Medical optimization of volume and nutritional status is key to the success of operative management. Visualization of the thoracic duct during thoracoscopy or an open thoracotomy can be enhanced by the preoperative enteric ingestion of cream, milk, or olive oil. Some have described enhanced visualization of the leak through injection of 1 % Evans blue dye in the thigh [35].

The procedure is ideally performed under single-lung ventilation. Traditionally, the operation involves three ports with port placement and patient positioning varying depending on the location of the leak [36, 37]. Most commonly, the duct is approached at the level of the diaphragm on the right side. In these cases, the patient is placed in the left lateral decubitus position and rolled forward (modified prone position) in order to enhance exposure of the posterior mediastinum. The right arm is extended in front of or over the head, and an axillary roll is placed. Neither central venous access nor arterial access is generally required for the operation although central venous access is often in place prior to surgery for parenteral nutrition.

The camera port is placed at the sixth or seventh intercostal space in the posterior axillary line. An instrument port is then inserted under direct vision in the midaxillary line 2–3 interspaces below the camera port, and the final working port is positioned at or above the level of the camera at the mid- to anterior axillary line. Alternatively, the site of chest tube insertion may be used for one of the port sites. Further, if the location of a lymph leak is identified preoperatively or at the time of initial thoracoscopic exploration, port site placement may vary. The surgeon and assistant face the patient and work from anterior to posterior. Low-pressure CO2 insufflation is generally required to collapse the lung with single- or dual-lung ventilation.

The operation begins with a limited exploration of the hemithorax with adhesiolysis as needed and residual fluid evacuation. Then, a thorough evaluation of the vertebra down to the level of the diaphragm is performed. If a distinct source of leakage is identified, then this leak is directly addressed for attempted ligation. A number of means including clipping, suture ligation, or sealing using an energy device can accomplish this. Some surgeons will choose to place fibrin glue at the ligation site [38]. If no distinct area of leakage is identified or the duct cannot be adequately sealed at the source of leakage, then the duct is approached at the level of the diaphragm. The duct should lie posterior and lateral to the esophagus and does require some dissection to visualize. Division of the inferior pulmonary ligament will assist in efforts to identify the duct. If the thoracic duct is not visualized after pleural dissection, mass ligation of the duct and its tributaries has proven useful in management [38]. This involves multiple ligations within the posterior mediastinum once the aorta, azygos vein, and esophagus have been identified and kept out of harm’s way. Due to the vast network of tributaries, overall lymphatic flow will not be affected, but the chylothorax should resolve [2, 38]. Ligation at the level of the diaphragm offers the benefit of blocking unrecognized tributaries. Although uncommon in the pediatric population, ligation during esophageal and cardiac surgery surgeries can be used as a prophylactic measure [39].

Pleurodesis is often employed as an adjunct to thoracoscopic duct ligation and has been shown to be both safe and effective in children [5]. During the thoracoscopic approach, mechanical pleurodesis is recommended with particular attention to the inferior thoracic space. This can be accomplished by a number of means including abrasion using a laparoscopic peanut or piece of a scratch pad introduced with a grasper. Partial pleurectomy may also be employed. We do not recommend chemical pleurodesis using talc. Pleurodesis is also a prominent choice when the leak site cannot be identified [2].