A 7-year-old girl was taken to Women and Children’s Hospital, Qingdao University for a heart murmur. Echocardiography (Echo) showed atrial septal defect (ASD) of 13 mm (Fig. 1) with enlarged right atrium and right ventricle, slightly dilated pulmonary artery (17 mm), and left ventricular ejection fraction (LVEF) of 65%. Due to severe scoliosis, the girl underwent five spinal operations and dual growth rods at Beijing Children’s Hospital. It is indicated by our physical examination that the child had a thoracic deformity with left chest collapse.

Three-dimensional reconstruction of the thorax showed bilateral thoracic asymmetry, the 4th, 5th, and 6th rib fused posteriorly, the 6th, 7th, 9th, and 10th ribs on the left side were obviously widened, and the spine was significantly convex to the left side (Fig. 2). Chest fluoroscopic imaging of the corrective device may generate an influence on the field of vision of interventional occlusion (Fig. 3). Based on our previous experience, we decided to perform ASD closure solely under the guidance of Transthoracic Echocardiography (TTE). The size and location of ASD, the length and hardness of the defect rim, pulmonary hypertension, and blood flow direction of the defect were evaluated from the apical four-chamber view, subcostal sagittal view, and parasternal short-axis view (Philips IE33). The written informed consent was obtained from the parents.

Under general anesthesia, a right femoral vein was punctured. Heparin was administered intravenously, and the activated clotting time was continuously monitored throughout the surgical procedure, maintaining it at over 220 s.

The length was marked on a 6Fr multifunctional catheter to indicate the distance from the puncture site to the right atrium, before being advanced through the inferior vena cava to the right atrium. Under the direction of real-time TTE, adjusting the angle, direction, and depth of the tip of the multifunctional catheter, it entered into the left atrium through the ASD. Feed the stiffened guide wire along the catheter, fix the guide wire in the left lower pulmonary vein, withdraw the catheter, feed the 8Fr delivery sheath along the stiffened guide wire to the left atrium, and withdraw the delivery sheath core and the guide wire. Under the guidance of TTE, the 16 mm occluder was pushed into the sheath. The left and right atrial disks were released in sequence. The shape of the occluder, position, and atrioventricular valve function were assessed by TTE (Fig. 4). Finally, the delivery sheath was removed, and compression bandages were applied. The operation time lasted 30 min. Aspirin was given (3–5 mg/kg, orally) every day for 6 months. The girl recovered and was discharged from the hospital 3 days after the intervention. There were no major cardiovascular-related complications.

The relationship between congenital heart disease (CHD) and congenital scoliosis has been explored for several decades [1]. Children with CHD are more likely to develop spinal and thoracic deformities in the fetal period or thoracic scoliosis after thoracic surgery [2,3,4]. Severe scoliosis with spinal rotation often occurs after surgical treatment of congenital heart disease [5]. Current evidence suggests a 10-fold increase in the prevalence of scoliosis in children with CHD compared with age-matched populations. The surgical treatment of CHD is reported to be associated with a high prevalence of scoliosis [6,7]. We introduce an exceptional instance of transcatheter closure of an ASD, a procedure that was uniquely navigated exclusively through Transthoracic Echocardiography (TTE). This particular case stands out due to the prior spinal corrective surgery of the patient, which involved the insertion of a dual growth rod, rendering X-ray fluoroscopy unsuitable for guiding the transcatheter treatment. Despite this earlier surgical procedure, the ASD closure was subsequently accomplished with remarkable success, solely relying on TTE throughout.

Clinically, Transesophageal Echocardiography (TEE) guided ASD closure has become a development trend in recent years [8]. The Echo presents prominent advantages for ASD intervention compared with fluoroscopy. TEE can visually display the influence of the occluder on the atrioventricular valve, coronary sinus, pulmonary vein, and adjoined tissues, and real-time monitoring of the procedure process, capable of occluder replacement if improperly positioned [9].

However, TEE is an invasive procedure that requires the insertion of an esophageal probe and general anesthesia with tracheal intubation to avoid aspiration, which increases the incidence of complications and costs. TTE provides high-resolution views of ASD itself and the spatial orientations regarding neighboring structures, offering indispensable information that can be substituted with TEE in pediatric patients [10]. However, there is no consensus regarding TTE being applied individually in ASD transcatheter closures. Although it is generally recognized internationally that cases with maldeveloped inferior and posterior borders as well as superior border defects pose certain risks when assessed using TTE, the effectiveness of TTE in cases without these conditions is not significantly different from that of TEE [11]. As confirmed by many experts, TTE can serve as a reliable tool for measuring the diameter of ASD and providing guidance during device closure when operated by skilled hands [12,13].

It is difficult for beginners to guide ASD closure with TTE merely. Regarding each step of the operation, the atrial septum needs to be observed from different perspectives, which requires the operator to be especially familiar with the two-dimensional anatomical spatial structure of the heart [14]. The operation time is relatively long, requiring the surgeon to make psychological preparations before the operation and communicate with the family about the expected operation time. Under routine circumstances, it is usually not easy to locate the tip of the catheter through the apical four-chamber view, parasternal long-axis view, and subxiphoid acoustic window. There are some difficulties in this section without fluoroscopy. Therefore, we have to rotate the catheter to assist its visualization from the Echo. It is required to mark the catheter with a sterile mark pen before insertion to indicate the distance from the puncture point to the apex of the heart. Under the guidance of TTE, the occluder was delivered through the sheath by pushing the cable slowly. The left and right atrial disc of the occluder was released in turns.

Congenital heart disease with scoliosis is a rare compound malformation [15]. For children of a spinal implanted plate with relative intervention contraindications, TTE is possibly a better alternative for the guidance of ASD occlusion. In conclusion, this report describes a successful case of transcatheter ASD closure guided entirely by TTE. It is suggested by this study that in selected pediatric patients with visual field occlusion under fluoroscopy, the application of TTE is efficacious and safe for assessment and guidance of ASD occlusion.