Lixia Liang

Nonintubated Video-Assisted Thoracoscopic Surgery Under Epidural Anesthesia Compared With Conventional Anesthetic Option A Randomized Control Study

Objective. The purposes of this study were to evaluate the feasibility, safety, and advantages of nonintubated video-assisted thoracoscopic surgery (VATS) under epidural anesthesia, by comparing with the performance of conventional approaches. Patients and methods. A total of 354 patients (245 men and 109 women) were recruited in this study. The surgical procedures included bullae resection, pulmonary wedge resection, and lobectomy. The anesthetic technique (epidural vs general) was selected randomly. Patients who underwent nonintubated VATS under epidural anesthesia comprised the intervention group, and patients who received VATS under general anesthesia with double lumen tube comprised the control group. Results. In total, 167 patients were included in the intervention group, and 180 patients were included in the control group. The 2 treatment groups of bullae resection showed significant differences in postoperative fasting time, duration of postoperative antibiotic use depending on the time when the white blood cells decreased to normal levels, and duration of postoperative hospital stay (P < .05). Nonintubated VATS is associated with a decreased level of inflammatory cytokines (P < .05). Conclusion. VATS under anesthesia with nontracheal intubation is safe and feasible, and has demonstrated advantages, including shorter postoperative fasting time, shorter duration of antibiotic use, and shorter hospital stay, compared with VATS under general anesthesia with double lumen tube.

Anesthesia with nontracheal intubation in thoracic surgery

OBJECTIVE To study one-lung respiration during VATS wedge resection of bullae and pulmonary nodules with nontracheal intubation, and to explore the changes of vital signs when patients return to two-lung ventilation. METHODS Twenty-two patients with normal cardiopulmonary function and absence of contraindications to epidural anesthesia were included in this study. VATS wedge resection of bullae or pulmonary nodules was performed. 0.5% Ropivacain was administrated for epidural anesthesia (T8-9), and 2 mL of 2% lidocaine was used for local anesthetic block of the intrathoracic vagus nerves. The BIS value was maintained between 50 and 70 by target-controlled infusion of propofol and remifentanil. Electrocardiogram (ECG), heart rate (HR), blood pressure (Bp), pulse oxygen saturation (SpO(2)), respiratory rate (RR), bispectral index (BIS) and urine volume were monitored. RESULTS None patients were converted to endotracheal intubation during anesthesia. MAP and SpO(2) after wound disclosure were stable (P>0.05), level of CVP significantly elevated, HR and RR increased (P<0.05), PaCO(2) increased gradually while PaO(2) remained stable. Fifteen minutes after wound closure, MAP, RR and SpO(2) returned to their pre-anesthesia levels, PH value gradually recovered, PaCO(2) tended to decrease and returned to normal one hour after wound closure. Physical agitation occurred in one case due to inadequate epidural anesthesia during skin incision. Cough before intrathoracic vagal blockade was noted in two cases (9.1%) because of lobe traction. CONCLUSIONS Nontracheal intubation is feasible in VATS wedge resection of bullae and pulmonary nodules. The patients are with stable intraoperative vital signs and none experiences hypoxemia; intraoperative hypercapnia is tolerable and transient, which can be improved quickly when bilateral lungs resume spontaneous respiration.

Analysis of feasibility and safety of complete video-assisted thoracoscopic resection of anatomic pulmonary segments under non-intubated anesthesia

OBJECTIVE To explore the feasibility and safety of complete video-assisted thoracoscopic surgery (C-VATS) under non-intubated anesthesia for the resection of anatomic pulmonary segments in the treatment of early lung cancer (T1N0M0), benign lung diseases and lung metastases. METHODS The clinical data of patients undergoing resection of anatomic pulmonary segments using C-VATS under non-intubated anesthesia in the First Affiliated Hospital of Guangzhou Medical University from July 2011 to November 2013 were retrospectively analyzed to evaluate the feasibility and safety of this technique. RESULTS The procedures were successfully completed in 15 patients, including four men and eleven women. The average age was 47 [21-74] years. There were ten patients with adenocarcinoma, one with pulmonary metastases, and four with benign lung lesions. The resected sites included: right upper apical segment, two; right lower dorsal segment, one; right lower basal segment, two; left upper lingular segment, three; left upper apical segment, one; left upper anterior apical segment, two; left upper posterior segment, one; left lower basal segment, one; left upper posterior and apical segments, one; and left upper anterior and apical segments plus wedge resection of the posterior segment, one. One case had intraoperative bleeding, which was controlled with thoracoscopic operation and no blood transfusion was required. No thoracotomy or perioperative death was noted. Two patients had postoperative bleeding without the need for blood transfusions, and were cured and discharged. The pathologic stage for all patients with primary lung cancer was IA. After 4-19 months of follow-up, no tumor recurrence and metastasis was found. The overall mean operative length was 166 minutes (range 65-285 minutes), mean blood loss 75 mL (range 5-1,450 mL), mean postoperative chest drainage 294 mL (range 0-1,165 mL), mean chest drainage time 2 days (range 0-5 days), and mean postoperative hospital stay 5 days (range 3-8 days). CONCLUSIONS Complete video-assisted throacoscopic segmentectomy under anesthesia without endotracheal intubation is a safe and feasible technique that can be used to treat a selected group of IA patients with primary lung cancer, lung metastases and benign diseases.

Non-intubated resection and reconstruction of trachea for the treatment of a mass in the upper trachea

Tumors of the upper trachea are typically treated by tracheal resection and reconstruction via neck incision under general anesthesia. In recent years, non-intubated thoracic surgery has been widely applied for the treatment of lung diseases due to its advantages including quick postoperative recovery. In this article, we describe the application of non-intubated tracheal resection and reconstruction in one patient for the treatment of a mass in upper trachea.

Complete video-assisted thoracoscopic surgery (VATS) bronchial sleeve lobectomy

BACKGROUND To explore the effectiveness of video-assisted thoracoscopic surgery (VATS) bronchial sleeve resection and reconstruction. METHODS The clinical data of patients who had received VATS bronchial sleeve lobectomy in our center from January 2008 to February 2015 were retrospectively analyzed. RESULTS Totally 118 patients (105 men and 13 women) received the VATS bronchial sleeve lobectomy. The procedures included sleeve resection of right upper lobe (n=59), right middle lobe (n=7), right lower lobe (n=8), left upper lobe (n=34), and left lower lobe (n=10). The lesions were confirmed to be squamous cell carcinoma (n=68), adenocarcinoma (n=16), mucoepidermoid carcinoma (n=8), adenosquamous carcinoma (n=7), large cell carcinoma (n=1), carcinoids (n=5), and others (n=13; including small cell carcinoma, pleomorphic carcinoma, and inflammatory myofibroblastic tumor). Operations lasted 118-223 min [mean ± standard deviations (SD): 124.00±31.75 min]. The length of removed bronchus was 1.50-2.00 cm (mean ± SD: 1.75±0.26 cm). The duration of bronchial anastomosis (from the first puncture to the completion of knotting) was 15-42 min (mean ± SD: 30.20±7.97 min). The number of dissected lymph node stations (at least three mediastinal lymph node stations, including station 7) was 5-9 stations (mean ± SD: 6.50±1.18 min). The number of dissected lymph nodes was 10-46 (mean ± SD: 26.00±10.48). The intraoperative blood loss was 20-400 mL (mean ± SD: 71.00±43.95 mL), and no blood transfusion was performed. All patients were observed in intensive care unit (ICU) for 1 day. Postoperative drainage was performed for 3-8 days (mean ± SD: 5.00±1.49 days). Postoperative hospital stay was 3-8 days (mean ± SD: 5.10±2.07 days). CONCLUSIONS VATS bronchial sleeve resection and reconstruction is a safe and feasible technique.

Video-assisted transthoracic surgery resection of a tracheal mass and reconstruction of trachea under non-intubated anesthesia with spontaneous breathing

Radical surgery for tracheal tumors is typically completed under basal anesthesia. Thus, endotracheal intubation and mechanical ventilation are required. However, these procedures may influence the surgical operation and meanwhile prolong the surgical duration and postoperative recovery. In this article we describe the application of video-assisted transthoracic surgery (VATS) resection of a tracheal mass and reconstruction of trachea a non-intubated patient with spontaneous breathing.

Non-intubated combined with video-assisted thoracoscopic in carinal reconstruction

Carinal reconstruction is a difficult technique combined with video-assisted thoracoscopic surgery (VATS). It has a high requirement on the operators skills in operating thoracoscope and meanwhile requires the close cooperation from anesthesiologists. Tracheal intubation and ventilator-assisted ventilation are key steps to ensure the success of surgery. However, tracheal intubation itself may influence the exposure of surgical field and increase the difficulty of anastomosis. In close cooperation of anesthesiologists, we did not perform tracheal intubation; rather, we carried out non-intubated complete VATS carinal reconstruction in a patient with adenoid cystic carcinoma (ACC) of the lower trachea. The awake complete VATS carinal reconstruction was successfully performed. The anastomosis lasted about 36 hours, and the whole surgical procedure lasted 230 min. The intraoperative blood loss was about 80 mL. The patient recovered well 100 min after surgery. A semi-solid diet began 6 hours following the surgery. This non-intubated anesthesia method makes the surgery easier, especially during the anastomosis of stumps. It is feasible and safe to apply this anesthesia technique in carinal reconstruction.

Right, middle, and lower bronchial sleeve lobectomy by video-assisted thoracic surgery

Surgical treatment remains the most effective approach to extending the long-term survival of patients with lung cancer (1). However, for tumors that have already invaded the orifice of upper lobe bronchus and/or main bronchus, lobectomy alone can not completely remove the tumors, whereas pneumonectomy will severely damage the lung functions. On the contrary, bronchial sleeve lobectomy is featured by not only the maximal resection of tumors but also the maximal reservation of the normal lung tissues and lung functions and the remarkably decreased complications.

Thoracoscopic surgery for tracheal and carinal resection and reconstruction under spontaneous ventilation

Objectives: To describe and assess the techniques of spontaneous‐ventilation video‐assisted thoracoscopic surgery (SV‐VATS) for tracheal/carinal resections and compare the outcomes with the conventional thoracoscopic intubated method. Methods: From May 2015 to November 2016, some 18 consecutive patients with malignant or benign diseases invading distal trachea and carina who met the criteria for SV were treated by SV‐VATS resection. To evaluate the feasibility of this novel technique, they were compared with a control group consisting of 14 consecutive patients with the same diseases who underwent VATS resection using intubated general anesthesia from October 2014 to April 2015. Data were collected with a median follow‐up of 10.2 months 75 (range: 1–27). Results: The SV‐VATS group consisted of 4 carinal resections and 14 tracheal resections. In the control group, 2 patients underwent carinal resection and 12 underwent tracheal resection. Median operative time was shorter in the SV‐VATS group compared with the intubated group (162.5 minutes vs 260 minutes), as was the median time for tracheal end‐to‐end anastomosis (22.5 minutes vs 45 minutes) and carinal reconstruction (40 minutes vs 86 minutes). The lowest oxygen saturation during the procedure was 94.2% ± 4.9% in SV‐VATS group and 93.9% ± 4.5% in the control group. The peak carbon dioxide level at the end of expiration was greater in the SV‐VATS group (47.7 ± 4.2 mm Hg vs 39.1 ± 5.7 mm Hg). No conversion to tracheal intubation was needed in the SV‐VATS group. Postoperative complications occurred in 6 patients in the SV‐VATS group and 9 in the control group. Patients who underwent SV‐VATS had a trend toward shorter postoperative hospital stays (11.5 ± 4.3 days vs 13.2 ± 6.3 days). One recurrence (SV‐VATS group) and 2 deaths (one in each group) were observed during follow‐up. Conclusions: SV‐VATS is a feasible procedure in tracheal and carinal resection and reconstruction in highly selected patients. It can be a valid alternative to conventional intubated VATS for airway surgery.

Nonintubated Spontaneous Respiration Anesthesia for Tracheal Glomus Tumor

Previous tracheal surgeries were performed under tracheal and cross-field intubation. However, the intubation would lead to bleeding if the tumors were large or hemorrhagic. Moreover, the tracheal intubation might interfere the surgical vision and anastomosis during the reconstruction process. Therefore, we performed a tracheal tumor resection and reconstruction via nonintubated spontaneous anesthesia. We describe the feasibility and safety of tracheal surgeries via such anesthesia.