Objective To explore the technique for reconstructing nasal subunits with the reversed vascularized preauricular and ear composite flap. Methods From June 2003 to August 2005 the preauricular and ear composite flap, which was pedicled by the reversed superficial temporal vessel, was harvested and transplanted to repair the defects of the nasal tip, soft triangle, and ala by the microsurgical technique. The flap ranged in area from 3.5 cm×2.5 cm to 2.0 cm×1.5 cm, with the pedicles 4 to 6 cm in length. The reversed superficial temporal vessel pedicles were directly anastomosed to the angular artery and vein adjacent to the nasal ala. Results Among the 12 patients who had been treated, 11 had their vessel pedicles successfully anastomosed to the angular vessels, while the remaining 1 patient had the stump of the superficial temporal vessel anastomosed after the flap harvest via the vessel graft because the angular vessels were not found in the recipient area. All the flaps survived with a satisfactory esthetic result after operation. Conclusion The technique for reconstructing nasal subunits with the reversed vascularized preauricular and ear composite flap, which is directly anastomosed to the angular vessel, can avoid the vessel grafting and therefore it can avoid an additional damage to the patient.
Objective To investigate the cl inical outcome of a surgical strategy by soft tissue expansion in treating acquired auricular defect. Methods Between January 2007 and December 2009, 136 patients with acquired auricular defect were treated with a surgical strategy by putting autoallergic costal framework after soft tissue expansion. There were 93 males and 43 females, aged 8-60 years (median, 20 years). Defects were caused by burn in 82 cases, by trauma in 47 cases, and by bite in 7 cases. Defect involved in almost the whole auricle and earlobe in 50 patients, 2/3 superior part of auricle in 35 patients, 1/3 superior part of auricle in 31 patients, 1/3 middle part of auricle in 9 patients, and 1/3 inferior part of auricle and earlobe in 11 patients. Results All the flaps had good blood supply, skin grafts all survived, and all the wounds healed by first intention after operation. All patients were followed up 6-24 months with an average of 14 months. All reconstructive auricle survived with good color, soft texture, and normal sensory function; the appearance had no enlargement and attrition, and the grafted costal cartilage framework had no malacosis, absorption, and deformation. The reconstructed ear had the same position, size, shape, and oto-cranium angle as normal ear. The curative effect was good according to ZHUANG Hongxing’s evaluation standard of auricular reconstruction. Conclusion To reconstruct auricle by soft tissue expansion is an effective method. The position of putting expander and the number of expanders are different in different patients.
ObjectiveTo explore the anthropometric changes of the auricle after auricular cartilage unfolding in moderate concha-type microtia patients, so as to provide the basis to help evaluate surgical timing and prognostic.MethodsA total of 33 children with moderate concha-type microtia, who were treated with auricular cartilage unfolding between October 2016 and September 2018 and met the inclusive criteria, were included in the study. There were 24 boys and 9 girls with an average age of 1.4 years (range, 1-3 years). Sixteen cases were left ears and 17 cases were right ears. The follow-up time was 12-23 months (mean, 17.5 months). The affected auricular detailed structures were observed and quantitatively analyzed before operation and at immediate after operation. The width, length, and perimeter of auricle before operation and at immediate after operation and at last follow-up were noted with three dimensional-scanning technology. The normal auricle was noted as control.ResultsThere were (7.5±1.0) and (11.3±0.8) structures of the affected auricle at pre- and post-operation, respectively, showing significant difference between pre- and post-operation (t=23.279, P=0.000). The length, width, and perimeter of the affected auricle constantly increased after operation, and there were significant differences between pre-operation and immediately after operation and between immediately after operation and last follow-up (P<0.05). The differences of length, width, and perimeter of the affected auricle between immediately after operation and last follow-up were (3.13±1.44), (2.44±0.92), and (8.50±3.76) mm, respectively. And the differences of length, width, and perimeter of the normal auricle between pre-operation and last follow-up were (3.16±1.54), (2.35±0.86), and (9.79±4.60) mm, respectively. There was no significant difference in the differences of length, width, and perimeter between the affected auricle and the normal auricle (P>0.05).ConclusionThe auricular cartilage unfolding in treatment of the moderate concha-type microtia can receive more ear structures and increase auricle sizes, which make it possible for free composite tissue transplantation. In addition, the affected and the contralateral normal auricles have a very similar growth rate and it offers the theoretical foundation for the early treatment for moderate concha-type microtia.
In the reconstruction of the concha, standing support was necessary. From 1984 to 1996, 33 cases of aurical defects were admitted. Three standing-materials were chosen, and they included carved autogenous cartilage, heterogenous concha cartilage and steel wire work silicon-wires with silastic rubber tube. After expansion of the postauricular skin by tinsion expander, the standing-material was enveloped and total ear reconstruction or repair was performed. After followed up for average of 3.5 years, of the twenty-two cases, 16 had a satisfactory result, unsatisfied in 3 and failure in 3. It was concluded that the outcome of autogenous concha cartilage as a standing-material was good. The other two materials if used should be very carefully.
Objective To investigate the technique and effectiveness of using narrow hypodermal pedicled retroauricular flap for repairing preauricular soft tissue defect. Methods Between June 2008 and July 2011, 11 cases of preauricular soft tissue defect were treated, which were caused by resection of preauricular tumors, including 5 cases of pigmented nevus, 2 cases of basal cell carcinoma, 2 cases of mixed hemangioma, and 2 cases of skin papilloma. There were 7 males and 4 females, aged from 26 to 75 years (mean, 50 years). The disease duration was 3-50 years (mean, 35 years). The size ofthe soft tissue defect ranged from 1.5 cm × 1.0 cm to 3.5 cm × 3.0 cm. The narrow hypodermal pedicled retroauricular flap was designed with its pedicle along the pathway of the superficial temporal artery and posterior auricular artery through tunnel to repair the defects. The size of the flaps ranged from 1.8 cm × 1.3 cm to 3.8 cm × 3.3 cm with the pedicle of 2-5 cm in length and 0.4-0.7 cm in width. The donor site was sutured directly or repaired with local flap. Results All flaps survived and incisions healed primarily after operation. Eight cases were followed up 6 months to 1 year. The flaps had good texture, flexibil ity, and color, and the auricle appearance was satisfactory. No recurrence of tumor was found. Conclusion The narrow hypodermal pedicled retroauricular flap has long and narrow pedicle, big transferring angle, large repairing area, no major blood vessel, and easy operation, so it is a simple and ideal technique for repairing preauricular soft tissue defect.
Objective To investigate the methods and effectiveness of ear reconstruction for the microtia patients with craniofacial deformities. Methods Between July 2000 and July 2010, ear reconstruction was performed with tissue expander and autogenous costal cartilages in 1 300 microtia patients with degree II+ hemifacial microsoma, and the clinical data were reviewed and analyzed. There were 722 males and 578 females, aged 5 years and 8 months to 33 years and 5 months (median, 12 years and 2 months). The expander was implanted into the retroauricular region in stage I; ear reconstruction was performed after 3-4 weeks of expansion in stage II; and reconstructed ear reshaping was carried out at 6 months to 1 year after stage II in 1 198 patients. Results Of 1 300 patients, delayed healing occurred in 28 cases after stage II, healing by first intention was obtained in the other 1 272 cases, whose new ears had good position and appearance at 1 month after stage II. After operation, 200 cases were followed up 1-9 years (mean, 3 years). One case had helix loss because of trauma, and 1 case had the new ear loss because of fistula infection. At last follow-up, the effectiveness were excellent in 110 cases, good in 65 cases, and fair in 23 cases with an excellent and good rate of 88.4%. Conclusion It is difficulty in ear reconstruction that the reconstructed ear is symmetrical to the contralateral one in the microtia patients with degree II+ hemifacial microsoma. The key includes the location of new ear, the fabrication of framework, and the utilization of remnant ear.
From Sept 1989 to Dec 1993, the auricular composite graft carrying a piece of postauriclar skin with subdermal vascular network was used to repair 7 cases having defects of nasal alar or tip and 1 having microtia. The width of the composite grafts ranged from 1.8cm to 2.6cm, and the size of the postauricular skin rangedfrom 0.08×1cm2 to 2.2×2.5cm2. All cases gained successful results. The mechanism of survival of the composite grafts, and the essential points in operation were detailed.