Post on 13-Jun-2020
Slide 1/39
Dr. Antonios Lontos, Assistant Professor Department of Mechanical Engineering
Frederick University, Cyprus, Email: eng.la@frederick.ac.cy
Presentation Title:
Design and construction of silicon lung and heart for the phantom
The project ΥΓΕΙΑ/ΔΥΓΕΙΑ/0311/27 (ΒΙΕ) is co-financed by the European Regional Development Fund and the Republic of Cyprus through the Research Promotion Foundation.
1st INTERDISCIPLARY ONCOLOGY CONFERENCE
“DIAGNOSIS AND THERAPY” 29th of March 2014, Nicosia - Cyprus
Project Title: Optimizing the Diagnostic Value in SPECT Myocardial Perfusion
Imaging under the influence of the respiratory motion
Slide 2/39
Table of contents
1. Introduction
2. Image processing and 3D design
3. Design of the moulds
4. Construction of aluminum moulds for heart and lungs
5. Construction of silicon heart and lungs
6. Conclusions
Slide 3/39
1. Introduction
The specificity of myocardial perfusion images (MPI) is influenced not only by the cardiac motion but also by various other parameters such as the respiratory motion Our scope was to develop a respiratory motion phantom, in order to study the influence the respiratory motion to MPI. We will also motion correct the images by independent reconstructions of each gated-frame followed by transformation of each image with respect to a reference image using known motion fields. Concluding on the influence the respiratory and diaphragmatic motion to MPI applying the proposed approach will result in the optimization of MPI protocols by the consortium physicians Further, the elaborated phantom will be used for Quality Assurance measurements to validate new protocols before implementation as well as for educational purposes
Slide 4/39
2. Image processing and 3D design
The first step to construct a real lung is to know the exact geometry and shape. CT scan were conducted and various medical images of human thorax were collected.
Slide 5/39
Thorax-CT flash-anatomy Total planes: 86
Lungs geometry after image processing
Slide 6/39
Left lung geometry
Real lung geometry Schematic lung geometry
Real lung geometry after image processing
Slide 7/39
Slide 8/39
Left lung geometry (volume 485 cm3)
Right lung geometry - (volume 569 cm3)
Slide 9/39
Design of heart chamber
Volume for heart chamber (Initial 80 cm3)
Inner part
Outer part
Slide 10/39
3. Design of the moulds
left lung assembly Right lung assembly
Slide 11/39
Design of different parts of the left lung mould
Part 1 Part 2 Part 3
Part 4 Part 5 Part 6
Slide 12/39
Assembly of left lung mould
Slide 13/39
Part 1 Part 2 Part 3
Part 4 Part 5 Part 6
Design of different parts for the right lung mould
Slide 14/39
Assembly of right lung mould
Slide 15/39
Design of different parts for heart mould – Inner part
Inner part
Slide 16/39
Design of different parts for heart mould – Outer part
Slide 17/39
4. Construction of aluminum moulds for heart and lungs
In order to manufacture all different parts for the left and right mould a CNC machine has been used.
Slide 18/39
Detail dimensions for part 5 left lung mould
Slide 19/39
Preparation of the CNC manufacturing
Slide 20/39
CNC manufacturing simulation
Slide 21/39
4. Construction of aluminum moulds for heart and lungs
Aluminum parts of the left lung mould Part 1
Part 2 Part 3
Part 4 Part 5
Slide 22/39
Aluminum parts of the left lung mould
Slide 23/39
Aluminum parts of the right lung mould
Slide 24/39
Assembly of the right lung mould
Slide 25/39
Moulds for the heart - inner part
Slide 26/39
Moulds for the heart – outer part
Slide 27/39
5. Construction of silicon heart and lungs
Two different silicon rubber were used in order to construct left and right lungs. Special features (very good flow, excellent mould release; usually no further release agent required, fast and non-shrink cure at room temperature which, can be accelerated considerably by the application of heat, medium Shore A hardness (approx. 40), good transparency of the cured rubber, high tear strength, outstanding resistance to casting resins, particularly, polyurethanes and epoxies, for long service life of the molds.
Elastosil M 4645 A/B, , RTV-2 Silastic 3481
Slide 28/39
Silicone mixing (component A+B)
Silicone parameters - Color - Density - Viscosity - Hardness - Elongation at break - Tear strength
Injection of silicon rubber into the lung moulds
Silicon injection mechanism Injection procedure
Slide 29/39
Injection of silicon rubber into the lung moulds
Left lung mould Silicon left lung with bubbles
Vacuum pump and chamber After mixture preparation 5-10 min in vacuum chamber
Slide 30/39
Silicon left and right lungs
Left lung
Right lung from white silicon rubber
Right lung
White silicon rubber White and transparent silicon rubber
Slide 31/39
Cage construction for better simulation of the respiratory motion
Thermoplastic cage Thermoplastic cage with silicon lungs
Slide 32/39
Transparent cardiac and respiratory phantoms within the anthropomorphic phantom stabilized by a tissue-equivalent support (proper distances and inclinations)
Shaped thermoplastics were sewed around the lungs to keep the right shape during inhalation
Lung-equivalent material inserted in the lungs
Phantom and lungs stabilization
Tissue-equivalent support
Slide 33/39
Silicon heart final construction, transparent silicon
Inner part Outer part
Inner part Outer part
Slide 34/39
Inner part testing
Outer part testing
NO pressure With pressure
NO pressure With pressure
Slide 35/39
Silicon heart final assembly and testing
NO pressure With pressure
Slide 36/39
Respiratory movement
Slide 37/39
Heart movement
Slide 38/39
Phantom
Slide 39/39
The project ΥΓΕΙΑ/ΔΥΓΕΙΑ/0311/27 (ΒΙΕ) is co-financed by the European Regional Development Fund and the Republic of Cyprus through the Research Promotion Foundation.
Thank you for your attention
The author would like to thank: - Yiannis Parpottas, Ph.D. in Nuclear Physics - Isabelle Chrysanthou, Ph.D. in Medical Physics - Antonis Antoniou, Ph.D. in Mechanical Engineering
and - Panayi Panayiotis (CNC manufacturing , Moulds Construction) “Machinery Panagiotis J. Panagi”