1.Preliminary application of CT and 3D-DSA data sources in 3D printing of intracranial arteriovenous ;malformations
Jianyi LI ; Xiangxue KONG ; Zhanglin WANG ; Peng PENG ; Guangzhong CHEN ; Mengqi DONG ; Kun QIN ; Chao PENG
Chinese Journal of Cerebrovascular Diseases 2016;(2):78-81
Objective To compare the effect of thin-sliced enhanced CT scanning and 3D-DSA data sources in the 3 D printing data reconstruction of intracranial arteriovenous malformation (AVM ). Methods Five patients with AVM were selected prospectively,3 were Spetzler-Martin grade II and 2 were grade III. Two of them used 256-slice spiral CT thin slice enhanced scanning. Three used the 3D-DSA rotating imaging,and the DICOM raw data of the examination results were extracted. Digital processing was performed by using the Mimics software,and the 3 D printing was performed according to the ratio of 1∶1 obtaining the solid model and the effects were compared. Results Using the data source 3 D printing of 256 slice spiral CT thin-slice enhanced scan could obtained skull and blood vessel image information and could reveal the smallest diameter of 0. 9 mm vessel,however,the fine branch structures of the vessel were difficult to distinguish. The 3D printing based on 3D-DSA data,although the digital subtraction did not have the skull data information,the vascular branches showed more abundant. It could reveal the smallest diameter of 0. 9 mm vessel. Conclusions Using the CT thin-slice enhanced scan or 3D-DSA data source can obtain reconstruction images of AVM nidus,and 3D-DSA shows that the better effect for spatial structure of AVM nidus. It is helpful to the design of preoperative treatment scheme and the development of corresponding auxiliary tools.
2.3D printing of the individual female pelvic structure
Ping LIU ; Lan CHEN ; Jianyi LI ; Chunlin CHEN ; Lei TANG ; Hui DUAN ; Xiangxue KONG ; Ruolan CHEN ; Bin CHEN
The Journal of Practical Medicine 2015;(8):1225-1229
Objective To explore the application of 3D printing technology in individual pelvic structure of female and its value in obstetrics and gynecology based on the CT datasets of the pelvic structure and digital three-dimensional reconstruction. Methods CTA image dataset of a patient from gynecology department was obtained for constructing three-dimensional models of each organ using the digital three-dimensional reconstruction technology , then the digital 3D model with the same size as the model displayed was printed with Z510 3D printer. Results 3D models of patient′s lumbosacral vertebrae, aorta artery, common iliac artery, internal and external iliac artery , postcava , common iliac vein , internal and external iliac vein , pelvis ureter , uterus and uterine artery were printed out in the same size replica of the virtual reality model. Conclusion 3D printed model has all the features of 3D vision and can be touched and felt by people , which can provide new insights for medical education, clinical and medical research.
3.Construction of a three-dimensional digital model of the liver of Wuzhishan mini-pig.
Lili ZHANG ; Jujiao XIAO ; Guangwei XU ; Xiangxue KONG ; Maoqing FU ; Zhanglin WANG ; Jianyi LI
Journal of Southern Medical University 2015;35(9):1362-1365
OBJECTIVETo construct a three-dimensional (3D) liver model of Wuzhishan mini-pig for virtual liver surgeries.
METHODSThe biliary tree and hepatic arteries of Wuzhishan mini-pig were perfused with perchloroethylene and ethyl acetate along mixed with lead oxide, and the hepatic vein and portal vein were perfused with a mixture of dental base acrylic resin and lead oxide. The sectional images were acquired using a 64-slice spiral CT, and the 3D models of the portal vein, hepatic vein, biliary tree, hepatic arteries, and liver parenchyma were reconstructed using Mimics software; the resection image of the liver was also designed. The intrahepatic vascular cast was prepared by corroding the soft tissue with hydrochloric acid.
RESULTS AND CONCLUSIONThe intrahepatic vascular cast obtained fully retained the vascular architecture and displayed the fifth- and sixth-level branches of the hepatic vein and portal vein and the third- and fourth-level branches of the artery and bile duct. The 3D model of liver allowed stereoscopic and accurate display of the third- and fourth-level branches of the hepatic vein and portal vein and the second- and third-level branches of the artery and bile duct. The 3D model showed fewer branches but represented the structural distribution identical to the cast. The 3D model could clearly display the spatial relationship between the vasculature and the soft tissue in virtual resection of the liver tissues, and thus provides a useful model for training of laparoscopic liver resection.
Animals ; Bile Ducts ; Hepatic Artery ; Hepatic Veins ; Imaging, Three-Dimensional ; Liver ; anatomy & histology ; Models, Anatomic ; Portal Vein ; Swine ; Swine, Miniature ; Tomography, Spiral Computed