Microfluidic models of the human circulatory system: versatile platforms for exploring mechanobiology and disease modeling.

The human circulatory system is a marvelous fluidic system, which is very sensitive to biophysical and biochemical cues. The current animal and cell culture models do not recapitulate the functional properties of the human circulatory system, limiting our ability to fully understand the complex biological processes underlying the dysfunction of this multifaceted system. In this review, we discuss the unique ability of microfluidic systems to recapitulate the biophysical, biochemical, and functional properties of the human circulatory system. We also describe the remarkable capacity of microfluidic technologies for exploring the complex mechanobiology of the cardiovascular system, mechanistic studying of cardiovascular diseases, and screening cardiovascular drugs with the additional benefit of reducing the need for animal models. We also discuss opportunities for further advancement in this exciting field.

A Review on Mock Circulatory Systems for in vitro Hemodynamic Performance Evaluation of Ventricular Assist Devices / 医用生物力学

Mock circulatory system (MCS) is an experimental platform for simulating hemodynamic performance of human circulatory system, and has been widely used in in-vitro hemodynamic performance evaluation of passive devices such as ventricular assist devices (VADs), artificial valves, as well as hemodynamic responses of mock circulation loop. MCSs are capable of simulating various physiological conditions, including health, exercise, and heart failure, by adjusting drive element of heart simulator and lumped-parameter element of vasculature components. Since 1 960 s, the research and development target of MSCs has evolved from meeting the basic performance evaluation requirement of VADs and mechanical valve to mimicking local hemodynamic characteristics in vital organs. This review summarizes the design principles, system construction of MCSs as well as its research progress and future prospects.

In vitro simulation experimental study of a fully magnetically levitated ventricular assist device based on mock circulatory system / 医用生物力学

Objective To investigate the circulatory supporting effect of the third generation fully magnetically levitated China Heart ventricular assist device (CH-VAD) under heart failure (HF) condition. Methods An in vitro mock circulatory system (MCS) was developed. This system could simulate a healthy adult under resting state and a patient with heart failure, and incorporate the CH-VAD to evaluate the assisting performance under continuous flow mode. Furthermore, CH-VAD was equipped with a pulsatile flow controller and its initial performance was accessed. The pulsatile mode was obtained by using sinusoidal velocity waveform of the pump which synchronized the CH-VAD with the ventricle simulator of the MCS. Results CH-VAD under continuous flow mode could recover the hemodynamic parameters (arterial pressure and cardiac output) under HF condition to normal range. Preliminary pulsatile test results showed that amplitude of current pulse speed had a minor influence on the hemodynamic performance. CH-VAD under continuous flow and pulsatile flow mode could obtain comparable mean arterial pressure, systolic arterial pressure, diastolic arterial pressure and mean flow. Conclusions CH-VAD can generate a certain degree of speed pulse via appropriate pulsatility control, so as to provide sufficient support on ventricular function. Further optimization on pulsatile controller of CH-VAD is required to conform to natural physiology. The developed MCS can be utilized as an effective and controllable in vitro platform for design, optimization and verification of VADs or other mechanical circulatory support devices.

In vitro simulation experimental study of a fully magnetically levitated ventricular assist device based on mock circulatory system / 医用生物力学

Objective To investigate the circulatory supporting effect of the third generation fully magnetically levitated China Heart ventricular assist device (CH-VAD) under heart failure (HF) condition.Methods An in vitro mock circulatory system (MCS) was developed.This system could simulate a healthy adult under resting state and a patient with heart failure,and incorporate the CH-VAD to evaluate the assisting performance under continuous flow mode.Furthermore,CH-VAD was equipped with a pulsatile flow controller and its initial performance was accessed.The pulsatile mode was obtained by using sinusoidal velocity waveform of the pump which synchronized the CH-VAD with the ventricle simulator of the MCS.Results CH-VAD under continuous flow mode could recover the hemodynamic parameters (arterial pressure and cardiac output) under HF condition to normal range.Preliminary pulsatile test results showed that amplitude of current pulse speed had a minor influence on the hemodynamic performance.CH-VAD under continuous flow and pulsatile flow mode could obtain comparable mean arterial pressure,systolic arterial pressure,diastolic arterial pressure and mean flow.Conclusions CH-VAD can generate a certain degree of speed pulse via appropriate pulsatility control,so as to provide sufficient support on ventricular function.Further optimization on pulsatile controller of CH-VAD is required to conform to natural physiology.The developed MCS can be utilized as an effective and controllable in vitro platform for design,optimization and verification of VADs or other mechanical circulatory support devices.

In vitro simulation experimental study of a fully magnetically levitated ventricular assist device based on mock circulatory system / 医用生物力学

Objective To investigate the circulatory supporting effect of the third generation fully magnetically levitated China Heart ventricular assist device (CH-VAD) under heart failure (HF) condition.Methods An in vitro mock circulatory system (MCS) was developed.This system could simulate a healthy adult under resting state and a patient with heart failure,and incorporate the CH-VAD to evaluate the assisting performance under continuous flow mode.Furthermore,CH-VAD was equipped with a pulsatile flow controller and its initial performance was accessed.The pulsatile mode was obtained by using sinusoidal velocity waveform of the pump which synchronized the CH-VAD with the ventricle simulator of the MCS.Results CH-VAD under continuous flow mode could recover the hemodynamic parameters (arterial pressure and cardiac output) under HF condition to normal range.Preliminary pulsatile test results showed that amplitude of current pulse speed had a minor influence on the hemodynamic performance.CH-VAD under continuous flow and pulsatile flow mode could obtain comparable mean arterial pressure,systolic arterial pressure,diastolic arterial pressure and mean flow.Conclusions CH-VAD can generate a certain degree of speed pulse via appropriate pulsatility control,so as to provide sufficient support on ventricular function.Further optimization on pulsatile controller of CH-VAD is required to conform to natural physiology.The developed MCS can be utilized as an effective and controllable in vitro platform for design,optimization and verification of VADs or other mechanical circulatory support devices.

In vitro simulation experimental study of a fully magnetically levitated ventricular assist device based on mock circulatory system / 医用生物力学

Objective To investigate the circulatory supporting effect of the third generation fully magnetically levitated China Heart ventricular assist device (CH-VAD) under heart failure (HF) condition.Methods An in vitro mock circulatory system (MCS) was developed.This system could simulate a healthy adult under resting state and a patient with heart failure,and incorporate the CH-VAD to evaluate the assisting performance under continuous flow mode.Furthermore,CH-VAD was equipped with a pulsatile flow controller and its initial performance was accessed.The pulsatile mode was obtained by using sinusoidal velocity waveform of the pump which synchronized the CH-VAD with the ventricle simulator of the MCS.Results CH-VAD under continuous flow mode could recover the hemodynamic parameters (arterial pressure and cardiac output) under HF condition to normal range.Preliminary pulsatile test results showed that amplitude of current pulse speed had a minor influence on the hemodynamic performance.CH-VAD under continuous flow and pulsatile flow mode could obtain comparable mean arterial pressure,systolic arterial pressure,diastolic arterial pressure and mean flow.Conclusions CH-VAD can generate a certain degree of speed pulse via appropriate pulsatility control,so as to provide sufficient support on ventricular function.Further optimization on pulsatile controller of CH-VAD is required to conform to natural physiology.The developed MCS can be utilized as an effective and controllable in vitro platform for design,optimization and verification of VADs or other mechanical circulatory support devices.