TY - JOUR
T1 - Evaluation of physical properties and image of polyvinyl chloride as breast tissue equivalence for dual-modality (mammography and ultrasound)
AU - Hariyanto, Aditya Prayugo
AU - Budiarti, Nurhanifa Tri
AU - Suprijanto,
AU - Ng, Kwan Hoong
AU - Haryanto, Freddy
AU - Endarko,
N1 - Publisher Copyright:
© 2023, Australasian College of Physical Scientists and Engineers in Medicine.
PY - 2023/9
Y1 - 2023/9
N2 - TMP is gradually becoming a fundamental element for quality assurance and control in ionizing and non-ionizing radiation imaging modalities as well as in the development of different techniques. This study aimed to evaluate and obtain polyvinyl chloride tissue mimicking material for dual-modality breast phantoms in mammography and ultrasound. Breast tissue equivalence was evaluated based on X-ray attenuation properties, speed of sound, attenuation, and acoustic impedance. There are six samples of PVC-plasticizer material with variations of PVC concentration and additives. The evaluation of X-ray attenuation was carried out using mammography from 23 to 35 kV, while the acoustic properties were assessed with mode A ultrasound and a transducer frequency of 5 MHz. A breast phantom was created from TMP material with tissue equivalence and was then evaluated using mammography as well as ultrasound to analyze its image quality. The results showed that samples A (PVC 5%, DOP 95%), B (PVC 7%, DOP 93%), C (PVC 10%, DOP 90%), E (PVC 7%, DOP 90%, graphite 3%), and F (PVC 7%, DOP 90%, silicone oil 3%) have the closest equivalent to the ACR breast phantom material with a different range of 0.01–1.39 in the 23–35 kV range. Based on the evaluation of the acoustic properties of ultrasound, A had high similarity to fat tissue with a difference of 0.03 (dB cm− 1 MHz− 1) and 0.07 (106 kg m− 2 s− 1), while B was close to the glandular tissue with a difference of 9.2 m s− 1. Multilayer breast phantom images’ results showed gray levels in mammography and ultrasound modalities. Therefore, this study succeeded in establishing TMP material for mammography and ultrasound. It can also be used for simple quality assurance and control programs.
AB - TMP is gradually becoming a fundamental element for quality assurance and control in ionizing and non-ionizing radiation imaging modalities as well as in the development of different techniques. This study aimed to evaluate and obtain polyvinyl chloride tissue mimicking material for dual-modality breast phantoms in mammography and ultrasound. Breast tissue equivalence was evaluated based on X-ray attenuation properties, speed of sound, attenuation, and acoustic impedance. There are six samples of PVC-plasticizer material with variations of PVC concentration and additives. The evaluation of X-ray attenuation was carried out using mammography from 23 to 35 kV, while the acoustic properties were assessed with mode A ultrasound and a transducer frequency of 5 MHz. A breast phantom was created from TMP material with tissue equivalence and was then evaluated using mammography as well as ultrasound to analyze its image quality. The results showed that samples A (PVC 5%, DOP 95%), B (PVC 7%, DOP 93%), C (PVC 10%, DOP 90%), E (PVC 7%, DOP 90%, graphite 3%), and F (PVC 7%, DOP 90%, silicone oil 3%) have the closest equivalent to the ACR breast phantom material with a different range of 0.01–1.39 in the 23–35 kV range. Based on the evaluation of the acoustic properties of ultrasound, A had high similarity to fat tissue with a difference of 0.03 (dB cm− 1 MHz− 1) and 0.07 (106 kg m− 2 s− 1), while B was close to the glandular tissue with a difference of 9.2 m s− 1. Multilayer breast phantom images’ results showed gray levels in mammography and ultrasound modalities. Therefore, this study succeeded in establishing TMP material for mammography and ultrasound. It can also be used for simple quality assurance and control programs.
KW - Attenuation
KW - Dual-modality
KW - Polyvinyl chloride
KW - The speed of sound
KW - Tissue mimicking
UR - http://www.scopus.com/inward/record.url?scp=85160592998&partnerID=8YFLogxK
U2 - 10.1007/s13246-023-01283-y
DO - 10.1007/s13246-023-01283-y
M3 - Article
C2 - 37253939
AN - SCOPUS:85160592998
SN - 2662-4729
VL - 46
SP - 1175
EP - 1185
JO - Physical and Engineering Sciences in Medicine
JF - Physical and Engineering Sciences in Medicine
IS - 3
ER -