Fluctuation in total curvature (δK) predicted aortic disease state (normal, successful surgery, or failed surgical outcomes) with a classification accuracy of 92.8 ±1.7%.
Observational
Does an imaging-based geometric descriptor using fluctuation in total curvature (δK) accurately predict aortic disease state?
Fluctuation in total curvature (δK) provides a highly accurate imaging-based geometric descriptor for predicting aortic disease state and surgical outcomes.
Abstract Clinical imaging modalities are a mainstay of modern disease management, but the full utilization of imaging-based data remains elusive. Aortic disease is defined by anatomic scalars quantifying aortic size, even though aortic disease progression initiates complex shape changes. We present an imaging-based geometric descriptor, inspired by fundamental ideas from topology and soft-matter physics that captures dynamic shape evolution. The aorta is reduced to a two-dimensional mathematical surface in space whose geometry is fully characterized by the local principal curvatures. Disease causes deviation from the smooth bent cylindrical shape of normal aortas, leading to a family of highly heterogeneous surfaces of varying shapes and sizes. To deconvolute changes in shape from size, the shape is characterized using integrated Gaussian curvature or total curvature. The fluctuation in total curvature ( δK ) across aortic surfaces captures heterogeneous morphologic evolution by characterizing local shape changes. We discover that aortic morphology evolves with a power-law defined behavior with rapidly increasing δK forming the hallmark of aortic disease. Divergent δK is seen for highly diseased aortas indicative of impending topologic catastrophe or aortic rupture. We also show that aortic size (surface area or enclosed aortic volume) scales as a generalized cylinder for all shapes. Classification accuracy for predicting aortic disease state (normal, diseased with successful surgery, and diseased with failed surgical outcomes) is 92.8 ±1.7% . The analysis of δK can be applied on any three-dimensional geometric structure and thus may be extended to other clinical problems of characterizing disease through captured anatomic changes.
Khabaz et al. (Mon,) conducted a observational in Aortic dissections. Fluctuation in total curvature (δK) was evaluated on Predicting aortic disease state (normal, diseased with successful surgery, and diseased with failed surgical outcomes). Fluctuation in total curvature (δK) predicted aortic disease state (normal, successful surgery, or failed surgical outcomes) with a classification accuracy of 92.8 ±1.7%.
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