OBJECTIVES: To verify the ability to identify the layered structures of the ureteral wall and to image a segment of the ureter in 3 dimensions with high-speed, endoscopic optical coherence tomography (EOCT). METHODS: We imaged a porcine ureter ex vivo using a spectral-domain EOCT with a specially designed circumferential scanning fiber catheter. The images were correlated with the histologic findings to identify the corresponding structures. Three-dimensional images and en face images at different depths from the luminal surface were reconstructed from the multiple cross-sectional images to visualize the layered structure of a segment of the ureter from different perspectives. RESULTS: The EOCT images clearly revealed all layers of the ureteral wall as shown in the histologic images. In particular, with the specially designed fiber catheter, the light beam was well centered during the rotation and pull back, allowing constant acquisition of high-fidelity images and unambiguous identification of the smooth muscle layers in all images. With high-speed EOCT, a segment of ureter (20 mm) can be imaged in <90 seconds at a high resolution. CONCLUSIONS: With its ability to visualize all layers of the ureteral wall, EOCT offers the potential to stage urothelial cancers that have infiltrated the muscular wall (Stage T2). This information will be complimentary to the diagnostic information obtained through ureteroscopic biopsy and computed tomography urogram.
OBJECTIVES: To verify the ability to identify the layered structures of the ureteral wall and to image a segment of the ureter in 3 dimensions with high-speed, endoscopic optical coherence tomography (EOCT). METHODS: We imaged a porcine ureter ex vivo using a spectral-domain EOCT with a specially designed circumferential scanning fiber catheter. The images were correlated with the histologic findings to identify the corresponding structures. Three-dimensional images and en face images at different depths from the luminal surface were reconstructed from the multiple cross-sectional images to visualize the layered structure of a segment of the ureter from different perspectives. RESULTS: The EOCT images clearly revealed all layers of the ureteral wall as shown in the histologic images. In particular, with the specially designed fiber catheter, the light beam was well centered during the rotation and pull back, allowing constant acquisition of high-fidelity images and unambiguous identification of the smooth muscle layers in all images. With high-speed EOCT, a segment of ureter (20 mm) can be imaged in <90 seconds at a high resolution. CONCLUSIONS: With its ability to visualize all layers of the ureteral wall, EOCT offers the potential to stage urothelial cancers that have infiltrated the muscular wall (Stage T2). This information will be complimentary to the diagnostic information obtained through ureteroscopic biopsy and computed tomography urogram.
Authors: U L Mueller-Lisse; O A Meissner; M Bauer; C Weber; G Babaryka; C G Stief; M F Reiser; U G Mueller-Lisse Journal: Urology Date: 2009-04-10 Impact factor: 2.649
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Authors: Hiram G Bezerra; Marco A Costa; Giulio Guagliumi; Andrew M Rollins; Daniel I Simon Journal: JACC Cardiovasc Interv Date: 2009-11 Impact factor: 11.195
Authors: P Kallidonis; G C Kagadis; P Kitrou; A Tsamandas; I Kyriazis; I Georgiopoulos; D Karnabatidis; S Tsantis; D Liourdi; A Al-Aown; E Liatsikos Journal: Lasers Med Sci Date: 2014-03-04 Impact factor: 3.161