Optimisation of radiation dose, image quality and contrast medium administration in coronary computed tomography angiography /Tan Sock Keow
Radiation dose and contrast medium administration are two major concerns in coronary computed tomography angiography (CCTA). This study aimed to assess the radiation dose and risk of radiation-induced cancer associated with different prospectively ECG-triggered CCTA protocols, and to optimise the...
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Format: | Thesis |
Published: |
2018
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Online Access: | http://studentsrepo.um.edu.my/9185/7/sock_keow.pdf http://studentsrepo.um.edu.my/9185/ |
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Institution: | Universiti Malaya |
Summary: | Radiation dose and contrast medium administration are two major concerns in
coronary computed tomography angiography (CCTA). This study aimed to assess the
radiation dose and risk of radiation-induced cancer associated with different
prospectively ECG-triggered CCTA protocols, and to optimise the radiation dose, image
quality and contrast medium administration with an improved retrospectively ECGtriggered
CCTA protocol. The study is divided into four phases whereby the phases that
involved patients recruitment were approved by the Institutional Ethics Committee
(Medical Ethics No: 989.35). Firstly, radiation dose received from prospectively ECGtriggered
CCTA using different generations of CT scanners was assessed through organ
doses measurement in a standard female adult anthropomorphic phantom. The measured
organ doses were used for the estimation of lifetime attributable risk (LAR) of cancer
incidence in different sex and age. Secondly, a low tube voltage (100 kVp) protocol was
developed for retrospectively ECG-triggered CCTA and tested in 30 patients. The
radiation dose and image quality were compared to the routine 120 kVp protocol. Then,
a personalised contrast volume calculation model based on patient characteristics and test
bolus parameters was developed and validated in 30 recruited patients. Finally, an
improved retrospectively ECG-triggered CCTA protocol was developed using the
combination of 100 kVp and personalised contrast protocol and validated in 30 recruited
patients. Among the prospectively ECG-triggered CCTA protocols, the highest effective
dose (HE) was received from 2 × 32-detector-row dual-source CT (DSCT) scanner (6.06
± 0.72 mSv). Although the heart is the organ of interest in CCTA imaging, the highest
iv
radiation dose was received by breasts and lungs (4 to 8 times higher than heart). The
estimated LARs were generally low for all cancers (less than 0.02 to 113 cases per
100,000 population). For patient’s body mass index (BMI) less than 30 kgm-2
, using
automatic tube current modulation, statistical significant (p < 0.05) radiation dose
reduction (37.8 %) and higher vessel contrast enhancement (VCE) were achieved at 100
kVp. A strong linear relationship was found between VCE and contrast volume (r = 0.97,
p < 0.05). Age, sex, body surface area (BSA) and peak contrast enhancement (PCE) at
test bolus were found to be significant predictors for VCE (p < 0.05). A personalised
contrast volume calculation model was then developed by applying these factors. The
model successfully reduced the total iodine dose (TID) while achieving optimal VCE and
image quality at 120 kVp compared to the routine contrast protocol (9.8 %, p < 0.05).
When combining both the low tube voltage (100 kVp) and personalised contrast protocol,
optimal VCE and image quality were achieved with statistical significant (p < 0.05)
radiation dose (33.8 %) and TID reduction (43.9 %) compared to 120 kVp. The radiation
doses and LAR for cancer incidence from a prospectively ECG-triggered CCTA are
relatively low and depend on the scanner model and imaging protocol. This study
successfully developed a scanning protocol using low tube voltage (100 kVp) and
personalised volume calculation that optimise radiation dose, image quality and contrast
medium administration for retrospectively ECG-triggered CCTA |
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