[HTML][HTML] Prototyping of cerebral vasculature physical models
Background: Prototyping of cerebral vasculature models through stereolithographic methods
have the ability to accurately depict the 3D structures of complicated aneurysms with high
accuracy. We describe the method to manufacture such a model and review some of its uses
in the context of treatment planning, research, and surgical training. Methods: We
prospectively used the data from the rotational angiography of a 40-year-old female who
presented with an unruptured right paraclinoid aneurysm. The 3D virtual model was then …
have the ability to accurately depict the 3D structures of complicated aneurysms with high
accuracy. We describe the method to manufacture such a model and review some of its uses
in the context of treatment planning, research, and surgical training. Methods: We
prospectively used the data from the rotational angiography of a 40-year-old female who
presented with an unruptured right paraclinoid aneurysm. The 3D virtual model was then …
Abstract
Background:
Prototyping of cerebral vasculature models through stereolithographic methods have the ability to accurately depict the 3D structures of complicated aneurysms with high accuracy. We describe the method to manufacture such a model and review some of its uses in the context of treatment planning, research, and surgical training.
Methods:
We prospectively used the data from the rotational angiography of a 40-year-old female who presented with an unruptured right paraclinoid aneurysm. The 3D virtual model was then converted to a physical life-sized model.
Results:
The model constructed was shown to be a very accurate depiction of the aneurysm and its associated vasculature. It was found to be useful, among other things, for surgical training and as a patient education tool.
Conclusion:
With improving and more widespread printing options, these models have the potential to become an important part of research and training modalities.
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