OBJECTIVE: A new technology is introduced that enables real-time 4D (three spatial dimensions plus time) X-ray guidance for vascular catheter interventions with acceptable levels of ionising radiation. METHODS: The enabling technology is a combination of low-dose tomographic data acquisition with novel compressed sensing reconstruction and use of prior image information. It was implemented in a prototype set-up consisting of a gantry-based flat detector system. In pigs (n = 5) angiographic interventions were simulated. Radiation dosage on a per time base was compared with the "gold standard" of X-ray projection imaging. RESULTS: Contrary to current image guidance methods that lack permanent 4D updates, the spatial position of interventional instruments could be resolved in continuous, spatial 4D guidance; the movement of the guide wire as well as the expansion of stents could be precisely tracked in 3D angiographic road maps. Dose rate was 23.8 μGy/s, similar to biplane standard angiographic fluoroscopy, which has a dose rate of 20.6 μGy/s. CONCLUSION: Real-time 4D X-ray image-guidance with acceptable levels of radiation has great potential to significantly influence the field of minimally invasive medicine by allowing faster and safer interventions and by enabling novel, much more complex procedures for vascular and oncological minimally invasive therapy. KEY POINTS: • Real-time 4D (three spatial dimensions plus time) angiographic intervention guidance is realistic. • Low-dose tomographic data acquisition with special compressed sensing-based algorithms is enabled. • Compared with 4D CT fluoroscopy, this method reduces radiation to acceptable levels. • Once implemented, vascular interventions may become safer and faster. • More complex intervention approaches may be developed.
OBJECTIVE: A new technology is introduced that enables real-time 4D (three spatial dimensions plus time) X-ray guidance for vascular catheter interventions with acceptable levels of ionising radiation. METHODS: The enabling technology is a combination of low-dose tomographic data acquisition with novel compressed sensing reconstruction and use of prior image information. It was implemented in a prototype set-up consisting of a gantry-based flat detector system. In pigs (n = 5) angiographic interventions were simulated. Radiation dosage on a per time base was compared with the "gold standard" of X-ray projection imaging. RESULTS: Contrary to current image guidance methods that lack permanent 4D updates, the spatial position of interventional instruments could be resolved in continuous, spatial 4D guidance; the movement of the guide wire as well as the expansion of stents could be precisely tracked in 3D angiographic road maps. Dose rate was 23.8 μGy/s, similar to biplane standard angiographic fluoroscopy, which has a dose rate of 20.6 μGy/s. CONCLUSION: Real-time 4D X-ray image-guidance with acceptable levels of radiation has great potential to significantly influence the field of minimally invasive medicine by allowing faster and safer interventions and by enabling novel, much more complex procedures for vascular and oncological minimally invasive therapy. KEY POINTS: • Real-time 4D (three spatial dimensions plus time) angiographic intervention guidance is realistic. • Low-dose tomographic data acquisition with special compressed sensing-based algorithms is enabled. • Compared with 4D CT fluoroscopy, this method reduces radiation to acceptable levels. • Once implemented, vascular interventions may become safer and faster. • More complex intervention approaches may be developed.
Authors: Rajiv Gupta; Michael Grasruck; Christoph Suess; Soenke H Bartling; Bernhard Schmidt; Karl Stierstorfer; Stefan Popescu; Tom Brady; Thomas Flohr Journal: Eur Radiol Date: 2006-03-10 Impact factor: 5.315
Authors: Johannes Salamon; Martin Hofmann; Caroline Jung; Michael Gerhard Kaul; Franziska Werner; Kolja Them; Rudolph Reimer; Peter Nielsen; Annika Vom Scheidt; Gerhard Adam; Tobias Knopp; Harald Ittrich Journal: PLoS One Date: 2016-06-01 Impact factor: 3.240