细胞联合碱性成纤维生长因子治疗大鼠心肌梗死

目的 探讨脂肪干细胞（ADSC）联合碱性成纤维生长因子（bFGF）提高心肌梗死大鼠心脏功能的可能机制.方法 SD大鼠50只,先行脂肪干细胞提取手术,分离、培养、鉴定脂肪干细胞,行干细胞成脂、成骨诱导分化,建立大鼠心肌梗死模型,选择缩短分数（FS）＜40％的SD大鼠（36只）,完全随机分4组：单纯注射PBS组（n=9）、单纯注射bFGF组（n=9）、PBS＋ADSC组（n=9）以及ADSC＋bFGF组（n=9）,以bFGF胶为可注射性载体,ADSC为种子细胞,1周后进行大鼠心梗部位移植.移植4周后对心梗面积、左心室室壁厚度、心梗部位微血管密度、ADSC在心梗部位分化情况等指标进行检测,并利用心脏超声对心梗大鼠的心脏功能进行测定.应用免疫组织化学、免疫荧光等方法评价其改善心脏功能可能机制.结果 成功分离ADSC并且通过流式细胞术表明大多数分离的脂肪干细胞CD90抗体阳性、CD29抗体阳性、CD45抗体和CD34抗体阴性.脂肪干细胞能够经过诱导分化成成脂、成骨细胞.PBS＋ADSC组以及ADSC＋bFGF组在室壁厚度、梗死面积、梗死区域微血管形成能力与PBS组相比,差异均有统计学意义,且以ADSC＋bFGF组最为显著（P＜0.01）.ADSC移植到大鼠心脏4周后,可以分化为cTnT阳性细胞、SMA阳性细胞以及vWAg阳性细胞.心功能检测结果表明PBS＋ADSC组同ADSC＋bFGF组一样,具有心梗修复能力.结论 移植ADSC的同时增加bFGF能促进梗死区的心肌再生以及血管化,并能显著改善心脏功能.     

Effect of basic fibroblast growth factor on vascularization in esophagus tissue engineering

We carried out an experimental study to evaluate the effect of basic fibroblast growth factor (bFGF)-containing collagen gel on vascularization in esophageal tissue engineering. We compared an acellular collagen sponge scaffold and an acellular collagen gel scaffold in combination with bFGF using a canine model. The construct was implanted in the cervical esophagus and the regenerated tissue was evaluated one month after surgery. Histological analysis confirmed a significantly large amount of blood vessels in the bFGF-containing collagen gel group as compared to the collagen gel group without bFGF (bFGF (-)). However, in the collagen sponge groups, no difference was observed between the bFGF (+) group and the bFGF (-) group. These results showed that bFGF-containing collagen gel is suitable not only for an acellular scaffold for tissue engineering but also for an effective tropic factor vehicle in vivo.     

Combined chondrocyte-copolymer implantation with slow release of basic fibroblast growth factor for tissue engineering an auricular cartilage construct

Basic fibroblast growth factor (b-FGF) may have a role in tissue-engineered chondrogenesis. However, when applied in solution, b-FGF rapidly diffuses from the implant site. In another approach for tissue engineering, poly-lactide-based copolymers have shown promise as scaffolds for chondrocytes used to tissue engineer auricular cartilage in the shape of an ear. This study evaluated the effectiveness of b-FGF impregnated in gelatin microspheres to achieve slow growth factor release for augmenting the in vivo chondrogenic response. Whereas 125I-labeled b-FGF injected in solution showed rapid in vivo clearance from the injection site (only 3% residual after 24 h), when incorporated into gelatin microspheres, 44% and 18% of the b-FGF remained at 3 and 14 days, respectively. Canine chondrocytes were isolated and grown in vitro onto ear-shaped poly-lactide/caprolactone copolymers for 1 week, then implanted into the dorsal subcutaneous tissue of nude mice; implants contained b-FGF either in free solution or in gelatin microspheres. A third group underwent preinjection of b-FGF in gelatin microspheres 4 days before chondrocyte-copolymer implantation. The implants with b-FGF-incorporated microspheres showed the greatest chondrogenic characteristics at 5 and 10 weeks postoperatively: good shape and biomechanical trait retention, strong (histologic) metachromasia, rich vascularization of surrounding tissues, and increased gene expression for type II collagen (cartilage marker) and factor VIII-related antigen (vascular marker). In the case of implant site preadministration with b-FGF-impregnated microspheres, the implant architecture was not maintained as well, and reduced vascularization and metachromasia was also apparent. In conclusion, these findings indicate that a sustained release of b-FGF augments neovascularization and chondrogenesis in a tissue-engineered cartilage construct.     

Binding and release of basic fibroblast growth factor from heparinized collagen matrices.

Endothelial cell seeding is a promising method to improve the performance of small-diameter vascular grafts. Growth of endothelial cells seeded on the luminal surface of synthetic vascular grafts, coated with a matrix suitable for cell seeding (e.g. collagen), can be accelerated by local, sustained release of basic fibroblast growth factor (bFGF). In this study two potential matrices for in vivo endothelial cell seeding were studied with respect to bFGF binding and release: collagen crosslinked using N-(3-dimethylaminopropyl)-N'-ethylcarbodiimide (EDC) and N-hydroxysuccinimide (NHS), as well as heparinized EDC/NHS-crosslinked collagen. bFGF binding was determined after incubation of circular samples (10 mm diameter) with 0.25 ml bFGF solution for 90 min. Immobilization of increasing amounts of heparin, also using EDC and NHS, to crosslinked collagen containing 14 free primary amino groups per 1000 amino acid residues (E/N14C) resulted in binding of increasing amounts of bFGF. A plateau in bFGF binding was observed for heparinized E/N14C containing approximately 2.0-3.0 wt% of immobilized heparin which was obtained using a molar ratio of EDC to heparin-carboxylic acid groups of 0.4 during heparin immobilization (E/N14C-H(0.4)). At concentrations up to 840 ng bFGF/ml, 10% of the added bFGF bound to E/N14C, while binding of bFGF to E/N14C-H(0.4) amounted to 22%. Both E/N14C and E/N14C-H(0.4) pre-loaded with bFGF showed sustained bFGF release. A burst release of 30% in endothelial cell culture medium (CM) was observed for E/N14C during the first 6 h, compared to 2% release from E/N14C-H(0.4). After 28 days, the bFGF release from E/N14C and E/N14C-H(0.4) in CM amounted to 100 and 65%, respectively. Combined results of binding and release of bFGF indicate that compared to E/N14C, E/N14C-H(0.4) is the substrate of choice for bFGF pre-loading and subsequent endothelial cell seeding.     

碱性成纤维细胞生长因子对离心管内培养骺板细胞生成软骨组织的作用

背景：采用离心管技术体外培养骺板细胞的报道已很多。 目的：观察碱性成纤维细胞生长因子对离心管内培养的骺板细胞生成类骺板组织的影响。 方法：获取3周龄新西兰白兔股骨远端的骺板组织,利用组织块纱巾培养法获得骺板细胞,加入含有10 μg/L碱性成纤维细胞生长因子的DMEM培养液,连续培养4周。 结果与结论：离心管内聚集的骺板细胞在含有碱性成纤维细胞生长因子的DMEM培养液中形成类骺板样组织块。在组织块外周形成类似骺软骨的生发层,中心的骺板细增殖情况良好,向肥大细胞方向分化。类骺板样组织甲苯胺蓝及番红“O”染色阳性,Ⅱ型胶原免疫组织化学染色呈强阳性。说明碱性成纤维细胞生长因子能够促进离心管中的骺板细胞形成富含蛋白聚糖及Ⅱ型胶原等细胞外基质的类骺板样软骨组织。     

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.     

Regeneration of canine tracheal cartilage by slow release of basic fibroblast growth factor from gelatin sponge

We investigated the efficiency of basic fibroblast growth factor (b-FGF) released from a gelatin sponge in the regeneration of tracheal cartilage. A 1-cm gap was made in the midventral portion of each of 10 consecutive cervical tracheal cartilages (rings 4 to 13) in 15 experimental dogs. In the control group (n = 5), the resulting gap was left blank. In the gelatin group (n = 5), a gelatin sponge alone was implanted in the gap. In the b-FGF group (n = 5), a gelatin sponge containing 100 mug b-FGF solution was implanted in the gap. We euthanatized one of the five dogs in each group at 1 month after implantation and one at 3 months and examined the implant sites macroscopically and microscopically. In the control and gelatin groups, no regenerated cartilage was observed in the tracheal cartilage gap at 1 or 3 months. The distances between the cartilage stumps had shrunk. In the b-FGF group, fibrous cartilage had started to regenerate from both host cartilage stumps at 1 month. At 3 months, regenerated fibrous cartilage filled the gap and had connected each of the stumps. The regenerated cartilage was covered with regenerated perichondrium originating from the host perichondrium. Shrinkage of the distance between the host cartilage stumps was not observed in the b-FGF group. We succeeded in inducing cartilage regeneration in the gaps in canine tracheal cartilage rings by using the slow release of b-FGF from a gelatin sponge. The regenerated cartilage induced by b-FGF was fibrous cartilage.