Your search keyword '"Throckmorton AL"' showing total 62 results

1. Series Multiblood Pump Design With Dual Activation for Pediatric Patients With Heart Failure.

Author

Palazzolo TC, Sarkisyan H, Matlis GC, McGowan J, Tchantchaleishvili V, Stevens RM, and Throckmorton AL

Abstract

The translational development of pediatric ventricular assist devices (VADs) lags years behind adult device options, negatively impacting pediatric patient outcomes. To address this need, we are developing a novel, series-flow, double-blood pump VAD that integrates an axial and centrifugal pump into a single device. The axial pump is used for initial circulatory assistance in younger patients; then, an internal activation mechanism triggers the centrifugal pump to activate in line with the axial pump, providing additional pressure and flow to match pediatric patient growth cycles. Here, we focused on the design and improvement of the device flow paths through computational analysis and in vitro hydraulic testing of a prototype. We estimated pressure-flow generation, fluid scalar stresses, and blood damage levels. In vitro hydraulic tests correlated well with shear stress transport (SST) predictions, with an average deviation of 4.5% for the complex, combined flow path. All data followed expected pump performance trends. The device exceeded target levels for blood damage in the blade tip clearances, and this must be both investigated and addressed in the next design phase. These study findings establish a strong foundation for the future development of the Drexel Double-Dragon VAD., Competing Interests: Disclosure: T.C.P., A.L.T., H.S. are inventors on patents and provisional patents for related blood pump designs by the USPTO. This research was performed in its entirety at Drexel University. The other authors have no conflicts of interest to report., (Copyright © ASAIO 2024.)

Published

2024

2. Next Generation Development of Hybrid Continuous Flow Pediatric Total Artificial Heart Technology: Design-Build-Test.

Author

Hirschhorn MD, Lawley JEM, Roof AJ, Johnson APT, Stoddard WA, Stevens RM, Rossano J, Arabia F, Tchantchaleishvili V, Massey HT, Day SW, and Throckmorton AL

Subjects

Humans, Child, Animals, Cattle, Prosthesis Design, Hydrodynamics, Equipment Design, Heart-Assist Devices, Heart Failure, Heart, Artificial

Abstract

To address the unmet clinical need for pediatric circulatory support, we are developing an operationally versatile, hybrid, continuous-flow, total artificial heart ("Dragon Heart"). This device integrates a magnetically levitated axial and centrifugal blood pump. Here, we utilized a validated axial flow pump, and we focused on the development of the centrifugal pump. A motor was integrated to drive the centrifugal pump, achieving 50% size reduction. The motor design was simulated by finite element analysis, and pump design improvement was attained by computational fluid dynamics. A prototype centrifugal pump was constructed from biocompatible 3D printed parts for the housing and machined metal parts for the drive system. Centrifugal prototype testing was conducted using water and then bovine blood. The fully combined device ( i.e. , axial pump nested inside of the centrifugal pump) was tested to ensure proper operation. We demonstrated the hydraulic performance of the two pumps operating in tandem, and we found that the centrifugal blood pump performance was not adversely impacted by the simultaneous operation of the axial blood pump. The current iteration of this design achieved a range of operation overlapping our target range. Future design iterations will further reduce size and incorporate complete and active magnetic levitation., Competing Interests: Disclosure: The authors wish to disclose that the lead author (A.L.T.) is an inventor on patents for the Drexel Dragon Heart blood pumps (two awarded patents and patent applications that are currently under consideration by the United States Patent and Trademark Office). The other authors have no conflicts of interest to report., (Copyright © ASAIO 2023.)

Published

2023

3. Impact of continuous-flow mechanical circulatory support on cerebrospinal fluid motility.

Author

Rose W, Throckmorton AL, Heintzelman B, and Tchantchaleishvili V

Subjects

Humans, Hemodynamics physiology, Homeostasis, Heart, Heart-Assist Devices adverse effects, Cardiovascular Diseases, Heart Failure therapy

Abstract

Background: Mechanical circulatory support (MCS), including ventricular assist devices (VADs), have emerged as promising therapeutic alternatives for end-stage congestive heart failure (CHF). The latest generation of these devices are continuous flow (CF) blood pumps. While there have been demonstrated benefits to patient outcomes due to CF-MCS, there continue to be significant clinical challenges. Research to-date has concentrated on mitigating thromboembolic risk (stroke), while the downstream impact of CF-MCS on the cerebrospinal fluid (CSF) flow has not been well investigated. Disturbances in the CSF pressure and flow patterns are known to be associated with neurologic impairment and diseased states. Thus, here we seek to develop an understanding of the pathophysiologic consequences of CF-MCS on CSF dynamics., Methods: We built and validated a computational framework using lumped parameter modeling of cardiovascular, cerebrovascular physics, CSF dynamics, and autoregulation. A sensitivity analysis was performed to confirm robustness of the modeling framework. Then, we characterized the impact of CF-MCS on the CSF and investigated cardiovascular conditions of healthy and end-stage heart failure., Results: Modeling results demonstrated appropriate hemodynamics and indicated that CSF pressure depends on blood flow pulsatility more than CSF flow. An acute equilibrium between CSF production and absorption was observed in the CF-MCS case, characterized by CSF pressure remaining elevated, and CSF flow rates remaining below healthy, but higher than CHF states., Conclusion: This research has advanced our understanding of the impact of CF-MCS on CSF dynamics and cerebral hemodynamics., (© 2023 International Center for Artificial Organ and Transplantation (ICAOT) and Wiley Periodicals LLC.)

Published

2023

4. Channel impeller design for centrifugal blood pump in hybrid pediatric total artificial heart: Modeling, magnet integration, and hydraulic experiments.

Author

Hirschhorn M, Catucci N, Day SW, Stevens RM, Tchantchaleishvili V, and Throckmorton AL

Subjects

Child, Humans, Magnets, Prosthesis Design, Pulsatile Flow, Magnetics, Equipment Design, Heart-Assist Devices, Heart, Artificial

Abstract

Background: The purpose of this research is to address ongoing device shortfalls for pediatric patients by developing a novel pediatric hybrid total artificial heart (TAH). The valveless magnetically-levitated MCS device (Dragon Heart) has only two moving parts, integrates an axial and centrifugal blood pump into a single device, and will occupy a compact footprint within the chest for the pediatric patient population., Methods: Prior work on the Dragon Heart focused on the development of pump designs to achieve hemodynamic requirements. The impeller of these pumps was shaft-driven and thus could not be integrated for testing. The presented research leverages an existing magnetically levitated axial flow pump and focuses on centrifugal pump development. Using the axial pump diameter as a geometric constraint, a shaftless, magnetically supported centrifugal pump was designed for placement circumferentially around the axial pump domain. The new design process included the computational analysis of more than 50 potential centrifugal impeller geometries. The resulting centrifugal pump designs were prototyped and tested for levitation and no-load rotation, followed by in vitro testing using a blood analog. To meet physiologic demands, target performance goals were pressure rises exceeding 90 mm Hg for flow rates of 1-5 L/min with operating speeds of less than 5000 RPM., Results: Three puck-shaped, channel impellers for the centrifugal blood pump were selected based on achieving performance and space requirements for magnetic integration. A quasi-steady flow analysis revealed that the impeller rotational position led to a pulsatile component in the pressure generation. After prototyping, the centrifugal prototypes (3, 4, and 5 channeled designs) demonstrated levitation and no-load rotation. Hydraulic experiments established pressure generation capabilities beyond target requirements. The pressure-flow performance of the prototypes followed expected trends with a dependence on rotational speed. Pulsatile blood flow was observed without pump-speed modulation due to rotating channel passage frequency., Conclusion: The results are promising in the advancement of this pediatric TAH. The channeled impeller design creates pressure-flow curves that are decoupled from the flow rate, a benefit that could reduce the required controller inputs and improve treatment of hypertensive patients., (© 2022 International Center for Artificial Organs and Transplantation and Wiley Periodicals LLC.)

Published

2023

5. Novel hybrid total artificial heart with integrated oxygenator.

Author

Chopski SG, Govender K, May A, Garven E, Stevens RM, Tchantchaleishvili V, and Throckmorton AL

Subjects

Humans, Equipment Design, Hemodynamics, Oxygenators, Heart, Artificial

Abstract

There continues to be an unmet therapeutic need for an alternative treatment strategy for respiratory distress and lung disease. We are developing a portable cardiopulmonary support system that integrates an implantable oxygenator with a hybrid, dual-support, continuous-flow total artificial heart (TAH). The TAH has a centrifugal flow pump that is rotating about an axial flow pump. By attaching the hollow fiber bundle of the oxygenator to the base of the TAH, we establish a new cardiopulmonary support technology that permits a patient to be ambulatory during usage. In this study, we investigated the design and improvement of the blood flow pathway from the inflow-to-outflow of four oxygenators using a mathematical model and computational fluid dynamics (CFD). Pressure loss and gas transport through diffusion were examined to assess oxygenator design. The oxygenator designs led to a resistance-driven pressure loss range of less than 35 mmHg for flow rates of 1-7 L/min. All of the designs met requirements. The configuration having an outside-to-inside blood flow direction was found to have higher oxygen transport. Based on this advantageous flow direction, two designs (Model 1 and 3) were then integrated with the axial-flow impeller of the TAH for simulation. Flow rates of 1-7 L/min and speeds of 10,000-16,000 RPM were analyzed. Blood damage studies were performed, and Model 1 demonstrated the lowest potential for hemolysis. Future work will focus on developing and testing a physical prototype for integration into the new cardiopulmonary assist system., (© 2022 Wiley Periodicals LLC.)

Published

2022

6. Invited commentary: Total anomalous pulmonary venous connection remains a challenging pediatric disease.

Author

Do-Nguyen CC, Throckmorton AL, and Stevens RM

Subjects

Child, Humans, Infant, Postoperative Period, Pulmonary Circulation, Retrospective Studies, Pulmonary Veins abnormalities, Pulmonary Veins surgery, Pulmonary Veno-Occlusive Disease surgery, Scimitar Syndrome surgery

Abstract

Cervantes-Salazar and colleagues report the long-term surgical outcomes of 414 patients with total anomalous pulmonary venous connection (TAPVC) from January 2003 to June 2019. With an overall survival rate of 87.2% from 2003 to 2019, the authors found that an increased mortality risk was associated with infracardiac TAPVC, pulmonary venous obstruction, and postoperative mechanical ventilation. Their comprehensive study with a large sample size of varying age groups, and patients with late referrals for surgery, provide valuable insight into TAPVC surgical outcomes. Improved survival for these patients continues to be a major goal of clinical teams striving to transform treatment paradigms. The promising result of the study reported by Cervantes-Salazar and colleagues gives our field hope for a better future for these patients., (© 2022 Wiley Periodicals LLC.)

Published

2022

7. Development of the Centrifugal Blood Pump for a Hybrid Continuous Flow Pediatric Total Artificial Heart: Model, Make, Measure.

Author

Fox CS, Palazzolo T, Hirschhorn M, Stevens RM, Rossano J, Day SW, Tchantchaleishvili V, and Throckmorton AL

Abstract

Clinically-available blood pumps and total artificial hearts for pediatric patients continue to lag well behind those developed for adults. We are developing a hybrid, continuous-flow, magnetically levitated, pediatric total artificial heart (TAH). The hybrid TAH design integrates both an axial and centrifugal blood pump within a single, compact housing. The centrifugal pump rotates around the separate axial pump domain, and both impellers rotate around a common central axis. Here, we concentrate our development effort on the centrifugal blood pump by performing computational fluid dynamics (CFD) analysis of the blood flow through the pump. We also conducted transient CFD analyses (quasi-steady and transient rotational sliding interfaces) to assess the pump's dynamic performance conditions. Through modeling, we estimated the pressure generation, scalar stress levels, and fluid forces exerted on the magnetically levitated impellers. To further the development of the centrifugal pump, we also built magnetically-supported prototypes and tested these in an in vitro hydraulic flow loop and via 4-h blood bag hemolytic studies ( n = 6) using bovine blood. The magnetically levitated centrifugal prototype delivered 0-6.75 L/min at 0-182 mmHg for 2,750-4,250 RPM. Computations predicted lower pressure-flow performance results than measured by testing; axial and radial fluid forces were found to be <3 N, and mechanical power usage was predicted to be <5 Watts. Blood damage indices (power law weighted exposure time and scalar stress) were <2%. All data trends followed expectations for the centrifugal pump design. Six peaks in the pressure rise were observed in the quasi-steady and transient simulations, correlating to the blade passage frequency of the 6-bladed impeller. The average N.I.H value ( n = 6) was determined to be 0.09 ± 0.02 g/100 L, which is higher than desired and must be addressed through design improvement. These data serve as a strong foundation to build upon in the next development phase, whereby we will integrate the axial flow pump component., Competing Interests: The authors declare to disclose that the lead and corresponding authors (CF and AT) from the BioCirc Research Laboratory are inventors on patents for the Drexel Dragon Heart blood pumps (two awarded USPTO patents and patent applications that are currently under consideration by the USPTO). JR discloses that he has served as a consultant for Abiomed, MyoKardia, Merck, Bayer, and Novartis. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Fox, Palazzolo, Hirschhorn, Stevens, Rossano, Day, Tchantchaleishvili and Throckmorton.)

Published

2022

8. Technology landscape of pediatric mechanical circulatory support devices: A systematic review 2010-2021.

Author

Palazzolo T, Hirschhorn M, Garven E, Day S, Stevens RM, Rossano J, Tchantchaleishvili V, and Throckmorton AL

Subjects

Child, Humans, Technology, Extracorporeal Membrane Oxygenation, Heart Failure surgery, Heart, Artificial adverse effects, Heart-Assist Devices adverse effects

Abstract

Background: Mechanical circulatory support (MCS) devices, such as ventricular assist devices (VADs) and total artificial hearts (TAHs), have become a vital therapeutic option in the treatment of end-stage heart failure for adult patients. Such therapeutic options continue to be limited for pediatric patients. Clinicians initially adapted or scaled existing adult devices for pediatric patients; however, these adult devices are not designed to support the anatomical structure and varying flow capacities required for this population and are generally operated "off-design," which risks complications such as hemolysis and thrombosis. Devices designed specifically for the pediatric population which seek to address these shortcomings are now emerging and gaining FDA approval., Methods: To analyze the competitive landscape of pediatric MCS devices, we conducted a systematic literature review. Approximately 27 devices were studied in detail: 8 were established or previously approved designs, and 19 were under development (11 VADs, 5 Fontan assist devices, and 3 TAHs)., Results: Despite significant progress, there is still no pediatric pump technology that satisfies the unique and distinct design constraints and requirements to support pediatric patients, including the wide range of patient sizes, increased cardiovascular demand with growth, and anatomic and physiologic heterogeneity of congenital heart disease., Conclusions: Forward-thinking design solutions are required to overcome these challenges and to ensure the translation of new therapeutic MCS devices for pediatric patients., (© 2022 International Center for Artificial Organs and Transplantation and Wiley Periodicals LLC.)

Published

2022

9. Microscale impeller pump for recirculating flow in organs-on-chip and microreactors.

Author

Cook SR, Musgrove HB, Throckmorton AL, and Pompano RR

Subjects

Animals, Equipment Design, Mice, Rotation, Stress, Mechanical, Heart-Assist Devices

Abstract

Fluid flow is an integral part of microfluidic and organ-on-chip technology, ideally providing biomimetic fluid, cell, and nutrient exchange as well as physiological or pathological shear stress. Currently, many of the pumps that actively perfuse fluid at biomimetic flow rates are incompatible with use inside cell culture incubators, require many tubing connections, or are too large to run many devices in a confined space. To address these issues, we developed a user-friendly impeller pump that uses a 3D-printed device and impeller to recirculate fluid and cells on-chip. Impeller rotation was driven by a rotating magnetic field generated by magnets mounted on a computer fan; this pump platform required no tubing connections and could accommodate up to 36 devices at once in a standard cell culture incubator. A computational model was used to predict shear stress, velocity, and changes in pressure throughout the device. The impeller pump generated biomimetic fluid velocities (50-6400 μm s -1 ) controllable by tuning channel and inlet dimensions and the rotational speed of the impeller, which were comparable to the order of magnitude of the velocities predicted by the computational model. Predicted shear stress was in the physiological range throughout the microchannel and over the majority of the impeller. The impeller pump successfully recirculated primary murine splenocytes for 1 h and Jurkat T cells for 24 h with no impact on cell viability, showing the impeller pump's feasibility for white blood cell recirculation on-chip. In the future, we envision that this pump will be integrated into single- or multi-tissue platforms to study communication between organs.

Published

2022

10. Tunable Blood Shunt for Neonates With Complex Congenital Heart Defects.

Author

Garven E, Rodell CB, Shema K, Govender K, Cassel SE, Ferrick B, Kupsho G, Kung E, Spiller KL, Stevens R, and Throckmorton AL

Abstract

Despite advancements in procedures and patient care, mortality rates for neonatal recipients of the Norwood procedure, a palliation for single ventricle congenital malformations, remain high due to the use of a fixed-diameter blood shunt. In this study, a new geometrically tunable blood shunt was investigated to address limitations of the current treatment paradigm (e.g., Modified Blalock-Taussig Shunt) by allowing for controlled modulation of blood flow through the shunt to accommodate physiological changes due to the patient's growth. First, mathematical and computational cardiovascular models were established to investigate the hemodynamic requirements of growing neonatal patients with shunts and to inform design criteria for shunt diameter changes. Then, two stages of prototyping were performed to design, build and test responsive hydrogel systems that facilitate tuning of the shunt diameter by adjusting the hydrogel's degree of crosslinking. We examined two mechanisms to drive crosslinking: infusion of chemical crosslinking agents and near-UV photoinitiation. The growth model showed that 15-18% increases in shunt diameter were required to accommodate growing patients' increasing blood flow; similarly, the computational models demonstrated that blood flow magnitudes were in agreement with previous reports. These target levels of diameter increases were achieved experimentally with model hydrogel systems. We also verified that the photocrosslinkable hydrogel, composed of methacrylated dextran, was contact-nonhemolytic. These results demonstrate proof-of-concept feasibility and reflect the first steps in the development of this novel blood shunt. A tunable shunt design offers a new methodology to rebalance blood flow in this vulnerable patient population during growth and development., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Garven, Rodell, Shema, Govender, Cassel, Ferrick, Kupsho, Kung, Spiller, Stevens and Throckmorton.)

Published

2022

11. The newly emerging field of pediatric engineering: Innovation for our next generation.

Author

Hirschhorn M, Garven EE, Wells JL, Stevens R, Tchantchaleishvili V, and Throckmorton AL

Subjects

Humans, Artificial Organs trends, Biomedical Engineering trends, Diffusion of Innovation, Pediatrics trends

Abstract

Neonates, infants, and children have unique physiology and body surface areas that dramatically change during growth and development, and the substantial diversity of complicated pediatric illnesses and rare childhood diseases are distinct from the adult sphere. Unfortunately, medical innovation is generally constrained to retrofitting adult treatment strategies for this heterogeneous population. This conventional, but limited, approach ignores the dynamic biopsychosocial, growth, and developmental complexities that abound, as one progresses through this life cycle from newborn onward toward early adulthood. Forward-thinking solutions are essential to advance the state-of-the-art to address the challenges and unmet clinical needs that are uniquely presented by the pediatric population, and it has become obvious that newly trained engineers are essential for success. These unmet clinical needs and the necessity of new technical skills and expertise give rise to the emergence of an entirely new field of engineering and applied science: Pediatric Engineering. The field of Pediatric Engineering flips conventional wisdom that adult therapies can simply be scaled or successfully modified for children. It commandeers design to suit the specific needs of the child, while anticipating the dynamic growth and development into adulthood. We are growing a new pipeline of educated scientists and engineers who will have developed a unique toolbox of skills that they can use to tackle unmet clinical needs in global pediatric healthcare for years to come., (© 2021 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2021

12. On the path to permanent artificial heart technology: Greater energy independence is paramount.

Author

Komlo CM, Throckmorton AL, and Tchantchaleishvili V

Subjects

Health Policy, Heart Failure surgery, Humans, Equipment Design, Heart, Artificial trends

Published

2021

13. A Cross University-Led COVID-19 Rapid-Response Effort: Design, Build, and Distribute Drexel AJFlex Face Shields.

Author

Throckmorton AL, Bass EJ, Ferrick B, Ramakrishnan A, Eichmann S, Catucci N, Eshelman B, McNamara J, Sundquist E, Beatson N, Hirschhorn M, Menon P, Datner E, Stevens R, and Marcolongo M

Subjects

Equipment Design, Humans, Intersectoral Collaboration, Philadelphia, COVID-19 prevention & control, Manufacturing Industry, Personal Protective Equipment supply & distribution, Printing, Three-Dimensional, Universities

Abstract

The purpose of this article is to demonstrate how a new cross-community leadership team came together, collaborated, coordinated across academic units with external community partners, and executed a joint mission to address the unmet clinical need for medical face shields during these unprecedented times. Key aspects of this success include the ability to forge and leverage new opportunities, overcome challenges, adapt to changing constraints, and serve the significant need across the Philadelphia region and healthcare systems. We teamed to design-build durable face shields (AJFlex Shields). This was accomplished by high-volume manufacturing via injection molding and by 3-D printing the key headband component that supports the protective shield. Partnering with industry collaborators and civic-minded community allies proved to be essential to bolster production and deliver approximately 33,000 face shields to more than 100 organizations in the region. Our interdisciplinary team of engineers, clinicians, product designers, manufacturers, distributors, and dedicated volunteers is committed to continuing the design-build effort and providing Drexel AJFlex Shields to our communities.

Published

2021

14. Fluid-structure interaction analysis of a collapsible axial flow blood pump impeller and protective cage for Fontan patients.

Author

Hirschhorn M, Bisirri E, Stevens R, and Throckmorton AL

Subjects

Biocompatible Materials, Humans, Models, Cardiovascular, Prosthesis Design, Fontan Procedure instrumentation, Heart-Assist Devices

Abstract

Limited donor organs and alternative therapies have led to a growing interest in the use of blood pumps as a treatment strategy for patients with single functional ventricle. The present study examines the use of collapsible and flexible impeller, cage, and diffuser designs of an axial blood pump for Fontan patients. Using one-way fluid-structure interaction (FSI) studies, the impact of blade deformation on blood damage and pump performance was investigated for flexible impellers. We evaluated biocompatible materials, including Nitinol, Bionate 80A polyurethane, and silicone for flow rates between 2.0-4.0 L/min and rotational speeds of 3000-9000 rpm. The level of deformation experienced by a cage and diffuser made of surgical stainless steel (control), Nitinol, and Bionate 80A polyurethane was also predicted using one-way FSI. The fluid pressure on the surface of the impeller, cage, and diffuser was determined using computational fluid dynamics (CFD), and then, the surface pressure was exported and used to investigate the impeller, cage, and diffuser deformation using finite element analysis. Finally, deformed impeller geometries were imported into the CFD software to determine the implication of deformation on pressure generation, blood damage index, and fluid streamlines. It was found that rotational speed, and not flow rate, is the largest determinant of impeller deformation, occurring at the blade trailing edges. The models predicted the maximum impeller deformation for Nitinol to be 40 nm, Bionate 80A polyurethane to be 106 μm, and silicone to be 2.8 mm, all occurring at 9000 rpm. The effects of silicone deformation on performance were significant, particularly at speeds above 5000 rpm where a decrease in pressure generation of more than 10% was observed. Despite this loss, the pressure generation at 5000 rpm exceeded the level required to alleviate Fontan complications. A blood damage estimation was performed and levels remained low. The effect of significant impeller deformation on blood damage was inconsistent and requires additional investigation. Cage and diffuser geometries made of steel and Nitinol deformed minimally but Bionate 80A experienced unacceptable levels of deformation, particularly in the free-flow case without a spinning impeller. These results support the continued evaluation of a flexible, pitch-adjusting, axial-flow, mechanical assist device as a clinical therapeutic option for patients with dysfunctional Fontan physiology., (© 2020 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2020

15. Clinical implications of LDH isoenzymes in hemolysis and continuous-flow left ventricular assist device-induced thrombosis.

Author

Gordon JS, Wood CT, Luc JGY, Watson RA, Maynes EJ, Choi JH, Morris RJ, Massey HT, Throckmorton AL, and Tchantchaleishvili V

Subjects

Animals, Humans, Isoenzymes blood, Thrombosis pathology, Heart-Assist Devices adverse effects, Hemolysis, L-Lactate Dehydrogenase blood, Thrombosis blood, Thrombosis etiology

Abstract

Pump-induced thrombosis continues to be a major complication of continuous-flow left ventricular assist devices (CF-LVADs), which increases the risks of thromboembolic stroke, peripheral thromboembolism, reduced pump flow, pump failure, cardiogenic shock, and death. This is confounded by the fact that there is currently no direct measure for a proper diagnosis during pump support. Given the severity of this complication and its required treatment, the ability to accurately differentiate CF-LVAD pump thrombosis from other complications is vital. Hemolysis measured by elevated lactate dehydrogenase (LDH) enzyme levels, when there is clinical suspicion of pump-induced thrombosis, is currently accepted as an important metric used by clinicians for diagnosis; however, LDH is a relatively nonspecific finding. LDH exists as five isoenzymes in the body, each with a unique tissue distribution. CF-LVAD pump thrombosis has been associated with elevated serum LDH-1 and LDH-2, as well as decreased LDH-4 and LDH-5. Herein, we review the various isoenzymes of LDH and their utility in differentiating hemolysis seen in CF-LVAD pump thrombosis from other physiologic and pathologic conditions as reported in the literature., (© 2019 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2020

16. Mechanical Circulatory Support of the Right Ventricle for Adult and Pediatric Patients With Heart Failure.

Author

Chopski SG, Murad NM, Fox CS, Stevens RM, and Throckmorton AL

Subjects

Adult, Child, Heart Ventricles physiopathology, Humans, Male, Heart Failure therapy, Heart-Assist Devices, Ventricular Dysfunction, Right therapy

Abstract

The clinical implementation of mechanical circulatory assistance for a significantly dysfunctional or failing left ventricle as a bridge-to-transplant or bridge-to-recovery is on the rise. Thousands of patients with left-sided heart failure are readily benefitting from these life-saving technologies, and left ventricular failure often leads to severe right ventricular dysfunction or failure. Right ventricular failure (RVF) has a high rate of mortality caused by the risk of multisystem organ failure and prolonged hospitalization for patients after treatment. The use of a blood pump to support the left ventricle also typically results in an increase in right ventricular preload and may impair right ventricular contractility during left ventricular unloading. Patients with RVF might also suffer from severe pulmonary dysfunction, cardiac defects, congenital heart disease states, or a heterogeneity of cardiophysiologic challenges because of symptomatic congestive heart failure. Thus, the uniqueness and complexity of RVF is emerging as a new domain of significant clinical interest that motivates the development of right ventricular assist devices. In this review, we present the current state-of-the-art for clinically used blood pumps to support adults and pediatric patients with right ventricular dysfunction or failure concomitant with left ventricular failure. New innovative devices specifically for RVF are also highlighted. There continues to be a compelling need for novel treatment options to support patients with significant right heart dysfunction or failure.

Published

2019

17. Externally applied compression therapy for Fontan patients.

Author

Hernandez J, Chopski SG, Lee S, Moskowitz WB, and Throckmorton AL

Abstract

Background: Limited therapeutic options are available for Fontan patients with dysfunctional or failing single ventricle physiology. This study describes the evaluation of an alternative, non-invasive, at-home therapeutic compression treatment for Fontan patients. Our hypothesis is that routinely administered, externally applied compression treatments to the lower extremities will augment systemic venous return, improve ventricular preload, and thus enhance cardiac output in Fontan patients., Methods: To initially evaluate this hypothesis, we employed the NormaTec pneumatic compression device (PCD) in a pilot clinical study (n=2). This device is composed of inflatable trouser compartments that facilitate circumferentially and uniformly applied pressure to a patient's lower extremities. Following an initial health screening, test subjects were pre-evaluated with a modified-Bruce treadmill exercise stress test, and baseline data on cardiorespiratory health was collected. After training, test subjects conducted 6 days of external compression therapy at-home. Subjects were then re-evaluated with a final treadmill stress test and data acquisition of new cardiorespiratory parameters., Results: Both subjects demonstrated improvement in exercise duration time, peak oxygen volume, and ventilator threshold, as compared to the baseline evaluation., Conclusions: These findings are promising and provide the foundation for future studies that will focus on increasing study participation (sample size) to better assess the clinical benefit of compression therapy for Fontan patients., Competing Interests: Conflicts of Interest: Joseph Hernandez is now the Director of Research for the Frederick Banting Foundation. The other authors have no conflicts of interest to declare.

Published

2018

18. Mechanical Circulatory Support Devices for Pediatric Patients With Congenital Heart Disease.

Author

Chopski SG, Moskowitz WB, Stevens RM, and Throckmorton AL

Subjects

Animals, Child, Equipment Design, Heart Defects, Congenital pathology, Heart Defects, Congenital surgery, Heart Ventricles pathology, Heart Ventricles surgery, Humans, Pediatrics instrumentation, Pediatrics methods, Ventricular Function, Assisted Circulation instrumentation, Assisted Circulation methods, Extracorporeal Membrane Oxygenation instrumentation, Extracorporeal Membrane Oxygenation methods, Heart Defects, Congenital therapy, Heart, Artificial

Abstract

The use of mechanical circulatory support (MCS) devices is a viable therapeutic treatment option for patients with congestive heart failure. Ventricular assist devices, cavopulmonary assist devices, and total artificial heart pumps continue to gain acceptance as viable treatment strategies for both adults and pediatric patients as bridge-to-transplant, bridge-to-recovery, and longer-term circulatory support alternatives. We present a review of the current and future MCS devices for patients having congenital heart disease (CHD) with biventricular or univentricular circulations. Several devices that are specifically designed for patients with complex CHD are in the development pipeline undergoing rigorous animal testing as readiness experiments in preparation for future clinical trials. These advances in the development of new blood pumps for patients with CHD will address a significant unmet clinical need, as well as generally improve innovation of the current state of the art in MCS technology., (© 2016 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2017

19. Vortical flow characteristics of mechanical cavopulmonary assistance: Pre- and post-swirl dynamics.

Author

Throckmorton AL, Chopski SG, Birewar SN, Joa TS, Huang P, Whitehead KK, Stevens RM, and Kresh JY

Subjects

Heart-Assist Devices, Hemodynamics, Prosthesis Design instrumentation

Abstract

Surgical optimization of the cavopulmonary connection and pharmacological therapy for dysfunctional Fontan physiology continue to advance, but these treatment approaches only slow the progression of decline to end-stage heart failure. The development of a mechanical cavopulmonary assist device will provide a viable therapeutic option in the bridging of patients to transplant or to stabilization. We hypothesize that rotational blood flow, delivered by an implantable axial flow blood pump, could effectively assist the venous circulation in Fontan patients by mimicking vortical blood flow patterns in the cardiovascular system. This study investigated seven new models of mechanical cavopulmonary assistance (single and dual-pump assist), created combinations of pump designs that deliver counter rotating vortical flow conditions, and analyzed pump performance, velocity streamlines, swirling strength, and energy augmentation in the cavopulmonary circuit for each support scenario. The model having an axial clockwise-oriented impeller in the inferior vena cava and an axial counterclockwise-oriented impeller rotating in the superior vena cava outperformed all of the support scenarios by enhancing the energy of the cavopulmonary circulation an average of 10.3% over the entire flow range and a maximum of 27.4% at %the higher flow rates. This research will guide the development of axial flow blood pumps for Fontan patients and demonstrated the high probability of %a cardiovascular benefit using counter rotating pumps in a dual support scenario, but found that this is dependent upon the patient-specific cavopulmonary anatomy.

Published

2016

20. Physics-driven impeller designs for a novel intravascular blood pump for patients with congenital heart disease.

Author

Chopski SG, Fox CS, McKenna KL, Riddle ML, Kafagy DH, Stevens RM, and Throckmorton AL

Subjects

Humans, Heart Defects, Congenital therapy, Heart-Assist Devices, Mechanical Phenomena, Prosthesis Design

Abstract

Mechanical circulatory support offers an alternative therapeutic treatment for patients with dysfunctional single ventricle physiology. An intravascular axial flow pump is being developed as a cavopulmonary assist device for these patients. This study details the development of a new rotating impeller geometry. We examined the performance of 8 impeller geometries with blade stagger or twist angles varying from 100° to 800° using computational methods. A refined range of blade twist angles between 300° and 400° was then identified, and 4 additional geometries were evaluated. Generally, the impeller designs produced 4-26mmHg for flow rates of 1-4L/min for 6000-8000 RPM. A data regression analysis was completed and found the impeller with 400° of blade twist to be the superior performer. A hydraulic test was conducted on a prototype of the 400° impeller, which generated measurable pressure rises of 7-28mmHg for flow rates of 1-4L/min at 6000-8000 RPM. The findings of the numerical model and experiment were in reasonable agreement within approximately 20%. These results support the continued development of an axial-flow, mechanical cavopulmonary assist device as a new clinical therapeutic option for Fontan patients., (Copyright © 2016 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2016

21. Beyond the VAD: Human Factors Engineering for Mechanically Assisted Circulation in the 21st Century.

Author

Throckmorton AL, Patel-Raman SM, Fox CS, and Bass EJ

Subjects

Animals, Clinical Decision-Making methods, Device Approval, Ergonomics methods, Humans, Precision Medicine methods, Prosthesis Design, Heart-Assist Devices adverse effects

Abstract

Thousands of ventricular assist devices (VADs) currently provide circulatory support to patients worldwide, and dozens of heart pump designs for adults and pediatric patients are under various stages of development in preparation for translation to clinical use. The successful bench-to-bedside development of a VAD involves a structured evaluation of possible system states, including human interaction with the device and auxiliary component usage in the hospital or home environment. In this study, we review the literature and present the current landscape of preclinical design and assessment, decision support tools and procedures, and patient-centered therapy. Gaps of knowledge are identified. The study findings support the need for more attention to user-centered design approaches for medical devices, such as mechanical circulatory assist systems, that specifically involve detailed qualitative and quantitative assessments of human-device interaction to mitigate risk and failure., (Copyright © 2015 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2016

22. Pressure-Flow Experimental Performance of New Intravascular Blood Pump Designs for Fontan Patients.

Author

Chopski SG, Fox CS, Riddle ML, McKenna KL, Patel JP, Rozolis JT, and Throckmorton AL

Subjects

Adolescent, Adult, Computer Simulation, Heart Defects, Congenital surgery, Hemodynamics, Humans, Hydrodynamics, Models, Cardiovascular, Pressure, Prosthesis Design, Fontan Procedure instrumentation, Heart-Assist Devices

Abstract

An intravascular axial flow pump is being developed as a mechanical cavopulmonary assist device for adolescent and adult patients with dysfunctional Fontan physiology. Coupling computational modeling with experimental evaluation of prototypic designs, this study examined the hydraulic performance of 11 impeller prototypes with blade stagger or twist angles varying from 100 to 600 degrees. A refined range of twisted blade angles between 300 and 400 degrees with 20-degree increments was then selected, and four additional geometries were constructed and hydraulically evaluated. The prototypes met performance expectations and produced 3-31 mm Hg for flow rates of 1-5 L/min for 6000-8000 rpm. A regression analysis was completed with all characteristic coefficients contributing significantly (P < 0.0001). This analysis revealed that the impeller with 400 degrees of blade twist outperformed the other designs. The findings of the numerical model for 300-degree twisted case and the experimental results deviated within approximately 20%. In an effort to simplify the impeller geometry, this work advanced the design of this intravascular cavopulmonary assist device closer to preclinical animal testing., (Copyright © 2015 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2016

23. Total Artificial Hearts-Past, Current, and Future.

Author

Fox CS, McKenna KL, Allaire PE, Mentzer RM Jr, and Throckmorton AL

Subjects

Heart-Assist Devices trends, Humans, Heart Failure therapy, Heart, Artificial trends

Abstract

We present a review of the evolution of total artificial hearts (TAHs) and new directions in development, including the coupling of VADs as biventricular TAH support., (© 2015 Wiley Periodicals, Inc.)

Published

2015

24. Three-dimensional laser flow measurements of a patient-specific fontan physiology with mechanical circulatory assistance.

Author

Chopski SG, Rangus OM, Downs EA, Moskowitz WB, and Throckmorton AL

Subjects

Equipment Design, Humans, Hydrodynamics, Fontan Procedure methods, Heart-Assist Devices, Hemodynamics physiology, Models, Cardiovascular

Abstract

Mechanical assistance of the Fontan circulation is hypothesized to enhance ventricular preload and improve cardiac output; however, little is known about the fluid dynamics. This study is the first to investigate the three-dimensional flow conditions of a blood pump in an anatomic Fontan. Laser measurements were conducted having an axial flow impeller in the inferior vena cava. Experiments were performed for a physiologic cardiac output, pulmonary arterial flows, and pump speeds of 1000-4000 rpm. The impeller had a modest effect on the flow conditions entering the total cavopulmonary connection at low pump speeds, but a substantial impact on the velocity at higher speeds. The higher speeds of the pump disrupted the recirculation region in the center of the anastomosis, which could be advantageous for washout purposes. No retrograde velocities in the superior vena cava were measured. These findings indicate that mechanical assistance is a viable therapeutic option for patients having dysfunctional single ventricle physiology., (Copyright © 2015 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2015

25. Stereo-particle image velocimetry measurements of a patient-specific Fontan physiology utilizing novel pressure augmentation stents.

Author

Chopski SG, Rangus OM, Fox CS, Moskowitz WB, and Throckmorton AL

Subjects

Equipment Design, Equipment Safety, Hemodynamics physiology, Humans, Models, Cardiovascular, Sensitivity and Specificity, Tricuspid Atresia surgery, Fontan Procedure instrumentation, Heart Defects, Congenital surgery, Heart Ventricles abnormalities, Heart-Assist Devices, Rheology methods, Stents

Abstract

Single ventricle anomalies are a challenging set of congenital heart defects that require lifelong clinical management due to progressive decline of cardiovascular function. Few therapeutic devices are available for these patients, and conventional blood pumps are not designed for the unique anatomy of the single ventricle physiology. To address this unmet need, we are developing an axial flow blood pump with a protective cage or stent for Fontan patients. This study investigates the 3-D particle image velocimetry measurements of two cage designs being deployed in a patient-specific Fontan anatomy. We considered a control case without a pump, impeller placed in the inferior vena cava, and two cases where the impeller has two protective stents with unique geometric characteristics. The experiments were evaluated at a cardiac output of 3 L/min, a fixed vena caval flow split of 40%/60%, a fixed pulmonary arterial flow split of 50%/50%, and for operating speeds of 1000-4000 rpm. The introduction of the cardiovascular stents had a substantial impact on the flow conditions leaving the pump and entering the cavopulmonary circulation. The findings indicated that rotational speeds above 4000 rpm for this pump could result in irregular flows in this specific circulatory condition. Although retrograde flow into the superior vena cava was not measured, the risk of this occurrence increases with higher pump speeds. The against-with stent geometry outperformed the other configurations by generating higher pressures and more energetic flows. These results provide further support for the viability of mechanical cavopulmonary assistance as a therapeutic treatment strategy for Fontan patients., (Copyright © 2015 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2015

26. Design of axial blood pumps for patients with dysfunctional fontan physiology: computational studies and performance testing.

Author

Kafagy DH, Dwyer TW, McKenna KL, Mulles JP, Chopski SG, Moskowitz WB, and Throckmorton AL

Subjects

Adolescent, Adult, Child, Child, Preschool, Equipment Failure Analysis, Equipment Safety, Female, Fontan Procedure adverse effects, Heart Defects, Congenital diagnosis, Humans, Male, Models, Cardiovascular, Risk Assessment, Computer-Aided Design, Fontan Procedure methods, Heart Defects, Congenital surgery, Heart-Assist Devices, Prosthesis Design

Abstract

Limited treatment options for patients having dysfunctional single ventricle physiology motivate the necessity for alternative therapeutic options. To address this unmet need, we are developing a collapsible axial flow blood pump. This study investigated the impact of geometric simplicity to facilitate percutaneous placement and maintain optimal performance. Three new pump designs were numerically evaluated. A transient simulation explored the impact of respiration on blood flow conditions over the entire respiratory cycle. Prototype testing of the top performing pump design was completed. The top performing Rec design generated the highest pressure rise range of 2-38 mm Hg for flow rates of 1-4 L/min at 4000-7000 RPM, exceeding the performance of the other two configurations by more than 26%. The blood damage indices for the new pump designs were determined to be below 0.5% and predicted hemolysis levels remained low at less than 7 × 10(-5)  g/100 L. Prototype testing of the Rec design confirmed numerical predictions to within an average of approximately 22%. These findings demonstrate that the pumps are reasonably versatile in operational ability, meet pressure-flow requirements to support Fontan patients, and are expected to have low levels of blood trauma., (Copyright © 2015 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2015

27. Experimental measurements of energy augmentation for mechanical circulatory assistance in a patient-specific Fontan model.

Author

Chopski SG, Rangus OM, Moskowitz WB, and Throckmorton AL

Subjects

Adolescent, Adult, Algorithms, Equipment Design, Hemodynamics, Humans, Pulmonary Artery surgery, Vena Cava, Inferior surgery, Vena Cava, Superior surgery, Young Adult, Fontan Procedure instrumentation, Heart-Assist Devices

Abstract

A mechanical blood pump specifically designed to increase pressure in the great veins would improve hemodynamic stability in adolescent and adult Fontan patients having dysfunctional cavopulmonary circulation. This study investigates the impact of axial-flow blood pumps on pressure, flow rate, and energy augmentation in the total cavopulmonary circulation (TCPC) using a patient-specific Fontan model. The experiments were conducted for three mechanical support configurations, which included an axial-flow impeller alone in the inferior vena cava (IVC) and an impeller with one of two different protective stent designs. All of the pump configurations led to an increase in pressure generation and flow in the Fontan circuit. The increase in IVC flow was found to augment pulmonary arterial flow, having only a small impact on the pressure and flow in the superior vena cava (SVC). Retrograde flow was neither observed nor measured from the TCPC junction into the SVC. All of the pump configurations enhanced the rate of power gain of the cavopulmonary circulation by adding energy and rotational force to the fluid flow. We measured an enhancement of forward flow into the TCPC junction, reduction in IVC pressure, and only minimally increased pulmonary arterial pressure under conditions of pump support., (Copyright © 2014 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2014

28. Pneumatically-driven external pressure applicator to augment Fontan hemodynamics: preliminary findings.

Author

Throckmorton AL, Bhavsar SS, Chopski SG, and Moskowitz WB

Abstract

Background: This study investigated the application of circumferentially applied, external pressure to the lower extremities as a preventative measure and long-term clinical treatment strategy for Fontan patients., Objective: We hypothesized that the application of circumferential pressure to the lower limbs will augment venous return and thus cardiac output., Methods: Two patients (an extra-cardiac and intra-atrial Fontan) were evaluated. Both trials were conducted during a routine cardiac catheterization. The aortic and inferior vena cava (IVC) pressures were recorded. We applied three different external pressures to the lower limbs based on the patient's diastolic pressure. Each pressure was applied with a one-minute rapid inflate/deflate period for a total of five cycles and a rest period between pressure intervals., Results: Patient 1 (age 37, female) demonstrated pressure rises of 10-15 mmHg in both the aortic and IVC pressures. Patient 2 (age 24, male) had undetectable pressure rise during the first pressure cycles and notable pressures rise of approximately 8-12 mmHg during the third cycle., Conclusions: External pressure application redistributes blood volume or cardiac output as a result of impedance in the lower extremities, enhancing venous pressure and return. Our findings strongly suggest an acute benefit from the implementation of external mechanical compression of the lower vasculature to increase cardiac output in Fontan patients.

Published

2013

29. Steady and transient flow analysis of a magnetically levitated pediatric VAD: time varying boundary conditions.

Author

Throckmorton AL, Tahir SA, Lopes SP, Rangus OM, and Sciolino MG

Subjects

Humans, Magnetics, Computer Simulation, Equipment Design, Heart-Assist Devices, Hemorheology physiology, Materials Testing, Models, Cardiovascular

Abstract

A magnetically levitated impeller within a pediatric ventricular assist device operates under highly transient flow conditions. In this study, computational analyses were performed to investigate the hydraulic performance and fluid forces on the impeller under the steady and dynamic flow conditions, including: 1) time-varying boundary conditions (TVBC) considering a pulsed pump flow rate and pulsed left ventricular pressure; 2) transient rotational sliding interfaces (TRSI) to capture virtual blade rotation. Under steady flow conditions, the pressure generation for 0.5-6 l/min over 6000-10000 rpm was 20-140 mmHg; experimental validation agreed to within 6-27%. Under transient flow conditions, the outflow pressure of the pump increased with higher inlet pressure during the TVBC simulation. During TVBC, the pressure rise across the pump decreased as a function of higher flow rates and increased as a function of lower flow rates. The radial fluid forces varied directly with the flow rate by demonstrating larger forces at higher flow rates. For TRSI simulations, pressure fluctuations due the blade passage frequency were found to have 12 peaks per revolution, having magnitude ranges of 
0.7 and 1.0 mmHg for 8 000 and 10 000 rpm, respectively. At 8 000 rpm, the fluid forces ranged from 1.15-1.17 N (axial) and 0.02-0.11 N (radial). Transient simulations model implant scenarios more realistically and provide critical information about the fluid conditions in the pump.

Published

2013

30. A viable therapeutic option: mechanical circulatory support of the failing Fontan physiology.

Author

Throckmorton AL, Lopez-Isaza S, Downs EA, Chopski SG, Gangemi JJ, and Moskowitz W

Subjects

Equipment Design, Humans, Assisted Circulation instrumentation, Computer Simulation, Fontan Procedure instrumentation, Heart Defects, Congenital surgery, Heart Ventricles surgery, Models, Cardiovascular

Abstract

A blood pump specifically designed to augment flow from the great veins through the lungs would ameliorate the poor physiology of the failing univentricular circulation and result in a paradigm shift in the treatment strategy for Fontan patients. This study is the first to examine mechanical cavopulmonary assistance with a blood pump in the inferior vena cava (IVC) and hepatic blood flow. Five numerical models of mechanical cavopulmonary assistance were investigated using a three-dimensional, reconstructed, patient-specific Fontan circulation from magnetic resonance imaging data. Pressure flow characteristics of the axial blood pump, energy augmentation calculations for the cavopulmonary circulation with and without pump support, and hemolysis estimations were determined. In all of the pump-supported scenarios, a pressure increase of 7-9.5 mm Hg was achieved. The fluid power of the cavopulmonary circulation was also positive over the range of flow rates. No retrograde flow from the IVC into the hepatic circulation was evident during support cases. Vessel suction risk, however, was found for greater operating rotational speeds. Fluid shear stresses and hemolysis predictions remained at acceptable levels with normalized index of hemolysis estimations at 0.0001 g/100 L. The findings of this study support the continued design and development of this blood pump technology for Fontan patients with progressive cardiovascular insufficiency. Validation of these flow and performance predictions will be completed in the next round of experimental testing with blood bag evaluation.

Published

2013

31. Dual-pump support in the inferior and superior vena cavae of a patient-specific fontan physiology.

Author

Throckmorton AL, Lopez-Isaza S, and Moskowitz W

Subjects

Assisted Circulation, Fontan Procedure methods, Hemodynamics physiology, Humans, Models, Anatomic, Venae Cavae surgery, Fontan Procedure instrumentation, Heart-Assist Devices, Models, Cardiovascular, Venae Cavae physiology

Abstract

The implementation of simultaneous mechanical cavopulmonary assistance having blood pumps located in both of the vena cavae is investigated as an approach to treating patients with an ailing Fontan physiology. Identical intravascular blood pumps are employed to model the hemodynamic support of a patient-specific Fontan. Pressure flow characteristics, energy gain calculations, and blood damage analyses are assessed for each model. The performance of the dual-support scenario is compared to conditions of mechanical support in the inferior vena cava only and to a nonsupported cavopulmonary circuit. The blood pump in the superior vena cava generates pressures ranging from 1 to 22 mm Hg for flow rates of 1-4 L/min at operating speeds of 1250-2500 rpm. The blood pump in the inferior vena cava produces pressures at levels approximately 20% lower. The blood pumps positively augment the hydraulic energy in the total cavopulmonary connection circuit as a function of flow rate and rotational speed. Scalar stress levels and fluid residence times are at acceptable levels. Damage indices for the dual-support case, however, are elevated slightly above 3.5%. These results suggest that concurrent, mechanical assistance of the inferior vena cava and superior vena cava in Fontan patients has the potential to be beneficial, but additional studies are needed to further explore this approach., (© 2013, Copyright the Authors. Artificial Organs © 2013, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2013

32. Steady flow analysis of mechanical cavopulmonary assistance in MRI-derived patient-specific fontan configurations.

Author

Downs EA, Moskowitz WB, and Throckmorton AL

Subjects

Computer Simulation, Equipment Design, Hemodynamics, Humans, Magnetic Resonance Imaging, Models, Anatomic, Models, Cardiovascular, Pulmonary Artery anatomy & histology, Pulmonary Artery physiology, Pulmonary Artery surgery, Vena Cava, Inferior anatomy & histology, Vena Cava, Inferior physiology, Vena Cava, Inferior surgery, Fontan Procedure instrumentation, Heart-Assist Devices

Abstract

This numerical study examined the performance of an intravascular axial flow blood pump for mechanical hemodynamic support of patients in the setting of Fontan failure, which presently has few treatment options. Three anatomically accurate geometries of the total cavopulmonary connection (TCPC) were generated using patients' magnetic resonance imaging data. These patient-specific geometries, as well as an idealized version with cylindrical vessels, were computationally analyzed with and without a pump in the inferior vena cava. Pressure flow characteristics, energy gain calculations, and blood damage analyses were performed for each model. The pump produced pressures of 1-14 mm Hg for 1500-4000 revolutions per minute, flow rates of 1-4 L/min, and pulmonary artery pressures of 8-24 mm Hg. Comparison of pump performance among the four models showed minimal intermodel differences (<5% deviation) in the pressure rise generated by the pump, the IVC pressure, and the energy imparted to the system by the pump. Blood damage analysis showed maximum fluid scalar stress values of 372 Pa or less, and the blood damage index was less than 2% in all of the models. These results suggest that this axial flow blood pump performs consistently in a variety of TCPC vessel geometries with low risk of blood trauma., (© 2012, Copyright the Authors. Artificial Organs © 2012, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2012

33. Uniquely shaped cardiovascular stents enhance the pressure generation of intravascular blood pumps.

Author

Throckmorton AL, Carr JP, Moskowitz WB, Gangemi JJ, Haggerty CM, and Yoganathan AP

Subjects

Biomechanical Phenomena, Blood Flow Velocity, Blood Pressure, Computer Simulation, Hemolysis, Humans, Materials Testing, Models, Cardiovascular, Numerical Analysis, Computer-Assisted, Prosthesis Design, Regression Analysis, Stress, Mechanical, Coronary Circulation, Heart-Assist Devices adverse effects, Hemodynamics, Stents adverse effects

Abstract

Objective: Advances in the geometric design of blood-contacting components are critically important as the use of minimally invasive, intravascular blood pumps becomes more pervasive in the treatment of adult and pediatric patients with congestive heart failure. The present study reports on the evaluation of uniquely shaped filaments and diffuser blades in the development of a protective stent for an intravascular cavopulmonary assist device for patients with a single ventricle., Methods: We performed numeric modeling, hydraulic testing of 11 stents with an axial flow blood pump, and blood bag experiments (n = 6) of the top-performing stent geometries to measure the levels of hemolysis. A direct comparison using statistical analyses, including regression analysis and analysis of variance, was completed., Results: The stent geometry with straight filaments and diffuser blades that extended to the vessel wall outperformed all other stent configurations. The pump with this particular stent was able to generate pressures of 2 to 32 mm Hg for flow rates of 0.5 to 4 L/min at 5000 to 7000 RPM. A comparison of the experimental performance data to the numeric predictions demonstrated an excellent agreement within 16%. The addition of diffuser blades to the stent reduced the flow vorticity at the pump outlet. The average and maximum normalized index of hemolysis level was 0.0056 g/100 L and 0.0064 g/100 L, respectively., Conclusions: The specialized design of the stents, which protect the vessel wall from the rotating components of the pump, proved to be advantageous by further augmenting the pressure generation of the pump, reducing the flow vorticity at the pump outlet, and enhancing flow control., (Copyright © 2012 The American Association for Thoracic Surgery. Published by Mosby, Inc. All rights reserved.)

Published

2012

34. Controlled pitch-adjustment of impeller blades for an intravascular blood pump.

Author

Throckmorton AL, Sciolino MG, Downs EA, Saxman RS, López-Isaza S, and Moskowitz WB

Subjects

Blood Circulation physiology, Blood Pressure, Equipment Design, Heart Failure therapy, Hemorheology, Humans, Models, Cardiovascular, Pressure, Prosthesis Design, Temperature, Assisted Circulation methods, Heart-Assist Devices

Abstract

Thousands of mechanical blood pumps are currently providing circulatory support, and the incidence of their use continues to increase each year. As the use of blood pumps becomes more pervasive in the treatment of those patients with congestive heart failure, critical advances in design features to address known limitations and the integration of novel technologies become more imperative. To advance the current state-of-the-art in blood pump design, this study investigates the inclusion of pitch-adjusting blade features in intravascular blood pumps as a means to increase energy transfer; an approach not explored to date. A flexible impeller prototype was constructed with a configuration to allow for a variable range of twisted blade geometries of 60-250°. Hydraulic experiments using a blood analog fluid were conducted to characterize the pressure-flow performance for each of these twisted positions. The flexible, twisted impeller was able to produce 1-25 mmHg for 0.5-4 L/min at rotational speeds of 5,000-8,000 RPM. For a given twisted position, the pressure rise was found to decrease as a function of increasing flow rate, as expected. Generally, a steady increase in the pressure rise was observed as a function of higher twisted degrees for a constant rotational speed. Higher rotational speeds for a specific twisted impeller configuration resulted in a more substantial pressure generation. The findings of this study support the continued exploration of this unique design approach in the development of intravascular blood pumps.

Published

2012

35. Twisted cardiovascular cages for intravascular axial flow blood pumps to support the Fontan physiology.

Author

Throckmorton AL, Downs EA, Hazelwood JA, Monroe JO, and Chopski SG

Subjects

Adolescent, Adult, Biomechanical Phenomena, Blood Flow Velocity, Computer Simulation, Diffusion Chambers, Culture, Heart Defects, Congenital physiopathology, Heart Failure etiology, Heart Failure physiopathology, Humans, Hydrodynamics, Materials Testing, Models, Cardiovascular, Models, Statistical, Numerical Analysis, Computer-Assisted, Prosthesis Design, Regression Analysis, Stress, Mechanical, Ventricular Pressure, Fontan Procedure adverse effects, Heart Defects, Congenital surgery, Heart Failure therapy, Heart-Assist Devices, Ventricular Function

Abstract

Failing single ventricle physiology represents an ongoing challenge in mechanical assist device development, requiring pressure augmentation in the cavopulmonary circuit, reduction of systemic venous pressure, and increased cardiac output to achieve hemodynamic stabilization. To meet these requirements, we are developing a percutaneously-placed, axial flow blood pump to support ailing single ventricle physiology in adolescents and adults. We have modified the outer cage of the device to serve as both a protective and functional design component. This study examined the performance of 3 cage geometries with varying directions of filament twist using numerical simulations and hydraulic experiments. All 3 cage and pump models performed in acceptable ranges to support Fontan patients. The cage design employing filaments that are twisted in the opposite direction to the impeller blades and in the direction of the diffuser blades (against-with) demonstrated superior performance by generating a pressure rise range of 5-38 mmHg of flow rates of 0.5-6 l/min at rotational speeds of 5000-7000 rpm. The blood damage indices for all of the cages were found to be well below 2%, and the scalar stress levels were below 200 Pa. This study represents ongoing progress in the development of the impeller and cage assembly. Validation of the results will continue in experiments with blood bag evaluation as well as by particle image velocimetry measurements.

Published

2012

36. Laser flow measurements in an idealized total cavopulmonary connection with mechanical circulatory assistance.

Author

Chopski SG, Downs E, Haggerty CM, Yoganathan AP, and Throckmorton AL

Subjects

Blood Flow Velocity, Child, Humans, Hydrodynamics, Models, Cardiovascular, Vena Cava, Inferior physiopathology, Vena Cava, Inferior surgery, Vena Cava, Superior physiopathology, Vena Cava, Superior surgery, Assisted Circulation instrumentation, Fontan Procedure instrumentation, Hemodynamics

Abstract

This study examined the interactive fluid dynamics between a cavopulmonary assist device and univentricular Fontan circulation. We conducted two-dimensional particle image velocimetry measurements on an idealized total cavopulmonary connection (TCPC) with an axial pump prototype intravascularly inserted into the inferior vena cava (IVC) and then in the IVC and the superior vena cava (SVC) for a dual-pump support case. The glass model of the TCPC consisted of rigid vessels having a diameter of 13.4 mm and a one-diameter vessel offset at the TCPC junction. Fluid velocity profiles were examined at a cardiac output of 3 L/min and SVC and IVC flow ratios of 30/70%, 40/60%, and 50/50% and pump rotational speeds from 3000 to 9000 rpm. In addition, cardiac outputs of 5 and 7 L/min were also examined. As compared to the flow profile with the pump present, the measured velocity field demonstrated the presence of rotational (i.e., out of plane) motion, which forced the higher-velocity regions toward the periphery of the vessel. As a result, few flow vortices were captured in the image plane downstream of the pump in the TCPC junction. However, the velocity profiles for all cases demonstrated the expected shunting preference of IVC flow toward the right pulmonary artery. Furthermore, the inclusion of the pump provided a pressure rise of 3 to 9 mm Hg, which would be sufficient to relieve systemic hypertension in Fontan patients with circulatory dysfunction., (© 2011, Copyright the Authors. Artificial Organs © 2011, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2011

37. Mechanical cavopulmonary assistance of a patient-specific Fontan physiology: numerical simulations, lumped parameter modeling, and suction experiments.

Author

Throckmorton AL, Carr JP, Tahir SA, Tate R, Downs EA, Bhavsar SS, Wu Y, Grizzard JD, and Moskowitz WB

Subjects

Assisted Circulation methods, Computer Simulation, Equipment Design, Fontan Procedure methods, Hemodynamics, Humans, Models, Cardiovascular, Suction instrumentation, Assisted Circulation instrumentation, Fontan Procedure instrumentation, Vena Cava, Inferior surgery

Abstract

This study investigated the performance of a magnetically levitated, intravascular axial flow blood pump for mechanical circulatory support of the thousands of Fontan patients in desperate need of a therapeutic alternative. Four models of the extracardiac, total cavopulmonary connection (TCPC) Fontan configuration were evaluated to formulate numerical predictions: an idealized TCPC, a patient-specific TCPC per magnetic resonance imaging data, and each of these two models having a blood pump in the inferior vena cava (IVC). A lumped parameter model of the Fontan physiology was used to specify boundary conditions. Pressure-flow characteristics, energy gain calculations, scalar stress levels, and blood damage estimations were executed for each model. Suction limitation experiments using the Sylgard elastomer tubing were also conducted. The pump produced pressures of 1-16 mm Hg for 2000-6000 rpm and flow rates of 0.5-4.5 L/min. The pump inlet or IVC pressure was found to decrease at higher rotational speeds. Maximum scalar stress estimations were 3 Pa for the nonpump models and 290 Pa for the pump-supported cases. The blood residence times for the pump-supported cases were shorter (0.9 s) as compared with the nonsupported configurations (2.5 s). However, the blood damage indices were higher (1.5%) for the anatomic model with pump support. The pump successfully augmented pressure in the TCPC junction and increased the hydraulic energy of the TCPC as a function of flow rate and rotational speed. The suction experiments revealed minimal deformation (<3%) at 9000 rpm. The findings of this study support the continued design and development of this blood pump., (© 2011, Copyright the Authors. Artificial Organs © 2011, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2011

38. Numerical, hydraulic, and hemolytic evaluation of an intravascular axial flow blood pump to mechanically support Fontan patients.

Author

Throckmorton AL, Kapadia JY, Chopski SG, Bhavsar SS, Moskowitz WB, Gullquist SD, Gangemi JJ, Haggerty CM, and Yoganathan AP

Subjects

Adolescent, Adult, Computer Simulation, Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Humans, Young Adult, Blood Vessel Prosthesis, Fontan Procedure instrumentation, Heart Defects, Congenital physiopathology, Heart Defects, Congenital surgery, Heart-Assist Devices, Hemolysis, Models, Cardiovascular

Abstract

Currently available mechanical circulatory support systems are limited for adolescent and adult patients with a Fontan physiology. To address this growing need, we are developing a collapsible, percutaneously-inserted, axial flow blood pump to support the cavopulmonary circulation in Fontan patients. During the first phase of development, the design and experimental evaluation of an axial flow blood pump was performed. We completed numerical modeling of the pump using computational fluid dynamics analysis, hydraulic testing of a plastic pump prototype, and blood bag experiments (n=7) to measure the levels of hemolysis produced by the pump. Statistical analyses using regression were performed. The prototype with a 4-bladed impeller generated a pressure rise of 2-30 mmHg with a flow rate of 0.5-4 L/min for 3000-6000 RPM. A comparison of the experimental performance data to the numerical predictions demonstrated an excellent agreement with a maximum deviation being less than 6%. A linear increase in the plasma-free hemoglobin (pfHb) levels during the 6-h experiments was found, as desired. The maximum pfHb level was measured to be 21 mg/dL, and the average normalized index of hemolysis was determined to be 0.0097 g/100 L for all experiments. The hydraulic performance of the prototype and level of hemolysis are indicative of significant progress in the design of this blood pump. These results support the continued development of this intravascular pump as a bridge-to-transplant, bridge-to-recovery, bridge-to-hemodynamic stability, or bridge-to-surgical reconstruction for Fontan patients.

Published

2011

39. Filament support spindle for an intravascular cavopulmonary assist device.

Author

Throckmorton AL, Kapadia JY, Wittenschlaeger TM, Medina TJ, Hoang HQ, and Bhavsar SS

Subjects

Adolescent, Adult, Blood Flow Velocity, Blood Pressure, Computer Simulation, Humans, Materials Testing, Models, Cardiovascular, Numerical Analysis, Computer-Assisted, Prosthesis Design, Regression Analysis, Stress, Mechanical, Fontan Procedure instrumentation, Heart-Assist Devices, Hemodynamics

Abstract

We are developing an intravascular axial flow blood pump to support adolescent and adult Fontan patients. To protect the blood vessel, this pump has an outer cage with radially arranged filaments and a newly designed spindle at the pump outlet. The outlet spindle is included to limit the axial movement of the rotor and to house bearings that support the rotor. This study evaluates the impact of the outlet spindle on pump performance using computational fluid dynamics (CFD) and experimental testing of a prototype configuration. We measured the pressure-flow performance of the prototype with a protective cage using a blood analog fluid. The pump with the cage filaments and spindle generated 1 to 16mmHg of pressure rise for flow rates of 1 to 4L/min at 4000 to 7000rpm. The difference between the CFD predictions and experimental results was found to be approximately 9.8%. Scalar stress levels remained below 570Pa with exposure times on the order of 1.5s. These results are acceptable and support the continued development of this cavopulmonary assist device with an outlet spindle to reinforce the protective cage filament design., (© 2010, Copyright the Authors. Artificial Organs © 2010, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2010

40. Interaction of an idealized cavopulmonary circulation with mechanical circulatory assist using an intravascular rotary blood pump.

Author

Bhavsar SS, Moskowitz WB, and Throckmorton AL

Subjects

Equipment Design, Hemodynamics, Humans, Models, Cardiovascular, Heart-Assist Devices

Abstract

This study evaluated the performance of an intravascular, percutaneously-inserted, axial flow blood pump in an idealized total cavopulmonary connection (TCPC) model of a Fontan physiology. This blood pump, intended for placement in the inferior vena cava (IVC), is designed to augment pressure and blood flow from the IVC to the pulmonary circulation. Three different computational models were examined: (i) an idealized TCPC without a pump; (ii) an idealized TCPC with an impeller pump; and (iii) an idealized TCPC with an impeller and diffuser pump. Computational fluid dynamics analyses of these models were performed to assess the hydraulic performance of each model under varying physiologic conditions. Pressure-flow characteristics, fluid streamlines, energy augmentation calculations, and blood damage analyses were evaluated. Numerical predictions indicate that the pump with an impeller and diffuser blade set produces pressure generations of 1 to 16 mm Hg for rotational speeds of 2000 to 6000 rpm and flow rates of 1 to 4 L/min. In contrast, for the same flow range, the model with the impeller only in the IVC demonstrated pressure generations of 1 to 9 mm Hg at rotational speeds of 10,000 to 12,000 rpm. Influence of blood viscosity was found to be insignificant at low rotational speeds with minimal performance deviation at higher rotational speeds. Results from the blood damage index analyses indicate a low probability for damage with maximum damage index levels less than 1% and maximum fluid residence times below 0.6 s. The numerical predictions further indicated successful energy augmentation of the TCPC with a pump in the IVC. These results support the continued design and development of this cavopulmonary assist device., (© 2010, Copyright the Authors. Artificial Organs © 2010, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2010

41. Hydraulic testing of intravascular axial flow blood pump designs with a protective cage of filaments for mechanical cavopulmonary assist.

Author

Kapadia JY, Pierce KC, Poupore AK, and Throckmorton AL

Subjects

Hemorheology, Heart-Assist Devices, Prosthesis Design

Abstract

To provide hemodynamic support to patients with a failing single ventricle, we are developing a percutaneously inserted, magnetically levitated axial flow blood pump designed to augment pressure in the cavopulmonary circulation. The device is designed to serve as a bridge-to-transplant, bridge-to-recovery, bridge-to-hemodynamic stability, or bridge-to-surgical reconstruction. This study evaluated the hydraulic performance of three blood pump prototypes (a four-bladed impeller, a three-bladed impeller, and a three-bladed impeller with a four-bladed diffuser) whose designs evolved from previous design optimization phases. Each prototype included the same geometric protective cage of filaments, which stabilize the rotor within the housing and protect the housing wall from the rotating blades. All prototypes delivered pressure rises over a range of flow rates and rotational speeds that would be sufficient to augment hemodynamic conditions in the cavopulmonary circulation. The four-bladed impeller outperformed the two remaining prototypes by >40%; this design was able to generate a pressure rise of 4-28 mm Hg for flow rates of 0.5-10 L/min at rotational speeds of 4,000-7,000 RPM. Successful development of this blood pump will provide clinicians with a feasible therapeutic option for mechanically supporting the failing Fontan.

Published

2010

42. Intravascular mechanical cavopulmonary assistance for patients with failing Fontan physiology.

Author

Bhavsar SS, Kapadia JY, Chopski SG, and Throckmorton AL

Subjects

Adolescent, Adult, Fontan Procedure methods, Hemodynamics, Hemolysis, Humans, Prosthesis Design, Young Adult, Fontan Procedure instrumentation, Heart-Assist Devices

Abstract

To provide a viable bridge-to-transplant, bridge-to-recovery, or bridge-to-surgical reconstruction for patients with failing Fontan physiology, we are developing a collapsible, percutaneously inserted, magnetically levitated axial flow blood pump to support the cavopulmonary circulation in adolescent and adult patients. This unique blood pump will augment pressure and thus flow in the inferior vena cava through the lungs and ameliorate the poor hemodynamics associated with the univentricular circulation. Computational fluid dynamics analyses were performed to create the design of the impeller, the protective cage of filaments, and the set of diffuser blades for our axial flow blood pump. These analyses included the generation of pressure-flow characteristics, scalar stress estimations, and blood damage indexes. A quasi-steady analysis of the diffuser rotation was also completed and indicated an optimal diffuser rotational orientation of approximately 12 degrees. The numerical predictions of the pump performance demonstrated a pressure generation of 2-25 mm Hg for 1-7 L/min over 3000-8000 rpm. Scalar stress values were less than 200 Pa, and fluid residence times were found to be within acceptable ranges being less than 0.25 s. The maximum blood damage index was calculated to be 0.068%. These results support the continued design and development of this cavopulmonary assist device, building upon previous numerical work and experimental prototype testing.

Published

2009

43. Design of a protective cage for an intravascular axial flow blood pump to mechanically assist the failing Fontan.

Author

Throckmorton AL and Kishore RA

Subjects

Adult, Computer Simulation, Equipment Design, Equipment Failure Analysis, Heart Ventricles physiopathology, Hemodynamics, Humans, Models, Cardiovascular, Heart-Assist Devices

Abstract

Currently, no long-term mechanical bridge-to-transplant or bridge-to-recovery therapeutic alternative exists for failing single ventricles. A blood pump that would augment pressure in the cavopulmonary circulation is needed, and would lead to a reduction in elevated systemic venous pressure, and improve cardiac output. Thus, we are developing a collapsible, percutaneously inserted, axial flow blood pump to support the cavopulmonary circulation in adult patients with a failing single ventricle physiology. This collapsible axial flow pump is designed for percutaneous positioning. The outer protective cage will be designed with radially arranged filaments as touchdown surfaces to protect the vessel wall from the rotating components. This study examined the geometric characteristics of the protective cage of filaments and the impeller through the development and numerical analysis of 13 models. A blood damage analysis was also performed on selected geometric models to assess the probability of blood trauma. All models demonstrated an acceptable hydraulic performance by delivering 2-6 L/min at a rotational speed of 6000-10 000 rpm and generating pressure rise of 5-20 mm Hg. Expected trends in the hydraulic performance of the pump models were found. This study represents the initial first design phase of the impeller and protective cage of filaments. Validation of these flow and performance predictions will be completed in the next round of experimental testing with blood bag evaluation.

Published

2009

44. Mechanical axial flow blood pump to support cavopulmonary circulation.

Author

Throckmorton AL, Kapadia J, and Madduri D

Subjects

Computer Simulation, Fontan Procedure, Heart Defects, Congenital physiopathology, Humans, Infant, Infant, Newborn, Materials Testing, Models, Cardiovascular, Numerical Analysis, Computer-Assisted, Prosthesis Design, Prosthesis Failure, Stress, Mechanical, Cardiac Catheterization instrumentation, Heart Defects, Congenital therapy, Heart-Assist Devices adverse effects, Hemodynamics, Pulmonary Circulation

Abstract

We are developing a collapsible, percutaneously inserted, axial flow blood pump to support the cavopulmonary circulation in infants with a failing single ventricle physiology. An initial design of the impeller for this axial flow blood pump was performed using computational fluid dynamics analysis, including pressure-flow characteristics, scalar stress estimations, blood damage indices, and fluid force predictions. A plastic prototype was constructed for hydraulic performance testing, and these experimental results were compared with the numerical predictions. The numerical predictions and experimental findings of the pump performance demonstrated a pressure generation of 2-16 mm Hg for 50-750 ml/min over 5,500-7,500 RPM with deviation found at lower rotational speeds. The axial fluid forces remained below 0.1 N, and the radial fluid forces were determined to be virtually zero due to the centered impeller case. The scalar stress levels remained below 250 Pa for all operating conditions. Blood damage analysis yielded a mean residence time of the released particles, which was found to be less than 0.4 seconds for both flow rates that were examined, and a maximum residence time was determined to be less than 0.8 seconds. We are in the process of designing a cage with hydrodynamically shaped filament blades to act as a diffuser and optimizing the impeller blade shape to reduce the flow vorticity at the pump outlet. This blood pump will improve the clinical treatment of patients with failing Fontan physiology and provide a unique catheter-based therapeutic approach as a bridge to recovery or transplantation.

Published

2008

45. Performance of a 3-bladed propeller pump to provide cavopulmonary assist in the failing Fontan circulation.

Author

Throckmorton AL, Ballman KK, Myers CD, Frankel SH, Brown JW, and Rodefeld MD

Subjects

Assisted Circulation methods, Equipment Design, Equipment Safety, Heart Bypass, Right methods, Hemodynamics physiology, Humans, Intraoperative Care methods, Pulsatile Flow, Sensitivity and Specificity, Technology Assessment, Biomedical, Tricuspid Atresia surgery, Assisted Circulation instrumentation, Fontan Procedure methods, Intraoperative Care instrumentation

Abstract

Purpose: We hypothesized that a propeller pump design would function optimally to provide cavopulmonary assist in a univentricular Fontan circulation., Description: The hydraulic and hemolysis performance of a rigid three-bladed propeller prototype (similar to a folding propeller design) was characterized. Pressure and flow measurements were taken for flow rates of 0.5 to 3 liters per minute (LPM) for 5,000 to 7,000 revolutions per minute (RPM) using a blood analog fluid. Hemolysis testing was performed using fresh bovine blood for 2 LPM at 6,000 RPM for a 6-hour duration., Evaluation: The prototype performed well over the design operating range by producing a pressure rise of 5 to 50 mm Hg. Plasma free hemoglobin concentration remained less than 15 mg/dL. The normalized index of hemolysis peaked during the first hour, and then remained less than 10 mg/dL thereafter., Conclusions: A propeller pump has the pressure-flow characteristics and minimal risk of hemolysis and venous pathway obstruction which make it ideal for temporary cavopulmonary assist. This type of device has the potential to provide a new therapeutic option for patients with failing univentricular Fontan physiology as a bridge-to-recovery or transplantation.

Published

2008

46. Pediatric circulatory support: current strategies and future directions. Biventricular and univentricular mechanical assistance.

Author

Throckmorton AL and Chopski SG

Subjects

Adolescent, Assisted Circulation mortality, Child, Heart Transplantation, Humans, Miniaturization instrumentation, Models, Cardiovascular, Pulsatile Flow, Assisted Circulation instrumentation, Assisted Circulation trends, Heart-Assist Devices trends

Abstract

Mechanical circulatory support is gaining increased recognition as a viable treatment option for pediatric patients who suffer from congenital or acquired heart disease. Historically, the treatment options have been very limited for pediatric patients, but recent technological advances, combined with new research into circulatory support devices, are seeking alternative therapeutics options for infants and children. We present a review of the technological advances of mechanical circulatory support in the pediatric population, including the recent emergence of a new class of circulatory support devices for pediatric patients with single ventricle physiology. The National Heart, Lung, and Blood Institute pediatric circulatory support program is discussed, in addition to the use of adult devices in pediatric applications, the Berlin Heart Excor, and several other blood pumps in development for bridge-to-transplant and bridge-to-recovery support. These devices have the potential to generate a paradigm shift in the treatment of the pediatric patients with heart failure--a shift is likely already be underway.

Published

2008

47. CFD analysis of a Mag-Lev ventricular assist device for infants and children: fourth generation design.

Author

Throckmorton AL and Untaroiu A

Subjects

Child, Hemorheology, Humans, Infant, Heart-Assist Devices, Models, Cardiovascular, Prosthesis Design instrumentation

Abstract

Thousands of pediatric patients suffering from heart failure would benefit from longer-term mechanical circulatory support. There are, however, few support systems available in the United States as viable mechanical assist alternatives for these patients. Therefore, we have designed and developed an axial flow pediatric ventricular assist device (PVAD) with an impeller that is fully suspended by magnetic bearings. This blood pump is designed to generate 0.5-4 L/min for pressure rises of 50-95 mm Hg over 6,000-9,000 rpm. We have performed four major design iterations. Building upon the third design phase, we made improvements to create the PVAD4 model. Numerical simulations of the PVAD4 under steady flow simulations were performed to compare the predictions of the latest PVAD4 model to the earlier PVAD3 design. The PVAD4 design resulted in lower fluid stress levels and an increase in pressure generation. A blood damage analysis was also completed. As compared with the earlier PVAD3 design, the damage analysis of the PVAD4 indicated a reduction in the mean and maximum damage index for the new design. All of these numerical findings are encouraging and demonstrate progress toward achieving a superior pump design.

Published

2008

48. Numerical design and experimental hydraulic testing of an axial flow ventricular assist device for infants and children.

Author

Throckmorton AL, Untaroiu A, Allaire PE, Wood HG, Lim DS, McCulloch MA, and Olsen DB

Subjects

Blood Flow Velocity, Child, Child, Preschool, Computational Biology methods, Humans, Infant, Magnetics, Plastics, Prosthesis Design instrumentation, Rheology, Rotation, Biomedical Engineering, Heart-Assist Devices, Materials Testing instrumentation, Numerical Analysis, Computer-Assisted

Abstract

Mechanical circulatory support options for infants and children are very limited in the United States. Existing circulatory support systems have proven successful for short-term pediatric assist, but are not completely successful as a bridge-to-transplant or bridge-to-recovery. To address this substantial need for alternative pediatric mechanical assist, we are developing a novel, magnetically levitated, axial flow pediatric ventricular assist device (PVAD) intended for longer-term ventricular support. Three major numerical design and optimization phases have been completed. A prototype was built based on the latest numerical design (PVAD3) and hydraulically tested in a flow loop. The plastic PVAD prototype delivered 0.5-4 lpm, generating pressure rises of 50-115 mm Hg for operating speeds of 6,000-9,000 rpm. The experimental testing data and the numerical predictions correlated well. The error between these sets of data was found to be generally 7.8% with a maximum deviation of 24% at higher flow rates. The axial fluid forces for the numerical simulations ranged from 0.5 to 1 N and deviated from the experimental results by generally 8.5% with a maximum deviation of 12% at higher flow rates. These hydraulic results demonstrate the excellent performance of the PVAD3 and illustrate the achievement of the design objectives.

Published

2007

49. Mechanical cavopulmonary assist for the univentricular Fontan circulation using a novel folding propeller blood pump.

Author

Throckmorton AL, Ballman KK, Myers CD, Litwak KN, Frankel SH, and Rodefeld MD

Subjects

Computational Biology methods, Computer Simulation, Fontan Procedure methods, Humans, Models, Cardiovascular, Prosthesis Design, Assisted Circulation, Biomedical Engineering, Blood Circulation, Heart Bypass, Right, Heart-Assist Devices

Abstract

A blood pump specifically designed to operate in the unique anatomic and physiologic conditions of a cavopulmonary connection has never been developed. Mechanical augmentation of cavopulmonary blood flow in a univentricular circulation would reduce systemic venous pressure, increase preload to the single ventricle, and temporarily reproduce a scenario analogous to the normal two-ventricle circulation. We hypothesize that a folding propeller blood pump would function optimally in this cavopulmonary circulation. The hydraulic performance of a two-bladed propeller prototype was characterized in an experimental flow loop using a blood analog fluid for 0.5-3.5 lpm at rotational speeds of 3,600-4,000 rpm. We also created five distinctive blood pump designs and evaluated their hydraulic performance using computational fluid dynamics (CFD). The two-bladed prototype performed well over the design range of 0.5-3.5 lpm, producing physiologic pressure rises of 5-18 mm Hg. Building upon this proof-of-concept testing, the CFD analysis of the five numerical models predicted a physiologic pressure range of 5-40 mm Hg over 0.5-4 lpm for rotational speeds of 3,000-7,000 rpm. These preliminary propeller designs and the two-bladed prototype achieved the expected hydraulic performance. Optimization of these configurations will reduce fluid stress levels, remove regions of recirculation, and improve the hydraulic performance of the folding propeller. This propeller design produces the physiologic pressures and flows that are in the ideal range to mechanically support the cavopulmonary circulation and represents an exciting new therapeutic option for the support of a univentricular Fontan circulation.

Published

2007

50. Fluid force predictions and experimental measurements for a magnetically levitated pediatric ventricular assist device.

Author

Throckmorton AL, Untaroiu A, Lim DS, Wood HG, and Allaire PE

Subjects

Child, Forecasting, Humans, Mechanics, Equipment Design instrumentation, Heart-Assist Devices, Hemorheology, Magnetics instrumentation

Abstract

The latest generation of artificial blood pumps incorporates the use of magnetic bearings to levitate the rotating component of the pump, the impeller. A magnetic suspension prevents the rotating impeller from contacting the internal surfaces of the pump and reduces regions of stagnant and high shear flow that surround fluid or mechanical bearings. Applying this third-generation technology, the Virginia Artificial Heart Institute has developed a ventricular assist device (VAD) to support infants and children. In consideration of the suspension design, the axial and radial fluid forces exerted on the rotor of the pediatric VAD were estimated using computational fluid dynamics (CFD) such that fluid perturbations would be counterbalanced. In addition, a prototype was built for experimental measurements of the axial fluid forces and estimations of the radial fluid forces during operation using a blood analog mixture. The axial fluid forces for a centered impeller position were found to range from 0.5 +/- 0.01 to 1 +/- 0.02 N in magnitude for 0.5 +/- 0.095 to 3.5 +/- 0.164 Lpm over rotational speeds of 6110 +/- 0.39 to 8030 +/- 0.57% rpm. The CFD predictions for the axial forces deviated from the experimental data by approximately 8.5% with a maximum difference of 18% at higher flow rates. Similarly for the off-centered impeller conditions, the maximum radial fluid force along the y-axis was found to be -0.57 +/- 0.17 N. The maximum cross-coupling force in the x direction was found to be larger with a maximum value of 0.74 +/- 0.22 N. This resulted in a 25-35% overestimate of the radial fluid force as compared to the CFD predictions; this overestimation will lead to a far more robust magnetic suspension design. The axial and radial forces estimated from the computational results are well within a range over which a compact magnetic suspension can compensate for flow perturbations. This study also serves as an effective and novel design methodology for blood pump developers employing magnetic suspensions. Following a final design evaluation, a magnetically suspended pediatric VAD will be constructed for extensive hydraulic and animal testing as well as additional validation of this design methodology.

Published

2007