Customized three-dimensional printed optical phantoms with user defined absorption and scattering

Sanjana Pannem; Jordan Sweer; Phuong Diep; Justine Lo; Michael Snyder; Gabriella Stueber; Yanyu Zhao; Syeda Tabassum; Raeef Istfan; Junjie Wu; Shyamsunder Erramilli; Darren M. Roblyer

doi:10.1117/12.2217051

18 March 2016 Customized three-dimensional printed optical phantoms with user defined absorption and scattering

Sanjana Pannem, Jordan Sweer, Phuong Diep, Justine Lo, Michael Snyder, Gabriella Stueber, Yanyu Zhao, Syeda Tabassum, Raeef Istfan, Junjie Wu, Shyamsunder Erramilli, Darren M. Roblyer

Author Affiliations +

Proceedings Volume 9700, Design and Quality for Biomedical Technologies IX; 970008 (2016) https://doi.org/10.1117/12.2217051
Event: SPIE BiOS, 2016, San Francisco, California, United States

Abstract

The use of reliable tissue-simulating phantoms spans multiple applications in spectroscopic imaging including device calibration and testing of new imaging procedures. Three-dimensional (3D) printing allows for the possibility of optical phantoms with arbitrary geometries and spatially varying optical properties. We recently demonstrated the ability to 3D print tissue-simulating phantoms with customized absorption (μ_a) and reduced scattering (μ_s`) by incorporating nigrosin, an absorbing dye, and titanium dioxide (TiO₂), a scattering agent, to acrylonitrile butadiene styrene (ABS) during filament extrusion. A physiologically relevant range of μ_a and μ_s` was demonstrated with high repeatability. We expand our prior work here by evaluating the effect of two important 3D-printing parameters, percent infill and layer height, on both μ_a and μ_s`. 2 cm³ cubes were printed with percent infill ranging from 10% to 100% and layer height ranging from 0.15 to 0.40 mm. The range in μ_a and μ_s` was 27.3% and 19.5% respectively for different percent infills at 471 nm. For varying layer height, the range in μ_a and μ_s` was 27.8% and 15.4% respectively at 471 nm. These results indicate that percent infill and layer height substantially alter optical properties and should be carefully controlled during phantom fabrication. Through the use of inexpensive hobby-level printers, the fabrication of optical phantoms may advance the complexity and availability of fully customizable phantoms over multiple spatial scales. This technique exhibits a wider range of adaptability than other common methods of fabricating optical phantoms and may lead to improved instrument characterization and calibration.

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Sanjana Pannem, Jordan Sweer, Phuong Diep, Justine Lo, Michael Snyder, Gabriella Stueber, Yanyu Zhao, Syeda Tabassum, Raeef Istfan, Junjie Wu, Shyamsunder Erramilli, and Darren M. Roblyer "Customized three-dimensional printed optical phantoms with user defined absorption and scattering", Proc. SPIE 9700, Design and Quality for Biomedical Technologies IX, 970008 (18 March 2016); https://doi.org/10.1117/12.2217051

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