Control Strategies for Afterload Reduction With an Artificial Vasculature Device

Giridharan, Guruprasad A.; Cheng, R.C.; Glower, Jacob; Ewert, Daniel; Sobieski, Michael A.; Slaughter, Mark S.; Koenig, Steven C.

doi:10.1097/mat.0b013e318256bb50

Cited by 5 publications

(5 citation statements)

References 36 publications

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“…These consist of a pulsatile pump, tubes, and compliance chambers, and are commonly used in cardiovascular research due to their versatility and low cost. [ 28–33 ] Nevertheless, these systems are limited to simplified representations of the cardiovascular network and building an in vitro model of the entire vascular tree remains challenging. [ 34 ]…”

Section: Introductionmentioning

confidence: 99%

Object‐Oriented Lumped‐Parameter Modeling of the Cardiovascular System for Physiological and Pathophysiological Conditions

Rosalia

Ozturk

Story

et al. 2021

Advcd Theory and Sims

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In this work, a lumped‐parameter Windkessel model of the cardiovascular system that simulates biomechanical parameters of the human physiology is presented. The object‐oriented platform provided by the MATLAB‐based modeling environment SIMSCAPE is employed to compute blood pressures and flows in each heart chamber and at various sites of the vascular tree. The hydraulic domain allows the determination of cardiovascular hemodynamics intuitively from geometrical and mechanical properties of the system, while custom elements model the pumping action of the heart and the effects of respiration on blood flow. The model is validated by comparing predicted hemodynamics with normal physiology during both systole and diastole, demonstrating that changes in arterial pressures with breathing are consistent with reported physiological effects of cardiorespiratory coupling. The capabilities of this platform are explored through two exemplary case studies: i) pressure‐overload heart failure due to aortic constriction, validated in vitro and via finite element analysis, and ii) single‐ventricle Fontan physiology, validated in vitro and compared with the clinical literature. This platform provides a practical tool for the calculation of cardiovascular hemodynamics from hydraulic parameters, enabling the intuitive creation of in silico representations of complex circulatory loops, the planning and optimization of medical interventions, and the prediction of clinically relevant patient‐specific hemodynamics.

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Section: Introductionmentioning

confidence: 99%

Object‐Oriented Lumped‐Parameter Modeling of the Cardiovascular System for Physiological and Pathophysiological Conditions

Rosalia

Ozturk

Story

et al. 2021

Advcd Theory and Sims

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“…However, when more circulations are concerned, or when the operation of some medical devices affects different circulations, more circulatory loops are required to be coupled to the MCL. Since coronary artery disease accounts for a large proportion of cardiovascular disease, many scholars have incorporated coronary circulation in the MCL ( Geven et al, 2004 ; Koenig et al, 2004 ; Pantalos et al, 2004 ; Park et al, 2006 ; Kaebnick et al, 2007 ; Park et al, 2007 ; Zannoli et al, 2009 ; Schampaert et al, 2011 ; Giridharan et al, 2012 ; Schampaert et al, 2014 ; Madukauwa-David et al, 2020 ). The flow characteristics of coronary circulation can be realized by means of the stepping motor cooperating with the valve ( Calderan et al, 2016 ), the parallel pipeline with the solenoid valve ( Rezaienia et al, 2017 ), PID control ( Gregory et al, 2020 ), the piston pump ( Madukauwa-David et al, 2020 ), etc.…”

Section: Advanced MCL With Complex Circulations For Other I...mentioning

confidence: 99%

Mock circulatory loop applications for testing cardiovascular assist devices and in vitro studies

Gao

Wan³

et al. 2023

Front. Physiol.

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The mock circulatory loop (MCL) is an in vitro experimental system that can provide continuous pulsatile flows and simulate different physiological or pathological parameters of the human circulation system. It is of great significance for testing cardiovascular assist device (CAD), which is a type of clinical instrument used to treat cardiovascular disease and alleviate the dilemma of insufficient donor hearts. The MCL installed with different types of CADs can simulate specific conditions of clinical surgery for evaluating the effectiveness and reliability of those CADs under the repeated performance tests and reliability tests. Also, patient-specific cardiovascular models can be employed in the circulation of MCL for targeted pathological study associated with hemodynamics. Therefore, The MCL system has various combinations of different functional units according to its richful applications, which are comprehensively reviewed in the current work. Four types of CADs including prosthetic heart valve (PHV), ventricular assist device (VAD), total artificial heart (TAH) and intra-aortic balloon pump (IABP) applied in MCL experiments are documented and compared in detail. Moreover, MCLs with more complicated structures for achieving advanced functions are further introduced, such as MCL for the pediatric application, MCL with anatomical phantoms and MCL synchronizing multiple circulation systems. By reviewing the constructions and functions of available MCLs, the features of MCLs for different applications are summarized, and directions of developing the MCLs are suggested.

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“…Since the AVD was programmed to produce an impedance less than or equal to that of the normal vasculature, the valve remains closed during cardiac systole. Under such conditions, the relationship between the pump volume, V, rate of change of pump volume, V', pump pressure, P, resistance, R, and compliance, C, is given by [12] :…”

Section: Methodsmentioning

confidence: 99%

“…The relationship between the pump volume, V, rate of change of pump volume, V', pump pressure, P, Resistance, R and compliance, C, is given by [12] R P CP'…”

Section: Parallel Rc Position Control (2 Element Windkessel)mentioning

confidence: 99%

“…Our computer simulation studies [11][12], an initial step in the device design process, demonstrated that the AVD has the potential to produce greater diastolic coronary perfusion, reduce ventricular workload while continuing to enable the left ventricle to fill and eject at normal volumes, and allow the heart to eject against a lower afterload (resistance and elastance) compared to continuous and asynchronous pulsatile assist techniques. It is our working hypothesis that afterload reduction during myocardial ejection using the AVD approach will augment the myocardial recovery process.…”

Section: Introductionmentioning

confidence: 99%

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In Vitro Evaluation of Control Strategies for an Artificial Vasculature Device

Glower

Cheng²,

Giridharan³

et al.

The 26th Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Ventricular assist devices (VADs) have been used successfully as a bridge to transplant in heart failure patients by unloading ventricular volume and restoring the circulation. An artificial vasculature device (AVD) that may better facilitate myocardial recovery than VAD by controlling the afterload seen by the ejecting heart is being developed. The AVD concept is to enable any user-defined input impedance (IM) with resistance (R) and compliance (C) components. In this study, a pulse duplicator was used to test the efficacy of the AVD concept for two control strategies in an adult mock circulation: (1) R-C in series and (2) 2-element Windkessel (R-C in parallel) using instantaneous impedance position control (IIPC) to maintain a desired value or profile of R and C. In vitro experiments were performed and the resulting cardiovascular pressures, volumes, flows, and the afterload (R and C) seen by the LV during ejection for simulated cardiac failure were recorded and analyzed. Our results indicate that setting the AVD to lower IM reduced LV volume and pressure, restored LV stroke volume, and increased coronary flow. The IIPC control algorithms are better suited to maintain any instantaneous IM or an IM profile, but are susceptible to measurement noise.

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Control Strategies for Afterload Reduction With an Artificial Vasculature Device

Cited by 5 publications

References 36 publications

Object‐Oriented Lumped‐Parameter Modeling of the Cardiovascular System for Physiological and Pathophysiological Conditions

Object‐Oriented Lumped‐Parameter Modeling of the Cardiovascular System for Physiological and Pathophysiological Conditions

Mock circulatory loop applications for testing cardiovascular assist devices and in vitro studies

In Vitro Evaluation of Control Strategies for an Artificial Vasculature Device

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