High resolution imaging capabilities are essential for accurately guiding successful endovascular interventional procedures. Present x-ray imaging detectors are not always adequate due to their inherent limitations. The newly-developed high-resolution micro-angiographic fluoroscope (MAF-CCD) detector has demonstrated excellent clinical image quality; however, further improvement in performance and physical design may be possible using CMOS sensors. We have thus calculated the theoretical performance of two proposed CMOS detectors which may be used as a successor to the MAF. The proposed detectors have a 300 μm thick HL-type CsI phosphor, a 50 μm-pixel CMOS sensor with and without a variable gain light image intensifier (LII), and are designated MAFCMOS- LII and MAF-CMOS, respectively. For the performance evaluation, linear cascade modeling was used. The detector imaging chains were divided into individual stages characterized by one of the basic processes (quantum gain, binomial selection, stochastic and deterministic blurring, additive noise). Ranges of readout noise and exposure were used to calculate the detectors' MTF and DQE. The MAF-CMOS showed slightly better MTF than the MAF-CMOS-LII, but the MAF-CMOSLII showed far better DQE, especially for lower exposures. The proposed detectors can have improved MTF and DQE compared with the present high resolution MAF detector. The performance of the MAF-CMOS is excellent for the angiography exposure range; however it is limited at fluoroscopic levels due to additive instrumentation noise. The MAF-CMOS-LII, having the advantage of the variable LII gain, can overcome the noise limitation and hence may perform exceptionally for the full range of required exposures; however, it is more complex and hence more expensive.
[1]
J A Rowlands,et al.
X-ray imaging using amorphous selenium: inherent spatial resolution.
,
1995,
Medical physics.
[2]
A. R. Cowen,et al.
Digital X-ray imaging
,
1991
.
[3]
S. Rudin,et al.
A theoretical and experimental evaluation of the microangiographic fluoroscope: A high-resolution region-of-interest x-ray imager.
,
2011,
Medical physics.
[4]
Stephen Rudin,et al.
Use of the Microangiographic Fluoroscope for Coiling of Intracranial Aneurysms
,
2011,
Neurosurgery.
[5]
A Fenster,et al.
A spatial-frequency dependent quantum accounting diagram and detective quantum efficiency model of signal and noise propagation in cascaded imaging systems.
,
1994,
Medical physics.
[6]
Stephen Rudin,et al.
Endovascular coil embolization of a very small ruptured aneurysm using a novel microangiographic technique: technical note
,
2012,
Journal of NeuroInterventional Surgery.
[7]
Robert D. Speller,et al.
DynAMITe: a wafer scale sensor for biomedical applications
,
2011
.
[8]
Stephen Rudin,et al.
Endovascular image-guided interventions (EIGIs).
,
2007,
Medical physics.
[9]
D. Jaffray,et al.
A ghost story: spatio-temporal response characteristics of an indirect-detection flat-panel imager.
,
1999,
Medical physics.