Your search keyword '"Daiyuan Song"' showing total 3 results

1. Determination of aortic pulse transit time based on waveform decomposition of radial pressure wave

Author

Daiyuan Song, Liling Hao, Lisheng Xu, Yang Yao, Wenyan Liu, Jun Yang, Hongxia Ning, and Lin Qi

Subjects

Adult, Male, Correlation coefficient, Science, Zero-point energy, Blood Pressure, Pulse Wave Analysis, Predictive markers, Measure (mathematics), Article, Vascular Stiffness, Humans, Waveform, Arterial Pressure, Aorta, Second derivative, Physics, Multidisciplinary, Arterial stiffening, Mechanics, Decomposition, Healthy Volunteers, Risk factors, Flow (mathematics), Radial Artery, Aortic pressure, Medicine, Female, Biomedical engineering

Abstract

Carotid-femoral pulse transit time (cfPTT) is a widely accepted measure of central arterial stiffness. The cfPTT is commonly calculated from two synchronized pressure waves. However, measurement of synchronized pressure waves is technically challenging. In this paper, a method of decomposing the radial pressure wave is proposed for estimating cfPTT. From the radial pressure wave alone, the pressure wave can be decomposed into forward and backward waves by fitting a double triangular flow wave. The first zero point of the second derivative of the radial pressure wave and the peak of the dicrotic segment of radial pressure wave are used as the peaks of the fitted double triangular flow wave. The correlation coefficient between the measured wave and the estimated forward and backward waves based on the decomposition of the radial pressure wave was 0.98 and 0.75, respectively. Then from the backward wave, cfPTT can be estimated. Because it has been verified that the time lag estimation based on of backward wave has strong correlation with the measured cfPTT. The corresponding regression function between the time lag estimation of backward wave and measured cfPTT is y = 0.96x + 5.50 (r = 0.77; p

Published

2021

2. Estimation of aortic pulse wave velocity based on waveform decomposition of central aortic pressure waveform

Author

Guozhe Sun, Alberto Avolio, Wenyan Liu, Daiyuan Song, Yang Yao, Yuelan Zhang, Lisheng Xu, and Jinzhong Yang

Subjects

Flow waveform, medicine.medical_specialty, Physiology, Biomedical Engineering, Biophysics, Blood Pressure, Pulse Wave Analysis, Vascular Stiffness, Aortic pressure waveform, Physiology (medical), Internal medicine, medicine, Waveform, Humans, Arterial Pressure, Pulse wave velocity, Aorta, Physics, Gold standard (test), medicine.disease, Carotid Arteries, Inflection point, cardiovascular system, Arterial stiffness, Cardiology, Aortic stiffness

Abstract

Objective. Aortic stiffness is associated with risk of cardiovascular events. Carotid-femoral pulse wave velocity (cfPWV) is the current noninvasive gold standard for assessing aortic stiffness. However, the cfPWV measurement is challenging, requiring simultaneous signals at the carotid and femoral sites. Approach. In this study, the aortic PWV is estimated using a single radial pressure waveform and compared with cfPWV. 111 subjects' aortic PWVs are estimated from the decomposition of the derived central aortic pressure waveform based on three types of reconstructed flow waveform: the peak of triangular flow waveform based on 30% ejection time (Q30%tri), the peak of triangular flow waveform based on inflection point (Qtri), and averaged flow waveform (Qavg). The central aortic pressure waveform is derived from a radial pressure waveform via a validated transfer function. Main results. The Qavg is used for estimating aortic PWV without the determination of the peak point of the triangular flow waveforms. The estimated aortic PWV shows good agreement with cfPWV. The mean difference ± SD is 0.29 ± 1.50 m/s (r2 = 0.29, p

Published

2021

3. Aortic pressure waveform reconstruction using a multi-channel Newton blind system identification algorithm

Author

Zongpeng Li, Yingxian Sun, Stephen E. Greenwald, Lisheng Xu, Tiemin Mei, Daiyuan Song, Wenyan Liu, Yufan Wang, and Ning Ji

Subjects

0301 basic medicine, Mean squared error, Computer science, Blood Pressure, Health Informatics, Femoral artery, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, medicine.artery, medicine, Animals, Humans, Waveform, Arterial Pressure, Multi channel, Models, Cardiovascular, System identification, Blood Pressure Determination, Rats, Computer Science Applications, Noise, 030104 developmental biology, Radial Artery, Aortic pressure, Canonical correlation, Algorithm, Algorithms, 030217 neurology & neurosurgery

Abstract

Background Central aortic pressure (CAP) as the major load on the left heart is of great importance in the diagnosis of cardiovascular disease. Studies have pointed out that CAP has a higher predictive value for cardiovascular disease than peripheral artery pressure (PAP) measured by means of traditional sphygmomanometry. However, direct measurement of the CAP waveform is invasive and expensive, so there remains a need for a reliable and well validated non-invasive approach. Methods In this study, a multi-channel Newton (MCN) blind system identification algorithm was employed to noninvasively reconstruct the CAP waveform from two PAP waveforms. In simulation experiments, CAP waveforms were recorded in a previous study, on 25 patients and the PAP waveforms (radial and femoral artery pressure) were generated by FIR models. To analyse the noise-tolerance of the MCN method, variable amounts of noise were added to the peripheral signals, to give a range of signal-to-noise ratios. In animal experiments, central aortic, brachial and femoral pressure waveforms were simultaneously recorded from 2 Sprague-Dawley rats. The performance of the proposed MCN algorithm was compared with the previously reported cross-relation and canonical correlation analysis methods. Results The results showed that the root mean square error of the measured and reconstructed CAP waveforms and less noise-sensitive using the MCN algorithm was smaller than those of the cross-relation and canonical correlation analysis approaches. Conclusion The MCN method can be exploited to reconstruct the CAP waveform. Reliable estimation of the CAP waveform from non-invasive measurements may aid in early diagnosis of cardiovascular disease.

Published

2021