Objective To investigate change of bispectral index(BIS) and hemodynamic index during induction and orotracheal intubation of sevoflurane anesthesia. Methods This study was a prospective before-after study in the same patients. A total of 30 ASA physical status I and II adult patients without airway abnormalities were enrolled to receive inhalation induction of anesthesia with 8% sevoflurane. Mean arterial pressure(MAP),heart rate(HR) and BIS were recorded before anesthesia(T1),when patients loss of consciousness(T2), before intubation (T3),at 1 min(T4) and 3 min(T5) after intubation. Results BIS at T1-T5 were 96.8±1.7,70.4±8.8,39.2±8.4,43.6±12.9 and 41.6±9.3 respectively, the measurements at T2-T5 were all markedly lower than at T1(Plt;0.05). HR at T3-T5 were all markedly higher than at T1(Plt;0.05). MAP at T2 and T3 were markedly lower than at T1, but at T4 was higher than at T1(Plt;0.05), and recovered to the level at T1 at T5(Pgt;0.05).BIS,HR and MAP at T4 were all significantly higher than T3(Plt;0.05). Conclusion Anesthesia induction with sevoflurane and small dose of succinylchoiline we used can provide adequate depth of general anesthesia,but can not prevent cardiovascular adverse reactions to intubation.
Objective To evaluate the clinical features and complications of bedside tracheal intubation in intensive care unit ( ICU) , and explore the suitable strategy of intubation. Methods In this retrospective study,42 patients who underwent bedside tracheal intubation in ICU during September 2008 and March 2009 were divided into a schedule group ( n =24) and an emergency group ( n =18) . The time to successful intubation, number of intubation attempts, and complications were recorded. The schedule group was defined as those with indications for intubation and fully prepared, while the emergency group was defined as those undergoing emergency intubations without full preparation due to rapid progression of disease and accidental extubation. Results The success rate for all patients was only 57. 1% on the first attempt ofintubation. The main complications during and after induction were hypotension ( 45. 2% ) and hypoxemia ( 50. 0% ) . Compared with the emergency group, the schedule group had fewer attempts to successful intubation ( 1. 71 ±1. 12 vs. 2. 67 ±1. 75) , higher success rate on the second attempt ( 87. 5% vs.61. 1%) , and lower ypoxemia incidence ( 29. 1% vs. 77. 8%, P lt; 0. 05) . Conclusions The tracheal intubation in ICU is a difficult and high risk procedure with obvious complications. Early recognition ofpatients with indications and well preparation are critical to successful bedside intubation.
Objective To observe the effects of ambroxol injection on mucosal surface structure of trachea injured by intratracheal instillation of amikacin. Methods 280 Wistar rats were randomly divided into four groups( n = 70 in each group) , ie. a normal control group, a normal saline group( intratracheally instilled normal saline) , an amikacin group ( intratracheally instilled amikacin) , and an ambroxol group ( intratracheally instilled amikacin and ambroxol simultaneously) . At the time points of 2, 12, 24, 48, 72 hours six animals in each group were killed and the samples of 1/3 lower segment of trachea were collected and observed by scanning electron microscope. Endotracheal intubation were made on other 6 animals to collecte broncho-alveolar lavage fluid ( BALF) for leucocyte count. Results Compared with the normal control group, elevated leucocyte count was observed in all other groups, various grades of swelling of the cilia were revealed, followed by more or less cilia laid flat with adjacent cilia conglutinated. Then partial cell membrane on top of some cilia bulged out. In terms of injury, the normal saline group was the most mild, and the amikacin group was most serious with the highest leucocyte count. All the parameters were relieved in ambroxol group. Conclusions Intratracheal instillation of amikacin causes acute injury of the ultrastructure of mucosal surface cilia. Ambroxol can promote the recovery process and alleviate inflammation of airway.
Objective To summarize the clinical experiences in treating primary tracheal tumors by surgery, so as to improve the results of surgical treatment. Methods The clinical data concerning 22 surgically treated patients were retrospectively analyzed. Four patients tumor were benign and eighteen cases’s tumor was malignant. Tracheal resections and end to end anastomosis were performed in 14 cases, carinal resection was performed in 4 cases, lateral tracheal wall resection was performed in 1 case, local scrape were performed in 2 cases, tumor was resected transfiberoptic bronchoscopy in 1 case. Tracheal resectable length was from 2.0cm to 5.2cm,and the average resectable length was 3.8cm in operation. Results 17 cases had been misdiagnosised ( 77.3%) in outpatient department. It was easy to be misdiagnosised as asthma. One case died of respiratory failure after operation in 30 days. The complication rate was 31.8%, complications consist of pneumonia in 4 cases, anastomosis leakage in 1 case and chylothorax in 2 cases. Anastomosis stenosis was found in 3 cases, the syndromes were improved after treatment.Twenty cases were followed up from 1 month to 8 years. Four cases with benign tumors were still alive. Among 16 cases with malignant tumors, 6 cases had survived more than 5 years, 3 cases died of brain, liver, bone metastasis of malignant tumors. Conclusion Surgical resection is the most effective treatment of tracheal tumors. Tracheal resection and reconstruction is the main choice of primary tracheal tumors treatment. Benign tumors can be resected conservatively. The reductions of operative complications are the key points of good surgical results. To know the characteristic of primary tracheal tumors well can reduce the misdiagnosis rate.
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 investigate effect of the removal of epithelium and mixed glands from the tracheal allografts on the graftimmunosuppression. Methods Fresh untreated tracheal allografts, cryopreserved tracheal allografts, and 10 off-epithelium tracheal allografts were obtained from 25 male SD rats. Fresh untreated tracheal allografts(40) were divided into 4 groups and dipped respectively in the solution of protease ⅩⅣ in 0, 0.1, 0.3 and 0.5 mg/ml at 4℃ for 12 hours. Thirty recipient male SD rats were randomly and equally divided into group A (fresh untreated tracheal allografts), group B(cryopreserved tracheal allografts), and group C(offepithelium tracheal allografts). The transplanted allografts were implanted into the abdominal cavity of other rats by being embedded in the greater omentum. Twenty-one days after transplantation, the tracheal graft segments were surgically removed, and then were initially fixed in cold 10% neutral buffered formalin solution for hematoxylineosin staining. Histological observation and lymphocyte infiltration were performed on the grafts to evaluate rejection. Results The 0.3 mg/ml protease ⅩⅣ could remove the epithelium and mixed glands of the grafts completely, but did no damage to cartilage. The cartilages of each group all survived and were revascularized. The lumens of group A were filled with granulation and necrosis tissue. In contrast, group B was filled with a few granulation tissues and group C was not at all. The number of lymphocyte infiltration in group A, B, and C was 29.16±2.69/HP, 15.17±2.19/HP, and 11.56±0.87/HP respectively. There was significant difference between group A and both group B and group C (Plt;0.05), and there was significant difference between group B and group C (Plt;0.05). Therefore, the grade of graftrejectionwas group Agt;group Bgt;group C. Conclusion The 0.3 mg/ml protease ⅩⅣ can completely remove the epithelium and mixed glands of grafts at 4℃ for 12 hours, and it preserves the normal structure of cartilage. The antigenicity of tracheal grafts can be greatly reduced by removing the epithelium and by the cryopreservation. The prior tracheal allograft in the omentum is feasible for the revascularization of the grafts.
Objective To investigate the application and long-termresults of epiglottic in reconstruction of the traumatic laryngotracheal stenosis.Methods From January 1988 to February 2002, 42 patients with traumatic laryngotracheal stenosis were treated, including 33 laryngeal stenosis and9 laryngotracheal stenosis. The following surgical treatment were performed: ① lowered epiglottic andbi-pedicled sternohyoid myofascial flap and ② lowered epiglottic and bipedicledsternohyoid myofascial flap and sternocleidomastoideus clavicle membrane flap. Results Thirty-seven patients(88.1%) were successfully decannulated 10 to 75 daysafter operation. Feeding tube lasted from 9 to 24 days, all the patients rehabilitated deglutition after surgery. The time of using stent was 9 to 19 days in 25cases.All patients were followed up 1 year to 3 years and 4 months. The function of larynx recovered completely in 37 decannulated patients and partially in 5cannulated patients. Conclusion Epiglottic- has the advantages of easy gain, high antiinfection and survival rate, and stable structure. A combination of epiglottic and the bipedicled sternohyoid myofascial flap plus sternocleidomastoideus clavicle membrane flap can repair large laryngeal and tracheal defects.
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 study the research advance in tracheal allografts undergoing revascularization and reepithelialization. Methods Therecent literature concerned was reviewed. The tracheal allografts are embedded in the omentum, which they were revascularized and reepithelialized by planting in self-epithelia, then the allografts with their omental pedicles were transplanted orthotopically to the cervical or the thoracic portion of the trachea. Results Compared withthe onestage tracheal allograft approach using the greater omentum, the twostage approach could increase the successful rate of revascularization and reepithelialization, and made the allografts accord with their physiology. Conclusion If the approach is successful, it can reduce graft-rejection, prevent graft-collapse and increase graft-viability after tracheal allograft.