Abstract
Degradation of the wall of human ascending thoracic aorta has been assessed through Optical Coherence Tomography (OCT). OCT images of the media layer of the aortic wall exhibit micro-structure degradation in case of diseased aortas from aneurysmal vessels or in aortas prone to aortic dissections. The degeneration in vessel walls appears as low-reflectivity areas due to the invasive appearance of acidic polysaccharides and mucopolysaccharides within a typical ordered microstructure of parallel lamellae of smooth muscle cells, elastin and collagen fibers. An OCT indicator of wall degradation can be generated upon the spatial quantification of the extension of degraded areas in a similar way as conventional histopathology. This proposed OCT marker offers a real-time clinical insight of the vessel status to help cardiovascular surgeons in vessel repair interventions. However, the delineation of degraded areas on the B-scan image from OCT is sometimes difficult due to presence of speckle noise, variable SNR conditions on the measurement process, etc. Degraded areas could be outlined by basic thresholding techniques taking advantage of disorders evidences in B-scan images, but this delineation is not always optimum and requires complex additional processing stages. This work proposes an optimized delineation of degraded spots in vessel walls, robust to noisy environments, based on the analysis of the second order variation of image intensity of backreflection to determine the type of local structure. Results improve the delineation of wall anomalies providing a deeper physiological perception of the vessel wall conditions. Achievements could be also transferred to other clinical scenarios: carotid arteries, aorto-iliac or ilio-femoral sections, intracranial, etc.
Highlights
Surgical repair of ascending thoracic aneurysms usually involves the substitution of the diseased portion of the aorta by a graft which has to be sewn onto both cut ends to replace the degraded vessel section that is removed [1]
Anomalous tissue regions produce different backscattering intensity profiles when imaged with Optical Coherence Tomography (OCT) due to the invasive appearance of acidic polysaccharides and mucopolysaccharides within a typical ordered microstructure of parallel lamellae of smooth muscle cell, elastin and collagen fibers
Aortic vessel walls from human samples were studied in laboratory. These samples correspond to 28 patients distributed into those from Thoracic Aortic Aneurysm (TAA) repair interventions (18 patients) and from heart donors (10 patients)
Summary
Surgical repair of ascending thoracic aneurysms usually involves the substitution of the diseased portion of the aorta by a graft which has to be sewn onto both cut ends to replace the degraded vessel section that is removed [1]. The sewing point of the thoracic aortic graft has to be the closest adjacent healthy tissue to prevent further medical complications: dissections, pseudo-aneurysm formation, etc. The aorta is a cardiovascular vessel which wall is structured in three different layers: intima, media and adventitia [2]. The media layer provides strength and elasticity to the wall due to an organized matrix of collagen and elastin fibers. The degradation of the media aortic layer has been documented as the main cause for the formation of an aneurysm [3] that, if it suffers from a dissection, it can lead to death. Anomalous tissue regions produce different backscattering intensity profiles when imaged with OCT due to the invasive appearance of acidic polysaccharides and mucopolysaccharides within a typical ordered microstructure of parallel lamellae of smooth muscle cell, elastin and collagen fibers
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