Advances in imaging techniques are changing the way in which prostate cancer can be detected and treated. However, these techniques have yet to be perfected and there is room for a great deal of improvement. To this end, a team of researchers from the University of California Los Angeles and the David Geffen School of Medicine, also in Los Angeles, worked together to pinpoint the areas of current imaging techniques that required modification and improvement.
The prostate cavity mold is designed to hold the excised tissue in the position necessary for an exact comparison with the MRI data. The form of the interior cavity of the mold is created from by using the 3D imaging software, Profuse, developed by Eigen, that generates true, navigable, and quantifiable 3D images from ultrasound. The “slice” images, or segmentations, that were used to build up the 3D model of the prostrate were then imported into SolidWorks in order to generate the mold cavity that would perfectly match the tissue surface.
The mold itself was made from polylactic acid plastic (PLA) and printed on Makerbot’s Replicator 2. It was manufactured in two halves with a central cavity in which the tissue is placed according to the position in the MRI. It also has a series of slits, in this case placed 4.5 mm apart, in order to correspond to the MR image planes. The printing of the mold was completed prior to the surgery and was ready in the grossing room, the area where pathology specimens from the operating room is taken for pathological review and analysis, when the operation commenced.
The team then worked to carefully study the data that had been available prior to the surgery through the MRI, with the reality of the condition of the excised tissue in a process known as MR-histology correlation. In comparing the data, the team discovered that while the MRI had accurately predicted the presence of the cancerous regions, it had produced data that indicated a significantly smaller lesion volume and extent.
The MRI reads the presence of cancer using the report generated by pulsing signals, T1 and T2 signals. The researchers noted that the cancer-positive regions discovered through the histology that had not been made visible through the MRI were observed to have low T2 signal responsiveness. This data indicates, therefore, the need for a refinement, to improve the MR sensitivity in order to increase the predictive capabilities of the images created.
By continuing to refine the images produced by an MRI, not only is the likelihood of greater detection accuracy increased, it also provides the surgeons with a better roadmap of what they are likely to encounter as they perform the procedure. In addition, to improvement in the possibilities for detection is also a lower rate of false positives that may lead to unnecessary surgeries, further testing, or other treatments.
The difficulties of studying the relationship between the imaged data and the actual tissue has been present, largely due to the deformation of the shape of the tissue once it has been removed from its site in the body. The 3D printed mold is designed to mitigate exactly this issue and allow for direct examination of the tissue in its in situ shape.
This, like so many other changes and advances in medical technology that involve 3D printing, builds upon the absolute personalization that is allowed by the technology. A great deal more research is necessary in order to confirm the findings gathered during this study, but one thing is for certain, 3D printing is contributing to addressing medical issues in an increasingly wider variety of ways, while allowing investigations to begin that previously had been impossible.
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