ObjectiveTo evaluate the clinical value of in vitro fenestration and branch stent repair in the treatment of thoracoabdominal aortic aneurysm in visceral artery area assisted by 3D printing.MethodsThe clinical data of 7 patients with thoracoabdominal aortic aneurysm involving visceral artery at the Department of Vascular Surgery, Shandong Provincial Hospital Affiliated to Shandong First Medical University from March 2016 to May 2019 were analyzed retrospectively. There were 5 males and 2 females with an average age of 70.2±3.9 years. Among them 4 patients had near-renal abdominal aortic aneurysm, 3 had thoracic aortic aneurysm, 4 had asymptomatic aneurysm, 2 had acute symptomatic aneurysm and 1 had threatened rupture of aneurysm. According to the preoperative CT measurement and 3D printing model, fenestration technique was used with Cook Zenith thoracic aortic stents, and branch stents were sewed on the main stents in vitro, and then the stents were modified by beam diameter technique for intracavitary treatment.ResultsAll the 7 patients completed the operation successfully, and a total of 18 branch arteries were reconstructed. The success rate of surgical instrument release was 100.0%. The average operation time was 267.0±38.5 min, the average intraoperative blood loss was 361.0±87.4 mL and the average hospital stay was 16.0±4.2 d. Immediate intraoperative angiography showed that the aneurysms were isolated, and the visceral arteries were unobstructed. Till May 2019, there was no death, stent displacement, stent occlusion, ruptured aneurysm or loss of visceral artery branches. Conclusion3D printing technology can completely copy the shape of human artery, intuitively present the anatomical structure and position of each branch of the artery, so that the fenestration technique is more accurate and the treatment scheme is more optimized.
ObjectiveTo evaluate the clinical value of three-dimensional (3D) printing model in accurate and minimally invasive treatment of double outlet right ventricle (DORV).MethodsFrom August 2018 to August 2019, 35 patients (22 males and 13 females) with DORV aged from 5 months to 17 years were included in the study. Their mean weight was 21.35±8.48 kg. Ten patients who received operations guided by 3D printing model were allocated to a 3D printing model group, and the other 25 patients who received operations without guidance by 3D printing model were allocated to a non-3D printing model group. Preoperative transthoracic echocardiography and CT angiography were performed to observe the location and diameter of ventricular septal defect (VSD), and to confirm the relationship between VSD and double arteries.ResultsThe McGoon index of patients in the 3D printing model group was 1.91±0.70. There was no statistical difference in the size of VSD (13.20±4.57 mm vs. 13.40±5.04 mm, t=−0.612, P=0.555), diameter of the ascending aorta (17.10±2.92 mm vs. 16.90±3.51 mm, t=0.514, P=0.619) or diameter of pulmonary trunk (12.50±5.23 mm vs. 12.90±4.63 mm, t=−1.246, P=0.244) between CT and 3D printing model measurements. The Pearson correlation coefficients were 0.982, 0.943 and 0.975, respectively. The operation time, endotracheal intubation time, ICU stay time and hospital stay time in the 3D printing model group were all shorter than those in the non-3D printing model group (P<0.05).ConclusionThe relationship between VSD and aorta and pulmonary artery can be observed from a 3D perspective by 3D printing technology, which can guide the preoperative surgical plans, assist physicians to make reasonable and effective decisions, shorten intraoperative exploration time and operation time, and decrease the surgery-related risks.
Objective To evaluate the application of three-dimensional printing technique in surgical treatments on complex congenital heart diseases. Methods Two patients were enrolled with complex congenital heart diseases. The computerized tomography data were used to build the 3D architecture of cardiac anomalies. The White-Jet-Process technique was used to print the models with 1∶1 ratio in size. The models were used to make the treatment strategy making, young surgeon training and operation simulation. Results The full color and hollowed-out cardiac models with 1∶1 ration in size were printed successfully. They were transected at the middle point of vertical axis, which was conveniently to explore the intracardiac anomalies. However, for patient 1, the model lost the atrial septal defect. Taking the two models as references, operation group held preoperative consultation, operation simulation, and finally, the operation plans were determined for the two patients. Both the two operation were carried out smoothly. Conclusion Although the limitations of 3D printing still exist in the application for congenital heart diseases, making the preoperative plan and operation simulation via 3D cardiac model could enhance the understanding of following operation and procedure details, which could improve the tacit cooperation among operation group members. Furthermore, operation results also could be improved potentially. Therefore, the cardiac 3D printing should be popularized in clinic in the future.
Objective To evaluate the deviation between actual and simulated screw placement after cervical pedicle screw placement assisted by 3D printed navigation template, and analyze the correlation between screw placement deviation and navigation pipe length. Methods A total of 40 patients undergoing cervical 1-7 pedicle screw insertion assisted by 3D printed navigation template in Zigong Fourth People’s Hospital between February 2018 and August 2020 were included in this prospective study. These patients were divided into 3 groups randomly, including 12 patients with a 5-mm pipe length (5 mm group), 13 patients with a 10-mm pipe length (10 mm group), and 15 patients with a 15-mm pipe length (15 mm group). Three-dimensional modeling was performed on preoperative cervical CT images of these patients and simulated pedicle screw was placed. Individualized pedicle screw navigation templates were designed according to the position and direction of simulated pedicle screws, and 3D printing was performed on the cervical model and navigation templates. Preoperative 3D printed model and navigation templates were used to simulate the surgical process to confirm the safety of screws. During the operation, pedicle screw placement was performed according to the preoperative design and simulated surgical process. The postoperative CT images were registered with the preoperative CT images in 3D model. The safety of screw placement was evaluated by the postoperative screw placement Grade, and the accuracy of screw placement was evaluated by measuring the deviation of screw placement point and the deviation of screw placement direction in horizontal plane (inclination angle) and sagittal plane (head inclination angle). The influence of different navigation pipe lengths on the safety and accuracy of screw placement was analyzed. Results A total of 164 pedicle screws were inserted with navigation template assistance, including 48 screws (38 in Grade 0 and 10 in Grade 1) in the 5 mm group, 52 screws in the 10 mm group (all in Grade 0), and 64 screws (52 in Grade 0 and 12 in Grade 1) in the 15 mm group, and the difference in the grade among the three groups was statistically significant (P<0.05). When the navigation pipe length was 5, 10, and 15 mm, respectively, the screw entry point deviation was (1.87±0.63), (1.44±0.63), and (1.66±0.54) mm, respectively, the inclination angle deviation was (2.72±0.25), (0.90±0.21), and (1.84±0.35)°, respectively, and the head inclination angle deviation was (8.63±1.83), (7.15±1.38), and (8.24±1.52)°, respectively. The deviations in the 10 mm group were all significantly less than those in the other two groups (P<0.05). Conclusions In the cervical pedicle screw placement assisted by navigation template, all the screws were Grade 0 or Grade 1, with high safety. The mean deviation of the screw entry point is within 2 mm, with high accuracy. When the length of navigation pipe is 10 mm, the safety and accuracy of screw placement can be fully guaranteed.
ObjectiveTo explore the feasibility of lumbar puncture models based on 3D printing technology for training junior orthopaedic surgeons to find the optimal pedicle screw insertion points.MethodsMimics software was used to design 3D models of lumbar spine with the optimal channels and alternative channels. Then, the printed lumbar spine models, plasticine, and cloth were used to build lumbar puncture models. From January 2018 to June 2019, 43 orthopedic trainees performed simulated operations to search for the insertion points of pedicle screws base on the models. The operations were performed once a day for 10 consecutive days, and the differences in operation scores and operation durations of the trainees among the 10 days were compared.ResultsAll the trainees completed the surgical training operations successfully, and there were significant differences in the operation scores (13.05±2.45, 14.02±3.96, 17.58±3.46, 21.02±2.04, 23.40±4.08, 25.14±3.72, 27.26±6.09, 33.37±4.23, 35.00±4.15, 38.49±1.70; F=340.604, P<0.001) and operation durations [(22.51±4.28), (19.93±4.28), (18.05±2.89), (17.05±1.76), (16.98±1.97), (15.47±1.74), (13.51±1.42), (12.60±2.17), (12.44±1.71), (11.91±1.87) minutes; F=102.359, P<0.001] among the 10 days.ConclusionThe 3D models of lumbar puncture are feasible and repeatable, which can contribute to surgical training.
Aortic valve disease is one of the major diseases threatening human health. Transcatheter aortic valve replacement (TAVR) is a new treatment for aortic disease. Preoperative evaluation is of great significance to the successful operation and the long-term quality of life of patients. The 3D printing technology can fully simulate the cardiac anatomy of patients, create personalized molds for patients, improve surgical efficiency, reduce surgical time and surgical trauma, and thus achieve better surgical results. In this review, the relevant literatures were searched, and the evaluation effect of 3D printing technology on the operation of TAVR was reviewed, so as to provide clinical reference.
The esophageal disease is a major clinical disease. The esophageal stent has extensive clinical applications in the treatment of esophageal diseases. However, the clinical application of esophageal stent is limited, because there are lots of complications after implantation of esophageal stent. Biodegradable esophageal stent has two advantages: biodegradability and good histocompatibility. It is expected to solve a variety of complications of esophageal stent and provide a new choice for the treatment of esophageal diseases. Standardized esophageal stents are not fully applicable to all patients. The application of 3D printing technology in the manufacture of biodegradable esophageal stent can realize the individualized treatment of esophageal stent. And meanwhile, the 3D printing technology can reduce the manufacturing cost of the stent. This review aimed to summarize and discuss the application of esophageal stent, the current research status and prospect of biodegradable esophageal stent and the prospect of 3D printing technology in degradable esophageal stent, hoping to provide evidence and perspectives for the research of biodegradable esophageal stent.
3D printing technology has a promising prospect of medical use and clinical value, and may play an important role in the field of thoracic and cardiovascular surgery, such as preoperative diagnosis, surgical planning, surgical approach alternatives and organ replacement. This review focuses on the development of 3D printing technology in recent years and its use and prospect in the field of thoracic and cardiovascular surgery including surgical teaching and simulation, personalized prosthesis implantation, and artificial organ transplantation.
Objective To compare the effect of three-dimensional visual (3DV) model, three-dimensional printing (3DP) model and computer-aided design (CAD) modified 3DP model in video-assisted thoracoscopic surgery (VATS) sublobular resection. MethodsThe clinical data of patients who underwent VATS sublobular resection in the Affiliated Hospital of Hebei University from November 2021 to August 2022 were retrospectively analyzed. The patients were divided into 3 groups including a 3DV group, a 3DP group and a CAD-3DP group according to the tools used. The perioperative indexes and subjective evaluation of operators, patients and their families were compared. ResultsA total of 22 patients were included. There were 5 males and 17 females aged 32-77 (56.95±12.50) years. There were 9 patients in the 3DV group, 6 patients in the 3DP group, and 7 patients in the CAD-3DP group. There was no statistical difference in the operation time, intraoperative blood loss, drainage volume, hospital stay time or postoperative complications among the groups (P>0.05). Based on the subjective evaluations of 4 surgeons, the CAD-3DP group was better than the 3DV group in the preoperative planning efficiency (P=0.025), intuitiveness (P=0.045) and doctor-patient communication difficulty (P=0.034); the CAD-3DP group was also better than the 3DP group in the overall satisfaction (P=0.023), preoperative planning difficulty (P=0.046) and efficiency (P=0.014). Based on the subjective evaluations of patients and their families, the CAD-3DP group was better than the 3DP group in helping understand the vessel around the tumor (P=0.016), surgical procedure (P=0.020), procedure selection (P=0.029), and overall satisfaction (P=0.048); the CAD-3DP group was better than the 3DV group in helping understand the tumor size (P=0.038). ConclusionCAD-modified 3DP model has certain advantages in pre-planning, intraoperative navigation and doctor-patient communication in the VATS sublobectomy.
Shear thinning is an ideal feature of bioink because it can reduce the chance of blocking. For extrusion based biological printing, bioink will experience shear force when passing through the biological printer. The shear rate will increase with the increase of extrusion rate, and the apparent viscosity of shear-thinning bioink will decrease, which makes it easier to block, thus achieving the structural fidelity of 3D printing tissue. The manufacturing of complex functional structures in tissue trachea requires the precise placement and coagulation of bioink layer by layer, and the shear-thinning bioink may well meet this requirement. This review focuses on the importance of mechanical properties, classification and preparation methods of shear-thinning bioink, and lists its current application status in 3D printing tissue trachea to discuss the more possibilities and prospects of this biological material in tissue trachea.