Abstract
Phantoms are essential tools for clinical training, surgical planning and the development of novel medical devices. However, it is challenging to create anatomically accurate head phantoms with realistic brain imaging properties because standard fabrication methods are not optimized to replicate any patient-specific anatomical detail and 3D printing materials are not optimized for imaging properties. In order to test and validate a novel navigation system for use during brain tumor surgery, an anatomically accurate phantom with realistic imaging and mechanical properties was required. Therefore, a phantom was developed using real patient data as input and 3D printing of molds to fabricate a patient-specific head phantom comprising the skull, brain and tumor with both ultrasound and X-ray contrast. The phantom also had mechanical properties that allowed the phantom tissue to be manipulated in a similar manner to how human brain tissue is handled during surgery. The phantom was successfully tested during a surgical simulation in a virtual operating room.The phantom fabrication method uses commercially available materials and is easy to reproduce. The 3D printing files can be readily shared, and the technique can be adapted to encompass many different types of tumor.
Highlights
Phantoms mimicking the specific properties of biological tissues are a useful resource for various experimental and teaching applications
NOTE: Do not leave for extended period once the glass spheres have been added, no longer than around 10 min, before pouring the Polyvinyl alcohol cryogel (PVA-c) into a mold, as the glass spheres will settle to the bottom of the beaker
Please click here to view a larger version of this figure. This protocol details the fabrication process of a patient specific brain phantom, which includes the skull, brain, and vestibular schwannoma tumor. 3D printing methods allowed for anatomically accurate detail to be achieved
Summary
Phantoms mimicking the specific properties of biological tissues are a useful resource for various experimental and teaching applications. A method is described for manufacturing a durable, patient-specific brain tumor model using readily available, commercial materials, which can be used for the training and validation of intraoperative ultrasound (US) using computerized tomography (CT) imaging. In order to be suitable for this application, the brain tumor phantom needs to possess several key properties It should be made of non-toxic materials, so it can safely be used in a clinical training environment. It should have realistic imaging properties; for the intended application, these include ultrasound attenuation and CT contrast. To the best of the author’s knowledge, this is the first report of a 3D-printed patient-specific brain tumor phantom model created with tissue-mimicking ultrasound and X-ray properties.
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