A Membrane Lung Design Based on Circular Blood Flow Paths

Fernando, Uditha Piyumindri; Thompson, Alex J.; Potkay, Joseph A.; Cheriyan, Hannah; Toomasian, John M; Kaesler, Andreas; Schlanstein, Peter; Hirschl, Ronald B.; Bull, Joseph L.; Bartlett, Robert H.

doi:10.1097/mat.0000000000000616

Cited by 16 publications

(20 citation statements)

References 18 publications

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“…Computational flow dynamics and in vivo testing of this low-resistance device demonstrated that the mixing of blood as it traversed the gated compartments augmented O 2 transfer and sufficiently removed CO 2 at a rated flow of 2 L/min. 46 The compliant thoracic artificial lung consists of a flexible chamber containing a mat of hollow-fiber bundles through which blood is routed by means of inlet and outlet conduits, while fresh gas flows adjacently. 47 Initial animal experiments with this device showed that the load on the right ventricle could be reduced with the device positioned between the pulmonary artery and left atrium, and flows Ͼ 7 L/min could be achieved.…”

Section: Wearable Ecmomentioning

confidence: 99%

Technical Advances in the Field of ECMO

Betit¹

2018

Respir Care

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Although the fundamentals of extracorporeal membrane oxygenation (ECMO) have not changed in 3 decades, the technical elements continue to improve and have evolved from an assemblage of individual components to more integrated systems with added features, enhanced safety, and improved maneuverability. The introduction of polymethylpentene (PMP) fiber technology has expanded the development of artificial membranes that have low resistance, are more biocompatible, and can be used for extended durations. Extracorporeal carbon dioxide removal techniques continue to be enhanced as stand alone technology and modified renal dialysis systems are introduced. Research continues in the development of compact and wearable artificial lungs that are intended to support patients for prolonged periods (eg, patients awaiting lung transplantation). The use of high-fidelity simulation training has become a standard and important method for reinforcing technical skills, refining troubleshooting sequences, and enhancing team interactions. Modifications to mannequins and ECMO systems coupled with clinical and physiologic scenarios will help achieve greater realism and enhance learning. ECMO technology continues to improve, with adaptability and versatility being essential attributes.

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Section: Wearable Ecmomentioning

confidence: 99%

Technical Advances in the Field of ECMO

Betit¹

2018

Respir Care

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“…Data from our previous work were used to provide the necessary resistance data to simulate the fiber bundle as an isotropic porous media. 26 The experimental resistance data for the original fiber mat (17 fibers/cm) were scaled down linearly by multiplying by a factor κ κ LR , where κ LR is the predicted permeability of the low-resistance fiber mat (six fibers/cm) into equation 1. This provided the resistance data for the low-resistance fiber mat to be input into the porous media model for the CFD simulations.…”

Section: Computational Fluid Dynamicsmentioning

confidence: 99%

“…The required gas exchange SA for the current device was estimated by scaling our previous design, which had a SA = 0.28 m 2 and a rated flow of 2 L/min, but a pressure drop of approximately 100 mm Hg. 26 Scaling down SA linearly (assuming equivalent gas exchange efficiency in the previous and new designs) gave a basis SA of 0.1 m 2 for the new design because this SA is expected to provide the necessary gas exchange to satisfy the rated flow requirement. Blood flow was simulated using the Solidworks Flow Simulation add-in (Dassault Systémes), and velocity and pressure profiles were generated (Figure 2).…”

Section: Computational Fluid Dynamicsmentioning

confidence: 99%

“…At 0.75 L/min, pressure drop in a single-inlet MLung using a fiber mat with 17 fibers/cm and a fiber length of 2 cm was 38 mm Hg (from previous work). 26 To further reduce pressure drop, three changes were made from the previously published design (Table 1): 1) the use of a dual-inlet design; 2) fiber length increased to 3 cm; and 3) reduction of the fiber bundle porosity by using a low-density fiber mat (six fibers/cm). Each of these changes independently reduces pressure drop, and when the fiber bundle is modeled as an isotropic porous media, a pressure drop of 2 mm Hg is predicted at a flow rate of 0.75 L/min.…”

Section: Computational Fluid Dynamicsmentioning

confidence: 99%

“…[21][22][23][24][25] Recently, we demonstrated a membrane lung based on a series of concentric gates, resulting in a circular blood flow path that induces secondary flows, disrupting the boundary layer, and improving overall gas exchange. 26 Based on our previous work, this study aims for designing a new AL that provides adequate gas exchange and pressure drop for pediatric patients.…”

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Low-Resistance, Concentric-Gated Pediatric Artificial Lung for End-Stage Lung Failure

et al. 2020

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Children with end-stage lung failure awaiting lung transplant would benefit from improvements in artificial lung technology allowing for wearable pulmonary support as a bridge-to-transplant therapy. In this work, we designed, fabricated, and tested the Pediatric MLung-a dual-inlet hollow fiber artificial lung based on concentric gating, which has a rated flow of 1 L/min, and a pressure drop of 25 mm Hg at rated flow. This device and future iterations of the current design are designed to relieve pulmonary arterial hypertension, provide pulmonary support, reduce ventilator-associated injury, and allow for more effective therapy of patients with end-stage lung disease, including bridge-to-transplant treatment. Keywords extracorporeal life support; hollow fiber oxygenator; wearable artificial lung One in five children with end-stage lung failure (ESLF) die while awaiting transplant. 1 Hollow fiber oxygenators or artificial lungs (ALs) are commonly used to provide pulmonary support in acute and bridge-to-transplant applications. In these devices, blood flows around a bundle of hollow fibers, while a sweep gas supplied to the fibers' lumens facilitates gas transfer via diffusion through the fiber wall. The benefits of a particular AL depend on the design properties and engineering of the AL, and device development must be thoughtfully targeted to the intended patient population to achieve optimal results. In this work, we design, fabricate, and test the performance of a paracorporeal, pumpless device intended for pediatric patients. This device, called the "Pediatric MLung," can be used as a bridge to transplant for children with ESLF.

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Physiology of Extracorporeal Gas Exchange

Bartlett

2020

Comprehensive Physiology

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A Membrane Lung Design Based on Circular Blood Flow Paths

Cited by 16 publications

References 18 publications

Technical Advances in the Field of ECMO

Technical Advances in the Field of ECMO

Low-Resistance, Concentric-Gated Pediatric Artificial Lung for End-Stage Lung Failure

Physiology of Extracorporeal Gas Exchange

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