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Kardiochirurgia i Torakochirurgia Polska/Polish Journal of Thoracic and Cardiovascular Surgery
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1/2021
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Original paper

First experiences in non-intubated, video-assisted thoracoscopic surgery: a single-centre study

Tayfun Kermenli
1
,
Cebrail Azar
2
,
Zafer Gundogdu
3

  1. Department of Thoracic Surgery, Istanbul Aydın University, Istanbul, Turkey
  2. Department of Chest Diseases, Medicalpark Elazığ Hospital, Istinye University, Istanbul, Turkey
  3. Department of Aesthesiology and Reanimation, Medicalpark Elazığ Hospital, Istinye University, Istanbul, Turkey
Kardiochir Torakochir Pol 2021; 18 (1): 15-22
DOI: https://doi.org/10.5114/kitp.2021.105181
Online publish date: 2021/05/15
Article file
- First experiences.pdf  [0.35 MB]
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Introduction

Single lung ventilation under general anaesthesia is the traditional anaesthesia technique used for chest surgery operations. This method creates a safe and optimal workspace for manipulations in thoracotomy and video-assisted thoracoscopic surgery (VATS) during surgery. On the other hand, with the help of video-assisted thoracoscopy in thoracic surgery, uniportal or biportal incisions have started to be used, and a tendency towards using a less invasive technique has occurred [1]. This situation also led to the development and change of anaesthesia techniques [2]. While single lung ventilation was performed with options such as bronchial blocker or double-lumen intubation, case series with increasing rates of non-intubated surgery have been reported in the literature in recent years [3]. In some studies, it is thought that general anaesthesia and deep sedation applied in thoracic surgery operations may cause more cognitive dysfunction than regional anaesthesia. On the other hand, it has been reported that single lung ventilation can increase atelectasis by creating perfusion inbalance [4]. As a result, in the postoperative period, spontaneous breathing was preferred to mechanical ventilation, for the respiratory parameters to return to normal more rapidly.

The most important issue for non-intubated VATS (NI-VATS) is to provide a spontaneous pneumothorax as the surgeon enters the thorax. In this way, perfect lung isolation can be achieved without the need for positive pressure ventilation in the opposite lung [5]. When supported with local anaesthesia, it is an extremely comfortable anaesthesia technique for the patient. In many studies, the hospital stay is shortened with this technique, postoperative recovery speeds up and general anaesthesia side effects are not seen, and hospital costs are also decreasing [6]. It has been shown that many video thoracoscopic surgeries, including anatomical lung resections, can be performed safely, with many reported patient series [7].

For non-intubated video-assisted thoracoscopic surgery, it is recommended that appropriate patients be selected at the initial stage, especially before the surgical and anaesthesia team gains experience [8]. It is reported that these cases should include pleural biopsy, peripheral lung nodule, or mediastinal mass biopsy [9]. In line with this information, we started our first experiences by selecting patients with suitable NI-VATS.

Aim

In this article, we shared the results of our patients who underwent mediastinal biopsy, pleural biopsy, lung wedge resection, and pleural delocculation with NI-VATS.

Material and methods

Patients who underwent surgery with non-intubated VATS between March 2015 and May 2020 in our clinic were included in the study. Written informed consent was obtained from each patient. The study was conducted in accordance with the principles of the Declaration of Helsinki. In the first period, from the patients who were scheduled to undergo a pleural biopsy, patients with a high general anaesthesia risk and a short estimated duration of surgery were NI-VATS technique was preferred. However, following the increase in the experience of the anaesthesia and surgical team, patients in whom ASA I-IV, pleural biopsy, peripheral nodule, lung biopsy, or wedge resection were planned, mediastinal mass biopsy, pneumothorax surgery, and empyema delocculation were also included. The patients were informed before the operation, and this technique was applied to the patients who preferred NI-VATS. Patient selection and exclusion criteria for non-intubated anaesthesia are given in Table I.

Table I

Inclusion and exclusion criteria of patients

Inclusion criteriaExclusion criteria

  1. The duration of surgery is less than 2 hours

  2. Patients who are scheduled for pleural biopsy, lung biopsy, pulmonary wedge resection, pneumothorax surgery, or mediastinal tumour biopsy

  3. No major bleeding risk

  4. Non-obese patients BMI< 30 kg/m2

  5. Patients without a difficult intubation history

  6. No respiratory distress

  7. No serious arrhythmia or cardiac disease

  1. The history of having thoracic surgery on the same hemithorax

  2. Patients with complex surgery planned

  3. People with known allergies to local anaesthetics

  4. Patients with abnormalities in bleeding parameters

  5. Obese patients BMI > 30 kg/m2

  6. Difficult intubation history and short neck

  7. Hypoxaemia (PaO2 < 60 mm Hg) or preoperative hypercapnia (PaCO2 > 50 mm Hg)

Sedation and local anaesthesia technique

The patients were evaluated in detail by the anaesthesia team before, and their preparations were made as they would be for routinely applied for general anaesthesia. In case of intubation requirement, they were informed about what to do, and an anaesthesia informed consent form was obtained from all patients. The patients who were taken to the operating room were primarily monitored; electrocardiogram, pulse rate, blood pressure, oxygen saturation (SpO2), and respiratory rate were followed. During the operation, oxygen saturation was monitored by pulse oximeter, and high-flow oxygen support was given from the nasal cannula to maintain the oxygen saturation above 95%. Following the opening of the patient’s vascular access, midazolam 0.05 mg/kg (Dormicum 15 mg/3 ml) was injected intravenously for sedation. Fentanyl (0.05% mg/ml) 0.5 mg/kg bolus and 6 mg/kg/h infusion or propofol (Propofol 1%, 200 mg/20 ml) 0.5 mg/kg bolus and 3 mg/kg/h infusion were started. As a local anaesthetic, 2.5 ml of 0.5% bupivacaine (Buvasin 0.5%, 20 ml) was applied to the incision site. In the patients who underwent surgery due to spontaneous pneumothorax and pleural abrasion, local anaesthesia was provided to the parietal pleura by giving bupivacaine into the thorax during the perioperative period. Vagal nerve blockade was performed with 0.5% bupivacaine to prevent the cough reflex in patients for whom it was deemed necessary.

Surgical technique

The right or left lateral decubitus position was given to the patients according to the planned surgical procedure. For the mediastinal mass biopsy, a 30° supine position with a back support pad was given. In each patient, a single 2-cm incision was opened as standard, and exploration was performed with a 5-mm 30° thoracoscope camera (Karl Storz endoscope; Karl Storz, Tuttlingen, Germany). When necessary, a second incision was opened and the operation was completed biportally. Endo grasper, endo cautery, endo dissector, and surgical energy devices were used as surgical instruments. At the end of the operation, Hemovac drainage or thorax drains were placed in the thorax according to the surgeon’s preference.

Statistical analysis

All data on clinical results before and after surgery were collected and analysed retrospectively. The findings from the patients were analysed with SPSS software (SPSS Inc., Chicago, IL, USA) using a mean and standard deviation (SD) with a 95% confidence interval (CI). Frequency and percentage were calculated for gender, comorbidity, ASA physical condition class, surgical procedure, and lesion localization. Findings such as anaesthesia induction time, operation time, drain removal time, and hospital stay were recorded.

Results

Between March 2015 and May 20, 32 patients underwent VATS under sedation and local anaesthesia without intubation. All patients were evaluated with appropriate imaging methods such as thorax computed tomography (CT) or positron emission tomography (PET) in the preoperative period. The mean age of the patients was 52.2 ±17.8 years (15–76). Twenty (62.5%) of the patients were male, and 12 (37.5%) were female. As comorbid disease in our patient group, 13 (40.6%) had extra-thoracic malignancy, hypertension 7 (21.9%), heart disease 6 (18.8%), COPD and asthma 5 (15.6%), and 4 (12.5%) patients had diabetes mellitus. According to the ASA (American Society of Anesthesiologists) score in the preoperative evaluation, there were ASA-I: 8, ASA-II: 12, ASA-III: 7, and ASA-IV: 5 patients. Video thoracoscopy procedure was performed for diagnostic purposes in 18 (56.2%) cases and for therapeutic purposes in 14 (43.8%) cases. Demographic and preoperative findings of the patients are given in Table II.

Table II

Clinical characteristics of patients

ParameterNon-intubated group (n = 32)%
Age52.2 ±17.8 (15–76)
Gender:
 Male2062.5
 Female1237.5
Comorbidity:
 Extrathoracic malignancy1340.6
 Hypertension721.9
 Diabetes mellitus412.5
 Cardiac diseases618.8
 COPD, asthma515.6
ASA physical status class:
 I825
 II1237.5
 III721.9
 IV515.6
Surgical procedure:
 Diagnostic1856.2
 Therapeutic1443.8
Lesion localisation:
 Left1031.2
 Right2268.8

Patients were placed on the operating table according to the area to be treated. Mediastinal mass biopsy was performed in a 30° supine position by placing a lower back elevation, and the right or left lateral decubitus position was preferred for other VATS procedures. Twenty-two (68.8%) patients underwent right hemithorax, and the left side was used in 10 (31.2%) patients. Pleural drainage and biopsy were performed in 10 (31.2%) of 32 patients (Figure 1), and wedge resection was performed in 8 patients. Three of these were procedures performed for interstitial lung disease biopsy (Figure 2), and the remaining 5 patients were operated on for metastasectomy due to lung metastasis of extrathoracic malignancy. Bullectomy and apical pleural abrasion were performed in 6 of our patients due to spontaneous pneumothorax (Figure 3). In these patients, local anaesthesia was achieved by applying 50 ml isotonic solution, 10 ml bupivacaine to the thoracic cavity to prevent pleural pain. The mediastinal mass biopsy was performed in 4 (12.5%) patients (Figure 4), and delocculation was performed in 4 (12.5%) patients due to empyema (Table III). Hemovac drains were used in 16 (50%), 20 Fr in 10 (31.2%), and 28 Fr thorax drains in 6 (18.8%) (Table IV).

Table III

Performed surgical procedures

Surgical proceduresNumber of patients%
Pleural drainage and biopsy1031.2
Wedge resection825
Bullectomy and pleural abrasion618.8
Empyema delocculation412.5
Mediastinal tumour biopsy412.5
Table IV

Perioperative and postoperative information of our patients

ParameterValues%
Anaesthetic induction duration [minutes]21 ±3.6 (15–30)
Number of port incisions:
 Uniportal1340.6
 Biportal1959.4
Operation time [minutes]28.4 ±9.56 (18–50)
Drain type:
 Hemovac drain1650
 20 Fr1031.2
 28 Fr618.8
Intraoperative blood loss [ml]16.4 ±0.64 (5–50)
Conversion to thoracotomy0
Conversion to intubation0
VAS score (in postoperative first 24 hours)2 ±0.6 (1–3)
Side effect of anaesthesia:
 Vomiting13
Complications (n = 2, 6%):
 Air leak13
 Cardiac arrythmia13
Drain removal time [days]1.75 ±0.80 (1–4)
Hospital stay [days]2.3 ±1.25 (1–5)
Figure 1

Pleural metastasis of breast ca. A, B – Thorax CT images (arrowhead), C – PET-CT images, D – Intraoperative view of the tumor (yellow arrow)

/f/fulltexts/KiTP/43774/KITP-18-43774-g001_min.jpg
Figure 2

A – Interstitial lung involvement in the posterior segment of the right lung (yellow arrow), B, C – Intraoperative view of wedge resection

/f/fulltexts/KiTP/43774/KITP-18-43774-g002_min.jpg
Figure 3

A, B – Images of apical bullae of the right lung (yellow arrow). C – Intraoperative view of the bullectomy, bullae (asterisk). D – Apical pleural abrasion with prolene mesh (yellow arrow)

/f/fulltexts/KiTP/43774/KITP-18-43774-g003_min.jpg
Figure 4

Thorax CT (A, asterisk) and PET-CT (B, arrowhead) images of anterior mediastinal mass. C – Intraoperative view of the anterior mediastinal mass (asterisk)

/f/fulltexts/KiTP/43774/KITP-18-43774-g004_min.jpg

If the operation time is prolonged, or if the sedative effect disappears in the patient, additional doses of medication are given to continue the sedation. Both the pain-controlling feature and the sedative effect of fentanyl were used. The mean anaesthesia induction time was 21 ±3.6 (15–30) minutes. After an appropriate position was given to the patient, local anaesthesia was applied with bupivacaine to the incision areas planned according to thorax CT before the operation. According to the surgical plan, 1 or 2 ports were opened. While the number of cases we operated uniportally was 13 (40.6%), the number of biportal cases was 19 (59.4%). During the operation, our average blood loss was measured as 16.4 ±0.64 (5–50) ml (Table IV). Following sedation, patients were followed up with spontaneous breathing, and high current oxygen support was provided so that the oxygen saturation did not fall below 95%. There were no patients in our patients who had to undergo intubation or who underwent thoracotomy in the perioperative period.

In the postoperative period, only 1 of our patients complained of nausea that would require medical treatment as a side effect after anaesthesia in their clinical follow-up. The pain scores of the patients at the postoperative 24th hour were measured with the Visual Analogue Scale (VAS) pain scoring technique. The mean VAS score in the first 24 hours postoperatively was found to be 2 ±0.6 (1–3). As a complication, prolonged air leakage was observed in 1 patient and cardiac arrhythmia was observed in 1 patient. The mean drain removal time was 1.75 ±0.80 (1–4) days, and the hospital discharge time was found to be 2.3 ±1.25 (1–5) days. There was no mortality among our patients in the first postoperative month. Perioperative and postoperative information of our patients are given in Table IV.

Discussion

The most important stress source encountered by patients for thoracoscopic surgery is that of providing single lung ventilation with general anaesthesia and double-lumen intubation. In terms of the postoperative period, paralysis caused by general anaesthesia affects the operation of the diaphragmatic muscle and normal respiratory physiology, thus increasing the risk of atelectasis [10]. Also, mechanical ventilation has some potential side effects such as pressure-related injury, lung overstretching, and the release of various pro-inflammatory mediators [11]. These reasons have enabled thoracic surgeons to prefer NI-VATS at increasing rates. On the other hand, it is aimed to avoid postoperative side effects and complications related to general anaesthesia. With this anaesthesia technique, there will be no serious change in normal respiratory physiology, and patient recovery is faster [12].

In our clinic, we preferred non-intubated VATS in our patients who were at high risk in terms of general anaesthesia, but who required surgery for diagnosis, in our ASA-III and IV patients. With the increase of our experience, we have started to use especially in peripheral lung nodules, interstitial lung disease, lung biopsy, mediastinal mass biopsies, empyema delocculation, and pneumothorax treatment. Up to this stage, we have not only performed anatomical lung resection. When choosing our first patients, cases such as pleural biopsy with a short surgery duration and low complication risk were preferred. In our case series, patients with ASA III–IV and high comorbidity were at the forefront, and as our experience increased, the proportion of our ASA I–II patients also increased.

We see that our patient group consists of heterogeneous patients, and we have not performed complex lung surgery yet. However, we can see that complex lung surgeries can be performed safely, with case series reported in the literature. Surgical procedures such as sleeve lung resections were reported after single-port thoracoscopic lobectomy in a non-intubated patient reported by Gonzales [13]. After Shao et al. [14] reported that they successfully performed sleeve resection in a non-intubated patient, there was an increase in the case series in which non-intubated lung resections were performed recently. In these series, we see that epidural anaesthesia is used in addition to sedation and local anaesthesia [14]. In our series, there were no patients who underwent anatomical lung resection, but there were 8 patients who underwent wedge resection. When choosing wedge resection cases, patients with peripheral and single nodules were preferred. On the other hand, we had 3 patients who underwent lung wedge biopsy due to interstitial lung disease. In these patients, we paid attention to criteria such as peripheral involvement, no signs of pleural adhesion in thorax CT, and no respiratory distress.

In addition to pleural diseases, pulmonary peripheral nodules, or lung resections reported from experienced centres, it has been shown that mediastinal tumour surgery can be performed with this technique. Jiang et al. [15] reported that they performed VATS thymectomy safely in 36 patients under spontaneous breathing support. Following this, Liu et al. [16] also reported a non-intubated subxiphoid VATS thymectomy case. Thanks to these studies, it is thought that postoperative myasthenic crisis and postoperative prolonged tracheal intubation can be reduced in myasthenia gravis patients [15, 16]. In our patient series, there were 4 patients who underwent mediastinal mass biopsy, and we did not see any complications in these patients.

The anaesthesia part of non-intubated VATS is also very important. It is known that preoperative anaesthesia preparation for single-lung ventilation in thoracic surgery is a detailed procedure that takes a long time. This extends the time spent by the patient in the operations room in total. Ambrogi et al. [17] showed in their study on 48 patients that the total time spent in the operating room in the non-intubated group was shorter than in the intubated group. The mean was 66 minutes in the non-intubated group, and 78 minutes in the intubated group, which was considered statistically significant [17]. In the meta-analysis of Chen et al., although there are similarities among the patients, it was reported that the time spent in the operations room was shortened, and side effects related to general anaesthesia were not observed [18].

One of the most important factors affecting patient comfort in postoperative follow-up is drain removal time. In our patients, VAS pain scores were measured as 2 ±0.6, and the time to remove the drain was found to be 1.75 ±0.80 days – the low values in these patients shortened the healing process. Hsiao et al. [19] showed that the drainage times of 12 patients who underwent single-port non-intubated VATS due to parapneumonic empyema were significantly lower than in patients who were treated with tube thoracostomy. Drainage days, postoperative fever subsided days, postoperative hospital days, and the total length of stay were evaluated in these patients, and a significant difference was found in all of them [19]. Drain removal time provides early control of postoperative pain. Another feature of this study is that, like our first cases, surgery was successfully performed in patients with coronary artery disease and reduced left ventricular ejection fraction, high risk of general anaesthesia, and high comorbidity [19].

Video-assisted thoracoscopic surgery has some complications such as bleeding, prolonged air leak, and postoperative pain [20]. In our patient series, prolonged air leakage was observed in 1 patient, and arrhythmia was observed in 1 patient. Our complication rate was found to be 6%, but because we are meticulous about patient selection we think that this rate may change with the increasing number of patients. General anaesthesia-related problems in VATS surgery were intubation-related airway trauma, increased risk of pneumonia, ventilator-associated lung injury, impaired cardiac performance, effects of neuromuscular blocking agents, and postoperative nausea and vomiting [21]. As a result of non-intubated VATS application with regional anaesthesia, only 1 patient suffered from nausea requiring medical treatment. We performed the surgical procedure very safely in 32 patients, and we did not have any patients who required intubation or returned to thoracotomy in the perioperative period. However, we think that conditions such as patients considered difficult to intubate, morbidly obese, those with intense pleural adhesions, and central and large tumours should be considered as contraindications for non-intubated VATS, especially until the surgical experience is increased.

When we look at the literature, we see that the recovery time and hospital stay are short in the patient series published [22]. We obtained results compatible with the literature in our patients. Our hospital stay was found to be 2.3 ±1.25 days. Because our patient series included a small number of patients, our study had some limitations. However, we still see that non-intubated VATS is a reliable method in terms of patient comfort and rapid recovery.

Conclusions

The non-intubated VATS approach can be safely applied in procedures such as lung resections, pleural or mediastinal interventions, and pneumothorax surgery. Both teams must be experienced because it is a technique that is dependent on the surgeon and anaesthesia team. With this technique, the absence of intubation and mechanical ventilation provides a faster return to normal respiratory physiology. In this way, the cost of hospital recovery will decrease by reducing the time of patient recovery and hospital stay. The reliability and effectiveness of non-intubated VATS should be evaluated with broader randomized studies.

Disclosure

The authors report no conflict of interest.

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Copyright: © 2021 Polish Society of Cardiothoracic Surgeons (Polskie Towarzystwo KardioTorakochirurgów) and the editors of the Polish Journal of Cardio-Thoracic Surgery (Kardiochirurgia i Torakochirurgia Polska). This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
  
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