Breakthrough: Fine Detail Voxel 3D Scanning and Printing

 Incredibly detailed 3D print of actual lung tissue obtained from a high resolution 3D scan

Incredibly detailed 3D print of actual lung tissue obtained from a high resolution 3D scan

Researchers from MIT have developed a new technique to enable highly detailed multimaterial 3D prints from 3D scanners.

3D prints have long been produced with models generated from 3D scanners, but in almost all cases these prints are a representation of the outer surface of the scanned object only - and then usually only in a single material or color. 

This has limited use of 3D printing in many industries. Consider a 3D scan obtained by an MRI or CAT scan device that represents the internal structure of a person’s body. The “external shape” of such a 3D model is not instructive: it’s a box. What is of interest is the differentiated interior where different tissue types make up the structure. 

Those structures have been impossible to 3D print, unless they were crudely extracted from the 3D model and printed separately. But then the context of the medical situation is less clear. 

The MIT researchers were able to develop a voxel based analysis technique in which such medical data is transformed into a highly detailed 3D multimaterial 3D model that can then be 3D printed on certain devices. 

 The workflow required to transform medical 3D scans into high resolution voxel 3D prints

The workflow required to transform medical 3D scans into high resolution voxel 3D prints

In particular, they used Stratasys’ PolyJet technology, best on the full color J750 device. By mapping the internal structures to different material combinations, and surrounding them with a bulk of transparent material, they can now 3D print actual representations of individual 3D medical scans with tremendous resolution and fidelity. 

To do so they transform the incoming point cloud obtained from the medical scanner, likely in DICOM format, and convert it layer by layer into a complex geometry of multimaterial voxels in very high resolution. This does require some thought as to the nature of the structures and an intent for how to perform the mapping, which I presume would vary depending on the exact purpose of the print. 

 A detailed transparent 3D print of an actual human hand obtained from medical scan data

A detailed transparent 3D print of an actual human hand obtained from medical scan data

The applications of this are several. The researchers mention: 

Presurgical planning, where surgeons can now 3D print a highly detailed model of their surgical target. They’ll be able to see - and touch - it in extreme detail, making the surgical results more reliable, safe and successful. 

Learning and Education, where students can examine highly detailed models of body structures that are nearly identical, visually, to the real thing. 

Preservation of Artifacts, where unique historical objects can be scanned and preserved, not just from the outside surface, but the interior as well. 

I would add one more to this: Artistic Pursuits, where complex 3D scans could be mixed to produce highly unusual artwork, in much the same what that astrophotography uses “scans” of the heavens to create attractive art. 

 These detailed 3D prints of human lung tissue are not only instructive, but also artistic

These detailed 3D prints of human lung tissue are not only instructive, but also artistic

But in a more profound thought, this technology could enable one to 3D scan an entire human and then 3D print a life-size replica - inside and out. It wouldn’t be a working human by any means, but instead a 100% accurate sculpture of the entire human body. 

For a working human print we’ll have to wait for several machine upgrades to occur. 

Via Science

General Fabb

Kerry Stevenson, aka "General Fabb" has been writing Fabbaloo posts since he launched the venture in 2007, with an intention to promote and grow the incredible technology of 3D printing across the world. So far, it seems to be working!

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