Your search keyword '"Cook, Keith E."' showing total 6 results

1. Establishment and evaluation of a rat model of extracorporeal membrane oxygenation (ECMO) thrombosis using a 3D-printed mock-oxygenator.

Author

Umei N, Lai A, Miller J, Shin S, Roberts K, Ai Qatarneh S, Ichiba S, Sakamoto A, and Cook KE

Subjects

Animals, Heparin pharmacology, Oxygenators, Printing, Three-Dimensional, Rats, Extracorporeal Membrane Oxygenation, Thrombosis

Abstract

Background: Extracorporeal membrane oxygenation (ECMO) research using large animals requires a significant amount of resources, slowing down the development of new means of ECMO anticoagulation. Therefore, this study developed and evaluated a new rat ECMO model using a 3D-printed mock-oxygenator., Methods: The circuit consisted of tubing, a 3D-printed mock-oxygenator, and a roller pump. The mock-oxygenator was designed to simulate the geometry and blood flow patterns of the fiber bundle in full-scale oxygenators but with a low (2.5 mL) priming volume. Rats were placed on arteriovenous ECMO at a 1.9 mL/min flow rate at two different heparin doses (n = 3 each): low (15 IU/kg/h for eight hours) versus high (50 IU/kg/h for one hour followed by 25 IU/kg/h for seven hours). The experiment continued for eight hours or until the mock-oxygenator failed. The mock-oxygenator was considered to have failed when its blood flow resistance reached three times its baseline resistance., Results: During ECMO, rats maintained near-normal mean arterial pressure and arterial blood gases with minimal hemodilution. The mock-oxygenator thrombus weight was significantly different (p < 0.05) between the low (0.02 ± 0.006 g) and high (0.003 ± 0.001 g) heparin delivery groups, and blood flow resistance was also larger in the low anticoagulation group., Conclusions: This model is a simple, inexpensive system for investigating new anticoagulation agents for ECMO and provides low and high levels of anticoagulation that can serve as control groups for future studies.

Published

2021

2. Cyclic peptide FXII inhibitor provides safe anticoagulation in a thrombosis model and in artificial lungs.

Author

Wilbs J, Kong XD, Middendorp SJ, Prince R, Cooke A, Demarest CT, Abdelhafez MM, Roberts K, Umei N, Gonschorek P, Lamers C, Deyle K, Rieben R, Cook KE, Angelillo-Scherrer A, and Heinis C

Subjects

Animals, Chlorides adverse effects, Cloning, Molecular, Disease Models, Animal, Drug Discovery, Extracorporeal Membrane Oxygenation methods, Factor XII antagonists & inhibitors, Female, Ferric Compounds adverse effects, Humans, Lung, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Rabbits, Recombinant Proteins pharmacology, Swine, Anticoagulants pharmacology, Blood Coagulation drug effects, Factor XIIa antagonists & inhibitors, Peptides, Cyclic drug effects, Thrombosis prevention & control

Abstract

Inhibiting thrombosis without generating bleeding risks is a major challenge in medicine. A promising solution may be the inhibition of coagulation factor XII (FXII), because its knock-out or inhibition in animals reduced thrombosis without causing abnormal bleeding. Herein, we have engineered a macrocyclic peptide inhibitor of activated FXII (FXIIa) with sub-nanomolar activity (K i  = 370 ± 40 pM) and a high stability (t 1/2  > 5 days in plasma), allowing for the preclinical evaluation of a first synthetic FXIIa inhibitor. This 1899 Da molecule, termed FXII900, efficiently blocks FXIIa in mice, rabbits, and pigs. We found that it reduces ferric-chloride-induced experimental thrombosis in mice and suppresses blood coagulation in an extracorporeal membrane oxygenation (ECMO) setting in rabbits, all without increasing the bleeding risk. This shows that FXIIa activity is controllable in vivo with a synthetic inhibitor, and that the inhibitor FXII900 is a promising candidate for safe thromboprotection in acute medical conditions.

Published

2020

3. Zwitterionic poly-carboxybetaine coating reduces artificial lung thrombosis in sheep and rabbits.

Author

Ukita R, Wu K, Lin X, Carleton NM, Naito N, Lai A, Do-Nguyen CC, Demarest CT, Jiang S, and Cook KE

Subjects

Animals, Blood Platelets drug effects, Blood Platelets metabolism, Fibrin metabolism, Lung drug effects, Photoelectron Spectroscopy, Rabbits, Sheep, Surface Properties, Betaine pharmacology, Coated Materials, Biocompatible pharmacology, Lung pathology, Thrombosis pathology

Abstract

Current artificial lungs fail in 1-4 weeks due to surface-induced thrombosis. Biomaterial coatings may be applied to anticoagulate artificial surfaces, but none have shown marked long-term effectiveness. Poly-carboxybetaine (pCB) coatings have shown promising results in reducing protein and platelet-fouling in vitro. However, in vivo hemocompatibility remains to be investigated. Thus, three different pCB-grafting approaches to artificial lung surfaces were first investigated: 1) graft-to approach using 3,4-dihydroxyphenylalanine (DOPA) conjugated with pCB (DOPA-pCB); 2) graft-from approach using the Activators ReGenerated by Electron Transfer method of atom transfer radical polymerization (ARGET-ATRP); and 3) graft-to approach using pCB randomly copolymerized with hydrophobic moieties. One device coated with each of these methods and one uncoated device were attached in parallel within a veno-venous sheep extracorporeal circuit with no continuous anticoagulation (N = 5 circuits). The DOPA-pCB approach showed the least increase in blood flow resistance and the lowest incidence of device failure over 36-hours. Next, we further investigated the impact of tip-to-tip DOPA-pCB coating in a 4-hour rabbit study with veno-venous micro-artificial lung circuit at a higher activated clotting time of 220-300 s (N ≥ 5). Here, DOPA-pCB reduced fibrin formation (p = 0.06) and gross thrombus formation by 59% (p < 0.05). Therefore, DOPA-pCB is a promising material for improving the anticoagulation of artificial lungs. STATEMENT OF SIGNIFICANCE: Chronic lung diseases lead to 168,000 deaths each year in America, but only 2300 lung transplantations happen each year. Hollow fiber membrane oxygenators are clinically used as artificial lungs to provide respiratory support for patients, but their long-term viability is hindered by surface-induced clot formation that leads to premature device failure. Among different coatings investigated for blood-contacting applications, poly-carboxybetaine (pCB) coatings have shown remarkable reduction in protein adsorption in vitro. However, their efficacy in vivo remains unclear. This is the first work that investigates various pCB-coating methods on artificial lung surfaces and their biocompatibility in sheep and rabbit studies. This work highlights the promise of applying pCB coatings on artificial lungs to extend its durability and enable long-term respiratory support for lung disease patients., (Copyright © 2019 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2019

4. Fabrication and in vivo thrombogenicity testing of nitric oxide generating artificial lungs.

Author

Amoako KA, Montoya PJ, Major TC, Suhaib AB, Handa H, Brant DO, Meyerhoff ME, Bartlett RH, and Cook KE

Subjects

Animals, Blood Cell Count, Blood Platelets metabolism, Copper blood, Fibrinogen metabolism, Hemodynamics, Lung blood supply, Lung ultrastructure, Rabbits, Regional Blood Flow, S-Nitrosothiols metabolism, Time Factors, Artificial Organs, Lung pathology, Nitric Oxide metabolism, Thrombosis metabolism, Tissue Engineering methods

Abstract

Hollow fiber artificial lungs are increasingly being used for long-term applications. However, clot formation limits their use to 1-2 weeks. This study investigated the effect of nitric oxide generating (NOgen) hollow fibers on artificial lung thrombogenicity. Silicone hollow fibers were fabricated to incorporate 50 nm copper particles as a catalyst for NO generation from the blood. Fibers with and without (control) these particles were incorporated into artificial lungs with a 0.1 m(2) surface area and inserted in circuits coated tip-to-tip with the NOgen material. Circuits (N = 5/each) were attached to rabbits in a pumpless, arterio-venous configuration and run for 4 h at an activated clotting time of 350-400 s. Three control circuits clotted completely, while none of the NOgen circuits failed. Accordingly, blood flows were significantly higher in the NOgen group (95.9 ± 11.7, p < 0.01) compared to the controls (35.2 ± 19.7; mL/min), and resistance was significantly higher in the control group after 4 h (15.38 ± 9.65, p < 0.001) than in NOgen (0.09 ± 0.03; mmHg/mL/min). On the other hand, platelet counts and plasma fibrinogen concentration expressed as percent of baseline in control group (63.7 ± 5.7%, 77.2 ± 5.6%; p < 0.05) were greater than those in the NOgen group (60.4 ± 5.1%, 63.2 ± 3.7%). Plasma copper levels in the NOgen group were 2.8 times baseline at 4 h (132.8 ± 4.5 μg/dL) and unchanged in the controls. This study demonstrates that NO generating gas exchange fibers could be a potentially effective way to control coagulation inside artificial lungs., (Copyright © 2013 Wiley Periodicals, Inc., a Wiley Company.)

Published

2013

5. Nitric oxide-generating silicone as a blood-contacting biomaterial.

Author

Amoako KA and Cook KE

Subjects

Biocompatible Materials adverse effects, Biocompatible Materials chemistry, Luminescent Measurements, Prostheses and Implants adverse effects, Copper chemistry, Materials Testing, Nitric Oxide, Silicones chemistry, Thrombosis prevention & control

Abstract

Coagulation upon blood-contacting biomaterials remains a problem for short- and long-term clinical applications. This study examined the ability of copper(II)-doped silicone surfaces to generate nitric oxide (NO) and locally inhibit coagulation. Silicone was doped with 3-μm copper [Cu(0)] particles yielding 3 to 10 weight percent (wt%) Cu in 70-μm thick Cu/silicone polymeric matrix composites (Cu/Si PMCs). At 3, 5, 8, and 10 wt% Cu doping, the surface expression of Cu was 12.1% ± 2.8%, 19.7% ± 5.4%, 29.0% ± 3.8%, and 33.8% ± 6.5%, respectively. After oxidizing Cu(0) to Cu(II) by spontaneous corrosion, NO flux, J(NO) (mol · cm(-2) · min(-1)), as measured by chemiluminescence, increased with surface Cu expression according to the relationship J(NO) = (1.63%SA(Cu) - 0.81) × 10(-11), R(2) = 0.98, where %SA(Cu) is the percentage of surface occupied by Cu. NO flux at 10 wt% Cu was 5.35 ± 0.74 × 10(-10) mol · cm(-2) · min(-1). The clotting time of sheep blood exposed to these surfaces was 80 ± 13 seconds with pure silicone and 339 ± 44 seconds when 10 wt% Cu(II) was added. Scanning electron microscopies (SEMs) of coatings showed clots occurred away from exposed Cu dendrites. In conclusion, Cu/Si PMCs inhibit coagulation in a dose-dependent fashion related to the extent of copper exposure on the coated surface.

Published

2011

6. Effect of artificial lung fiber bundle geometric design on micro‐ and macro‐scale clot formation.

Author

Lai, Angela, Omori, Natsuha, Napolitano, Julia E., Antaki, James F., and Cook, Keith E.

Subjects

OXYGENATORS, SYNTHETIC fibers, THROMBOSIS, FLOW velocity, BLOOD flow

Abstract

The hollow fiber membrane bundle is the functional component of artificial lungs, transferring oxygen to and carbon dioxide from the blood. It is also the primary location of blood clot formation and propagation in these devices. The geometric design of fiber bundles is defined by a narrow set of parameters that determine gas exchange efficiency and blood flow resistance, principally: fiber packing density, path length, and frontal area. These same parameters also affect thrombosis. This study investigated the effect of these parameters on clot formation using 3D printed flow chambers that mimic the geometry and blood flow patterns of fiber bundles. Hollow fibers were represented by an array of vertical micro‐rods (380 μm diameter) arranged with three packing densities (40%, 50%, and 60%) and two path lengths (2 and 4 cm). Blood was pumped through these devices corresponding to three mean blood flow velocities (16, 20, and 25 cm/min). Results showed that (1) clot formation decreases dramatically with decreasing packing density and increasing blood flow velocity, (2) clot formation at the outlet of the fiber bundle enhances deposition upstream, and consequently (3) greater path length provides greater clot‐free fiber surface area for gas exchange than a shorter path length. These results can help guide the design of less thrombogenic, more efficient artificial lung designs. [ABSTRACT FROM AUTHOR]

Published

2024