Sage Journals: Discover world-class research

Abstract

Background:

Imaging has a critical impact on surgical decision making and three-dimensional (3D) digital models of patient pathology can now be made commercially. We developed a 3D digital model of a cancer of the head of the pancreas by integrating actual CT data with 3D modeling process. After this process, the virtual pancreatic model was also produced using a high-quality 3D printer.

Patients and Methods:

A 56-year-old female with pancreatic head adenocarcinoma presented with biliary obstruction and jaundice. The CT scan showed a borderline resectable tumor with a clear involvement of the gastroduodenal artery but doubtful relationships with the hepatic artery. Our team in collaboration with the Immersive Touch team used multiple series from the CT and segmented the relevant anatomy to understand the physical location of the tumor. An STL file was then developed and printed.

Results:

Reconstructing and compositing the different series together enhanced the imaging, which allowed clearer observations of the relationship between the mass and the blood vessels, and evidence that the tumor was unresectable. Data files were converted for printing a 100% size rendering model, used for didactic purposes and to discuss with the patient.

Conclusions:

This study showed that (1) reconstructing enhanced traditional imaging by merging and modeling different series together for a 3D view with diverse angles and transparency, allowing the observation of previously unapparent anatomical details; (2) with this new technology surgeons and residents can preobserve their planned surgical intervention, explore the patient-specific anatomy, and sharpen their procedure choices; (3) high-quality 3D printed models are increasingly useful not only in the clinical realm but also for personalized patient education.

Get full access to this article

View all access options for this article.

References

Marro

, et al. Three-dimensional printing and medical imaging: A review of the methods and applications. Curr Probl Diagn Radiol, 2016; 45:2–9.

Rengier

, et al. 3D printing based on imaging data: Review of medical applications. Int J Comput Assist Radiol Surg, 2010; 5:335–341.

Lin

, et al. Immersive virtual reality for visualization of abdominal CT. Proc SPIE Int Soc Opt Eng, 2013; 28; 8673.

Alaraj

, et al. Role of cranial and spinal virtual and augmented reality simulation using immersive touch modules in neurosurgical training. Neurosurgery, 2013; 72 Suppl 1:115–123.

Brennan

, et al. Virtual Whipple: Preoperative surgical planning with volume-rendered MDCT images to identify arterial variants relevant to the Whipple procedure. Am J Roentgenol, 2007; 188:W451–W455.

Haigron

, et al. Issues in image-guided therapy. IEEE Eng Med Biol Mag, 2009; 28:96–98.

Michalski

, et al. The shape of things to come: 3D printing in medicine. J Am Med Assoc, 2014; 312:2213–2214.

Memon

, et al. Assessing the surgeon's technical skills: Analysis of the available tools. Acad Med, 2010; 85:869–880.

Dickinson

, et al. Individualizing management of complex esophageal pathology using three-dimensional printed models. Ann Thorac Surg, 2015; 100:692–697.

10.

Bernhard

, et al. Personalized 3D printed model of kidney and tumor anatomy: A useful tool for patient education. World J Urol, 2016; 34:337–345.

11.

Jones

, et al. Three-dimensional modeling may improve surgical education and clinical practice. Surg Innov, 2016; 23:189–195.

12.

Fisichella

, et al. Three-dimensional printing models in surgery. Surgery, 2016. DOI: 10.1016/j.surg.2016.01.002

Usefulness of Three-Dimensional Modeling in Surgical Planning,Resident Training,and Patient Education

Abstract

Abstract

Background:

Patients and Methods:

Results:

Conclusions:

Get full access to this article

References