Aortopexy for tracheomalacia via a suprasternal incision

Update on aortopexy and posterior tracheopexy for tracheomalacia in patients with esophageal atresia

Despite improving the survival after repair of esophageal atresia (EA), the morbidity of EA repair remains high. Specifically, tracheomalacia (TM) is one of the most frequent complications of EA repair. Continuous positive airway pressure is generally applied for the treatment of TM. However, surgical intervention is required against an apparent life-threatening event or inability to perform extubation for a long period. According to our review, most cases of TM showed symptom improvement after aortopexy. The ratio of the trachea's lateral and anterior-posterior diameter at the brachiocephalic artery crossing the trachea, which reflects the compression of the trachea by the brachiocephalic artery, is a good indicator of aortopexy. Our finding suggests that most TM cases associated with EA may not be caused by tracheal fragility alone, but may involve blood vessel compression. Posterior tracheopexy (PT) is also an effective treatment for TM. Recently, open or thoracoscopic PT was able to be performed simultaneously with EA repair. In many cases, aortopexy or PT is a safe and effective surgical treatment for TM with EA. Other surgical procedures, such as external stenting, should be considered for patients with diffuse-type TM for whom aortopexy and PT appear relatively ineffective.

Factors associated with success following transcervical innominate artery suspension

OBJECTIVE

Aortopexy including innominate artery suspension is a well-established treatment of anterior vascular compression and associated tracheomalacia. We report the results of our case series of cervical approach to innominate artery suspension and hypothesize that increased distance from the innominate to the sternum is predictive of superior symptomatic outcome.

STUDY DESIGN

Retrospective Case Series.

METHODS

All cases of cervical innominate artery suspension at our institution over the last 10 years were reviewed. CT scans of the neck and chest were reviewed to obtain anatomical measurements including anterior-posterior thoracic outlet distance, thymic thickness, and sternum-innominate artery distance. Measurements were compared with surgical outcomes as verified by follow up bronchoscopy and clinical course to determine factors predictive of success.

RESULTS

Ten cases of cervical innominate artery suspension were performed by the otolaryngology service at our institution over the last 10 years. Six patients had improvement in their symptoms. The average sternum-innominate artery distance (SID) was larger (14.4 mm (95% CI 9.1-19.7)) in patients who had improvement in clinical symptoms following innominate suspension compared to those that did not improve (6.3 mm (95% CI 2.5-10.1)) (p value = 0.02). Similarly, the anterior-posterior distance of the thoracic outlet was larger (34.9 mm (95% CI 27.4-42.4)) in patients who had improvement post-op compared to those that did not improve (22.6 mm (95% CI 18.2-27.2) (p value = 0.01). Two patients required spine surgery to achieve improvement in their symptoms.

CONCLUSION

Cervical innominate artery suspension is successful in carefully selected patients. More space in the thoracic outlet and larger distance from the innominate artery to the sternum is associated with symptomatic improvement.

Limited upper mini-sternotomy approach for closed heart surgery in the newborns and infants

BACKGROUND

The mini-sternotomy has become a common approach of choice for a wide range of congenital defects requiring minimally invasive surgery. Here, we aimed to present closed heart surgery results via limited upper mini-sternotomy in the newborn and infants.

METHODS

A total of 46 infants who underwent pulmonary artery banding, patent ductus arteriosus ligation, and aortopexy via limited upper mini-sternotomy between December 2017 and October 2020 were enrolled. Patients included 26 males and 20 females with ages ranging from 2 days to 12 months (median age 3.25 ± 0.9 months). The weight ranged from 0.7 kg to 8 kg (median weight 3.6 ± 1.8 kg). These patients were evaluated retrospectively in terms of clinical, preoperative, intraoperative, and postoperative parameters.

RESULTS

Closed heart surgery procedures were corrected successfully without adverse events intraoperatively. The median operation time was 32 min (32 ± 7 min). The limited upper mini-sternotomy was performed on 46 patients, including the pulmonary banding (18 patients), PDA ligation (16 patients), and aortopexy (12 patients). No patients required conversion to full sternotomy or to extend the incision. Re-intervention to adjust the tightness of the band was required in 1 patient. There were 4 cases of mortality (8.6%). All four death cases had comorbidity and low birth weight (2500 g or less).

CONCLUSION

Limited upper mini-sternotomy is a technically feasible, safe, and effective approach that providing an adequately surgical view in closed heart surgery to reduce the invasiveness of the closed heart surgical repair via median sternotomy or thoracotomy approach.

Thoracoscopic aortopexy for symptomatic tracheobronchomalacia

AIM

Symptomatic tracheobronchomalacia can be fatal. Successful treatment includes aortopexy. We report outcomes of the thoracoscopic approach in a single centre.

METHODS

All patients undergoing thoracoscopic aortopexies from 2009 to 2018 were retrospectively reviewed. Data was reported as median (interquartile range). Risk factors for subsequent tracheostomy were analyzed with logistics regression model, p < 0.05 as significant.

RESULTS

Twenty-one patients with mid to distal tracheomalacia (n = 17) and bronchial involvement (n = 4) were determined on bronchoscopy, tracheobronchogram, or CT thorax. Preoperative patient demographics and comorbidities, e.g., gastro-oesophageal reflux disease, prematurity, and cardiac anomalies were recorded. Indications for thoracoscopic aortopexy were apparent life-threatening event(s) (n = 14), recurrent chest infections (n = 5), and failure to wean invasive ventilation (n = 2). Thoracoscopic aortopexies (n = 20) with conversion to open (n = 1) were performed. Intraoperative bleeding (n = 2) occurred, and chest tube (n = 1) was inserted for monitoring. Intraoperative bronchoscopy (n = 17) confirmed improvement of tracheomalacia. Anesthetic time was 140 (90-160) minutes. Postoperatively, 2 patients had dehiscence of the aorta from the sternum. They underwent redo open aortopexy with posterior tracheopexy, and 1 required subsequent tracheostomy. Another 2 patients required tracheostomies. Potential risk factors for subsequent tracheostomy were investigated, and only the association of tracheobronchomalacia was close to significance (OR 16 (95% CI 0.95-267.03), p = 0.05). Follow up duration was 365 (72-854) days. Symptoms resolution occurred in n = 17 (81%) of patients.

CONCLUSION

Different modalities were used to delineate the site of tracheobronchomalacia and its etiology. Tracheomalacia with bronchial involvement may be a risk factor for subsequent tracheostomy.

LEVEL OF EVIDENCE

Level 3 (Case Series).