At Nicklaus Children’s Hospital in Miami, Director of Pediatric Cardiovascular Surgery Dr. Redmond Burke dedicates his intellect and his hands to repairing tiny hearts. Burke performs challenging operations, often for children who have nowhere else to turn. In the complex yet highly tactile task of rebuilding the vital organ, he has a new ally: 3D printing.
For patients with rare defects, Burke must plan procedures based on each child’s condition and anatomy. In the case of Mia Gonzalez, that meant untangling a double aortic arch, a structural defect in which a complete vascular ring wraps around the trachea or esophagus, restricting airflow and causing coughing and frequent respiratory infections. Before coming to Nicklaus Children’s Hospital, Mia spent the first four years of her life in and out of hospitals, misdiagnosed with asthma and struggling to breathe and swallow.
Using Stratasys solutions, the hospital created an anatomically precise 3D model of Mia’s heart, directly from her CT scan. With the model, Burke and his team were able to figure out which part of her arch should be divided to achieve the best physiological result. The clearer plan that resulted from the model reduced operating-room time by two hours, according to the hospital – significant in terms of risk to the patient as well as cost.
Adenelie Gonzalez was born with a lethal heart defect called a total anomalous pulmonary venous connection. Previous surgeries she underwent as a newborn and at nine months, and four catheterizations, provided only temporary help. By age four she weighed only 28 pounds, and her health was deteriorating rapidly. Her cardiologist had difficulty finding a surgeon willing to take on a high-risk surgery.
“Looking at Adenelie’s X-rays and catheterizations, I thought she was inoperable,” said Burke. “Her deformity was one-of-a-kind.” Images on a computer screen were not enough. “But I thought that holding and manipulating a flexible 3D replica of this child’s heart might allow me to design an operation that hadn’t been done before. We could configure the necessary patches to create the exact shapes and dimension to match her deformed pulmonary veins.”
Burke carried the model heart in his gym bag, and when he had free minutes he would reach into the bag, feel the model, look at it, flip it over, and run through possible reconstructions in his mind. He manipulated the model as he later would Adenelie’s living heart, moving vessels around to explore possible repairs. In one of those idle moments he figured out a practical solution.
Burke determined the exact size and geometry needed for the repair parts so they could be prepared in advance, minimizing the time Adenelie would have to spend on bypass. Later, he used the model to explain the surgery to Adenelie’s parents, and to prep his team.
In the operating room, Adenelie’s heart was connected to a bypass machine and cooled to freezing temperatures so it could be manipulated without damage. Dr. Burke made the repairs and her heart was rewarmed. It began beating normally. For the first time in her life, Adenelie’s internal heart pressures measured normal.
“Without a 3D printed model, I might not have been able to figure out the repair method that I used, and I’m not sure if the operation would have been successful,” Burke said.