Encouraging Regular Aortic Valve Opening for EVAHEART 2 LVAD Support Using Virtual Patient Hemodynamic Speed Modulation Analysis.

This study focuses on investigating the EVAHEART 2 left ventricular assist device (LVAD) toward designing optimal pump speed modulation (PSM) algorithms for encouraging aortic valve (AV) flow. A custom-designed virtual patient hemodynamic model incorporating the EVAHEART 2 pressure-flow curves, cardiac chambers, and the systemic and pulmonary circulations was developed and used in this study. Several PSM waveforms were tested to evaluate their influence on the mean arterial pressure (MAP), cardiac output (CO), and AV flow for representative heart failure patients.

COMPETENCE Trial: The EVAHEART 2 continuous flow left ventricular assist device.

Background: Continuous flow left ventricular assist devices have improved outcomes in patients with end-stage heart failure that require mechanical circulatory support. Current devices have an adverse event profile that has hindered widespread application. The EVAHEART®2 left ventricular assist device (EVA2) has design features such as large blood gaps, lower pump speeds and an inflow cannula that does not protrude into the left ventricle that may mitigate the adverse events currently seen with other continuous flow devices.

Evaluation of cardiac beat synchronization control for a rotary blood pump on valvular regurgitation with a mathematical model.

We have studied the cardiac beat synchronization (CBS) control for a rotary blood pump (RBP) and revealed that it can promote pulsatility and reduce cardiac load. Besides, patients with LVAD support sometimes suffer from aortic and mitral regurgitation (AR and MR). A control method for the RBP should be validated in wider range of conditions to clarify its benefits and pitfalls prior to clinical application.

Decreased RPM reduces von Willebrand factor degradation with the EVAHEART LVAS: implications for device-specific LVAD management.

Background: Continuous-flow left ventricular assist devices (LVADs) produces supraphysiologic shear stress that causes von Willebrand factor (VWF) degradation and a bleeding diathesis. Reduction of revolutions per minute (RPM) with axial-flow LVADs does not decrease shear stress enough to reduce VWF degradation and bleeding. However, it is unknown if RPM reduction with centrifugal flow LVADs may minimize VWF degradation.

Mathematical evaluation of cardiac beat synchronization control used for a rotary blood pump.

We studied a control method of rotary blood pumps (RBPs), which is called as the cardiac beat synchronization (CBS) system. Usually, RBPs operate at constant target rotational speed, meanwhile, the CBS system modulates target speed synchronizing with cardiac beat. We built a computer simulation method to evaluate the CBS system.

Reducing regional flow stasis and improving intraventricular hemodynamics with a tipless inflow cannula design: An in vitro flow visualization study using the EVAHEART LVAD.

Due to the high stroke rate of left ventricular assist device (LVAD) patients, reduction of thrombus has emerged as an important target for LVAD support. Left ventricular blood flow patterns with areas of flow stasis and recirculation are associated with platelet aggregation, which is worsened by exposure to high shear stress. Previous reports of intraventricular thrombus in LVAD patients have identified the outside of the LVAD inflow cannula as a nidus for LV thrombus formation.

In vitro comparison of the hemocompatibility of two centrifugal left ventricular assist devices.

Objectives: Shear stress from left ventricular assist devices induces von Willebrand factor degradation and platelet dysfunction, leading to nonsurgical bleeding. We characterized the hemostatic changes induced by 2 centrifugal left ventricular assist devices, the HeartMate 3 (Abbott Inc, Chicago, Ill) and the EVAHEART (Evaheart Inc, Houston, Tex), for comparison.

Methods: Whole blood from 8 healthy volunteers was used ex vivo.

Surgical Techniques for Implanting the EVAHEART 2 Double Cuff Tipless Inflow Cannula.

The EVAHEART 2 (Sun Medical Technology Research Corporation, Nagano, Japan) is an investigational centrifugal ventricular assist device in the United States, introduced a new type inflow, named "double cuff tipless" inflow cannula intended to mitigate the risks of cannula malposition and subsequent ischemic stroke events associated with thrombi around the inflow cannula. To achieve these performance benefits of the "tipless" design, however, it is crucial to adhere to the recommended surgical procedure. We introduced a polymer-based patient model that mimics a dilated cardiomyopathy apex for inflow cannula implantation training.

Virtual Fitting and Hemodynamic Simulation of the EVAHEART 2 Left Ventricular Assist Device and Double-Cuff Tipless Inflow Cannula.

Inflow malposition during surgery, postoperative pump migration, inflow obstruction, and right ventricular compression are major contributors to low flow and adverse events in patients with ventricular assist devices (VADs). These position abnormalities can lead to adverse events including ischemic stroke. To address these problems, we conducted a virtual anatomical fitting study and hemodynamic simulation on iterative cannula designs, resulting in the EVAHEART 2 with the novel double-cuff tipless (DCT) inflow cannula and smaller pump design.

Preclinical Evaluation of the EVAHEART 2 Centrifugal Left Ventricular Assist Device in Bovines.

The EVAHEART 1 left ventricular assist device was miniaturized to the EVAHEART 2, with a new inflow cannula designed to mitigate the risks of malposition. To evaluate the safety of the new double-cuff tipless inflow cannula, in vivo studies were performed in healthy bovines. Eight consecutive studies were done: five short-term studies of hematological adaptation and three long-term studies of tissue adaptation.

The Effect of Inflow Cannula Length on the Intraventricular Flow Field: An In Vitro Flow Visualization Study Using the Evaheart Left Ventricular Assist Device.

Left ventricular assist device (LVAD) inflow cannula malposition is a significant risk for pump thrombosis. Thrombus development is influenced by altered flow dynamics, such as stasis or high shear that promote coagulation. The goal of this study was to measure the intraventricular flow field surrounding the apical inflow cannula of the Evaheart centrifugal LVAD, and assess flow stasis, vortex structures, and pulsatility for a range of cannula insertion depths and support conditions.

Left Ventricular Assist Device Design Reduces von Willebrand Factor Degradation: A Comparative Study Between the HeartMate II and the EVAHEART Left Ventricular Assist System.

Background: Supraphysiologic shear stress from continuous-flow left ventricular assist devices (LVADs) accelerates von Willebrand factor (vWF) degradation and predisposes patients to nonsurgical bleeding. It is unknown whether unique design characteristics of LVADs differentially affect vWF degradation. We tested the hypothesis that the centrifugal-flow EVAHEART (Evaheart, Houston, TX) left ventricular assist system (LVAS), which was designed to minimize shear stress (low operational revolutions per minute [rpm], larger flow gaps, low shear stress, flat H-Q curve), reduced vWF degradation versus the axial-flow HeartMate II (Thoratec, Pleasanton, CA) LVAD.

Large cardiac tumor managed with resection and two ventricular assist devices.

Symptomatic cardiac tumors can lead to a rapid clinical deterioration and death. Prompt surgical resection is ideal in this situation as it is the only proven treatment to date. We report the radical resection of a large malignant cardiac tumor that obstructed the right ventricular outflow tract.

Introductory tests to in vivo evaluation: magnetic coupling influence in motor controller.

An implantable centrifugal blood pump has been developed with original features for a ventricle assist device (VAD). This pump is part of a multicenter and international study with objective to offer simple, affordable, and reliable devices to developing countries. Previous computational fluid dynamics investigations were performed followed by prototyping and in vitro tests.

Experience of sternal secondary closure by means of a titanium fixation system after transverse thoracosternotomy.

Sternal dehiscence is a common complication after transverse thoracosternotomy in patients undergoing bilateral sequential lung transplantation (BSLT). These patients can be treated with conservative therapy, but severe dehiscence requires surgical reapproximation and secondary closure of the sternum. Seventy-one cases of patients who underwent BSLT between January 2007 and May 2009 were reviewed retrospectively.

Preliminary studies for the development of a second generation granulocytapheresis (G-CAP) column. Part II: in vitro and ex vivo studies.

Our previous studies concluded Egyptian cotton was the most appropriate material for making a second generation granulocytapheresis (G-CAP) column as structural dimensions of the cotton fibers are able to attract granulocytes. Unfortunately, it is considered to be blood incompatible as its fibers are of non-synthetic origins. In this study we examined the alteration of the removal rates of blood cells with different surface modifications of Egyptian cotton to enhance its blood compatibility.

Fungal mycotic vegetation in the ascending aorta.

In most clinical scenarios, the appropriate diagnostic methodology and treatment plan can be determined in a timely manner. However, complex clinical cases with obscure etiology can be deceptive, and a multidisciplinary approach can help to clarify things. At the Methodist DeBakey Heart & Vascular Center, we encountered a huge progressive mass in the ascending aorta in a 50-year-old chronic hemodialysis patient after mechanical aortic valve replacement.

Superior mesenteric artery mycotic aneurysm in patients with left ventricular assist device support and intravenous drug abuse.

Mycotic aneurysm of the superior mesenteric artery (SMA) is one of the complications associated with infective endocarditis. However, there are no previous case reports in the literature describing mycotic SMA aneurysm after left ventricular assist device (LVAD) implantation. We describe the case of a 31-year-old male diagnosed with congestive heart failure due to nonischemic dilated cardiomyopathy who underwent LVAD implantation for bridge to heart transplantation.

The need to change our objective for artificial heart development: from totally implantable permanent ventricular assist devices to wearable therapeutic ventricular assist devices.

As a therapeutic VAD to be combined with drugs, apheresis, and cellular implants, it is advisable to develop a wearable VAD for less than 6 months of application. Such an example was shown by describing the therapeutic BCM Gyro centrifugal VAD.

Evaluation of systemic external microwave hyperthermia for treatment of pleural metastasis in orthotopic lung cancer model.

External microwave (EMW) hyperthermia system (2.45 GHz wave frequency) was evaluated by in vitro studies and in vivo pleural metastasis animal model. Three different non-small-cell lung cancer cells and normal fibroblast cells (control) were treated once a day for 3 days with the prototype EMW system applying mild (39 degrees C), moderate (43 degrees C), and severe (47 degrees C) hyperthermia.

Preliminary studies for the development of a second generation granulocytapheresis (G-CAP) column.

The preliminary studies for developing a second generation granulocytapheresis (G-CAP) column were made. In the past, the G-CAP column has been used for the treatment of ulcerative colitis and rheumatoid arthritis. However, recent clinical studies have revealed that the therapeutic effects of the G-CAP column are not significant compared with those of the sham column.

A new transcutaneous energy transmission system with hybrid energy coils for driving an implantable biventricular assist device.

We have developed a new transcutaneous energy transmission (TET) system for a totally implantable biventricular assist device (BVAD) system in the New Energy and Industrial Development Organization (NEDO) artificial heart project. The TET system mainly consists of an energy transmitter, a hybrid energy coil unit, an energy receiver, an internal battery system, and an optical telemetry system. The hybrid energy coil unit consists of an air-core energy transmission coil and an energy-receiving coil having a ferrite core.