Objective To investigate the efficacy and influential factors of interventional therapy for post-intubation tracheal stenosis. Methods The clinical data of 69 patients with tracheal stenosis after tracheal intubation in the First Affiliated Hospital of Guangzhou Medical University from February 2010 to March 2015 were retrospectively analyzed. The effects of interventional treatment for tracheal stenosis after intubation were evaluated by reviewing the medical records and telephone follow-up for more than 1 year. Multivariate logistic regression model was used to analyze the influential factors. Results The study recruited 69 patients with the median age of 44 years. After the interventional treatment, ATS dyspnea score decreased from (2.41±0.76) points to (0.65±0.62) points ( P<0.01), the diameter of airway lumen increased from (4.24±2.05)mm to (10.57±3.14)mm ( P<0.01). The short-term effective rate of interventional therapy was 92.8% (64/69) but the restenosis rate in 1 month, 3 months and 1 year after interventional treatment were 56.5%, 26.1% and 36.2%, respectively. Multivariate logistic regression analysis showed that diabetes (OR=2.819, 95%CI 1.973-4.062), shortness of breath score >3 points (OR=13.816, 95%CI 5.848-32.641), trachea stenosis diameter <4.5 mm (OR=7.482, 95%CI 4.015-13.943), tracheal stenosis grade ≥4 (OR=3.815, 95%CI 2.258-6.447), stenosis in the upper trachea (OR=5.173, 95%CI 3.218-8.316) were risk factors of interventional therapy for post-intubation tracheal stenosis. Conclusions The general efficacy of interventional treatment for tracheal stenosis after tracheal intubation is poor, and the recurrence rate is still high. The high degree of tracheal stenosis, diabetes mellitus and upper tracheal stenosis are important factors that affect the efficacy of respiratory interventional therapy.
In tracheal resection and reconstruction, a technically demanding, complex, and high-risk procedure, management of the anastomotic site significantly impacts postoperative outcomes and long-term quality of life. However, comprehensive studies detailing perioperative anastomotic management strategies in tracheal reconstruction remain scarce. This review summarizes perioperative management strategies for tracheal reconstruction, covering preoperative assessment, surgical techniques, and other key aspects. It also highlights future research directions and challenges, aiming to provide clinicians with a systematic guide to perioperative management in tracheal reconstruction.
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 investigate the current situation of salivation in patients with orotracheal cannula, and to systematically analyze its influencing factors. Methods Patients who underwent tracheal intubation treatment in 47 tertiary comprehensive medical institutions were selected between October 10th and 20th, 2023. A cross-sectional survey method was used to conduct an online survey of the patient’s salivation status. The patients were divided into the salivation group and no-salivation group. Results A total of 565 questionnaires were collected and 561 were valid, with an effective recovery rate of 99%. Among 561 patients, 284 were males (50.62%) and 277 were females (49.38%), with an age of (59.80±10.96) years; 159 cases of salivation occurred, with a total static saliva flow rate of (7.21±3.15) mL and the incidence of salivation was 28.34% (159/561). There were statistically significant differences in age, education level, body mass index, primary disease, number of concurrent functional impairments, concurrent oral diseases, smoking, intubation days, intubation depth, intubation process, sedation and/or analgesia days, and enteral nutrition treatment between the two groups (P<0.05). There was no statistically significant difference in other indicators between the two groups (P>0.05). The results of multivariate logistic regression analysis showed that body mass index, neurological diseases, number of concurrent functional impairments, concurrent oral diseases, smoking, intubation days and intubation process were independent risk factors for salivation in patients with oral catheterization. Conclusion The incidence of salivation in patients with orotracheal cannula is 28.34%, which is directly related to body mass index, neurological diseases, number of concurrent functional impairments, concurrent oral diseases, smoking, intubation days and intubation process.
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.
ObjectiveTo evaluate the difference between the tracheal intubation connected to conventional ventilation (TI-CV) and rigid bronchoscopy connected to high frequency ventilation (RB-HFV) under general anesthesia on patients with transbronchial cryobiopsy (TBCB).MethodA prospective, randomized, controlled trial was conducted in interstitial lung disease patients with TBCB from August 2018 to February 2019 in the First Affiliated Hospital of Guangzhou Medical University. According to the different methods of intubation, the patients were divided to a TI-CV group and a RB-HFV group randomly. The operating duration, extubation duration, total anesthesia time, heart rate, blood pressure and arterial blood gas analysis were collected and analyzed.ResultsSixty-five patients were enrolled. There were 33 patients with an average age of (48.0±15.0) years in TI-CV group and 32 patients with an average age of (48.8±10.8) years in RB-HFV group. The basic line of body mass index, pulmonary function (FEV1, FVC and DLCO), arterial blood gas (pH, PaO2 and PaCO2) and heart rate (HR), mean arterial pressure (MAP) had no significant differences between two groups. At the first 5 minutes of operation, the pH was (7.34±0.06) and (7.26±0.06), and the PaCO2 was (48.82±9.53) and (62.76±9.80) mm Hg in TI-CV group and RB-HFV group respectively, with significant differences (P=0.000). At the end of operation, the pH was (7.33±0.06) and (7.21±0.08), the PaCO2 was (48.91±10.49) and (70.93±14.83) mm Hg, the HR were (79.6±21.1) and (93.8±18.7) bpm, the MAP were (72.15±13.03) and (82.63±15.65) mm Hg in TI-CV group and RB-HFV group respectively, with significant differences (P<0.05). There were no differences in the operating duration and extubation duration between two groups. The total anesthesia time was (47.4±8.8) and (53.3±11.6) min with significant difference (P=0.017). Five minutes after the extubation, there were no significant difference in the pH, PaO2, PaCO2, HR and MAP between two groups. No serious complications occurred in either group.ConclusionsCompared with rigid bronchoscopy, TI-CV under general anesthesia is more conducive to maintain effective ventilation, and maintain the HR and MAP stable during the TBCB procedure. TBCB procedure should be performed by TI-CV under general anesthesia in patients with poor cardiopulmonary function.
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 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.
ObjectiveTo investigate that the TGF- beta/Smad signaling pathway mediated epithelial mesenchymal transition (EMT) in trachea stenosis after transplantation. Methods180-220 g male rats (n=50) were randomly divided into a control group and an experimental group. no surgical operation rats were in the control group. tracheal transplantation rats (Wistar-SD rat) were in the experimental group. Graft specimens were obtained in rats on 3,7,10,14,35,90 days after operation. HE staining is used to explain the fibrosis degree of tracheal stenosis. The fibrosis degree of tracheal stenosis was detected by calculating the fibrosis rate. Immunohistochemical staining was used to detect transplanted tracheal, such as EMT related molecules E-cadherin, vimentin, alpha-SMA expression, p-Smad2/3 expression and transcription factor ZEB1, Snail1 expression in tracheal graft specimens. ResultsHE staining showed that the tracheal fibrosis rate of the control group was 0.171±0.020, fibrosis rate was 0.537±0.013 (P < 0.01) on the third day after transplantation. The result of immunohistochemical staining showed that vimentin positive epithelial cells increased significantly (P < 0.05). E-cadherin expression significantly reduced (P < 0.05). Compared with the control group, TGF- beta expression increased (P < 0.05) in the experiment group. Compared with the control group, the expression of p-Smad2/3, the transcription factor ZEB1 and Snail1 significantly increased (P < 0.05) in the experiment group. ConclusionMechanism of tracheal stenosis may be due to EMT. At the same time, TGF- beta/Smad signaling pathway and transcription factor ZEB1, Snail1 may regulate the EMT.
Stent migration is one of the common complications after tracheal stent implantation. The causes of stent migration include size mismatch between the stent and the trachea, physiological movement of the trachea, and so on. In order to solve the above problems, this study designed a non-uniform Poisson ratio tracheal stent by combining the size and structure of the trachea and the physiological movement of the trachea to improve the migration of the stent, meanwhile ensuring the support of the stent. In this study, the stent corresponding to cartilage was constructed with negative Poisson's ratio, and the stent corresponding to the circular connective tissue and muscular membrane was constructed with positive Poisson's ratio. And four kinds of non-uniform Poisson's ratio tracheal stents with different link lengths and negative Poisson's ratio were designed. Then, this paper numerically simulated the expansion and rebound process of the stent after implantation to observe the support of the stent, and further simulated the stretch movement of the trachea to calculate the diameter changes of the stent corresponding to different negative Poisson's ratio structures. The axial migration of the stent was recorded by applying different respiratory pressure to the wall of the tracheal wall to evaluate whether the stent has anti-migration effect. The research results show that the non-uniform Poisson ratio stent with connecting rod length of 3 mm has the largest diameter expansion in the negative Poisson ratio section when the trachea was stretched. Compared with the positive Poisson's ratio structure, the axial migration during vigorous breathing was reduced from 0.024 mm to 0.012 mm. The negative Poisson's ratio structure of the non-uniform Poisson's ratio stent designed in this study did not fail in the tracheal expansion effect. Compared with the traditional stent, the non-uniform Poisson's ratio tracheal stent has an anti-migration effect under the normal movement of the trachea while ensuring the support force of the stent.