Cameron Allan Gunn1, Xiao Hu2, Lieven Vandenberghe1. 1. Electrical and Computer Engineering Department, UCLA, Los Angeles, CA 90095, United States of America. 2. Department of Physiological Nursing, UCSF, San Francisco, CA 94143, United States of America.
Abstract
OBJECTIVE: Many physiological signals are degraded by significant corruptions that limit their usefulness. One example is cerebral blood flow velocity (CBFV) signals, measured by transcranial Doppler, which are susceptible to large errors from patient motion. In this paper, we propose a method to remove artifacts and impute sections of missing data in these signals. APPROACH: The method exploits the low-order dynamical relationship between CBFV, arterial blood pressure and, where available, intracranial pressure. It enhances the measured signals by fitting them to a low-order dynamical model, using convex regularization terms that improve robustness to large deviations and missing data. The method is based on a convex optimization formulation and utilizes recent work in trace norm approximation and subspace system identification. MAIN RESULTS: Simulations demonstrate that the method successfully removes real CBFV artifacts and can impute missing data with reasonable accuracy. Performance was improved when intracranial pressure data was available. CONCLUSION: The methods presented can be used by researchers to remove artifacts and estimate missing sections in CBFV signals. The general approach may be applied to other biomedical signal processing settings. SIGNIFICANCE: This low-order dynamical approach has ongoing applications in noninvasive intracranial pressure estimation.
OBJECTIVE: Many physiological signals are degraded by significant corruptions that limit their usefulness. One example is cerebral blood flow velocity (CBFV) signals, measured by transcranial Doppler, which are susceptible to large errors from patient motion. In this paper, we propose a method to remove artifacts and impute sections of missing data in these signals. APPROACH: The method exploits the low-order dynamical relationship between CBFV, arterial blood pressure and, where available, intracranial pressure. It enhances the measured signals by fitting them to a low-order dynamical model, using convex regularization terms that improve robustness to large deviations and missing data. The method is based on a convex optimization formulation and utilizes recent work in trace norm approximation and subspace system identification. MAIN RESULTS: Simulations demonstrate that the method successfully removes real CBFV artifacts and can impute missing data with reasonable accuracy. Performance was improved when intracranial pressure data was available. CONCLUSION: The methods presented can be used by researchers to remove artifacts and estimate missing sections in CBFV signals. The general approach may be applied to other biomedical signal processing settings. SIGNIFICANCE: This low-order dynamical approach has ongoing applications in noninvasive intracranial pressure estimation.
Authors: Sunghan Kim; Fabien Scalzo; Marvin Bergsneider; Paul Vespa; Neil Martin; Xiao Hu Journal: IEEE Trans Biomed Eng Date: 2010-11-22 Impact factor: 4.538