BACKGROUND: Manufacturers have provided C-arm CT imaging technologies for applications in interventional radiology in recent years. However, clinical imaging protocols and radiation doses have not been well studied or reported. OBJECTIVE: The purpose of this study is to develop low-dose settings for clinically acceptable CT imaging of temporomandibular joint in interventional radiology suites, using a C-arm imaging angiography system. MATERIALS AND METHODS: CT scans were performed with a flat-panel digital C-arm angiographic system on a 5-year-old anthropomorphic phantom. The CTDI was determined for various rotation times, dose settings and Cu filter selections. The CTDI values were compared with those of conventional low-dose CT for the same phantom. The effectiveness of using Cu filters to reduce dose was also investigated. Images were reviewed by a senior radiologist for clinical acceptance. RESULTS: The manufacturer's default setting gave an equivalent CTDI of 4.8 mGy. Optimizing the dose settings and adding copper filtration reduced the radiation dose by 94%. This represents a 50% reduction from conventional CT. CONCLUSION: Use of Cu filters and low-dose settings significantly reduced radiation dose from that of standard settings. This phantom study process successfully guided the clinical implementation of low-dose studies for all ages at our institution.
BACKGROUND: Manufacturers have provided C-arm CT imaging technologies for applications in interventional radiology in recent years. However, clinical imaging protocols and radiation doses have not been well studied or reported. OBJECTIVE: The purpose of this study is to develop low-dose settings for clinically acceptable CT imaging of temporomandibular joint in interventional radiology suites, using a C-arm imaging angiography system. MATERIALS AND METHODS: CT scans were performed with a flat-panel digital C-arm angiographic system on a 5-year-old anthropomorphic phantom. The CTDI was determined for various rotation times, dose settings and Cu filter selections. The CTDI values were compared with those of conventional low-dose CT for the same phantom. The effectiveness of using Cu filters to reduce dose was also investigated. Images were reviewed by a senior radiologist for clinical acceptance. RESULTS: The manufacturer's default setting gave an equivalent CTDI of 4.8 mGy. Optimizing the dose settings and adding copper filtration reduced the radiation dose by 94%. This represents a 50% reduction from conventional CT. CONCLUSION: Use of Cu filters and low-dose settings significantly reduced radiation dose from that of standard settings. This phantom study process successfully guided the clinical implementation of low-dose studies for all ages at our institution.
Authors: Anne Marie Cahill; Kevin M Baskin; Robin D Kaye; Bita Arabshahi; Randy Q Cron; Esi M Dewitt; Larissa Bilaniuk; Richard B Towbin Journal: AJR Am J Roentgenol Date: 2007-01 Impact factor: 3.959
Authors: Rebecca Fahrig; Robert Dixon; Thomas Payne; Richard L Morin; Arundhuti Ganguly; Norbert Strobel Journal: Med Phys Date: 2006-12 Impact factor: 4.071
Authors: John M Racadio; Drazenko Babic; Robert Homan; John W Rampton; Manish N Patel; Judy M Racadio; Neil D Johnson Journal: AJR Am J Roentgenol Date: 2007-12 Impact factor: 3.959
Authors: Michael Acord; Sphoorti Shellikeri; Seth Vatsky; Abhay Srinivasan; Ganesh Krishnamurthy; Marc S Keller; Anne Marie Cahill Journal: Pediatr Radiol Date: 2017-10-05