At BMI, we process and interpolate CT and MRI images, in close cooperation with the radiologist and the surgical team, to fabricate extremely accurate three-dimensional replicas of patient anatomy. We use the highly detailed cross-sectional images from medical scan data to create three dimensional digital surface models of the desired anatomy.
The cross sectional images from the scan data are organized, reviewed, and structures of interest are selected (segmented) to contruct three dimensional surface models of the anatomy. BMI also offers biomedical and anatomical engineering services that go beyond anatomical replication. For example, a reconstructive implant may be designed using mirrored anatomy, or assembly features may be added to a functional model intended for educational use.
Prior to fabrication of the model, three dimensional drawings can be provided for review and approval. These digital surface models are then built to produce physical Biomodels using additive fabrication (see "Model Fabrication Process" below).
We can fabricate Biomodels out of a variety of materials, including trasparent, translucent, and opaque materials, which can be either rigid or flexible. Specific features can be colored if needed. Soft tissue gingival models and customized implants may then be fabricated using the Biomodel as a mold or template. Our Biomodels may also be used as sacrificial mandrels for casting in silicone and other materials.
BioCAD models are digital anatomical models that are compatible with computer-aided design and manufacturing (CAD/CAM) software used in engineering. More specifically, the three dimentional data of complex anatomical geometries are translated from point clouds or digital surface meshes into NURBS surface models that can then be more readily used by biomedical engineers for design modification and anaylsis. BioCAD models often combine anatomical geometries with mechanical features for applications such as medical device testing.
Originally developed for engineering purposes, additive manufacturing enables the fabrication of anatomical structures containing complex, irregular geometries that would otherwise be difficult to accurately reproduce.
A 3D rendering of the part is generated. Software is then used to slice the file from top to bottom. The slice data is then sent to a machine that fabricates the part layer by layer.
The majority of the Biomodels that we produce are fabricated using stereolithography, an additive manufacturing process. Models are built from a photopolymer resin that is exposed to light from a computer-guided UV laser.
The laser traces the pattern of the cross-sectional slice data on the surface of liquid resin. The UV laser light cures the exposed resin, causing it to solidify. An elevator platform lowers the model incrementally and a blade then sweeps across the cross section, coating it with additional liquid resin for the next layer. This process is repeated untill all layers of the model have been built. The model is then immersed in a chemical bath to remove excess material, cured in a UV oven, and a protective coating is applied.
The typical slice thickness is 0.15mm, thinner than CT slices which range from 0.2mm to 3mm. Biomodels can be made out of resins that are USP class VI approved for sterilization and use in the operating room.
A variety of material and post processing options are available for our Biomodels including colored or transluscent resin, modeled textures, and polishing.
Figure depicting Biomodel fabrication via stereolithography.
Left: Model with texture applied. Right: Polished model.