Your search keyword '"Horvath, Dennis W."' showing total 7 results

1. Evaluation of centrifugal blood pump performances for biventricular support in the virtual simulation model.

Author

Kuroda, Taiyo, Miyamoto, Takuma, Horvath, Dennis W., Miyagi, Chihiro, Horvath, David J., Polakowski, Anthony R., Fukamachi, Kiyotaka, and Karimov, Jamshid H.

Subjects

HEART assist devices, CENTRIFUGAL pumps, CARDIOVASCULAR system, ARTIFICIAL blood circulation, HEART

Abstract

Background: Despite the advances in the left ventricular assist device (LVAD), there are still situations that require a biventricular assist device (BVAD) system. The purpose of this study was to explore and compare the system performance interactions with the HeartMate3 (HM3) and HeartWare (HVAD) in a BVAD configuration using the virtual mock loop (VML) simulation tool. Methods: The VML simulation tool is an in silico implementation of a lumped parameter model of the cardiovascular system with mechanical circulatory support. Patients with ejection fractions of 60%, 20%, and 15% were simulated in VML, and the HVAD and HM3 in a BVAD with ventricular cannulation were applied to simulated conditions. Pump speeds that restored baseline normal hemodynamics were determined. To determine the optimal speeds for BVAD, the left and right arterial pressures (LAP, RAP) were plotted. Results: In the HVAD, LAP and RAP are balanced at 11 mm Hg with LVAD 3500 rpm, right ventricular assist device (RVAD) 2200 rpm; at 13 mm Hg with LVAD 3000 rpm, RVAD 1700 rpm; and at 14 mm Hg with LVAD 2500 rpm, RVAD 1300 rpm. For the HM3, at 8 mm Hg with LVAD 7000 rpm, RVAD 5000 rpm; at 9 mm Hg with LVAD 6000 rpm, RVAD 4300 rpm; and at 9.5 mm Hg with LVAD 5000 rpm, RVAD 3500 rpm. Conclusion: The RVAD/LVAD speed ratios required for atrial balance were approximately 0.6 for the HVAD and 0.7 for the HM3. However, the HVAD required RVAD speeds below its range of operation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Modeling of Virtual Mechanical Circulatory Hemodynamics for Biventricular Heart Failure Support.

Author

Horvath, Dennis W., Polakowski, Anthony R., Flick, Christine, Fukamachi, Kiyotaka, Horvath, David J., and Karimov, Jamshid H.

Abstract

Objective: In this study, a mechanical circulatory support simulation tool was used to investigate the application of a unique device with two centrifugal pumps and one motor for the biventricular assist device (BVAD) support application. Several conditions—including a range of combined left and right systolic heart failure severities, aortic and pulmonary valve regurgitation, and combinations of high and low systemic and pulmonary vascular resistances—were considered in the simulation matrix. Relative advantages and limitations of using the device in BVAD applications are discussed. Methods: The simulated BVAD pump was based on the Cleveland Clinic pediatric continuous-flow total artificial heart (P-CFTAH), which is currently under development. Different combined disease states (n = 10) were evaluated to model the interaction with the BVAD, considering combinations of normal heart, moderate failure and severe systolic failure of the left and right ventricles, regurgitation of the aortic and pulmonary valves and combinations of vascular resistance. The virtual mock loop simulation tool (MATLAB; MathWorks®, Natick, MA) simulates the hemodynamics at the pump ports using a lumped-parameter model for systemic/pulmonary circulation characteristic inputs (values for impedance, systolic and diastolic ventricular compliance, beat rate, and blood volume), and characteristics of the cardiac chambers and valves. Results: Simulation results showed that this single-pump BVAD can provide regulated support of up to 5 L/min over a range of combined heart failure states and is suitable for smaller adult and pediatric support. However, good self-regulation of the atrial pressure difference was not maintained with the introduction of aortic valve regurgitation or high systemic vascular resistance when combined with low pulmonary vascular resistance. Conclusions: This initial in silico study demonstrated that use of the P-CFTAH as a BVAD supports cardiac output and arterial pressure in biventricular heart failure conditions. A similar but larger device would be required for a large adult patient who needs more than 5 L/min of support. [ABSTRACT FROM AUTHOR]

Published

2020

3. A simulation tool for mechanical circulatory support device interaction with diseased states.

Author

Horvath, David J., Horvath, Dennis W., Karimov, Jamshid H., Kuban, Barry D., Miyamoto, Takuma, and Fukamachi, Kiyotaka

Abstract

We have created a simulation model to investigate the interactions between a variety of mechanical circulatory support (MCS) devices and the circulatory system with various simulated patient conditions and disease states. The present simulation accommodates a family of continuous-flow MCS devices under various stages of consideration or development at our institution. This article describes the mathematical core of the in silico simulation system and shows examples of simulation output imitating various disease states and of selected in vitro and clinical data from the literature. [ABSTRACT FROM AUTHOR]

Published

2020

4. Analysis of Cleveland Clinic continuous‐flow total artificial heart performance using the Virtual Mock Loop: Comparison with an in vivo study.

Author

Miyamoto, Takuma, Horvath, David J., Horvath, Dennis W., Kuban, Barry D., Fukamachi, Kiyotaka, and Karimov, Jamshid H.

Subjects

ARTIFICIAL hearts, IN vivo studies, CARDIOVASCULAR system, VASCULAR resistance, CLINICS

Abstract

The Virtual Mock Loop (VML) is a mathematical model designed to simulate mechanism of the human cardiovascular system interacting with mechanical circulatory support devices. Here, we aimed to mimic the hemodynamic performance of Cleveland Clinic's self‐regulating continuous‐flow total artificial heart (CFTAH) via VML and evaluate the accuracy of the VML compared with an in vivo acute animal study. The VML reproduced 124 hemodynamic conditions from three acute in vivo experiments in calves. Systemic/pulmonary vascular resistances, pump rotational speed, pulsatility, and pulse rate were set for the VML from in vivo data. We compared outputs (pump flow, left and right pump pressure rises, and atrial pressure difference) between the two systems. The pump performance curves all fell in the designed range. There was a strong correlation between the VML and the in vivo study in the left pump flow (r2 = 0.84) and pressure rise (r2 = 0.80), and a moderate correlation in right pressure rise (r2 = 0.52) and atrial pressure difference (r2 = 0.59). Although there is room for improvement in simulating right‐sided pump performance of self‐regulating CFTAH, the VML acceptably simulated the hemodynamics observed in an in vivo study. These results indicate that pump flow and pressure rise can be estimated from vascular resistances and pump settings. [ABSTRACT FROM AUTHOR]

Published

2020

5. Simulated Performance of the Cleveland Clinic Continuous-Flow Total Artificial Heart Using the Virtual Mock Loop.

Author

Miyamoto, Takuma, Horvath, David J., Horvath, Dennis W., Karimov, Jamshid H., Byram, Nicole, Kuban, Barry D., and Fukamachi, Kiyotaka

Published

2019

6. Use of a Mechanical Circulatory Support Simulation to Study Pump Interactions With the Variable Hemodynamic Environment.

Author

Horvath, David J., Horvath, Dennis W., Karimov, Jamshid H., Byram, Nicole, Kuban, Barry D., Miyamoto, Takuma, and Fukamachi, Kiyotaka

Subjects

CARDIOVASCULAR diseases, HEART assist devices, ARTIFICIAL hearts, HEMODYNAMICS, IMPLANTED cardiovascular instruments, COMPUTER simulation

Abstract

The Virtual Mock Loop, a versatile virtual mock circulation loop, was developed using a lumped‐parameter model of the mechanically assisted human circulatory system. Inputs allow specification of a variety of continuous‐flow pumps (left, right, or biventricular assist devices) and a total artificial heart that can self‐regulate between left and right pump outputs. Hemodynamic inputs were simplified using a disease‐based input panel, allowing selection of a combination of cardiovascular disease states, including systolic and diastolic heart failure, stenosis, and/or regurgitation in each of the four valves, and high to low systemic and pulmonary vascular resistance values. The menu‐driven output includes a summary of hemodynamic parameters and graphical output of selected flows, pressures, and volumes in the heart's four chambers as well as in the pulmonary artery and aorta. New tools to augment experimental research on implantable heart‐assist devices and to increase our understanding of patient‐specific pump interactions are in high demand. The purpose of this ongoing study is to demonstrate the use of a system analysis computer simulation to explore and better comprehend the interactions of mechanical circulatory support pumps with a more extensive combination of patient‐specific or simulation conditions than can be established by practical experimentation. Usability is an important factor in constructing computer models for research purposes, and among our primary objectives in creating this simulation model were to make it as portable and useful as possible outside the lab environment, by people not involved in the creation of its operational software. [ABSTRACT FROM AUTHOR]

Published

2018

7. Abstract 14637: Assessment of Atrial and Ventricular Cannulation Options for Left Ventricular Assistance in Virtual Model.

Author

Karimov, Jamshid, Horvath, David J, Horvath, Dennis W, Miyamoto, Takuma, Byram, Nicole, Kuban, Barry D, and Fukamachi, Kiyotaka

Published

2018