A moving liver phantom in an anthropomorphic thorax for SPECT MP imaging

Panagi, Sotiris; Hadjiconstanti, Anastasia; Charitou, G; Kaolis, Demetris; Petrou, I; Kyriacou, Costas; Parpottas, Yiannis

doi:10.1007/s13246-021-01081-4

Cited by 5 publications

(3 citation statements)

References 7 publications

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“…Therefore, the developed simulation models can be used to validate new types of tools or to learn surgical techniques. These consist of thoracic-and organ phantoms [3][4][5][6][7][8], tissue phantoms [9][10][11][12] and head and brain phantoms [13][14][15][16][17][18][19], which are especially signi cant for neurosurgery. This also includes neurovascular phantoms that re ect the anatomy of the vessels inside the brain.…”

Section: Introductionmentioning

confidence: 99%

Reduction of animal testing - Influence of the orientation of constructed blood vessels during the 3D printing on the measurement of the pseudo-oxygen saturation of an artificial blood substitute using conventional oxygen sensors: a test series

Jung,

Hoffmann,

Winkler

et al. 2023

Preprint

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Background The development of phantoms to reduce animal testing or to validate new instruments or operation techniques is of increasing importance. On this account, a blood circulation-phantom was developed and used to evaluate conventional oxygen sensors for a newly developed spatula for direct measurement of the blood oxygen saturation at the parenchyma. Methods A solution of copper and nickel sulfate was used as blood substitute. A total of seven different solutions with a pseudo-saturation between 50% and 100% were created. To evaluate the solution as a suitable blood substitute, a two-stage feasibility study was conducted. This study consisted of capturing the absorption spectra of the two sulfate solutions and calibrating the used oxygen sensor. Additionally, blood vessels with a simplified geometry were designed and manufactured using an elastic material (Elastic 50A) with a 3D printer (Formlabs Form 2). To determine the orientation during the printing process, various vessels were printed. Measurements to assess the effects of disturbance (rotation of the vessels during measurements) on the sensor readouts were prepared. Results Upon analyzing the absorption spectra of the blood substitute and ordinary blood, it was observed that the components of the solution behaved similarly to oxygenated and deoxygenated blood, confirming the suitability of copper and nickel sulfate as a blood substitute. The impact of disturbances was also verified through the rotation of the 3D-printed vessels. It was shown that a measurement directly on the disturbances led to outliers and higher values. An optimal orientation was determined to be a lateral placement (90° or 270°) of the sensor. Regarding the orientation of the vessels within the printing space, an orientation of 45° yielded the best results, as the individual layers least affected the light emitted and received by the oxygen sensor. All results pertain to constructed vessels developed using a Formlabs Form 2 printer and Elastic 50A material by Formlabs. Conclusion The achieved results demonstrate the influence of the orientation of the vessel during 3D printing as well as the influence of the position of the vessel during the measurement using a conventional oxygen sensor.

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Section: Introductionmentioning

confidence: 99%

Reduction of animal testing - Influence of the orientation of constructed blood vessels during the 3D printing on the measurement of the pseudo-oxygen saturation of an artificial blood substitute using conventional oxygen sensors: a test series

Jung,

Hoffmann,

Winkler

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…Cardiac phantoms have been developed by many groups to address the costs and impracticalities of current commercially available phantoms [3] and to create myocardial left ventricle phantoms with a variety of defects to assess image quality for different pathology-mimicking scenarios [4]. A moving 3D printed liver phantom was designed to characterise the effect of liver motion and impact on defect detection in myocardial perfusion imaging at various liver-tomyocardial proximities [5].…”

Section: Introductionmentioning

confidence: 99%

Fabrication of 3D Printed Hollow Spheres for QC and Feasibility for Use With xSPECT Bone

Lam

Young

2023

Preprint

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Quantitative accuracy and constancy of Siemens xSPECT Bone quantitative reconstruction algorithm (xBone) can be monitored using activity-filled hollow spheres, which could be 3D printed (3DP-S) and increases accessibility to phantoms. One concern is that 3D prints can have air gaps in the walls which may pose issues for attenuation correction and xBone tissue zone mapping. This study assessed the feasibility of using 3DP-S with materials PLA, PETG and Resin as substitutes for commercial hollow spheres (C-S). Phantom preparation and acquisition parameters were based on the white paper. A Jaszczak phantom was fitted with six 99mTc- and contrast-filled 3DP-S. SPECT/CT acquisitions were performed on the Siemens Intevo T6 and reconstructed with xBone. Regions-of-interest for activity concentration measurements were drawn to the internal diameter of the spheres. PLA and PETG printed via filament freeform fabrication resulted in minute air gaps mainly at steep overhang however did not impact xBone zone maps. Activity concentration recovery of the 3DP-S were within +/-5% of C-S when sufficient projection angles are used. Resin printed via masked stereolithography experienced minor resin pooling and increased wall thickness – the smallest sphere was not usable. Resin printing achieved the best watertightness and transparency. PLA and PETG were most affordable but was labour intensive in construction. PLA performed best overall in print reproducibility and quantitative accuracy. Similarly printed hollow spheres can be used for quality control of xBone accuracy where C-S are not available. While 3D printing increases accessibility to phantoms, close oversight is required of printing conditions.

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“…

We thank Panagi et al [1] for their thoughtful approach to constructing a liver phantom for myocardial perfusion imaging (MPI). There are a number of sources within the gastrointestinal system which may be responsible for artefacts in MPI (in terms of motion, scatter and attenuation).

…”

mentioning

confidence: 99%

Phantoms to simulate gastrointestinal artefact in MPI

2022

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We thank Panagi et al. [1] for their thoughtful approach to constructing a liver phantom for myocardial perfusion imaging (MPI). There are a number of sources within the gastrointestinal system which may be responsible for artefacts in MPI (in terms of motion, scatter and attenuation). The stomach and bowel are others [2]. Would they require similar principles of design?Stomach and bowel are also highly variable in position [3]. This would make sense particularly in viscera which are not anatomically fixed within peritoneum. Specifically, the study concentrated on cranio-caudal motion. Are other directions clinically significant in the authors' experience? How can the phantom be further enhanced to account adequately for intra-abdominal motion?Beyond that, how could we account for artefactual gastric radiotracer uptake exacerbated by medications such as proton pump inhibitors? This is an increasingly common problem as this therapy becomes more common. We have found it to increase the frequency of image re-acquisition [4].

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A moving liver phantom in an anthropomorphic thorax for SPECT MP imaging

Cited by 5 publications

References 7 publications

Reduction of animal testing - Influence of the orientation of constructed blood vessels during the 3D printing on the measurement of the pseudo-oxygen saturation of an artificial blood substitute using conventional oxygen sensors: a test series

Reduction of animal testing - Influence of the orientation of constructed blood vessels during the 3D printing on the measurement of the pseudo-oxygen saturation of an artificial blood substitute using conventional oxygen sensors: a test series

Fabrication of 3D Printed Hollow Spheres for QC and Feasibility for Use With xSPECT Bone

Phantoms to simulate gastrointestinal artefact in MPI

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