Patrick Bosshard scite author profile

Patrick Bosshard

3Publications

33Citation Statements Received

89Citation Statements Given

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Affiliations

ETH Zurich, Board of the Swiss Federal Institutes of Technology

Publications

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Anthropomorphic phantom for deformable lung and liver CT and MR imaging for radiotherapy

et al. 2020

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In this study, a functioning and ventilated anthropomorphic phantom was further enhanced for the purpose of CT and MR imaging of the lung and liver. A deformable lung, including respiratory tract was 3D printed. Within the lung's inner structures is a solid region shaped from a patient's lung tumour and six nitro-glycerine capsules as reference landmarks. The full internal mesh was coated, and the tumour filled, with polyorganosiloxane based gel. A moulded liver was created with an external casing of silicon filled with polyorganosiloxane gel and flexible plastic internal structures. The liver, fitted to the inferior portion of the right lung, moves along with the lung's ventilation. In the contralateral side, a cavity is designed to host a dosimeter, whose motion is correlated to the lung pressure. A 4DCT of the phantom was performed along with static and 4D T1 weighted MR images. The CT Hounsfield units (HU) for the flexible 3D printed material were -600 -100HU (lung and liver structures), for the polyorganosiloxane gel 50 -120HU (lung coating and liver filling) and for the silicon 650 -800HU (liver casing). The MR image intensity units were 0 -150, 0 -100 and 80 -110 respectively. The maximum range of motion in the 4D imaging for the superior lung was 1 -3.5mm and 3.5 -8mm in the inferior portion. The liver motion was 5.5 -8.0mm at the tip and 5.7 -10.0mm at the dome. No measurable drift in motion was observed over a two hour session and motion was reproducible over three different sessions for sin 2 (t), sin 4 (t) and a patient-like breathing curve with the interquartile range of amplitudes for all breathing cycles within 0.5mm. The addition of features within the lung and of a deformable liver will allow the phantom to be used for imaging studies such as validation of 4DMRI and pseudo CT methods.

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Hierarchical porous materials made by stereolithographic printing of photo-curable emulsions

Kleger

Minas

Bosshard

et al. 2021

Sci Rep

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Porous materials are relevant for a broad range of technologies from catalysis and filtration, to tissue engineering and lightweight structures. Controlling the porosity of these materials over multiple length scales often leads to enticing new functionalities and higher efficiency but has been limited by manufacturing challenges and the poor understanding of the properties of hierarchical structures. Here, we report an experimental platform for the design and manufacturing of hierarchical porous materials via the stereolithographic printing of stable photo-curable Pickering emulsions. In the printing process, the micron-sized droplets of the emulsified resins work as soft templates for the incorporation of microscale porosity within sequentially photo-polymerized layers. The light patterns used to polymerize each layer on the building stage further generate controlled pores with bespoke three-dimensional geometries at the millimetre scale. Using this combined fabrication approach, we create architectured lattices with mechanical properties tuneable over several orders of magnitude and large complex-shaped inorganic objects with unprecedented porous designs.

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Hierarchical porous materials made by stereolithographic printing of photo-curable emulsions

Kleger¹,

Minas²,

Bosshard³

et al. 2021

Preprint

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