An experimental study, repairing of articular cartilage by free periosteal graft in rabbit, was designed. Two 4.5mm wide circular full-thikness cartilage defects were drilled on the medial femoral condyle, in 24 adult rabbits. A graft of periosteum from the proximal tibia was fitted into the defect (right side), by using fibrinogen glue. On the control side (left side), the defect was fulled with fibrinogen glue, or repaired by periehondrial grafts which were taken from their own ribs. This experiment indicated that both periosteum and perichnodrium have the same potential of cartilagious regeneration. And the processes of regeneration are also the same. So we suggest to use free autologous periosteal grafts to replace free autologous perichondrial grafts to cure the articular cartilage defects.
ObjectiveTo explore the application and effectiveness of thin-ribbed cartilage with the perichondrium in the correction of secondary cleft lip nasal deformity as the lateral crural onlay graft.MethodsA retrospective study was performed based on the data of 28 patients with secondary nasal deformity of cleft lip between October 2015 and April 2017. There were 16 males and 12 females with an average age of 24 years (range, 18-31 years). There were 11 cases with secondary nasal deformities on the left side, 13 cases on the right side, and 4 cases on both sides. Three-dimensional stereotaxy of the nasolabial muscles was used to correct the deformity. The costal cartilage as the support was used to perform nasal columella and nasal dorsum while the thin-ribbed cartilage with the perichondrium was used as wing cartilage support. The photography of nasal position was taken before operation and at 6-8 months after operation. The midpoint of the junction between the nasal columella and the upper lip was marked point O; the lateral horizontal line passing through the point O was marked as X-line, and the longitudinal line (the midline) as Y-line. The distance of the highest point of the affected nostril to the X-line, the distance of the nostril’s outermost point to the Y-line, the symmetries of both the most lateral and the highest point of the bilateral nostrils, and the distance of the highest point of the nasal tip to the X-line were measured.ResultsAll incisions healed by first intention. All patients were followed up 6 to 24 months with an average of 12 months. The size and shape of the noses were stable, and no compli cation, such as cartilage exposure, hematoma, or infection occurred during the postoperative follow-up. There were 4 cases with obvious incision scars, 3 cases with nostril and alar asymmetry, and 1 case of lateral side of the nose without well positioned. The symmetry of the highest points of bilateral nostrils was 57.643%±27.491% before operation and 90.246%±18.769% after operation. The symmetry of the most lateral points of the bilateral nostrils was 77.391%±30.628% before operation and 92.373%±21.662% after operation. And there were significant differences between pre- and post-operation (P<0.05). There were also significant differences in the distance of highest point of the affected nostril to the X-line, the distance of the nostril’s outermost point to the Y-line, and the distance of the highest point of the nasal tip to the X-line (P<0.05). No thoracic contour change occurred at the costal cartilage donor site.ConclusionThe thin-ribbed cartilage with the perichondrium has good support and long-term stability, and it can be used as one of the ideal materials for nasal alar cartilage transplantation for nasal deformity secondary to cleft lip.
To study how to repair the cartilage defect according to the principles of tissue engineering with acellular cartilage matrix as scaffold material. Methods The ear cartilage was obtained from a New Zealand white rabbit(weighing 2.4 kg )and then treated by a modified Courtman’s four-step method to produce the acellular cartilage matrix. Eighteen New Zealand white rabbits (aged 6 months, weighing 2.4-2.6 kg) with no sex l imit were divided into three groups. Forevery rabbit, two pieces of ear cartilage measured 1 cm × 1 cm were excised in each ear. Defects were repaired as follows: group A with the combined graft of acellular cartilage matrix and perichondium, group B with acellular cartilage matrix and group C with perichondium. Three animals in each group were killed 4 and 12 weeks postoperatively, respectively. Tissue samples obtained were analyzed with gross observation, hematoxyl in-eosin stain, Safranine O-alcian blue stain and type II collagen messenger RNA in situ hybridization respectively. Results In gross observation, the repaired sites in groups A and B were not change meaningfully in their shape 4 weeks postoperatively; but they felt a bit of thicker and harder 12 weeks postoperatively. In group C two repaired sites formed scabs at 2 weeks and perforated at 5 weeks. In histological observation, there was a sl ight inflammatory reaction surrounding the acellular cartilage matrix 4 weeks after it was implanted in groups A and B. The inflammatory cells were mainly lymphocytes. The perichondrium graft in group C was collapsed in the defects in HE stain. The defect sites were negative for Safranine O-alcian blue stain and type II collagen mRNA in situ hybridization in all groups. At 12 weeks cells were found in the acellular matrix which arranged in irregular manner in group A in HE stain and was positive for Safranine O-alcian blue stain and type II collagen mRNA in site hybridization. In groups B and C, no new cell was found in HE stain and the repaired sites were negative for Safranine O-alcian blue stain and type II collagen mRNA in situ hybridization. Conclusion Acellular
OBJECTIVE: To provide experimental basis for improving the curative effect of pectus excavatum. METHODS: Twelve rabbits were adopted in this experiment. After the bilateral second and third costal cartilages of the rabbits were resected subperichondrially, their right second and third costal perichondriums were damaged intentionally. Then, the bilateral third costal perichondriums were stitched into a tube-like structure and the second ones were left opened. After 2, 4, 6 of operation, the bilateral second and third neocartilages were measured for their width, and histological character were observed under microscope. RESULTS: 1. After 2, 4, 6 months of operation, the average width of the bilateral second neocartilages were significantly greater than the preoperative ones. 2. 4 and 6 months after operations, there was no significant difference in the average width of the bilateral third neocartilages and the preoperative ones. 3. The amount, distribution of costal neocartilage cells and the arrangement of costal neocartilage matrix within the left second and third costal cartilages were better than the right under the light microscope. 4. The left third costal neocartilage was regenerated and remodeled better than all the others. CONCLUSION: The integrality of costal perichondrium is in favor of the regeneration of costal cartilage, and the sleeve stitch of costal perichondrium facilitates the remodeling of costal neocartilage.
Objective To investigate and compare the effectiveness of perichondrial cutaneous graft (PCCG) of dorsal auricle for repairing defect after excision of melanocytic nevus in different parts of the face. Methods Between February 2008 and October 2012, 29 cases of facial melanocytic nevus were admitted. There were 11 males and 18 females, aged 3-25 years (median, 11 years). The locations were the upper eyelid in 5 cases, the nose in 15 cases, and the buccal region in 9 cases. The size of the nevi ranged from 1.2 cm × 1.0 cm to 4.0 cm × 2.2 cm. Defects after excision of nevi were repaired by PCCG of the dorsal auricle, which size ranged from 1.5 cm × 1.5 cm to 4.2 cm × 2.5 cm. The postoperative effectiveness was scored by patients according to color match, scar formation, and flatness of the reception site. The satisfaction evaluations were compared by the score among different parts. Results All the PCCG survived. All the patients were followed up 7-15 months (mean, 10 months). All the reception site had good color match and acceptable scar formation. The nasal part had good flatness, and the upper eyelid had poor flatness. Score comparison showed no significant difference in color match between 3 parts (P gt; 0.05). Nasal part had significantly less scar formation than buccal region and upper eyelid (P lt; 0.05), but no significant difference between buccal region and upper eyelid (P gt; 0.05). Nasal part and buccal region both had significantly better flatness than upper eyelid (P lt; 0.05), but no significant difference between nasal part and buccal region (P gt; 0.05). The overall evaluation score of nasal part and buccal region was significantly higher than that of the upper eyelid group (P lt; 0.05), and the score of the nasal part was significantly higher than that of the buccal region (P lt; 0.05). Conclusion PCCG of dorsal auricle has a good color match in repair of facial defect, especially in repair of nasal defect with good flatness and no obvious scar formation.
In order to observe the histological changes of the autogenous perichondrium graft from rib in the repair of injured articular cartilage of the condylar process of mandible, 50 rabbits were used, in which 15 were served as control. The articular cartilage with its subchondral bone were resected and an autogenous graft of costal perichondrium was sutured onto the raw surface of the condylar process, and in the controls, only the articular portion of the condylar process was resected without the application of autogenous costal perichondrium graft. The morphological changes of the newly formed cartilage during the process of its development were investigated by hiostological and autoradiog aphic techniques. The result revealed that 10 days after operation, the graft had increased in thickness and was richly populated form the proliferation of mesenchyme-like cells. Twenty to thirty days later, the chondrocytes were matured and the newly formed cartilage had covered the bony surface of mandibular condyle. At 60 days, the newly formed cartilagenous joint surface became glossy, and the morphology and arrangement of cells tended to be regular simulating the morphology of normal articular cartilage. From the experiment, it could be concluded that (1) The autogenous perichondrium graft placed on the condylar surface of mandible could form new articular cartilage which was similar in tissue morphology to the normal condylar cartilage. (2) The process of development of newly formed cartilage was similar to that of the normal cartilage. (3) The motion and loading on the joint could promote the formation of new cartilage and undergo biological reformation, gradually resulting in normal joint morphology. On this basis, the clinical application of autogenous perichondrium graft to repair injured cartilage of the condylar process of the mandible was feasible.