Fabrication and <i>in vivo</i> thrombogenicity testing of nitric oxide generating artificial lungs

Amoako, Kagya A.; Montoya, P.; Major, Terry C.; Suhaib, Ahmed B.; Handa, Hitesh; Brant, David O.; Meyerhoff, Mark E.; Bartlett, Robert H.; Cook, Keith E.

doi:10.1002/jbm.a.34655

Cited by 27 publications

(30 citation statements)

References 27 publications

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“…Blood‐contacting medical devices typically fail in the long‐term due to clot formation. Significant advances have been made toward achieving materials capable of longer‐term use, including (1) heparin coatings to reduce thrombin generation, (2) various coatings that resist adsorption of plasma proteins, and (3) nitric oxide (NO) gas to reduce platelet activation . Each technology is inspired by a single mechanism of the rather multimodal approach used by the endothelium to control coagulation.…”

Section: Introductionmentioning

confidence: 99%

“…On their own, pCB grafted surfaces have shown undetectable nonspecific protein adsorption (<0.3 ng cm −2 ) from single‐protein solutions or complex media by surface plasmon resonance. NO releasing or generating surfaces are capable of reducing platelet adsorption by ≈40%, and markedly reduce clot formation in artificial lungs . Unfortunately, in applications requiring large surface‐area‐to‐volume ratios (e.g., artificial lungs and kidneys) or small bore architecture (vascular grafts), NO secretion or zwitterionic grafting alone may not be adequate to counter coagulation and preserve device function, particularly when device use of weeks to months is required.…”

Section: Introductionmentioning

confidence: 99%

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Multimodal, Biomaterial‐Focused Anticoagulation via Superlow Fouling Zwitterionic Functional Groups Coupled with Anti‐Platelet Nitric Oxide Release

Amoako

Sundaram

Suhaib

et al. 2016

Adv Materials Inter

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The functions of anti‐fouling, zwitterionic polycarboxybetaine (pCB) coating, and anti‐platelet nitric oxide (NO) release replicate key anticoagulant properties of the endothelium. The two approaches, only tested separately thus far, are paired on gas permeable polydimethylsiloxane (PDMS) membranes and evaluated for fibrinogen (Fg) and platelet adsorption. Uncoated (control) and pCB‐coated PDMS separate sheep plasma (108 platelets per milliliter) and gas flow chambers within bioreactors used in this study, and either 100 or 0 ppm of NO/N2 flows through the gas chamber so PDMS transfers NO into flowing plasma. Surface‐adsorbed platelets are quantified using a lactate dehydrogenase assay after 8h plasma recirculation. Fg and platelet adsorption on pCB‐coated PDMS are 10.40% ± 3.0% of control (p < 0.01) and 23.3% ± 7.4% (p < 0.01) of control, respectively. NO flux alone limits platelet adsorption to 79.0% ± 5.0% (p < 0.05) of control. Together, NO and pCB reduce platelet adsorption to 6.90% ± 1.30% of control (p < 0.001). The data suggest that pCB coating and NO act in concert to reduce platelet fouling at significantly higher levels than either pCB coating or NO release alone.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multimodal, Biomaterial‐Focused Anticoagulation via Superlow Fouling Zwitterionic Functional Groups Coupled with Anti‐Platelet Nitric Oxide Release

Amoako

Sundaram

Suhaib

et al. 2016

Adv Materials Inter

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“…The WBC and Plt were corrected for hemodilution using standard methods. 21 Mean arterial pressure (MAP) was recorded hourly from pressure transducers coupled with a patient monitor (Solar 8000, Marquette Electronics, Milwaukee, WI). CTAL blood inlet and outlet pressures were measured with pressure transducers (ICU Medical, San Clemente, CA) coupled with a data acquisition system (Biopac Systems, Goleta, CA), and cTAL flowrate was measured via an ultrasonic flow meter and probe (TS410 with 14PXL, Transonic, Ithaca, NY).…”

Section: Methodsmentioning

confidence: 99%

Fourteen Day In Vivo Testing of a Compliant Thoracic Artificial Lung

et al. 2017

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The compliant Thoracic Artificial Lung (cTAL) has been studied in acute in vivo and in vitro experiments. The cTAL’s long term function and potential use as a bridge to lung transplantation are assessed presently. The cTAL without anti-coagulant coatings was attached to sheep (n=5) via the pulmonary artery and left atrium for 14 days. Systemic heparin anticoagulation was utilized. cTAL resistance, cTAL gas exchange, hematologic parameters, and organ function were recorded. Two sheep were euthanized for non-device related issues. The cTAL’s resistance averaged 1.04±0.05 mmHg/(L/min) with no statistically significant increases. The cTAL transferred 180±8 mL/min of oxygen with 3.18±0.05 L/min of blood flow. Except for transient surgical effects, organ function markers were largely unchanged. Necropsies revealed pulmonary edema and atelectasis, but no other derangements. Hemoglobin levels dropped with device attachment but remained steady at 9.0±0.1 g/dL thereafter. In a fourteen day experiment, the cTAL without anti-coagulant coatings exhibited minimal clot formation. Sheep physiology was largely unchanged, except for device attachment related hemodilution. This suggests that patients treated with the cTAL shouldn’t require multiple blood transfusions. Once tested with anti-coagulant coatings and plasma resistant gas exchange fiber, the cTAL could serve as a bridge to transplantation.

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“…The next generation of devices will have surfaces which inhibit platelet adhesion to the surface, usually by causing platelet 'anesthesia' for those platelets which get very close to the surface. Currently, this is being done with nitric oxide eluting from the plastic [17,18]. The use of nitric oxide or similar materials to prevent platelet adhesion will greatly decrease the need for anticoagulation, and when combined with surface antifibrin chemicals, may eliminate the need for anticoagulation altogether.…”

Section: Anticoagulationmentioning

confidence: 97%

Current and future status of extracorporeal life support for respiratory failure in adults

Bartlett

Deatrick

2016

Current Opinion in Critical Care

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

Cited by 27 publications

References 27 publications

Multimodal, Biomaterial‐Focused Anticoagulation via Superlow Fouling Zwitterionic Functional Groups Coupled with Anti‐Platelet Nitric Oxide Release

Multimodal, Biomaterial‐Focused Anticoagulation via Superlow Fouling Zwitterionic Functional Groups Coupled with Anti‐Platelet Nitric Oxide Release

Fourteen Day In Vivo Testing of a Compliant Thoracic Artificial Lung

Current and future status of extracorporeal life support for respiratory failure in adults

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