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This Article Abstract Full Text (PDF) All Versions of this Article: 31/5/1019    most recent 09031936.00099507v1 Alert me when this article is cited Alert me if a correction is posted Permissions Request Permissions Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Lin, S-M. Articles by Kuo, H-P. Search for Related Content PubMed PubMed Citation Articles by Lin, S-M. Articles by Kuo, H-P.

Metallic stent and flexible bronchoscopy without fluoroscopy for acute respiratory failure

¹ Dept of Thoracic Medicine, Chang Gung Memorial Hospital, Chang Gung University, College of Medicine, Taipei, Taiwan. ² Both authors contributed equally to this article.

CORRESPONDENCE: H-P. Kuo, Dept of Thoracic Medicine, Chang Gung Memorial Hospital, 199 Tun-Hwa N. Rd, Taipei, Taiwan. Fax: 886 33272474. E-mail: q8828{at}ms11.hinet.net

Keywords: Bronchoscopy, respiratory failure, stent, Ultraflex

Received: August 3, 2007
Accepted December 13, 2007

	ABSTRACT

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

 
Stent implantation has been reported to facilitate liberation from mechanical ventilation in patients with respiratory failure due to central airway disease. The present retrospective cohort study sought to evaluate the risk and benefit of stent implantation via bronchoscopy without fluoroscopic guidance in mechanically ventilated patients.

From July 2001 to September 2006, 26 patients with acute respiratory failure were recruited. A bronchoscope was inserted through a mouth guard into the space between the tracheal wall and the endotracheal tube. A guide wire was inserted via the flexible bronchoscope to the lesion site. The bronchoscope was reintroduced through the endotracheal tube. Under bronchoscopic visualisation, the delivery catheter was advanced over the guide wire to deploy the stent.

These procedures were successfully performed in 26 patients, with 22 stents placed in the trachea and seven in the main bronchus. Of the 26 patients, 14 (53.8%) became ventilator independent during their stay in the intensive care unit. Severe pneumonia was the most common cause, in seven (58.3%) out of 12 patients, for continued ventilator dependence after stenting. Granulation tissue formation was found in seven patients during the follow-up period.

It is concluded that metallic stents can be safely implanted without fluoroscopic guidance in patients with respiratory failure, to facilitate ventilator independence.

Patients who have symptoms associated with central airway lesions should be treated with a multidisciplinary approach, including surgical, medical and endoscopic intervention 1–3. Self-expandable metallic stents (SEMSs) have been widely used in the past decade to treat patients with benign and malignant airway diseases. They have been successfully implanted using a flexible bronchoscope while the patient received conscious sedation and a local anaesthetic 4–6. Due to potentially hazardous complications, the US Food and Drug Administration (FDA) has warned that SEMS implantation should be considered only if the patient is not eligible for surgery, rigid bronchoscopy or silicone stent implantation. For patients who are not candidates for surgery or general anaesthesia, SEMS implantation may provide a good alternative 7. Covered SEMSs have been used to seal off tracheo-oesophageal fistulas and to avoid aspiration symptoms 8–10.

Among patients with obstruction of the trachea and main stem bronchi, respiratory failure is one of the most severe complications. Due to advances in endobronchial stents and insertion techniques, interventional bronchoscopic procedures have been reported to facilitate weaning from mechanical ventilation 11–14. Rigid bronchoscopy under general anaesthesia and flexible bronchoscopy under fluoroscopic guidance are the most common methods of stent implantation in mechanically ventilated patients. Some patients, however, are not candidates for surgical intervention or rigid bronchoscopy with a general anaesthetic because of illness severity and comorbidities or because they refuse surgery. In addition, fluoroscopy requires special facilities that may not be available in every intensive care unit (ICU). Therefore, the present authors have developed a modified procedure to implant stents using flexible bronchoscopy without fluoroscopic guidance in mechanically ventilated patients in the ICU at the Chang Gung Memorial Hospital (Taipei, Taiwan).

The current study was designed to evaluate the safety, efficacy and complications of this procedure. Furthermore, the possible causes of failure of the procedure to eliminate the need for a mechanical ventilator were identified.

	MATERIALS AND METHODS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

 
Patient recruitment
From July 2001 to September 2006, 29 tracheobronchial stents were implanted in 26 consecutive patients with respiratory failure associated with central airway obstruction or fistula in an ICU of a tertiary hospital. Informed consent was obtained from each patient or their guardian prior to this procedure. Most of the patients (21 out of 26) had malignant diseases at an advanced stage, with or without complications. For those with benign lesions, other medical conditions or complications precluded some of them from surgical correction. Due to illness severity, high surgical risk or surgical refusal, none of these patients were candidates for surgery or stent implantation under rigid bronchoscopy. Patients' baseline characteristics are shown in table 1. Ventilator liberation was defined as successful if re-intubation was not required within 48 h after endotracheal extubation.

View larger version (91K): [in this window] [in a new window]   Fig. 1— a) Tracheal stenosis caused by tumour invasion. b) The guide wire was inserted via a bronchoscope through the lesion, outside the endotracheal tube. c) The guide wire was left at the lesion site. d) The delivery catheter (Boston Scientific, Natick, MA, USA) deployed the stent under bronchoscopic guidance. e) An Ultraflex stent (Boston Scientific) was successfully implanted.

Assessment of stent condition
Each patient underwent bronchoscopic examination 1 week after SEMS implantation, and then every 3–6 months thereafter, to evaluate the position and integrity of the stent and granuloma formation. The alignment of the airway was assessed before and after stent implantation. If breathlessness, intractable coughing, increased mucus production or stent-related symptoms occurred, additional bronchoscopic examination was performed for further assessment.

Statistical analysis
Data were expressed as mean±SD. The factors potentially associated with successful liberation from mechanical ventilation were compared using the Fisher exact test. Odds ratios and their 95% confidence intervals were used to assess the difference.

	RESULTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

 
The patients' baseline characteristics are summarised in table 1. All procedures were performed successfully. The procedure time was 24.2±8.8 min. During the procedure, 100% oxygenation and assistant/control mode-ventilator support were given to the patients. All the patients underwent pulse oxymeter and arterial line monitoring for oxygen saturation and blood pressure, respectively. There was no desaturation <90% or hypotension (systolic blood pressure <90 mmHg) requiring medical intervention during or after the procedure. Malignant diseases contributed to lesions in 21 patients; oesophageal cancer was the most common aetiology, followed by lung cancer and buccal cancer. The locations and causes of central airway lesions are summarised in table 2. Tracheo-oesophageal fistula, tumour invasion and tumour compression were the three most common causes for stent implantation. The 22 tracheal stents were of varying size (16x40 mm (n = 1), 16x80 mm (n = 2), 18x40 mm (n = 3), 18x60 mm (n = 8), 20x60 mm (n = 4) and 20x80 mm (n = 4)) and were chosen according to lesion size; two stents were uncovered. The seven main bronchus stents were of varying size as follows: 10x40 mm (n = 1), 12x40 mm (n = 1), 14x40 mm (n = 3), 16x60 mm (n = 1) and 18x60 mm (n = 1); all were covered.

View larger version (10K): [in this window] [in a new window]   Fig. 2— The percentage of patients remaining on mechanical ventilation after stent implantation. Of 26 patients, 14 (53.8%) were ventilator independent after stent implantation; 13 of these were free from the ventilatory support within 1 day of stent implantation.

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

The average diameter of the adult trachea is >20 mm 16. The inner diameter of an endotracheal tube is 7.5 mm and the outer diameter is 10–11 mm. Given the elastic character of the trachea, when using a 7.26-mm diameter No. 22Fr delivery catheter (Boston Scientific), there was enough space for the catheter carrying the stent to pass outside the endotracheal tube. The average time for stent implantation was 24.2 min. The risks of thoracic surgery and radiation exposure during fluoroscopy were avoided using the present method. The use of flexible rather than rigid bronchoscopy for airway stent implantation has long been a subject of debate 17, 18. Both techniques have advantages in different respects. Rigid tools provide a wide view of the operating space. Silicone and dynamic stents are designed to be implanted using a rigid bronchoscope. Flexible bronchoscopy with fluoroscopic guidance allows more pneumologists to perform stent implantation, thus averting operating room costs and the risks of general anaesthesia 4. Unlike fluoroscopy, the method described in the present study provided direct visualisation of stent deployment, which decreases the chance of stent malpositioning. The use of the present technique also provides broader accessibility for mechanically ventilated patients unsuitable for surgery, and would be a viable alternative when surgical or fluoroscopic equipment is not available.

The easy accessibility of flexible bronchoscopy has made SEMSs increasingly popular 7, 19, 20. Due to potential complications and the difficulty of removing Ultraflex SEMSs from patients with benign lesions, the US FDA has warned that SEMS implantation should only be considered for patients with benign lesions if they are not candidates for surgery, rigid bronchoscopy or silicone stent implantation. All patients in the present study were in a critical condition; therefore, general anaesthesia, rigid bronchoscopy and subsequent silicone stent implantation were not feasible.

The ventilator liberation rate in the present study was 53.8%, which is similar to that obtained in a previous study 12. Among the causes of ventilator liberation failure after stenting, severe pneumonia was the most common reason. Pneumonia is a frequent complication in patients with central airway disease, due to inadequate drainage of secretions. The implantation of an SEMS should be assessed carefully in these patients, especially if the lobes involved are not directly related to the obstructed airway. Using this new method of stent implantation, a multicentre prospective study is essential for investigation of the factors leading to ventilator liberation failure among patients with respiratory failure due to central airway disease.

In the present study, the incidence of granulation tissue formation (26.9%) after stent implantation was similar to that previously reported in mechanically ventilated patients 14. Pneumothorax occurred in one patient after stent implantation but resolved spontaneously. Interventional bronchoscopy has the inherent risk of causing pneumothorax when positive pressure ventilation is used 21. In addition, the elevated airway pressure caused by the bronchoscope and delivery catheter in the trachea may also contribute to the development of pneumothorax.

In conclusion, the current study describes a new method of stent implantation in mechanically ventilated patients with central airway lesions. This method is potentially safe and time saving, and facilitates ventilator independence for the patient. Severe pneumonia may be a negative factor for ventilator discontinuation after airway stenting.

	Statement of interest

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

 
None declared.

	REFERENCES

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION Statement of interest REFERENCES

 

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This Article Abstract Full Text (PDF) All Versions of this Article: 31/5/1019    most recent 09031936.00099507v1 Alert me when this article is cited Alert me if a correction is posted Permissions Request Permissions Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Lin, S-M. Articles by Kuo, H-P. Search for Related Content PubMed PubMed Citation Articles by Lin, S-M. Articles by Kuo, H-P.