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When used for MRI, make sure that all parts are 3D printed as dense parts. Usually 3D printer offer the otpion to print a part either as "dense" or "sparse". The "sparse" option results in faster printing and lower consumption of plastic. However it is not adequate for MRI because the air trapped inside the small plastic cavities due to the sparse 3D printing option create off-resonance effects that may significantly distort images of the phantom. It is our experience that printing all plastic parts as "dense" is an absolute necessity at 7 Tesla. This problem may be less pronounced at lower field strength.  
When used for MRI, make sure that all parts are 3D printed as dense parts. Usually 3D printer offer the otpion to print a part either as "dense" or "sparse". The "sparse" option results in faster printing and lower consumption of plastic. However it is not adequate for MRI because the air trapped inside the small plastic cavities due to the sparse 3D printing option create off-resonance effects that may significantly distort images of the phantom. It is our experience that printing all plastic parts as "dense" is an absolute necessity at 7 Tesla. This problem may be less pronounced at lower field strength.  


The next step is to seal the parts. Even if your 3D printer offers a "waterproof" printing option, which is sometimes available on 3D printers, there is no guarantee that the parts will actually be waterproof. 3D printing of waterproof parts is actually very difficult. Most "waterproof" 3D printing strategies results in reasonably waterproof parts when these are flat (e.g., flat panels) but almost always fail for complex geometries such as a human head. Obviously, an MRI phantom should not leak since this would result in potential damage to the coil and other electronic components.
The next step is to seal the parts. Even if your 3D printer offers a "waterproof" printing option, which is sometimes available on 3D printers, there is no guarantee that the parts will actually be waterproof. 3D printing of waterproof parts is actually very difficult. Most "waterproof" 3D printing strategies results in reasonably waterproof parts when these are flat (e.g., flat panels) but almost always fail for complex geometries such as a human head. Obviously, an MRI phantom should not leak since this would result in potential damage to the coil and other electronic components. We have experimented with several techniques including painting the plastic parts with epoxy and melting of the plastic surface with a solvent (acetone can be used to melt ABS parts. Methylene chloride can be used to melt polycarbonate plastic). We have found that these two methods do not work well however. The method that we currently use for all our models consists in spraying the parts with a rubber spray. For our phantoms, we apply three thick coats of rubber spray on the outside and the inside of all parts (covering the outside of the outer parts prevents leaks and sweating in the event where some water infiltrates the plastic parts because of failure of the inner-most rubber coat). We use a red rubber spray as opposed to a black one since the latter color is often achieved using ferrite nanoparticles that may be magnetic. Note that the parts must be entirely sealed with spray before assembly, including the small grooves and nudges (we impose a gap between fitting parts of at least 1 mm in our models in order to account for the increased thickness of the part due to the waterproof coating).
 
 
[[Rubber spray.jpg]]
 
leads to phantoms that do not leak at all, even months





Revision as of 17:25, 23 March 2015

A.A. Martinos Center / Wald group anthropomorphic phantom builder's Wiki

Giorgio phant.jpg

This Wiki is a resource for people interested in constructing anthropomorphic MRI phantoms developed by Larry Wald's group at the Martinos Center for Biomedical Imaging, Massachusetts General Hospital.

The basic principle is that improved anthropomorphic phantoms lead to better and faster development of MRI methodology with less use of healthy subject volunteers. This is both cost effective and ethical. Therefore we distribute our designs and ask only that you reference the appropriate paper and the source of the design.

Designs are available in standard CAD format are intended to be 3D printed. Most of the components are open source designs.


MGH Phantoms for download


General process for making 3D printed phantoms

This section contains general instructions for making 3D printed phantoms. More detailed/specific instructions are available for individual phantoms.

Once you have downloaded the CAD files for a specific phantom, you should 3D print the different parts using your favorite 3D printer. Note that some parts may require you to be able to dissolve the support material, which is not always possible with all 3D printers (we have tried to add these 3D printing details for each phantom, but if you have any doubt contact Bastien Guerin [guerin at nmr dot mgh dot harvard dot edu]). This mostly affects complex parts such as the skull which has many grooves and cavities that may not be always easily reachable. If you do dissolve the support material using a solvent, make sure that the parts are clean and perfectly dry before continuing working with them (this may require leaving them in a well-ventilated area for one or two days).

When used for MRI, make sure that all parts are 3D printed as dense parts. Usually 3D printer offer the otpion to print a part either as "dense" or "sparse". The "sparse" option results in faster printing and lower consumption of plastic. However it is not adequate for MRI because the air trapped inside the small plastic cavities due to the sparse 3D printing option create off-resonance effects that may significantly distort images of the phantom. It is our experience that printing all plastic parts as "dense" is an absolute necessity at 7 Tesla. This problem may be less pronounced at lower field strength.

The next step is to seal the parts. Even if your 3D printer offers a "waterproof" printing option, which is sometimes available on 3D printers, there is no guarantee that the parts will actually be waterproof. 3D printing of waterproof parts is actually very difficult. Most "waterproof" 3D printing strategies results in reasonably waterproof parts when these are flat (e.g., flat panels) but almost always fail for complex geometries such as a human head. Obviously, an MRI phantom should not leak since this would result in potential damage to the coil and other electronic components. We have experimented with several techniques including painting the plastic parts with epoxy and melting of the plastic surface with a solvent (acetone can be used to melt ABS parts. Methylene chloride can be used to melt polycarbonate plastic). We have found that these two methods do not work well however. The method that we currently use for all our models consists in spraying the parts with a rubber spray. For our phantoms, we apply three thick coats of rubber spray on the outside and the inside of all parts (covering the outside of the outer parts prevents leaks and sweating in the event where some water infiltrates the plastic parts because of failure of the inner-most rubber coat). We use a red rubber spray as opposed to a black one since the latter color is often achieved using ferrite nanoparticles that may be magnetic. Note that the parts must be entirely sealed with spray before assembly, including the small grooves and nudges (we impose a gap between fitting parts of at least 1 mm in our models in order to account for the increased thickness of the part due to the waterproof coating).


Rubber spray.jpg

leads to phantoms that do not leak at all, even months



References about phantom making

[http://www.ncbi.nlm.nih.gov/pubmed/17659546 Design, Construction and Evaluation of an Anthropomorphic Head Phantom With Realistic Susceptibility Artifacts

[http://www.ncbi.nlm.nih.gov/pubmed/3821466 New Polyvinyl Alcohol Gel Material for MRI Phantoms

[http://www.ncbi.nlm.nih.gov/pubmed/16148391 Tissue-mimicking phantom materials for narrowband and ultrawideband microwave applications

[http://www.ncbi.nlm.nih.gov/pubmed/22396226 A Novel MRI-Compatible Brain Ventricle Phantom for Validation of Segmentation and Volumetry Methods

[http://www.ncbi.nlm.nih.gov/pubmed/21866208 Heterogeneous Anthropomorphic Phantoms With Realistic Dielectric Properties For Microwave Breast Imaging Experiments

[http://www.ncbi.nlm.nih.gov/pubmed/22225325 An anthropomorphic polyvinyl alcohol brain phantom based on Colin27 for use in multimodal imaging