For the diagnosis of atherosclerosis, biomedical imaging techniques such as intravascular ultrasound (IVUS) and optical coherence tomography (OCT) have been developed. The combined use of IVUS and OCT is hypothesized to remarkably increase diagnostic accuracy of vulnerable plaques. We have developed an integrated IVUS-OCT imaging apparatus, which includes the integrated catheter, motor drive unit, and imaging system. The dual-function imaging catheter has the same diameter of current clinical standard. The imaging system is capable for simultaneous IVUS and OCT imaging in real time. Ex vivo and in vivo experiments on rabbits with atherosclerosis were conducted to demonstrate the feasibility and superiority of the integrated intravascular imaging modality.

For the diagnosis of atherosclerosis, biomedical imaging techniques such as intravascular ultrasound (IVUS) and optical coherence tomography (OCT) have been developed. The combined use of IVUS and OCT is hypothesized to remarkably increase diagnostic accuracy. We report our progress on the probe design and imaging system for achieving a miniature catheter that is capable for in vivo animal study. The integrated IVUS-OCT catheter is featured by a sequential arrangement of an ultrasound transducer and an OCT probe. The capability of the integrated IVUS-OCT imaging catheter and system is demonstrated by in vitro and in vivo imaging experiments of rabbit abdominal aorta. © 2012 IEEE.

OBJECTIVE: Combined use of optical coherence tomography (OCT) and intravascular ultrasound (IVUS) is a potential method for accurate assessment of plaques characteristics and vulnerability. The aim of this study is to develop and evaluate the feasibility of a fully integrated intracoronary OCT-IVUS imaging technique to visualize plaques in living animals. BACKGROUND: In vivo imaging of plaques by an integrated OCT-IVUS system has not been reported. METHODS: Simultaneous real-time OCT-IVUS imaging is performed using an integrated OCT-IVUS system and a single fully-integrated catheter with a 3.6F outer-diameter same as a commercial IVUS catheter. RESULTS: To verify in vivo imaging capability of this technique, five atherosclerotic-model rabbits and a swine were imaged. Images were obtained in these animals without complications. Linear regression shows a high correlation between rabbit plaque sizes determined from histology and OCT/IVUS estimated plaque sizes (R2=0.955, P<0.001 between OCT and histology; R2=0.970, P<0.001 between IVUS and histology). Classification of plaque types and quantitative analysis of plaque sizes were performed in vitro using cadaver coronary segments (n=14). CONCLUSIONS: For the first time, this study shows that an integrated intracoronary OCT-IVUS system is feasible and safe to use in vivo to detect atherosclerotic plaques. This technique provides high resolution and deep penetration capability simultaneously which can facilitate a more powerful tool to explore the development of plaques and may lead to a more accurate assessment of vulnerable plaques in patients.

For the diagnosis of atherosclerosis, biomedical imaging techniques such as intravascular ultrasound (IVUS) and optical coherence tomography (OCT) have been developed. The combined use of IVUS and OCT is hypothesized to remarkably increase diagnostic accuracy of vulnerable plaques. We have developed an integrated IVUS-OCT imaging apparatus, which includes the integrated catheter, motor drive unit, and imaging system. The dual-function imaging catheter has the same diameter of current clinical standard. The imaging system is capable for simultaneous IVUS and OCT imaging in real time. Ex vivo and in vivo experiments on rabbits with atherosclerosis were conducted to demonstrate the feasibility and superiority of the integrated intravascular imaging modality.