Your search keyword '"Wu, Zhongjun J."' showing total 18 results

1. Computational fluid dynamics-based design and in vitro characterization of a novel pediatric pump-lung.

Author

Han D, Zhang J, He G, Griffith BP, and Wu ZJ

Subjects

Humans, Child, Animals, Sheep, Hydrodynamics, Lung, Oxygenators, Equipment Design, Hemolysis, Extracorporeal Membrane Oxygenation adverse effects

Abstract

Background: Although extracorporeal membrane oxygenation (ECMO) has been used to provide temporary support for pediatric patients suffering severe respiratory or cardiac failure since 1970, ECMO systems specifically designed for pediatric patients, particularly for long-term use, remain an unmet clinical need. We sought to develop a new pediatric ECMO system, that is, pediatric pump-lung (PPL), consisting of a unique cylinder oxygenator with an outside-in radial flow path and a centrifugal pump., Methods: Computational fluid dynamics was used to analyze the blood fluid field for optimized biocompatible and gas exchange performances in terms of flow characteristics, hemolysis, and gas transfer efficiency. Ovine blood was used for in vitro hemolysis and gas transfer testing., Results: Both the computational and experimental data showed that the pressure drop through the PPL's oxygenator is significantly low, even at a flow rate of more than 3.5 L/min. The PPL showed better hemolysis performance than a commercial ECMO circuit consisting of the Quadrox-iD pediatric oxygenator and the Rotaflow pump at a 3.5 L/min flow rate and 250 mm Hg afterload pressure. The oxygen transfer rate of the PPL can reach over 200 mL/min at a flow rate of 3.5 L/min., Conclusions: The PPL has the potential to provide adequate blood pumping and excellent respiratory support with minimal risk of hemolysis for a wide range of pediatric patients., (© 2023 The Authors. Artificial Organs published by International Center for Artificial Organ and Transplantation (ICAOT) and Wiley Periodicals LLC.)

Published

2024

2. Spinal Cord Infarction With Prolonged Femoral Venoarterial Extracorporeal Membrane Oxygenation.

Author

Pasrija C, Kon ZN, Mazzeffi MA, Zhang J, Wu ZJ, Tran D, Bittle GJ, Ghoreishi M, Miller TR, Alkhatib H, Tobin N, Taylor BS, Deatrick KB, Rector R, Herr DL, and Griffith BP

Subjects

Humans, Hypoxia etiology, Hypoxia therapy, Infarction, Retrospective Studies, Extracorporeal Membrane Oxygenation adverse effects, Extracorporeal Membrane Oxygenation methods, Spinal Cord Injuries diagnostic imaging, Spinal Cord Injuries etiology, Spinal Cord Injuries therapy, Spinal Cord Ischemia diagnostic imaging, Spinal Cord Ischemia etiology

Abstract

Objectives: There have been sporadic reports of ischemic spinal cord injury (SCI) during venoarterial extracorporeal membrane oxygenation (VA-ECMO) support. The authors observed a troubling pattern of this catastrophic complication and evaluated the potential mechanisms of SCI related to ECMO., Design: This study was a case series., Setting: This study was performed at a single institution in a University setting., Participants: Patients requiring prolonged VA-ECMO were included., Interventions: No interventions were done. This was an observational study., Measurements and Main Results: Four hypotheses of etiology were considered: (1) hypercoagulable state/thromboembolism, (2) regional hypoxia/hypocarbia, (3) hyperperfusion and spinal cord edema, and (4) mechanical coverage of spinal arteries. The SCI involved the lower thoracic (T7-T12 level) spinal cord to the cauda equina in all patients. Seven out of 132 (5.3%) patients with prolonged VA-ECMO support developed SCI. The median time from ECMO cannulation to SCI was 7 (range: 6-17) days.There was no evidence of embolic SCI or extended regional hypoxia or hypocarbia. A unilateral, internal iliac artery was covered by the arterial cannula in 6/7 86%) patients, but flow into the internal iliac was demonstrated on imaging in all available patients. The median total flow (ECMO + intrinsic cardiac output) was 8.5 L/min (LPM), and indexed flow was 4.1 LPM/m 2 . The median central venous oxygen saturation was 88%, and intracranial pressure was measured at 30 mmHg in one patient, suggestive of hyperperfusion and spinal cord edema., Conclusions: An SCI is a serious complication of extended peripheral VA-ECMO support. Its etiology remains uncertain, but the authors' preliminary data suggested that spinal cord edema from hyperperfusion or venous congestion could contribute., Competing Interests: Conflict of Interest C. Pasrija, Z. N. Kon, B. P. Griffith, M. Ghoreishi, and G.J. Bittle have a patent pending for an ECMO cannula. B. P. Griffith & D.L. Herr receives consultant fees for an ECMO system., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

3. Ambulatory home wearable lung: progress and future directions.

Author

Shah A, Awad MA, Wu ZJ, and Griffith BP

Subjects

Adult, Humans, Lung, Extracorporeal Membrane Oxygenation, Influenza A Virus, H1N1 Subtype, Respiratory Distress Syndrome, Wearable Electronic Devices

Abstract

Extracorporeal life support (ECLS) was first implemented as an extension of cardiopulmonary bypass technology. The early use of ECLS in patients with acute respiratory distress syndrome (ARDS) was discouraging, likely due to limitations of technology and understanding of the disease process. However, over the last decade, there has been a rapid expansion in ECLS use. This "rebirth" in 2009 was largely driven by the need for ECLS during the Influenza A subtype H1N1 pandemic and the results of the conventional ventilatory support versus extracorporeal membrane oxygenation for severe adult respiratory failure (CESAR) trial showing improved outcomes in patients with ARDS on ECLS compared to traditional management. Along with the increase in overall use of ECLS, there has been an increase in the number of patients with lung failure who are on long-term support, either awaiting lung recovery or transplantation. Many of these patients are awake, participating in physical rehabilitation, and even ambulating while supported with ECLS. Given the recent advances in patient care, and improvements in ECLS technology, the movement towards home for stable patients supported with ECLS may be on the horizon. Patients supported with ventricular assist devices (VAD) underwent a similar transition towards home in the 1990s, before which they were hospital bound. The road to an ambulatory home wearable lung will likely mirror that pathway. This review will give a brief overview of the transition of VAD patients out of the hospital, the history of ECLS, the current state of ECLS for lung failure, new and upcoming ECLS technology, and hurdles on the road home for ECLS patients., Competing Interests: The authors declare no conflict of interest. Z.J. Wu and B.P. Griffith disclose intellectual property and financial interests in Breethe, Inc. A. Shah discloses intellectual property interest related to cannulation of extracorporeal membrane oxygenation., (© 2021 The Author(s). Published by IMR Press.)

Published

2021

4. Flow characteristics and hemolytic performance of the new Breethe centrifugal blood pump in comparison with the CentriMag and Rotaflow pumps.

Author

He G, Zhang J, Shah A, Berk ZB, Han L, Dong H, Griffith BP, and Wu ZJ

Subjects

Cardiopulmonary Bypass, Hemolysis, Humans, Hydrodynamics, Assisted Circulation, Extracorporeal Membrane Oxygenation, Heart-Assist Devices

Abstract

Blood pumps have been increasingly used in mechanically assisted circulation for ventricular assistance and extracorporeal membrane oxygenation support or during cardiopulmonary bypass for cardiac surgery. However, there have always been common complications such as thrombosis, hemolysis, bleeding, and infection associated with current blood pumps in patients. The development of more biocompatible blood pumps still prevails during the past decades. As one of those newly developed pumps, the Breethe pump is a novel extracorporeal centrifugal blood pump with a hybrid magnetic and mechanical bearing with attempt to reduce device-induced blood trauma. To characterize the hydrodynamic and hemolytic performances of this novel pump and demonstrate its superior biocompatibility, we use a combined computational and experimental approach to compare the Breethe pump with the CentriMag and Rotaflow pumps in terms of flow features and hemolysis under an operating condition relevant to ECMO support (flow: 5 L/min, pressure head: ~350 mmHg). The computational results showed that the Breethe pump has a smaller area-averaged wall shear stress (WSS), a smaller volume with a scalar shear stress (SSS) level greater than 100 Pa and a lower device-generated hemolysis index compared to the CentriMag and Rotaflow pumps. The comparison of the calculated residence times among the three pumps indicated that the Breethe pump might have better washout. The experimental data from the in vitro hemolysis testing demonstrated that the Breethe pump has the lowest normalized hemolysis index (NIH) than the CentriMag and Rotaflow pumps. It can be concluded based on both the computational and experimental data that the Breethe pump is a viable pump for clinical use and it has better biocompatibility compared to the clinically accepted pumps.

Published

2021

5. Device-Induced Hemostatic Disorders in Mechanically Assisted Circulation.

Author

Wang S, Griffith BP, and Wu ZJ

Subjects

Animals, Blood Platelets pathology, Cardiopulmonary Bypass adverse effects, Cell-Derived Microparticles metabolism, Cell-Derived Microparticles pathology, Extracorporeal Membrane Oxygenation adverse effects, Hemolysis, Hemostatic Disorders blood, Humans, Platelet Activation, Prosthesis Design, Prosthesis Implantation adverse effects, Risk Assessment, Risk Factors, Stress, Mechanical, Treatment Outcome, Blood Platelets metabolism, Cardiopulmonary Bypass instrumentation, Extracorporeal Membrane Oxygenation instrumentation, Heart-Assist Devices, Hemostatic Disorders etiology, Oxygenators, Membrane, Prosthesis Implantation instrumentation

Abstract

Mechanically assisted circulation (MAC) sustains the blood circulation in the body of a patients undergoing cardiac surgery with cardiopulmonary bypass (CPB) or on ventricular assistance with a ventricular assist device (VAD) or on extracorporeal membrane oxygenation (ECMO) with a pump-oxygenator system. While MAC provides short-term (days to weeks) support and long-term (months to years) for the heart and/or lungs, the blood is inevitably exposed to non-physiological shear stress (NPSS) due to mechanical pumping action and in contact with artificial surfaces. NPSS is well known to cause blood damage and functional alterations of blood cells. In this review, we discussed shear-induced platelet adhesion, platelet aggregation, platelet receptor shedding, and platelet apoptosis, shear-induced acquired von Willebrand syndrome (AVWS), shear-induced hemolysis and microparticle formation during MAC. These alterations are associated with perioperative bleeding and thrombotic events, morbidity and mortality, and quality of life in MCS patients. Understanding the mechanism of shear-induce hemostatic disorders will help us develop low-shear-stress devices and select more effective treatments for better clinical outcomes.

Published

2021

6. Understanding Extracorporeal Membrane Oxygenation Induced Coagulopathy: Many Pieces to the Puzzle.

Author

Mazzeffi MA, Chow JH, Wu ZJ, and Tanaka KA

Subjects

Humans, Blood Coagulation Disorders etiology, Extracorporeal Membrane Oxygenation adverse effects

Published

2020

7. Impact of high mechanical shear stress and oxygenator membrane surface on blood damage relevant to thrombosis and bleeding in a pediatric ECMO circuit.

Author

Sun W, Wang S, Chen Z, Zhang J, Li T, Arias K, Griffith BP, and Wu ZJ

Subjects

Blood Platelets cytology, Cell-Derived Microparticles metabolism, Child, Extracorporeal Membrane Oxygenation instrumentation, Healthy Volunteers, Hemorrhage blood, Hemorrhage prevention & control, Humans, Platelet Activation, Platelet Glycoprotein GPIb-IX Complex metabolism, Platelet Membrane Glycoproteins metabolism, Stress, Mechanical, Thrombosis blood, Thrombosis prevention & control, Blood Platelets metabolism, Extracorporeal Membrane Oxygenation adverse effects, Hemorrhage etiology, Oxygenators, Membrane adverse effects, Thrombosis etiology

Abstract

The roles of the large membrane surface of the oxygenator and the high mechanical shear stress (HMSS) of the pump in the extracorporeal membrane oxygenation (ECMO) circuit were examined under a pediatric support setting. A clinical centrifugal pump and a pediatric oxygenator were used to construct the ECMO circuit. An identical circuit without the oxygenator was constructed for comparison. Fresh human blood was circulated in the two circuits for 4 hours under the identical pump speed and flow. Blood samples were collected hourly for blood damage assessment, including platelet activation, generation of platelet-derived microparticles (PDMP), losses of key platelet hemostasis receptors (glycoprotein (GP) Ibα (GPIbα) and GPVI), and high molecular weight multimers (HMWM) of von Willebrand factor (VWF) and plasma free hemoglobin (PFH). Platelet adhesion on fibrinogen, VWF, and collagen was further examined. The levels of platelet activation and generation of PDMP and PFH exhibited an increasing trend with circulation time while the expression levels of GPIbα and GPVI receptors on the platelet surface decreased. Correspondingly, the platelets in the blood samples exhibited increased adhesion capacity to fibrinogen and decreased adhesion capacities on VWF and collagen with circulation time. Loss of HMWM of VWF occurred in both circuits. No statistically significant differences were found in all the measured parameters for blood damage and platelet adhesion function between the two circuits. The results indicate that HMSS from the pump played a dominant role in blood damage associated with ECMO and the impact of the large surface of the oxygenator on blood damage was insignificant., (© 2020 International Center for Artificial Organ and Transplantation (ICAOT) and Wiley Periodicals, Inc.)

Published

2020

8. High-efficiency, high-flux in-line hemofiltration using a high blood flow extracorporeal circuit.

Author

Grazioli A, Shah SR, Rabin J, Shah R, Madathil RJ, King JD, DiChiacchio L, Rector RP, Deatrick KB, Wu ZJ, and Herr DL

Subjects

Humans, Male, Middle Aged, Extracorporeal Membrane Oxygenation methods, Hemofiltration methods

Abstract

The ability of current renal replacement therapy modalities to achieve rapid solute removal is limited by membrane surface area and blood flow rate. Extracorporeal membrane oxygenation offers high blood flow and hemodynamic support that may be harnessed to overcome limitations in traditional renal replacement therapy. Using an extracorporeal membrane oxygenation circuit, we describe a high blood flow, high-efficiency hemofiltration technique using in-line hemofilters (hemoconcentrators) and standard replacement fluid to enhance solute clearance. Using this approach and a total of 5 L of replacement volume per treatment, creatinine (Cr) clearances of 8.3 L/hour and 11.2 L/hour using one and two hemoconcentrators, respectively, were achieved. With use of a high blood flow rate of up to 5 L/min, this hemofiltration technique can potentially offer clearance of 30 times that of continuous renal replacement therapy and of 6 times that of hemodialysis which may expand the ability to remove substances traditionally not considered removable via existing extracorporeal therapies.

Published

2020

9. Evaluation of an autoregulatory ECMO system for total respiratory support in an acute ovine model.

Author

Conway RG, Berk ZB, Zhang J, Li T, Tran D, Wu ZJ, and Griffith BP

Subjects

Animals, Fuzzy Logic, Male, Sheep, Extracorporeal Membrane Oxygenation instrumentation

Abstract

Extracorporeal membrane oxygenation (ECMO) has become a mainstay of therapy for patients suffering from severe respiratory failure. Ambulatory ECMO systems aim to provide long-term out-of-hospital respiratory support. As a patient's activity level changes, the required level of ECMO support varies with oxygen consumption and metabolic fluctuations. To compensate for such changes, an autoregulatory ECMO system (AR-ECMO) has been developed and its performance was evaluated as a proof of concept in an acute ovine model. The AR-ECMO system consists of a regular ECMO circuit and an electromechanical control system. A custom fuzzy logic control algorithm was implemented to adjust the blood flow and sweep gas flow of the ECMO circuit to meet the varying respiratory demand by utilizing two noninvasive sensors for venous oxyhemoglobin saturation and the oxygenator exhaust gas CO 2 concentration. Disturbance responses of the AR-ECMO to induced acute respiratory distress were assessed for six hours in four juvenile sheep cannulated with a veno-pulmonary artery ECMO configuration, including acute ventilator shutoff, ventilator step change (off-on-off), and forced desaturation. All sheep survived for the study duration. The AR-ECMO system was able to respond and maintain stable hemodynamics and physiological blood gas contents (SpO 2  = 96.3 % ± 4.29, pH 7.44 ± 0.09, pCO 2  = 38.9 ± 9.9 mm Hg, and pO 2 =237.9 ± 123.6 mm Hg) during simulated respiratory distress. Acceptable correlation between oxygenator exhaust gas CO 2 and oxygenator outlet pCO 2 were observed (R 2  = 0.84). In summary, the AR-ECMO system successfully maintained physiologic control of peripheral oxygenation and carbon dioxide over the study period, utilizing only measurements taken directly from the ECMO circuit. The range of system response necessitates an adaptable system in the setting of variable metabolic demands. The ability of this system to respond to significant disturbances in ventilator support is encouraging. Future work to evaluate our AR-ECMO system in long-term, awake animal studies is necessary for further refinement., (© 2020 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2020

10. Extracorporeal Respiratory Support With a Miniature Integrated Pediatric Pump-Lung Device in an Acute Ovine Respiratory Failure Model.

Author

Wei X, Sanchez PG, Liu Y, Claire Watkins A, Li T, Griffith BP, and Wu ZJ

Subjects

Animals, Carbon Dioxide blood, Child, Disease Models, Animal, Heart Atria surgery, Hemodynamics, Humans, Hypercapnia therapy, Oxygen blood, Pulmonary Artery surgery, Respiration, Artificial methods, Sheep, Acute Lung Injury surgery, Extracorporeal Membrane Oxygenation instrumentation, Heart-Lung Machine, Respiratory Insufficiency surgery

Abstract

Respiratory failure is one of the major causes of mortality and morbidity all over the world. Therapeutic options to treat respiratory failure remain limited. The objective of this study was to evaluate the gas transfer performance of a newly developed miniature portable integrated pediatric pump-lung device (PediPL) with small membrane surface for respiratory support in an acute ovine respiratory failure model. The respiratory failure was created in six adult sheep using intravenous anesthesia and reduced mechanical ventilation at 2 breaths/min. The PediPL device was surgically implanted and evaluated for respiratory support in a venovenous configuration between the right atrium and pulmonary artery. The hemodynamics and respiratory status of the animals during support with the device gas transfer performance of the PediPL were studied for 4 h. The animals exhibited respiratory failure 30 min after mechanical ventilation was reduced to 2 breaths/min, indicated by low oxygen partial pressure, low oxygen saturation, and elevated carbon dioxide in arterial blood. The failure was reversed by establishing respiratory support with the PediPL after 30 min. The rates of O 2 transfer and CO 2 removal of the PediPL were 86.8 and 139.1 mL/min, respectively. The results demonstrated that the PediPL (miniature integrated pump-oxygenator) has the potential to provide respiratory support as a novel treatment for both hypoxia and hypercarbia. The compact size of the PediPL could allow portability and potentially be used in many emergency settings to rescue patients suffering acute lung injury., (Copyright © 2016 International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2016

11. Right ventricular unloading and respiratory support with a wearable artificial pump-lung in an ovine model.

Author

Liu Y, Sanchez PG, Wei X, Li T, Watkins AC, Li SY, Griffith BP, and Wu ZJ

Subjects

Animals, Disease Models, Animal, Heart Atria physiopathology, Heart Atria surgery, Hemodynamics physiology, Linear Models, Pulmonary Artery physiopathology, Pulmonary Artery surgery, Sheep, Stroke Volume physiology, Treatment Outcome, Ventricular Dysfunction, Right physiopathology, Equipment Design, Extracorporeal Membrane Oxygenation instrumentation, Extracorporeal Membrane Oxygenation methods, Heart-Assist Devices, Ventricular Dysfunction, Right surgery

Abstract

Background: Device availability of mechanical circulatory or respiratory support to the right heart has been limited. The purpose of this study was to investigate the effect of right heart unloading and respiratory support with a wearable integrated artificial pump-lung (APL)., Methods: The APL device was placed surgically between the right atrium and pulmonary artery in 7 sheep. Anti-coagulation was performed with heparin infusion. The device's ability to unload the right ventricle (RV) was investigated by echocardiograms and right heart catheterization at different bypass flow rates. Hemodynamics and echocardiographic data were evaluated. APL flow and gas transfer rates were also measured at different device speeds., Results: Hemodynamics remained stable during APL support. There was no significant change in systemic blood pressure and cardiac index. Central venous pressure, RV pressure, RV end-diastolic dimension and RV ejection fraction were significantly decreased when APL device flow rate approached 2 liters/min. Linear regression showed significant correlative trends between the hemodynamic and cardiac indices and device speed. The oxygen transfer rate increased with device speed. The oxygen saturation from the APL outlet was fully saturated (>95%) during support. The impact of APL support on blood elements (plasma free hemoglobin and platelet activation) was minimal., Conclusions: APL device support significantly unloaded the RV with increasing device speed. The device also provided stable hemodynamics and respiratory support in terms of blood flow and oxygen transfer. The right heart unloading performance of this wearable device needs to be evaluated further in an animal model of right heart failure with long-term support., (Copyright © 2014 International Society for Heart and Lung Transplantation. Published by Elsevier Inc. All rights reserved.)

Published

2014

12. Computational model-based design of a wearable artificial pump-lung for cardiopulmonary/respiratory support.

Author

Wu ZJ, Taskin ME, Zhang T, Fraser KH, and Griffith BP

Subjects

Computer Simulation, Computer-Aided Design, Equipment Design, Hemolysis, Humans, Hydrodynamics, Pressure, Extracorporeal Membrane Oxygenation instrumentation, Ventilators, Mechanical

Abstract

Mechanical ventilation and extracorporeal membrane oxygenation are the only immediate options available for patients with respiratory failure. However, these options present significant shortcomings. To address this unmet need for respiratory support, innovative respiratory assist devices are being developed. In this study, we present the computational model-based design, and analysis of functional characteristics and hemocompatibility performance, of an innovative wearable artificial pump-lung (APL) for ambulatory respiratory support. Computer-aided design and computational fluid dynamics (CFD)-based modeling were utilized to generate the geometrical model and to acquire the fluid flow field, gas transfer, and blood damage potential. With the knowledge of flow field, gas transfer, and blood damage potential through the whole device, design parameters were adjusted to achieve the desired specifications based on the concept of virtual prototyping using the computational modeling in conjunction with consideration of the constraints on fabrication processes and materials. Based on the results of the CFD design and analysis, the physical model of the wearable APL was fabricated. Computationally predicted hydrodynamic pumping function, gas transfer, and blood damage potential were compared with experimental data from in vitro evaluation of the wearable APL. The hydrodynamic performance, oxygen transfer, and blood damage potential predicted with computational modeling, along with the in vitro experimental data, indicated that this APL meets the design specifications for respiratory support with excellent biocompatibility at the targeted operating condition., (© 2011, Copyright the Authors. Artificial Organs © 2011, International Center for Artificial Organs and Transplantation and Wiley Periodicals, Inc.)

Published

2012

13. Computational design and in vitro characterization of an integrated maglev pump-oxygenator.

Author

Zhang J, Taskin ME, Koert A, Zhang T, Gellman B, Dasse KA, Gilbert RJ, Griffith BP, and Wu ZJ

Subjects

Adult, Animals, Computer Simulation, Equipment Design, Extracorporeal Membrane Oxygenation adverse effects, Hemolysis, Hemorheology, Humans, Magnetics, Materials Testing, Oxygen blood, Pressure, Respiratory Insufficiency blood, Rotation, Sheep, Stress, Mechanical, Time Factors, Computer-Aided Design, Extracorporeal Membrane Oxygenation instrumentation, Oxygenators, Membrane adverse effects, Respiratory Insufficiency therapy

Abstract

For the need for respiratory support for patients with acute or chronic lung diseases to be addressed, a novel integrated maglev pump-oxygenator (IMPO) is being developed as a respiratory assist device. IMPO was conceptualized to combine a magnetically levitated pump/rotor with uniquely configured hollow fiber membranes to create an assembly-free, ultracompact system. IMPO is a self-contained blood pump and oxygenator assembly to enable rapid deployment for patients requiring respiratory support or circulatory support. In this study, computational fluid dynamics (CFD) and computer-aided design were conducted to design and optimize the hemodynamics, gas transfer, and hemocompatibility performances of this novel device. In parallel, in vitro experiments including hydrodynamic, gas transfer, and hemolysis measurements were conducted to evaluate the performance of IMPO. Computational results from CFD analysis were compared with experimental data collected from in vitro evaluation of the IMPO. The CFD simulation demonstrated a well-behaved and streamlined flow field in the main components of this device. The results of hydrodynamic performance, oxygen transfer, and hemolysis predicted by computational simulation, along with the in vitro experimental data, indicate that this pump-lung device can provide the total respiratory need of an adult with lung failure, with a low hemolysis rate at the targeted operating condition. These detailed CFD designs and analyses can provide valuable guidance for further optimization of this IMPO for long-term use.

Published

2009

14. An ex vivo comparison of partial thromboplastin time and activated clotting time for heparin anticoagulation in an ovine model.

Author

Berk, Zachary B. K., Shah, Aakash, Sun, Wenji, Griffith, Bartley P., and Wu, Zhongjun J.

Subjects

PARTIAL thromboplastin time, HEPARIN, ARTIFICIAL blood circulation, EXTRACORPOREAL membrane oxygenation, ANTICOAGULANTS

Abstract

Background: Sheep are a primary model of mechanical circulatory support (MCS) with heparin anticoagulation therapy frequently being monitored by activated clotting time (ACT) due to ease and cost. In patients undergoing long‐term heparin therapy, other anticoagulation monitoring strategies, such as activated partial thromboplastin time (aPTT), have proven to be more reliable indicators for the adequacy of anticoagulation, frequently determined by heparin concentration. As there is a paucity of similar studies in sheep, we sought to investigate the correlation between heparin concentration and ACT and aPTT using whole sheep blood in an ex vivo model. Methods: Fresh whole blood was serially drawn from an adult female Dorset‐hybrid sheep and aliquots were placed into tubes containing heparin saline solutions with concentrations ranging from 0 to 7.81 U heparin per mL of whole blood. ACT and aPTT values were measured on each of the samples. The experiment was performed four times with the same animal. A simple linear regression was performed to determine correlation, and subgroup analysis was performed on low versus high heparin concentrations typically seen in human patients on long‐term MCS, such as extracorporeal membrane oxygenation (ECMO), versus cardiopulmonary bypass, respectively. Results: aPTT measurements versus the heparin concentration had an R2 = 0.7295. ACT measurements versus the heparin concentration had a R2 = 0.4628. aPTT measurements versus the ACT measurements had a R2 = 0.2974. The strength of the correlation between aPTT and heparin concentration increased at low heparin concentrations (R2 = 0.8392). Conclusion: aPTT had a more reliable correlation to heparin concentration and thus anticoagulation level than ACT. This was particularly true at lower heparin concentrations, similar to ranges seen for patients on ECMO. The correlation between aPTT and ACT values was poor. Further in vivo studies should be performed to confirm our results. [ABSTRACT FROM AUTHOR]

Published

2022

15. Neutrophil injury and function alterations induced by high mechanical shear stress with short exposure time.

Author

Sun, Wenji, Wang, Shigang, Zhang, Jiafeng, Arias, Katherin, Griffith, Bartley P., and Wu, Zhongjun J.

Subjects

STRAINS & stresses (Mechanics), SHEARING force, HEART assist devices, PHAGOCYTIC function tests, BLOOD cells, NEUTROPHILS, VIRAL shedding

Abstract

High mechanical shear stresses (HMSS) can cause damage to blood, which manifests as morphologic changes, shortened life span, biochemical alterations, and complete rupture of blood cells and proteins, leading to the alterations of normal blood function. The aim of this study is to determine the state of neutrophil activation and function alterations caused by HMSS with short exposure time relevant to ventricular assist devices. Blood from healthy donors was exposed to three levels of HMSS (75Pa, 125Pa, and 175Pa) for a short exposure time (0.5 s) using our Couette‐type blood‐shearing device. Neutrophil activation (Mac‐1, platelet‐neutrophil aggregates) and surface expression levels of two key functional receptors (CD62L and CD162) on neutrophils were evaluated by flow cytometry. Neutrophil phagocytosis and transmigration were also examined with functional assays. Results showed that the expression of Mac‐1 on neutrophils and platelet‐neutrophil aggregates increased significantly while the level of CD62L expression on neutrophils decreased significantly after the exposure to HMSS. The Mac‐1 expression progressively increased while the CD62L expression progressively decreased with the increased level of HMSS. The level of CD162 expression on neutrophils slightly increased after the exposure to HMSS, but the increase was not significant. The phagocytosis assay data revealed that the ability of neutrophils to phagocytose latex beads coated with fluorescently labeled rabbit IgG increased significantly with the increased level of HMSS. The transmigration ability of neutrophils slightly increased after the exposure to HMSS, but did not reach a significant level. In summary, HMSS with a short exposure time of 0.5 seconds could induce neutrophil activation, platelet‐neutrophil aggregation, shedding of CD62L receptor, and increased phagocytic ability. However, the exposure to the three levels of HMSS did not cause a significant change in neutrophil transmigration capacity and shedding of CD162 receptor on neutrophils. [ABSTRACT FROM AUTHOR]

Published

2021

16. Extracorporeal Respiratory Support with a Miniature Integrated Pediatric Pump-Lung device (PediPL) in an Acute Ovine Respiratory Failure Model

Author

Wei, Xufeng, Sanchez, Pablo G, Liu, Yang, Watkins, A Claire, Li, Tieluo, Griffith, Bartley P, and Wu, Zhongjun J

Subjects

Sheep, Acute Lung Injury, Hemodynamics, Carbon Dioxide, Heart-Lung Machine, Pulmonary Artery, Respiration, Artificial, Article, Hypercapnia, Oxygen, Disease Models, Animal, Extracorporeal Membrane Oxygenation, Animals, Humans, Heart Atria, Child, Respiratory Insufficiency

Abstract

Respiratory failure is one of the major causes of mortality and morbidity all over the world. Therapeutic options to treat respiratory failure remain limited. The objective of this study was to evaluate the gas transfer performance of a newly developed miniature portable integrated pediatric pump-lung device (PediPL) with small membrane surface for respiratory support in an acute ovine respiratory failure model. The respiratory failure was created in six adult sheep using intravenous anesthesia and reduced mechanical ventilation at 2 breaths/min. The PediPL device was surgically implanted and evaluated for respiratory support in a venovenous configuration between the right atrium and pulmonary artery. The hemodynamics and respiratory status of the animals during support with the device gas transfer performance of the PediPL were studied for 4 h. The animals exhibited respiratory failure 30 min after mechanical ventilation was reduced to 2 breaths/min, indicated by low oxygen partial pressure, low oxygen saturation, and elevated carbon dioxide in arterial blood. The failure was reversed by establishing respiratory support with the PediPL after 30 min. The rates of O

Published

2016

17. Effects of Cardiopulmonary Support With a Novel Pediatric Pump-Lung in a 30-Day Ovine Animal Model.

Author

Liu, Yang, Sanchez, Pablo G., Wei, Xufeng, Watkins, Amelia C., Niu, Shuqiong, Wu, Zhongjun J., and Griffith, Bartley P.

Subjects

CARDIOPULMONARY bypass, HEART transplantation, EXTRACORPOREAL membrane oxygenation, LUNG transplantation, MECHANICAL ventilators

Abstract

The scarcity of donor organs has led to the development of devices that provide optimal long-term respiratory or cardiopulmonary support to bridge recipients as they wait for lung and/or heart transplantation. This study was designed to evaluate the 30-day in vivo performance of the newly developed pediatric pump-lung ( PediPL) for cardiopulmonary support using a juvenile sheep model. The PediPL device was placed surgically between the right atrium and descending aorta in eight sheep (25.4-31.2 kg) and evaluated for 30 days. Anticoagulation was maintained with continuous heparin infusion (activated clotting time 150-200 s). The flow rate was measured continually, and gas transfer was measured daily. Plasma free hemoglobin, platelet activation, hematologic data, and blood biochemistry were assessed twice a week. Sheep were euthanized after 30 days. The explanted devices were examined for gross thrombosis. Six sheep survived for 30-32 days. During the study, the oxygen transfer rate of the devices was 54.9 ± 13.2 mL/min at a mean flow rate of 1.14 ± 0.46 L/min with blood oxygen saturation of 95.4% ± 1.7%. Plasma free hemoglobin was 8.2 ± 3.7 mg/dL. Platelet activation was 5.35 ± 2.65%. The animals had normal organ chemistries except for surgery-related transient alterations in kidney and liver function. Although we found some scattered thrombi on the membrane surfaces of some explanted devices during the necropsy, the device function and performance did not degrade. The PediPL device was capable of providing cardiopulmonary support with long-term reliability and good biocompatibility over the 30-day duration and offers the potential option for bridging pediatric patients with end-stage heart or lung disease to heart and/or lung transplantation. [ABSTRACT FROM AUTHOR]

Published

2015

18. Biocompatibility Assessment of a Long-Term Wearable Artificial Pump-Lung in Sheep.

Author

Zhou, Kang, Niu, Shuqiong, Bianchi, Giacomo, Wei, Xufeng, Garimella, Narayana, Griffith, Bartley P., and Wu, Zhongjun J.

Subjects

ARTIFICIAL respiration, BIOCOMPATIBILITY, SHEEP as laboratory animals, BLOOD platelet activation, PULMONARY artery, SELECTINS, COMPARATIVE studies

Abstract

The purpose of this study was to assess the biocompatibility of a newly developed long-term wearable artificial pump-lung ( APL) in a clinically relevant ovine animal model. The wearable APL device was implanted in five sheep through left thoracotomy. The device was connected between the right atrium and pulmonary artery and evaluated for 30 days. Three sheep were used as the sham control. Platelet activation was assessed by measuring platelet surface P-selectin ( CD62 P) expression with flow cytometry and plasma soluble P-selectin with an enzyme-linked immunosorbent assay. Thrombotic deposition on the device components and hollow fiber membranes were analyzed with digital imaging and scanning electron microscopy. Surface P-selectin of the APL and sham groups changed significantly over the study period, but without significant differences between the two groups. Soluble P-selectin for the two groups peaked in the first 24 h after the surgery. Soluble P-selectin of the APL group remained slightly elevated over the study period compared to the presurgical baseline value and was slightly higher compared to that of the sham group. Plasma free hemoglobin remained in the normal ranges in all the animals. In spite of the surgery-related alteration in laboratory tests and elevation of platelet activation status, the APL devices in all the animals functioned normally (oxygen transfer and blood pumping) during the 30-day study period. The device flow path and membrane surface were free of gross thrombus. Electron microscopy images showed only scattered thrombi on the fibers (membrane surface and weft). In summary, the APL exhibited excellent biocompatibility. Two forms of platelet activation, surgery-related and device-induced, in the animals implanted with the wearable APL were observed. The limited device-induced platelet activation did not cause gross thrombosis and impair the long-term device performance. [ABSTRACT FROM AUTHOR]

Published

2013