Objective To review the research of the artificial tracheal prosthesis in the past decade so as to provide theoretical references for the development of the artificial tracheal prosthesis. Methods The l iterature about the artificial tracheal prosthesis was extensively reviewed and analyzed. Results Many new materials are used for the research of artificialtracheal prosthesis which have excellent biocompatibil ity and stabil ity of the structural characteristics. And many compl ications such as migration, obstruction, and infection have been resolved, but so far none of the new materials has been used for cl inical treatment successfully. Conclusion The choice of the materials for artificial tracheal prosthesis is the key to succeed. Biodegradable polymer materials with its unique biological properties become the new direction of the tracheal prosthesis research.
Objective To review the recent research progress of base and clinical application of tracheal replacement. Methods Literature concerning tracheal prosthesis and the current achievements were extensively and comprehensively reviewed. Results Most tracheal lesions can be resected and achieve primary reconstruction, but the resectable length was limited.Tracheal replacement was an efficient and feasible way to substitutethe defects resulting from extended resection. Conclusion Newtechniques such as tissue engineering, tracheal transplantation, new tracheal prosthesis of biomaterials break fresh ground for the more rapid development of tracheal surgery.
Objective To review the research advances of the tracheal prosthesis. Methods The articles concerned in recent years were extensively reviewed. Results There were still many arguments about the use of tracheal substitutes. Avariety of artificial trachea had been designed and assessed, but so far none of them had been satisfactory for clinical use. The failures were mainly due to their high mortality and incidence of complication such as prosthetic defluvium, granuloma formation, local infection, air leakage, anastomotic stenosis or obstruction. Conclusion The major causes of the poor effectiveness by the use of tracheal prosthesis are closely related to its biological compatibilities. The selected biomaterials and the design of prosthesis hold the key to a breakthrough in research and clinical use of tracheal prosthesis.
OBJECTIVE: To compare the effect of several types of rib rings with intercostal muscles for the replacement of trachea in thorax. METHODS: The surface layer of the third rib of dogs were ripped off and curved into triangular, quadrilateral and polygonal form. These three types of rib rings with intercostal muscles were used to replace a segment of trachea in thorax. RESULTS: The stability of triangular rib ring was very well, but stricture of ring were often happened because of its smaller internal diameter. These stability of quadrilateral rib ring was the worst. The polygonal rib ring presented the biggest diameter and good stability compared to the other two kinds of rings. If silicone tube was supplemented in the polygonal rib ring, the quality of artificial trachea was excellent. CONCLUSION: The rib rings with intercostal muscles are successfully used for replacing the defect of trachea in canine thorax. The polygonal rib rings have the best quality in the three types of rib ring for tracheal replacement.
ObjectiveTo observe the morphological and pathological changes after transplantation of polytetrafluoroethylene (PTFE) in vivo. MethodsPTFE microporous polypropylene tube which was encircled by spiral steel wire was used to prepare the artificial trachea.Forty New Zealand white rabbits (weighing,4-5 kg) were selected,and were divided into 2 groups.After the cervical trachea (2 cm in length) was removed,the end-to-end anastomosis between the trachea and PTFE artificial trachea was performed in the experimental group (n=20),and end-to-end anastomosis of the trachea in the control group (n=20).The survival of the rabbits was observed after operation;the X-ray,gross,and histological observations were carried out at 2,4,and 6 months after operation.The longitudinal tensile and radial support biomechanical tests were performed before and after transplantation. ResultsThe survival time was more than 2 months and the artificial airway was patency in 15 rabbits of the experimental group;the tissue outside the artificial trachea was like tracheal tissue,which filled in the defect,but it was more than 4 months.X-ray observation showed that the PTFE artificial trachea had no obvious displacement in the experimental group,and no tracheostenosis was observed in the control group.After 2 months,there was no epithelial tissue on the artificial airway wall;after 4 months,there was some epithelial cells on the artificial airway wall,incomplete endothelialization and trachea layer structure were seen with no tracheal ciliated columnar epithelium;after 6 months,the artificial trachea wall was covered with epithelium basically,and some ciliated columnar epithelium cells were found,which had the physiological function of the trachea.The transplanted PTFE artificial trachea could keep the stability of the biological mechanics performance,and could be used for the rabbit tracheal reconstruction. ConclusionPTFE artificial trachea can induce to form a tracheal tissue in the trachea tissues of recipients,each layer of the trachea is relatively complete and the experiment animals can be short-term survival.
ObjectiveTo perfect the surgical process that trachea could be reconstructed by nickel-titanium (Ni-Ti) alloy stent wrapped with autologous pericardium, and to evaluate the effectiveness and observe the complications. MethodsIn the experiment, twelve healthy Bama suckling pigs with weight of 18-25 kg were selected. The pericardium was harvested to cover the Ni-Ti alloy stent. The compound artificial trachea was used to reconstruct long-segmental (6 cm) trachea defect. The effectiveness, complications, the properties, and growth rate of the new mucosa of the artificial trachea lumen were observed. ResultsOf 12 pigs, 2 died soon because of hemorrhage and infection, respectively; 7 died at 2-4 months after operation because of hyperplasia at the middle section and blockage of phlegm plug; 3 survived after 42 weeks postoperatively, but accompanied with dyspnea symptom. At 1, 2, 3, 4, and 5 months after operation, the average crawl length of the new trachea mucosa was 1, 3, 5, 7, and 10 mm, respectively; the occurrence rates of anastomotic stenosis were 0 (0/10), 0 (0/9), 0 (0/4), 33.3% (1/3), and 33.3% (1/3) respectively; and the occurrence rates of scar hyperplasia in the middle of lumen were 20% (2/10), 66.7% (6/9), 75.0% (3/4), 66.7% (2/3), and 100% (3/3), respectively. At 7 months postoperatively, the bronchoscopy examination showed that the scar in central part of artificial trachea had the trends of stagnation, softening, and narrowing, and respiratory symptom had the trend of slight ease. Hyperplasia tissue could be found in central part of artificial trachea by autopsy and was verified to be fiber cells and necrotic tissue by pathology examination. ConclusionNi-Ti alloy stent with autologous pericardium can insure that the reconstructed tracheal lumen is unobstructed, and support the trachea epithelium regeneration; the main factors of the death of the experimental animals are the lumen hyperplasia of the artificial trachea and the blockage of the secondary phlegm plug.