Three-dimensional hemodynamics analysis of the circle of Willis in the patient-specific nonintegral arterial structures

Liu, Xin; Gao, Zhifan; Xiong, Hongyan; Ghista, Dhanjoo N.; Ren, Lijie; Zhang, Heye; Wu, Wanqing; Huang, Wenhua; Hau, William Kongto

doi:10.1007/s10237-016-0773-6

Cited by 44 publications

(37 citation statements)

References 42 publications

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“…Since medical imaging technologies may allow to export target anatomical model in a STL file extension and although STL is a common file extension, it is not possible to perform a dynamic simulation analysis to target model in all cases. Therefore, the target model may require to be modeled manually or a 3rd party software such as Comsol, Abaqus or Fluent may be utilized to overcome the lack of STL file support especially in dynamic analysis [23,24]. On the other hand, researchers may perform static analysis on an STL file by means of a tool such as Power Surfacing or may apply directly to the generated mesh surfaces of the model in SolidWorks [25].…”

Section: Resultsmentioning

confidence: 99%

Patient Specific Cardiovascular Disease Modelling Based on the Computational Fluid Dynamics Simulations: Segmentation and Hemodynamic Model of a Thoracic Artery

2020

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Section: Resultsmentioning

confidence: 99%

Patient Specific Cardiovascular Disease Modelling Based on the Computational Fluid Dynamics Simulations: Segmentation and Hemodynamic Model of a Thoracic Artery

2020

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“…Hemodynamic monitoring of SV, CO, and BP are important and useful in many clinical diagnoses and therapies, such as serious heart failure and cardiogenic shock [ 14 , 15 ], early detecting the resuscitation of progressive hemorrhage and hypovolemic shock [ 16 ], fluid responsiveness in patients undergoing gastrointestinal surgery [ 17 ], and detecting the changes in the aortic pressure due to orthostatic-related syncope [ 18 ]. There are now some methods that are acceptable for noninvasive SV measurement such as echocardiography and impedance cardiography.…”

Section: Discussionmentioning

confidence: 99%

Using the Pulse Contour Method to Measure the Changes in Stroke Volume during a Passive Leg Raising Test

Liu

Tan

et al. 2018

Sensors

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The pulse contour method is often used with the Windkessel model to measure stroke volume. We used a digital pressure and flow sensors to detect the parameters of the Windkessel model from the pulse waveform. The objective of this study was to assess the stability and accuracy of this method by making use of the passive leg raising test. We studied 24 healthy subjects (40 ± 9.3 years), and used the Medis® CS 1000, an impedance cardiography, as the comparing reference. The pulse contour method measured the waveform of the brachial artery by using a cuff. The compliance and resistance of the peripheral artery was detected from the cuff characteristics and the blood pressure waveform. Then, according to the method proposed by Romano et al., the stroke volume could be measured. This method was implemented in our designed blood pressure monitor. A passive leg raising test, which could immediately change the preloading of the heart, was done to certify the performance of our method. The pulse contour method and impedance cardiography simultaneously measured the stroke volume. The measurement of the changes in stroke volume using the pulse contour method had a very high correlation with the Medis® CS 1000 measurement, the correlation coefficient of the changed ratio and changed differences in stroke volume were r2 = 0.712 and r2 = 0.709, respectively. It was shown that the stroke volume measured by using the pulse contour method was not accurate enough. But, the changes in the stroke volume could be accurately measured with this pulse contour method. Changes in stroke volume are often used to understand the conditions of cardiac preloading in the clinical field. Moreover, the operation of the pulse contour method is easier than using impedance cardiography and echocardiography. Thus, this method is suitable to use in different healthcare fields.

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“…Recently, carotid artery measurement studies for diagnosis of cardiovascular disease have been investigated [1–3], and computational approaches and modeling studies of blood vessels for vascular stenosis and blood flow analysis have been increased [4–7] in western medicine. On the other hand, many studies of eastern medicine have aimed to objectify, quantify, and automate wrist pulse diagnosis by employing modern sensors for data acquisition, data processing, and pattern classification [8].…”

Section: Introductionmentioning

confidence: 99%

Pulse wave response characteristics for thickness and hardness of the cover layer in pulse sensors to measure radial artery pulse

et al. 2018

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BackgroundPiezo-resistive pressure sensors are widely used for measuring pulse waves of the radial artery. Pulse sensors are generally fabricated with a cover layer because pressure sensors without a cover layer are fragile when they come into direct contact with the skin near the radial artery. However, no study has evaluated the dynamic pulse wave response of pulse sensors depending on the thickness and hardness of the cover layer. This study analyzed the dynamic pulse wave response according to the thickness and hardness of the cover layer and suggests an appropriate thickness and hardness for the design of pulse sensors with semiconductor device-based pressure sensors.MethodsPulse sensors with 6 different cover layers with various thicknesses (0.8 mm, 1 mm, 2 mm) and hardnesses (Shore type A; 30, 43, 49, 71) were fabricated. Experiments for evaluating the dynamic pulse responses of the fabricated sensors were performed using a pulse simulator to transmit the same pulse wave to each of the sensors. To evaluate the dynamic responses of the fabricated pulse sensors, experiments with the pulse sensors were conducted using a simulator that artificially generated a constant pulse wave. The pulse wave simulator consisted of a motorized cam device that generated the artificial radial pulse waveform by adjusting the stroke of the cylindrical air pump and an air tube that conveyed the pulse to the artificial wrist.ResultsThe amplitude of the measured pulse pressure decreased with increasing thickness and hardness of the cover layer. Normalized waveform analysis showed that the thickness rather than the hardness of the cover layer contributed more to waveform distortion. Analysis of the channel distribution of the pulse sensor with respect to the applied constant dynamic pressure showed that the material of the cover layer had a large effect.ConclusionsIn this study, in-line array pulse sensors with various cover layers were fabricated, the dynamic pulse wave responses according to the thickness and the hardness of the cover layer were analyzed, and an appropriate thickness and hardness for the cover layer were suggested. The dynamic pulse wave responses of pulse sensors revealed in this study will contribute to the fabrication of improved pulse sensors and pulse wave analyses.

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Three-dimensional hemodynamics analysis of the circle of Willis in the patient-specific nonintegral arterial structures

Cited by 44 publications

References 42 publications

Patient Specific Cardiovascular Disease Modelling Based on the Computational Fluid Dynamics Simulations: Segmentation and Hemodynamic Model of a Thoracic Artery

Patient Specific Cardiovascular Disease Modelling Based on the Computational Fluid Dynamics Simulations: Segmentation and Hemodynamic Model of a Thoracic Artery

Using the Pulse Contour Method to Measure the Changes in Stroke Volume during a Passive Leg Raising Test

Pulse wave response characteristics for thickness and hardness of the cover layer in pulse sensors to measure radial artery pulse

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