Anteromedial thigh flaps: an anatomical study to localize and classify anteromedial thigh perforators.

Until now, research on flaps in the anteromedial thigh region has focused on flaps in specific regions. To elucidate the complete pattern of suitable anteromedial thigh perforators, an anatomical study was performed by dissecting nine thighs from different cadavers. The ideal perforator has maximum length and diameter and runs through a septum. According to the data found in our study, these perforators can predominantly be found in the middle third of the anteromedial thigh region. All of the three main thigh vessels supply perforators which can be used for flaps. Pertaining to length and diameter the most suitable perforators originate from the deep femoral artery, which can be found in the proximal and middle third of the anteromedial thigh. Musculocutaneous perforators are found to be longer than septocutaneous perforators. Because of their position, the proximal and distal third perforators should preferentially be used for local pedicled flaps. Defects in the pelvic area and around the knee can be closed with perforator flaps from the proximal and distal anteromedial thigh, respectively. Because of their diameter, length, and number, the middle third perforators should be the first choice for harvesting free flaps. Skin closure is easily achieved in the anteromedial thigh region even when larger flaps are used.

Ectopic bone formation in rats: the importance of the carrier.

Much research has been done to develop the ideal bone graft substitute (BGS). One approach to develop this ideal BGS is the use of growth factors, but for this approach osteoprogenitor cells are needed at the site of reconstruction. An alternative is a cell-based approach, where enough cells are provided to form bone in a carrier material. In previous studies of our group, titanium (Ti) carriers have been used, because of the excellent mechanical properties and the bone-compatibility of this material. On the other hand, calcium phosphate (CaP) ceramics are known for their excellent osteoconductivity. The aim of this study is to investigate the influence of the carrier in a cell-based bone regeneration approach, whereby we hypothesize that CaP-ceramic implants will induce more bone formation than Ti-fiber implants, in the same animal model as our previous experiment. Ti-fiber mesh implants and ceramic implants were seeded with rat bone marrow cells (RBM) and implanted subcutaneously. Histological analysis after one, three and six weeks showed differences in the way of bone formation in the two groups: bone appeared to grow from the center to the periphery of the implant in the titanium group, while bone formation in the ceramic group occurred through the whole implant. Histomorphometrical analysis after one week showed very limited bone formation for both the titanium and ceramic group. At three weeks, the amount of bone formation was increased till about 10% for the titanium group and 18% for the ceramic group. No significant difference between the two groups could be observed. In the six week group, the bone formation was 6% (Ti) and 23% (CaP), respectively (P < 0.001). Further, bone formation started earlier in the CaP-ceramic scaffolds than in the Ti scaffolds. Our hypothesis could be confirmed: ceramic implants induce more bone formation than titanium implants.

Demineralized bone matrix-induced ectopic bone formation in rats: in vivo study with follow-up by magnetic resonance imaging, magnetic resonance angiography, and dual-energy X-ray absorptiometry.

The aim of this study was to further explore the use of magnetic resonance imaging (MRI), magnetic resonance angiography (MRA), and dual-energy X-ray absorptiometry (DEXA) to assess bone formation and blood circulation in a pedicled bone graft substitute. In 14 Wistar rats, initially 10 weeks old, heterogeneous demineralized femur bone matrix implants were wrapped in pedicled adductor thigh muscle flaps. One rat died after surgery. Subsequently, bone formation and maintenance of blood vessel functionality were evaluated in six rats 6 weeks postimplantation by means of in vivo MRI/MRA and postmortem histomorphometry. The other seven rats were left for 12 weeks, whereafter bone formation was evaluated by in vivo DEXA and postmortem histomorphometry. The results demonstrated that after 6 weeks bone formation was present in four of six animals, quantified as 42 (+/-35)% and 25 (+/-19)% by means of MRI and histomorphometry, respectively. MRA was able to show patency of the pedicles of these four rats only, which suggests that the lack of blood supply in the other two rats is the cause of the failure to form bone. In the 12-week group, histology showed increased bone formation without signs of osteolysis, which was quantified histomorphometrically to be as high as 48 (+/-15)%. DEXA failed to show bone formation. It is concluded that in vivo MRI proved to be a reliable method for monitoring ectopic bone formation in a rat model, whereas in vivo DEXA was unable to detect the implants. Furthermore, in vivo MRA proved to be a useful technique for studying the circulation of muscle flaps in this animal model.

Ectopic bone formation in rats: the importance of vascularity of the acceptor site.

Bone graft substitutes (BGS) can be fabricated by the combination of three key ingredients: (1) competent bone-forming cells, (2) a suitable framework or scaffold, and (3) the presence of biological stimulants. Although much research has been done to develop the ideal BGS, still the results are not very consistent. In view of this, the cellularity and vascularity of the recipient site are supposed to be important for the osteoinductive capacity of BGS. Therefore, we hypothesized that a muscle recipient site could favor bone formation in a cell-based BGS compared to a subcutaneous recipient site due to the higher vascularity of muscle tissue. To prove this hypothesis, 48 titanium fiber mesh implants were seeded with rat bone marrow stromal cells (RBM) and implanted subcutaneously and intramuscularly in the adductor thigh muscle of rats. The amount of bone formation after 1, 3 and 6 weeks was evaluated by histology and histomorphometry as well as by calcium content. Analysis revealed that the bone formation increased during implantation. However, bone formation did not exceed 12% of the implant surface, both for the intramuscular and subcutaneous recipient site. Also, no significant differences in bone amount between these two sites existed. Consequently, our hypothesis could not be confirmed.

Bone formation by rat bone marrow cells cultured on titanium fiber mesh: effect of in vitro culture time.

The objective of this study was to examine the effect of cell culture time on bone formation by rat bone marrow cells seeded in titanium fiber mesh. As a seeding technique, a high cell suspension was used (3 x 10(6) cells/mL). Therefore, 30 meshes were repeatedly rotated in a 10 mL tube (containing 30 x 10(6) cells) on a rotation plate (2 rpm) for 3 h. Osteogenic cells were cultured for 1, 4, and 8 days on titanium fiber mesh and finally implanted subcutaneously in rats. Meshes without cells were also implanted subcutaneously in rats. DNA and scanning electron microscopy (SEM) analyses and calcium measurements determined cellular proliferation and differentiation during the in vitro incubation period of the mesh implants. Four weeks after implant insertion, the animals were sacrificed. The implants, with their surrounding tissue, were retrieved and prepared for histologic evaluation and calcium measurements. DNA analysis of the in vitro experiment showed a lag phase from day 1 through day 4, but a 42% increase in DNA between days 4 and 8. SEM and calcium measurements indicated an increase in calcium from day 1 to day 4, yet only a small but significant increase from days 4 to 8. Histologic analysis demonstrated that bone was formed in all day 1 and day 4 implants, and that the bone-like tissue was present uniformly through the meshes. The bony tissue was morphologically characterized by osteocytes embedded in a mineralized matrix, with a layer of osteoid and osteoblasts at the surface. The day 8 implants showed only calcium phosphate deposition in the titanium fiber mesh. Calcium measurements of the implants revealed that calcification in day 1 implants was significantly higher (p < 0.05) compared to day 4 and day 8 implants. No significant difference in calcium content existed between day 4 and day 8 implants. On the basis of our results, we conclude that 1) bone formation was generated more effectively in osteogenic cells by a short culture time after seeding in titanium fiber mesh; 2) dynamic cell seeding is probably more effective than static cell seeding; and 3) selection of the right cells from the heterogenous bone marrow population remains a problem.

Bone formation in transforming growth factor beta-I-loaded titanium fiber mesh implants.

The osteoconductive properties of porous titanium (Ti) fiber mesh with or without a calcium phosphate (Ca-P) coating and osteoinductive properties of noncoated Ti fiber mesh loaded with recombinant human Transforming Growth Factor beta-1 (rhTGF-beta1) were investigated in a rabbit non-critical size cranial defect model. Nine Ca-P-coated and 18 non-coated porous titanium implants, half of them loaded with rhTGF-beta1, were bilaterally placed in the cranium of 18 New Zealand White rabbits. At 8 weeks postoperative, the rabbits were sacrificed and the skulls with the implants were retrieved. Histological analysis demonstrated that in the TGF-beta1-loaded implants, bone had been formed throughout the implant, up to its center, whereas in the non-loaded implants only partial ingrowth of bone was observed. Bone formation had a trabecular appearance together with bone marrow-like tissue. No difference in ingrowth could be observed between the non-TGF-beta1-loaded non-coated implants and the Ca-P-coated ones. All histological findings were confirmed by image analysis: 97% ingrowth was seen in the rhTGF-beta1-loaded implants, while only 57% and 54% ingrowth was observed in the non-loaded Ca-P-coated and non-coated implants, respectively. Bone surface area and bone fill were significantly higher in the rhTGF-beta1-loaded implants (1.37 mm2 and 36%, respectively) than in the non-loaded implants (0.57 mm2 and 26%). No statistical difference was found for any parameter between the Ca-P-coated and noncoated implants. Quadruple fluorochrome labeling showed that in the Ti and Ti-CaP implants mainly bone guidance had occurred from the former defect edge, while in the Ti-TGF-beta1 implants bone formation had mainly started in the center of a pore and proceeded in a centrifugal manner. Our results show that: (1) the combination of Timesh with TGF-beta1 can induce orthotopic bone formation; (2) Ti-fiber mesh has good osteoconductive properties; (3) a thin Ca-P coating, as applied in this study, does not seem to further enhance the bone-conducting properties of a titanium scaffold material.

Bone formation in transforming growth factor beta-1-coated porous poly(propylene fumarate) scaffolds.

This study determined the bone growth into pretreated poly(propylene fumarate) (PPF) scaffolds implanted into a subcritical size, rabbit cranial defect. PPF scaffolds were constructed by using a photocrosslinking-porogen leaching technique. These scaffolds were then either prewetted (PPF-Pw), treated with RF glow-discharge (PPF-Gd), coated with fibronectin (PPF-Fn), or coated with rhTGF-beta1 (PPF-TGF-beta1). One of each scaffold type was then placed into the cranium of nine rabbits. The rabbits were sacrificed after 8 weeks, and the scaffolds were retrieved for histological analysis. The most bone formation was present in the PPF-TGF-beta1 implants; the newly formed bone had a trabecular appearance together with bone marrow-like tissue. Little or no bone formation was observed in implants without rhTGF-beta1. These histological findings were confirmed by image analysis. Bone surface area, bone area percentage, pore fill percentage, and pore area percentage were significantly higher in the rhTGF-beta1-coated implants than in the noncoated implants. No statistical difference was seen between the PPF-Fn, PPF-Pw, or PPF-Gd scaffolds for these parameters. Quadruple fluorochrome labeling showed that in PPF-TGF-beta1 implants bone formation mainly started in the interior of a pore and proceeded toward the scaffold. We conclude that (a) PPF-TGF-beta1 scaffolds can indeed adequately induce bone formation in porous PPF, and (b) PPF scaffolds prepared by the photocrosslinking-porogen leaching technique are good candidates for the creation of bone graft substitutes.

Soft and hard tissue response to photocrosslinked poly(propylene fumarate) scaffolds in a rabbit model.

The treatment of large cranial defects may be greatly improved by the development of precisely formed bone tissue engineering scaffolds. Such scaffolds could be constructed by using UV laser stereolithography to photocrosslink a linear, biodegradable polymer into a three-dimensional implant. We have previously presented a method to photocrosslink the biodegradable polyester, poly(propylene fumarate) (PPF). To ensure the safety and effectiveness of this technique, the soft and hard tissue response to photocrosslinked PPF scaffolds of different pore morphologies was investigated. Four classes of photocrosslinked PPF scaffolds, constructed with differing porosities (57-75%) and pore sizes (300-500 or 600-800 microm), were implanted both subcutaneously and in 6.3-mm-diameter cranial defects in a rabbit model. The rabbits were sacrificed at 2 and 8 weeks, and the implants were analyzed by light microscopy, histological scoring analysis, and histomorphometric analysis. Results showed the PPF scaffolds elicit a mild tissue response in both soft and hard tissues. Inflammatory cells, vascularization, and connective tissue were observed at 2 weeks; a decrease in inflammatory cell density and a more organized connective tissue were observed at 8 weeks. Scaffold porosity and scaffold pore size were not found to significantly affect the observed tissue response. Evidence of scaffold surface degradation was noted both by histology and histomorphometric analysis. Bone ingrowth in PPF scaffolds implanted into cranial defects was <3% of the defect area. The results indicate that photocrosslinked PPF scaffolds are biocompatible in both soft and hard tissues and thus may be an attractive platform for bone tissue engineering.

In vivo magnetic resonance imaging explorative study of ectopic bone formation in the rat.

In animal studies of tissue engineering of bone, histology remains the standard for assessing bone formation. As longitudinal studies with this method are feasible only at the cost of large numbers of animals, we looked for an alternative. Therefore, demineralized bone matrix (DBM) and inactivated demineralized bone matrix (iDBM) implants were subcutaneously implanted in a rat. At 1, 3, 5, and 7 weeks postimplantation soft X-ray and magnetic resonance imaging (MRI) were done to monitor bone formation in the implants. At 7 weeks, the animal was killed and the implants were retrieved for histology. Our results showed that in vivo MRI is well suited to assess bone formation larger than 0.5 mm in diameter and to monitor the complete three-dimensional shape of the newly formed bone noninvasively and longitudinally. The MRI results matched well with the histology results obtained at 7 weeks. In contrast, X-ray imaging appeared inappropriate to monitor the bone formation process in DBM.