Your search keyword '"artificial lung"' showing total 245 results

1. Toward a Servoregulation Controller to Automate CO2 Removal in Wearable Artificial Lungs

Author

William R. Lynch, Joseph A. Potkay, John M. Toomasian, Alex J. Thompson, Robert H. Bartlett, and Alvaro Rojas-Pena

Subjects

Materials science, Flow (psychology), Biomedical Engineering, Biophysics, Wearable computer, PID controller, Bioengineering, Article, Artificial lung, Biomaterials, Wearable Electronic Devices, Extracorporeal Membrane Oxygenation, Control theory, Co2 removal, Animals, Humans, Lung, Sheep, Exhaust gas, General Medicine, Carbon Dioxide, Respiration, Artificial, Control system, Cattle, Blood Gas Analysis, Biomedical engineering

Abstract

A laptop-driven, benchtop control system that automatically adjusts carbon dioxide (CO(2)) removal in artificial lungs is described. The proportional-integral-derivative (PID) feedback controller modulates pump-driven air sweep gas flow through an artificial lung to achieve a desired exhaust gas CO(2) partial pressure (EGCO(2)). When EGCO(2) increases, the servoregulator automatically and rapidly increases sweep flow to remove more CO(2). If EGCO(2) decreases, the sweep flow decreases to reduce CO(2) removal. System operation was tested for 6 hr in-vitro using bovine blood and in-vivo in three proof-of-concept sheep experiments. In all studies, the controller automatically adjusted the sweep gas flow to rapidly (

Published

2021

2. Exogenous surfactant in the late respiratory phase of COVID-19

Author

K. G. Shapovalov, S. А. Lukyanov, V. А. Konnov, and O. А. Rozenberg

Subjects

Insufflation, RC705-779, Inhalation, business.industry, respiratory failure, 030208 emergency & critical care medicine, General Medicine, medicine.disease, Artificial lung, Diseases of the respiratory system, 03 medical and health sciences, Pneumonia, Nebulizer, 0302 clinical medicine, covid-19, 030228 respiratory system, Respiratory failure, Pulmonary surfactant, Anesthesia, native surfactant, medicine, Breathing, late respiratory phase, pneumonia, business

Abstract

The article presents data on the course of inhalations with a native surfactant administered in two patients (66 and 53 years old) at the late respiratory phase of the new coronavirus infection of COVID-19 (the 22nd and the 19th days from the disease onset) who received non-invasive artificial lung ventilation.Subjects and methods.For inhalations, an AeroNeb™ micropump nebulizer was used; for one inhalation, 75 mg of surfactant-BL was dissolved in 5 ml of isotonic sodium chloride solution. The treatment course included 5 days with 2 inhalations a day.Results.In both patients, upon the end of this therapy with the native surfactant, regression of respiratory failure was noted, the level of respiratory support was reduced to insufflation with humidified oxygen, and rehabilitation measures were started with subsequent discharge from the hospital.

Published

2021

3. SYSVENT: Prova de Conceito de um Protótipo para Ventilar Doentes em Cuidados Intensivos

Author

Nuno Cortesão, Marco Fernandes, José Vale Machado, António H Carneiro, F. L. Fernandes, and Danielson Pina

Subjects

medicine.medical_specialty, Spectrum analyzer, business.industry, Context (language use), General Medicine, Artificial lung, law.invention, Volume (thermodynamics), Proof of concept, law, Intensive care, Emergency medicine, Ventilation (architecture), medicine, business, Tidal volume

Abstract

Introdução: A pandemia pelo novo coronavírus provocou rotura em hospitais de vários países por falta de recursos para ventilaçãoinvasiva. Assim, a Ordem dos Médicos convidou intensivistas que, em colaboração com a SYSADVANCE S.A., desenvolveram o SYSVENT OM1, um ventilador capaz de operar em modos controlados e assistidos (volume e pressão) e apto para tratar doentes em cuidados intensivos. Neste estudo fazemos a prova de conceito, comparando volume-corrente, pressão inspiratória e pressão positiva tele-expiratória programados, com os valores medidos pelo ventilador e por um equipamento de medição externo.Material e Métodos: Montámos o ventilador em série com um pulmão artificial e um analisador de fluxos. Medimos o volume-corrente expiratório e a pressão inspiratória, em três níveis de compliance e seis patamares de volume-corrente. A pressão positiva tele-expiratória foi medida com incrementos de 2 cmH2O ao longo de oito patamares. Para cada medição realizámos três leituras.Resultados: Considerando cada uma das três variáveis isoladamente, a média da diferença máxima entre os valores programados e os valores medidos situa-se, para todas elas, dentro do que considerámos ser aceitável para um modelo protótipo (volume-corrente = -28,1 mL, pressão inspiratória = 0,8 cmH2O e pressão positiva tele-expiratória = -1,1 cmH2O). Essa diferença é maior quando avaliada com o equipamento de medição externa comparativamente com o ventilador.Discussão: Os resultados mostraram uma boa capacidade de monitorização e de precisão. Documentaram-se limitações técnicas relacionadas com o pulmão artificial e com o analisador de fluxos que não desvirtuam os resultados, mas limitam a sua amplitude.Conclusão: Para os parâmetros testados, o ventilador apresenta boa performance de funcionamento, está de acordo com as premissasiniciais e tem potencial para uso clínico.

Published

2021

4. First in vivo assessment of RAS-Q technology as lung support device for pulmonary hypertension

Author

Bart Meyns, Michael Halwes, and Tom Verbelen

Subjects

Technology, Pulmonary Circulation, Medicine (miscellaneous), Hemodynamics, 030204 cardiovascular system & hematology, BRIDGE, Engineering, 0302 clinical medicine, DESIGN, Original Research Articles, Medicine, Cardiac Assist Devices and Artificial Heart, General Medicine, ATTACHMENT, oxygenator, medicine.anatomical_structure, gas exchanger, Cardiology, Female, Life Sciences & Biomedicine, medicine.medical_specialty, ARTIFICIAL LUNG, Hypertension, Pulmonary, Biomedical Engineering, OVERLOADED RIGHT VENTRICLE, Bioengineering, Heart-Lung Machine, Oxygenators, compliance, Artificial lung, Pulmonary hypertension, Biomaterials, 03 medical and health sciences, In vivo, Internal medicine, Animals, Humans, right ventricular unloading, Engineering, Biomedical, Transplantation, Science & Technology, Sheep, Lung, Pulmonary Gas Exchange, business.industry, medicine.disease, Compliance (physiology), 030228 respiratory system, Ventricle, Ventricular Function, Right, business

Abstract

Objectives: To assess the in vivo hemodynamic effects on the pressure overloaded right ventricle of RAS-Q® technology, the world’s first gas exchanger with a fully integrated compliance. Methods: In six acute in vivo trials RAS-Q was implanted in sheep between the pulmonary artery and left atrium. Right ventricular pressure overload was induced by pulmonary artery banding. Pressures and flows were recorded in baseline, moderate and severe pulmonary hypertension conditions. In one trial, RAS-Q was benchmarked against the pediatric Quadrox-i®. Results: With 1.00 and 1.17 L/min, RAS-Q delivered 31% and 39% of the total cardiac output in moderate and severe pulmonary hypertension, respectively. Pulmonary artery pressures and mean pulmonary artery pressure/mean arterial blood pressure ratio successfully decreased, implying a successful right ventricular unloading. Cardiac output was restored to normal levels in both pulmonary hypertension conditions. With both devices in parallel, RAS-Q provided three times higher flow rates and a 10 times higher pressure relief, compared to the pediatric Quadrox-i. Conclusion: A gas exchanger with a fully integrated compliance better unloads the right ventricle compared to a non-compliant gas exchanger and it can restore cardiac output to normal levels in cases of severe pulmonary hypertension.

Published

2020

5. Toward a Long-Term Artificial Lung

Author

Thomas Schmitz-Rode, Hans Peter Wendel, Rolf Rossaint, Jutta Arens, Oliver Grottke, Axel Haverich, Lars S. Maier, and Ulrich Steinseifer

Subjects

lung support, Computer science, lung assist, structural integration, Biomedical Engineering, Biophysics, Bioengineering, Economic shortage, Review Article, 030204 cardiovascular system & hematology, implantable artificial lung, In vivo tests, in vitro verification, Artificial lung, Biomaterials, miniaturization, 03 medical and health sciences, 0302 clinical medicine, anticoagulation regimes, biocompatibility, in silico analysis, Animals, Humans, Lung, artificial lung, General Medicine, Limiting, hemocompatibility, Clot formation, Transplantation, 030228 respiratory system, Risk analysis (engineering), in vivo validation, Artificial Organs, ECMO, Destination therapy

Abstract

Only a very small portion of end-stage organ failures can be treated by transplantation because of the shortage of donor organs. Although artificial long-term organ support such as ventricular assist devices provide therapeutic options serving as a bridge-to-transplantation or destination therapy for end-stage heart failure, suitable long-term artificial lung systems are still at an early stage of development. Although a short-term use of an extracorporeal lung support is feasible today, the currently available technical solutions do not permit the long-term use of lung replacement systems in terms of an implantable artificial lung. This is currently limited by a variety of factors: biocompatibility problems lead to clot formation within the system, especially in areas with unphysiological flow conditions. In addition, proteins, cells, and fibrin are deposited on the membranes, decreasing gas exchange performance and thus, limiting long-term use. Coordinated basic and translational scientific research to solve these problems is therefore necessary to enable the long-term use and implantation of an artificial lung. Strategies for improving the biocompatibility of foreign surfaces, for new anticoagulation regimes, for optimization of gas and blood flow, and for miniaturization of these systems must be found. These strategies must be validated by in vitro and in vivo tests, which remain to be developed. In addition, the influence of long-term support on the pathophysiology must be considered. These challenges require well-connected interdisciplinary teams from the natural and material sciences, engineering, and medicine, which take the necessary steps toward the development of an artificial implantable lung.

Published

2020

6. Assessing and improving the biocompatibility of microfluidic artificial lungs

Author

Joseph A. Potkay, Marcus J. Goudie, Alex J. Thompson, Orsolya Lautner-Csorba, Mark M.P. Jeakle, Hitesh Handa, Terry C. Major, Alvaro Rojas-Pena, and Lindsay J. Ma

Subjects

Blood Platelets, Biocompatibility, Microfluidics, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Polyethylene glycol, Biochemistry, Article, Artificial lung, Nitric oxide, Biomaterials, chemistry.chemical_compound, In vivo, PEG ratio, Animals, Humans, Platelet activation, Lung, Molecular Biology, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Surface coating, chemistry, Quality of Life, Rabbits, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions, Biotechnology, Biomedical engineering

Abstract

Microfluidic artificial lungs (µALs) have the potential to improve the treatment and quality of life for patients with acute or chronic lung injury. In order to realize the full potential of this technology (including as a destination therapy), the biocompatibility of these devices needs to be improved to produce long-lasting devices that are safe for patient use with minimal or no systemic anticoagulation. Many studies exist which probe coagulation and thrombosis on polydimethyl siloxane (PDMS) surfaces, and many strategies have been explored to improve surface biocompatibility. As the field of µALs is young, there are few studies which investigate biocompatibility of functioning µALs; and even fewer which were performed in vivo. Here, we use both in vitro and in vivo models to investigate two strategies to improve µAL biocompatibility: 1) a hydrophilic surface coating (polyethylene glycol, PEG) to prevent surface fouling, and 2) the addition of nitric oxide (NO) to the sweep gas to inhibit platelet activation locally within the µAL. In this study, we challenge µALs with clottable blood or platelet-rich plasma (PRP) and monitor the resistance to blood flow over time. Device lifetime (the amount of time the µAL remains patent and unobstructed by clot) is used as the primary indicator of biocompatibility. This study is the first study to: 1) investigate the effect of NO release on biocompatibility in a microfluidic network; 2) combine a hydrophilic PEG coating with NO release to improve blood compatibility; and 3) perform extended in vivo biocompatibility testing of a µAL. We found that µALs challenged in vitro with PRP remained patent significantly longer when the sweep gas contained NO than without NO. In the in vivo rabbit model, neither approach alone (PEG coating nor NO sweep gas) significantly improved biocompatibility compared to controls (though with larger sample size significance may become apparent); while the combination of a PEG coating with NO sweep gas resulted in significant improvement of device lifetime. STATEMENT OF SIGNIFICANCE: The development of microfluidic artificial lungs (µALs) can potentially have a massive impact on the treatment of patients with acute and chronic lung impairments. Before these devices can be deployed clinically, the biocompatibility of µALs must be improved and more comprehensively understood. This work explores two strategies for improving biocompatibility, a hydrophilic surface coating (polyethylene glycol) for general surface passivation and the addition of nitric oxide (NO) to the sweep gas to quell platelet and leukocyte activation. These two strategies are investigated separately and as a combined device treatment. Devices are challenged with clottable blood using in vitro testing and in vivo testing in rabbits. This is the first study to our knowledge that allows statistical comparisons of biocompatible µALs in animals, a key step towards eventual clinical use.

Published

2020

7. Effect of Hematocrit on the CO2 Removal Rate of Artificial Lungs

Author

Katelin S. Omecinski, William J. Federspiel, Brian J. Frankowski, and Alexandra G. May

Subjects

Extracorporeal Circulation, medicine.medical_specialty, ARDS, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Hematocrit, Article, Artificial lung, Extracorporeal, Biomaterials, Pulmonary Disease, Chronic Obstructive, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, Co2 removal, medicine, Animals, Lung, Saline, Respiratory Distress Syndrome, COPD, Noninvasive Ventilation, medicine.diagnostic_test, business.industry, General Medicine, Carbon Dioxide, medicine.disease, medicine.anatomical_structure, 030228 respiratory system, Cardiology, Cattle, Artificial Organs, business, human activities, circulatory and respiratory physiology

Abstract

Extracorporeal CO(2) removal (ECCO(2)R) can permit lung protective or noninvasive ventilation strategies in patients with chronic obstructive pulmonary disease (COPD) and acute respiratory distress syndrome (ARDS). With evidence supporting ECCO(2)R growing, investigating factors which affect CO(2) removal is necessary. Multiple factors are known to affect the CO(2) removal rate (vCO(2)) which can complicate the interpretation of changes in vCO(2); however, the effect of hematocrit on the vCO(2) of artificial lungs has not been investigated. This in vitro study evaluates the relationship between hematocrit level and vCO(2) within an ECCO(2)R device. In vitro gas transfer was measured in bovine blood in accordance with the ISO 7199 standard. Plasma and saline were used to hemodilute the blood to hematocrits between 33% and 8%. The vCO(2) significantly decreased as the blood was hemodiluted with saline and plasma by 42% and 32%, respectively, between a hematocrit of 33% and 8%. The hemodilution method did not significantly affect the vCO(2). In conclusion, the hematocrit level significantly affects vCO(2) and should be taken into account when interpreting changes in the vCO(2) of an ECCO(2)R device.

Published

2020

8. Advancing Front Oxygen Transfer Model for the Design of Microchannel Artificial Lungs

Author

Keith E. Cook, Rei Ukita, Joseph A. Potkay, and Khalil Khanafer

Subjects

Oxygen transfer, Microchannel, Biomedical Engineering, Biophysics, Bioengineering, Equipment Design, General Medicine, Mechanics, 030204 cardiovascular system & hematology, Models, Biological, Respiratory support, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, 030228 respiratory system, Volume (thermodynamics), Shear stress, Artificial Organs, Lung, Mathematics

Abstract

Microchannel artificial lungs may provide highly efficient, long-term respiratory support, but a robust predictive oxygen transfer (VO2) model is needed to better design them. To meet this need, we first investigated the predictive accuracy of Mikic, Benn, and Drinker's advancing front (AF) oxygen transfer theory by applying it to previous microchannel lung studies. Here, the model that included membrane resistance showed no bias toward overprediction or underprediction of VO2 (median error: -1.13%, interquartile range: [-26.9%, 19.2%]) and matched closely with existing theory. Next, this theory was expanded into a general model for investigating a family of designs. The overall model suggests that, for VO2 = 100 ml/min, fraction of delivered oxygen (FDO2) = 40%, wall shear stress ((Equation is included in full-text article.)) = 30 dyn/cm, and blood channel height = 20-50 μm, a compact design can be achieved with priming volume ((Equation is included in full-text article.)) = 5.8-32 ml; however, manifolding may be challenging to satisfy the rigorous total width ((Equation is included in full-text article.)) requirement ((Equation is included in full-text article.)= 76-475 m). In comparison, 100-200 μm heights would yield larger dimensions ((Equation is included in full-text article.)122-478 ml) but simpler manifolding ((Equation is included in full-text article.)4.75-19.0 m). The device size can be further adjusted by varying FDO2, (Equation is included in full-text article.), or VO2. This model may thus serve as a simple yet useful tool to better design microchannel artificial lungs.

Published

2020

9. Three‐dimensional Membranes for Artificial Lungs: Comparison of Flow‐Induced Hemolysis

Author

Matthias Wessling, Daniel Arnemann, Ulrich Steinseifer, Jutta Arens, Christian Cornelissen, Felix Hesselmann, Patrick Bongartz, Thomas Schmitz-Rode, Sebastian V. Jansen, TechMed Centre, and Biomechanical Engineering

Subjects

Materials science, In vitro test, Biomedical Engineering, Medicine (miscellaneous), Three-dimensional membrane, Bioengineering, Hemolysis, Artificial lung, Biomaterials, TPMS, Pressure loss, medicine, Humans, Fiber, Lung, Pressure drop, Laminar flow, Membranes, Artificial, General Medicine, Equipment Design, medicine.disease, Membrane, Hollow fiber membrane, Printing, Three-Dimensional, Artificial Organs, Biomedical engineering, Gyroid

Abstract

Artificial organs 46(3), 412-426 (2022). doi:10.1111/aor.14081, Published by Wiley-Blackwell, Oxford [u.a.]

Published

2022

10. A pumpless artificial lung without systemic anticoagulation: The Nitric Oxide Surface Anticoagulation system

Author

Brian P. Fallon, Adrianna Kayden, Alvaro Rojas Pena, Robert H. Bartlett, Alex J. Thompson, Gergely Lautner, Mark W. Langley, Ronald B. Hirschl, Orsolya Lautner-Csorba, Matthew D. Johnson, and Stephen L Harvey

Subjects

medicine.medical_specialty, medicine.medical_treatment, Activated clotting time, Nitric Oxide, Extracorporeal, Argatroban, Artificial lung, Article, Extracorporeal Membrane Oxygenation, Internal medicine, medicine.artery, medicine, Extracorporeal membrane oxygenation, Animals, Humans, Platelet activation, Child, Lung, Sheep, medicine.diagnostic_test, business.industry, Anticoagulants, General Medicine, Blood flow, Oxygen Saturation, Pediatrics, Perinatology and Child Health, Pulmonary artery, Cardiology, Surgery, business, medicine.drug

Abstract

Background Artificial lungs have the potential to serve as a bridge to transplantation or recovery for children with end-stage lung disease dependent on extracorporeal life support, but such devices currently require systemic anticoagulation. We describe our experience using the novel Nitric Oxide (NO) Surface Anticoagulation (NOSA) system—an NO-releasing circuit with NO in the sweep gas—with the Pediatric MLung—a low-resistance, pumpless artificial lung. Methods NO flux testing: MLungs (n = 4) were tested using veno-venous extracorporeal life support in a sheep under anesthesia with blood flow set to 0.5 and 1 L/min and sweep gas blended with 100 ppm NO at 1, 2, and 4 L/min. NO and NO2 were measured in the sweep and exhaust gas to calculate NO flux across the MLung membrane. Pumpless implants: Sheep (20–100 kg, n = 3) underwent thoracotomy and cannulation via the pulmonary artery (device inflow) and left atrium (device outflow) using cannulae and circuit components coated with an NO donor (diazeniumdiolated dibutylhexanediamine; DBHD-N2O2) and argatroban. Animals were connected to the MLung with 100 ppm NO in the sweep gas under anesthesia for 24 h with no systemic anticoagulation after cannulation. Results NO flux testing: NO flux averaged 3.4 ± 1.0 flux units (x10−10 mol/cm2/min) (human vascular endothelium: 0.5–4 flux units). Pumpless implants: 3 sheep survived 24 h with patent circuits. MLung blood flow was 716 ± 227 mL/min. Outlet oxygen saturation was 98.3 ± 2.6%. Activated clotting time was 151±24 s. Platelet count declined from 334,333 ± 112,225 to 123,667 ± 7,637 over 24 h. Plasma free hemoglobin and leukocyte and platelet activation did not significantly change. Conclusions The NOSA system provides NO flux across a gas-exchange membrane of a pumpless artificial lung at a similar rate as native vascular endothelium and achieves effective local anticoagulation of an artificial lung circuit for 24 h.

Published

2021

11. Study of the effectiveness of using decamethoxin-based antiseptic compositions for treating endotracheal tubes in order to prevent the development of ventilator-associated pneumonia in intensive care patients

Author

A. V. Kulik, O. I. Zhorniak, V. M. Burkot, N. S. Fomina, P. V. Zhorniak, and Y. Y. Trofimenko

Subjects

medicine.drug_class, business.industry, Septic shock, Ventilator-associated pneumonia, General Medicine, Antimicrobial, medicine.disease, Intensive care unit, Artificial lung, law.invention, Pneumonia, Antiseptic, law, Anesthesia, Intensive care, medicine, business

Abstract

Annotation. The use of artificial lung ventilation in patients of intensive care unit often leads to airway contamination of conditionally pathogenic microorganisms and the development of ventilator-associated pneumonia. The clinical manifestations of ventilator-associated pneumonia can vary widely from mild to development of critical conditions accompanied by septic shock. This significantly worsens the patient's condition and prognosis for effective treatment. The paper presents the results of the study of the use of adhesive antiseptic compositions based on the domestic antiseptic drug decamethoxin in order to give antimicrobial properties to intubation tubes. An antibacterial adhesive was applied to the surface of segments of the endotracheal intubation tube, after which the samples were dried in a sterile box. The sensitivity of the microorganisms to the components of the antiseptic compositions was studied by the diameter of the growth retardation zone around the studied fragments of endotracheal intubation tubes placed in the thickness of the pre-seeded microorganism’s dense nutrient medium. The results were statistically analyzed using standard application package for biomedical research “STATISTICA 5.5”. It has been proved that adhesive film-forming compositions based on decamethoxin confer pronounced antimicrobial properties to endotracheal intubation tubes. The most susceptible to antimicrobial activity were gram-positive microorganisms of the genus Staphylococcus, and the most resistant were representatives of gram-negative bacteria of the genus Acinetobacter. The obtained research results allow us to predict the effectiveness of the use of adhesive hydrophilic and hydrophobic antiseptic compositions based on the domestic antiseptic decamethoxin to provide protective properties of the surface of endotracheal tubes, prevent the process of bacterial film formation and prevention of ventilator-associated patients.

Published

2020

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

Author

Jiafeng Zhang, Zachary B. K. Berk, Douglas Tran, Zhongjun J. Wu, Robert G. Conway, Tieluo Li, and Bartley P. Griffith

Subjects

Male, medicine.medical_treatment, 0206 medical engineering, Biomedical Engineering, Medicine (miscellaneous), Hemodynamics, Bioengineering, 02 engineering and technology, 030204 cardiovascular system & hematology, Article, Artificial lung, Biomaterials, 03 medical and health sciences, Extracorporeal Membrane Oxygenation, 0302 clinical medicine, Fuzzy Logic, Extracorporeal membrane oxygenation, medicine, Animals, Respiratory system, Oxygenator, Sheep, Respiratory distress, business.industry, General Medicine, Oxygenation, 020601 biomedical engineering, surgical procedures, operative, Respiratory failure, Anesthesia, business

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 Auto-Regulatory 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 CO2 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 mmHg, and pO(2) =237.9 ± 123.6 mmHg) 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.

Published

2020

13. How Computational Modeling can Help to Predict Gas Transfer in Artificial Lungs Early in the Design Process

Author

Jutta Arens, Peter C. Schlanstein, Thomas Schmitz-Rode, Andreas Kaesler, Ulrich Steinseifer, Georg Wagner, Sascha Groß-Hardt, Marius Rosen, and Biomechanical Engineering

Subjects

gas transfer prediction, Oxygenators, Swine, Computer science, Flow (psychology), Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Computational fluid dynamics, Artificial lung, Biomaterials, 03 medical and health sciences, Extracorporeal Membrane Oxygenation, 0302 clinical medicine, Intensive care, Mass transfer, micro-scale CFD model, Animals, Humans, Computer Simulation, Oxygenator, artificial lung, Simulation, Oxygenators, Membrane, gas transfer modeling, business.industry, Hemodynamics, 22/2 OA procedure, Equipment Design, General Medicine, oxygenator, 030228 respiratory system, Volume (thermodynamics), Hydrodynamics, business

Abstract

Wearable extracorporeal membrane oxygenation (ECMO) circuits may soon become a viable alternative to conventional ECMO treatment. Common device-induced complications, however, such as blood trauma and oxygenator thrombosis, must first be addressed to improve long-term reliability, since ambulatory patients cannot be monitored as closely as intensive care patients. Additionally, an efficient use of the membrane surface can reduce the size of the devices, priming volume, and weight to achieve portability. Both challenges are linked to the hemodynamics in the fiber bundle. While experimental test methods can often only provide global and time-averaged information, computational fluid dynamics (CFD) can give insight into local flow dynamics and gas transfer before building the first laboratory prototype. In this study, we applied our previously introduced micro-scale CFD model to the full fiber bundle of a small oxygenator for gas transfer prediction. Three randomized geometries as well as a staggered and in-line configuration were modeled and simulated with Ansys CFX. Three small laboratory oxygenator prototypes were built by stacking fiber segments unidirectionally with spacers between consecutive segments. The devices were tested in vitro for gas transfer with porcine blood in accordance with ISO 7199. The error of the predicted averaged CFD oxygen saturations of the random 1, 2, and 3 configurations relative to the averaged in-vitro data (over all samples and devices) was 2.4%, 4.6%, 3.1%, and 3.0% for blood flow rates of 100, 200, 300, and 400 ml/min, respectively. While our micro-scale CFD model was successfully applied to a small oxygenator with unidirectional fibers, the application to clinically relevant oxygenators will remain challenging due to the complex flow distribution in the fiber bundle and high computational costs. However, we will outline our future research priorities and discuss how an extended mass transfer correlation model implemented into CFD might enable an a priori prediction of gas transfer in full size oxygenators.

Published

2019

14. Comparison of the Filtration Efficiency of Different Face Masks Against Aerosols

Author

Connor Stahl, Kevin Frederick, Sachin Chaudhary, Christopher J. Morton, Douglas Loy, Krishna Muralidharan, Armin Sorooshian, and Sairam Parthasarathy

Subjects

0301 basic medicine, Medicine (General), Materials science, aerosol, Airflow, Artificial lung, law.invention, 03 medical and health sciences, R5-920, 0302 clinical medicine, law, 030212 general & internal medicine, Tidal volume, Filtration, SARS-CoV-2, viral transmission, COVID-19, General Medicine, respiratory system, Brief Research Report, Aerosol, mask, Face masks, 030104 developmental biology, Medicine, Particle, Particle size, Biomedical engineering

Abstract

Background: The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic can spread through virus-containing aerosols ( ≤ 5 μm) and larger airborne droplets. Quantifying filtration efficiency of different kinds of masks and linings for aerosols that fall within the most penetrating particle size (80-400 nm) is critical to limiting viral transmission. The objective of our experiment was to compare the “real-world” filtering efficiency of different face masks for fine aerosols (350 nm) in laboratory simulations.Methods: We performed a simulated bench test that measured the filtering efficiency of N95 vs. N99 masks with elastomeric lining in relation to baseline (“background”) aerosol generation. A mannequin head was placed within a chamber and was attached to an artificial lung simulator. Particles of known size (350 ± 6 nm aerodynamic diameter) were aerosolized into the chamber while simulating breathing at physiological settings of tidal volume, respiratory rate, and airflow. Particle counts were measured between the mannequin head and the lung simulator at the tracheal airway location.Results: Baseline particle counts without a filter (background) were 2,935 ± 555 (SD) cm−3, while the N95 (1348 ± 92 cm−3) and N99 mask with elastomeric lining (279 ± 164 cm−3; p Conclusion: The filtration efficiency of the N95 (54.1%) and N99 (90.5%) masks were lower than the filtration efficiency rating. N99 masks with elastomeric lining exhibit greater filtration efficiency than N95 masks without elastomeric lining and may be preferred to contain the spread of SARS-CoV-2 infection.

Published

2021

15. In vitro delivery efficiencies of nebulizers for different breathing patterns

Author

Hyun Mok Park, Ki Chang Nam, Kyung Hwa Chang, Sang-Hyub Moon, Bong Joo Park, and Sun Kook Yoo

Subjects

Adult, Respiratory simulator, Biomedical Engineering, Efficiency, 030226 pharmacology & pharmacy, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Breathing pattern, Dosage, Administration, Inhalation, Medical technology, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Flow sensor, R855-855.5, Aerosolization, Aerosols, Radiological and Ultrasound Technology, business.industry, Research, Nebulizers and Vaporizers, Nebulizer, General Medicine, 030228 respiratory system, Drug delivery, Airway, business, Biomedical engineering

Abstract

BackgroundNebulizers are medical devices that deliver aerosolized medication directly to lungs to treat a variety of respiratory diseases. However, breathing patterns, respiration rates, airway diameters, and amounts of drugs delivered by nebulizers may be respiratory disease dependent.MethodIn this study, we developed a respiratory simulator consisting of an airway model, an artificial lung, a flow sensor, and an aerosol collecting filter. Various breathing patterns were generated using a linear actuator and an air cylinder. We tested six home nebulizers (jet (2), static (2), and vibrating mesh nebulizers (2)). Nebulizers were evaluated under two conditions, that is, for the duration of nebulization and at a constant output 1.3 mL using four breathing patterns, namely, the breathing pattern specified in ISO 27427:2013, normal adult, asthmatic, and COPD.ResultsOne of the vibrating mesh nebulizers had the highest dose delivery efficiency. The drug delivery efficiencies of nebulizers were found to depend on breathing patterns.ConclusionWe suggest a quantitative drug delivery efficiency evaluation method and calculation parameters that include considerations of constant outputs and residual volumes. The study shows output rates and breathing patterns should be considered when the drug delivery efficiencies of nebulizers are evaluated.

Published

2021

16. Human Cadaveric Artificial Lung Tumor-Mimic Training Model

Author

Réka Székely, Ödön Wagner, Tamas Ruttkay, Bence Szabaczki, Kinga Karlinger, Béla Merkely, Gabor Baksa, Laszlo Barany, Ferenc Imre Suhai, Gergely Rácz, and Gergely Pölöskei

Subjects

Cancer Research, medicine.medical_specialty, Lung Neoplasms, Percutaneous, Models, Biological, Artificial lung, lung tumor, 030218 nuclear medicine & medical imaging, Pathology and Forensic Medicine, tumor mimic, 03 medical and health sciences, 0302 clinical medicine, Cadaver, pseudotumor, medicine, Humans, Lung, Simulation Training, Original Research, Fixation (histology), cadaver workshop, hands-on training, business.industry, General Medicine, Society Journal Archive, medicine.anatomical_structure, Oncology, Surgical Procedures, Operative, 030220 oncology & carcinogenesis, Lung tumor, Radiology, Tomography, X-Ray Computed, Airway, business, Cadaveric spasm

Abstract

Introduction: An important phase in surgical training is gaining experience in real human anatomical situations. When a cadaver is available it may complement the various artificial practice models. However, it is often necessary to supplement the characteristics of the cadavers with a simulation of a tumor. Our objective was to develop an easy-to-create, realistic artificial tumor-mimic model for peripheral lung tumor resection practice.Methods: In our work we injected barium sulphate enriched silicone suspension into 10 isolated, non-fixed lungs of human cadavers, through the puncture of the visceral pleura. Four lesions–apical, hilar and two peripheral–were created in each of ten specimens. After fixation CT scans were obtained and analyzed. The implanted tumor-mimics were examined after anatomical preparation and slicing. Also performed CT-guided percutaneous puncture was also performed to create the lesions in situ in two lungs of human cadavers.Results: Analyzing the CT data of 10 isolated lungs, out of 40 lesions, 34 were nodular (85.0%) and in the nodular group five were spiculated (12.5%). Satellite lesions were formed in two cases (5.0%). Relevant outflow into vessels or airway occurred in five lesions (12.5%). Reaching the surface of the lung occured in 11 lesions (27.5%). The tumor-mimics were elastic and adhered well to the surrounding tissue. The two lesions, implanted via percutaneous puncture, both were nodular and one also showed lobulated features.Conclusion: Our artificial tumor-mimics were easy to create, varied in shape and size, and with percutaneous implantation the lesions provide a model for teaching every step of a surgical procedure.

Published

2021

17. Emergency 3-Dimensional-Printed Devices for Splitting Ventilators in Lungs With Different Compliances: An In Vitro Study

Author

Antônio R Carraretto, Marcelo Frizzera-Borges, Jório B M Lemos, and Fausto Frizzera

Subjects

Male, 2019-20 coronavirus outbreak, Emergency Medical Services, Ventilators, Mechanical, Coronavirus disease 2019 (COVID-19), Computer science, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), COVID-19, Economic shortage, General Medicine, Pulmonary compliance, Artificial lung, Printing, Three-Dimensional, Tidal Volume, In vitro study, Humans, Lung, Lung Compliance, Tidal volume, Biomedical engineering

Abstract

Ventilator shortages occurred due to the severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2). This in vitro study evaluated the effectiveness of 3-dimensional (3D)-printed splitters and 3D-printed air flow limiters (AFL) in delivering appropriate tidal volumes (TV) to lungs with different compliances. Groups were divided according to the size of the AFL: AFL-4 was a 4-mm device, AFL-5 a 5-mm device, AFL-6 a 6-mm device, and no limiter (control). A ventilator was split to supply TV to 2 artificial lungs with different compliances. The AFL improved TV distribution.

Published

2021

18. Validation of transcutaneous carbon dioxide monitoring using an artificial lung during adult pulsatile cardiopulmonary bypass

Author

Jeffrey B Riley, Lawrence Garrison, Steve Wysocki, Hali Julick, and Jennifer Souai

Subjects

030232 urology & nephrology, Biomedical Engineering, Pulsatile flow, Medicine (miscellaneous), Bioengineering, 030204 cardiovascular system & hematology, Artificial lung, law.invention, Microcirculation, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Hyperbaric oxygen, Carbon dioxide monitoring, law, Cardiopulmonary bypass, Medicine, Lung, Monitoring, Physiologic, Cardiopulmonary Bypass, business.industry, General Medicine, Carbon Dioxide, Jet ventilation, chemistry, Anesthesia, Carbon dioxide, business, Blood Gas Monitoring, Transcutaneous

Abstract

Measurements of transcutaneous carbon dioxide (tcCO2) have been used in multiple venues, such as during procedures utilizing jet ventilation, hyperbaric oxygen therapy, as well as both the adult and neo-natal ICUs. However, tcCO2 measurements have not been validated under conditions which utilize an artificial lung, such cardiopulmonary bypass (CPB). The purpose of this study was to (1) validate the use of tcCO2 using an artificial lung during CPB and (2) identify a location for the sensor that would optimize estimation of PaCO2 when compared to the gold standard of blood gas analysis. tcCO2 measurements ( N = 185) were collected every 30 min during 54 pulsatile CPB procedures. The agreement/differences between the tcCO2 and the PaCO2 were compared by three sensor locations. Compared to the earlobe or the forehead, the submandibular PtcCO2 values agreed best with the PaCO2 and with a median difference of –.03 mmHg (IQR = 5.4, p 2 measurement. The multiple linear regression model for predicting the agreement between the submandibular tcCO2 and PaCO2 included the SvO2, the oxygenator gas to blood flow ratio, and the native perfusion index ( R2 = 0.699, df = 1, 60; F = 19.1, p Our experience in utilizing tcCO2 during CPB has demonstrated accuracy in estimating PaCO2 when compared to the gold standard arterial blood gas analysis, even during CO2 flooding of the surgical field.

Published

2021

19. Artificial lungs––Where are we going with the lung replacement therapy?

Author

N. Shigemura, Justyna Swol, Masaki Anraku, Shingo Ichiba, Ulrich Steinseifer, and Roberto Lorusso

Subjects

medicine.medical_specialty, Coronavirus disease 2019 (COVID-19), medicine.medical_treatment, 0206 medical engineering, LIFE-SUPPORT, Biomedical Engineering, FIBER BUNDLE, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, Oxygenators, 030204 cardiovascular system & hematology, extracorporeal life support, BRIDGE, Artificial lung, EXTRACORPOREAL MEMBRANE-OXYGENATION, Biomaterials, Wearable Electronic Devices, 03 medical and health sciences, 0302 clinical medicine, CO2 REMOVAL, lung transplantation, medicine, Extracorporeal membrane oxygenation, Humans, Lung transplantation, wearable portable lung, Intensive care medicine, artificial lung, biofabricated lung, GOAT FETUSES, Lung, Tissue Engineering, PUMP-LUNG, COVID-19, IN-VITRO, General Medicine, extracorporeal membrane oxygenation, 020601 biomedical engineering, SINGLE-CENTER EXPERIENCE, Transplantation, end&#8208, medicine.anatomical_structure, Biomimetic Devices, Intensive Care, Neonatal, stage lung disease, GAS-EXCHANGE, Destination therapy

Abstract

Lung transplantation may be a final destination therapy in lung failure, but limited donor organ availability creates a need for alternative management, including artificial lung technology. This invited review discusses ongoing developments and future research pathways for respiratory assist devices and tissue engineering to treat advanced and refractory lung disease. An overview is also given on the aftermath of the coronavirus disease 2019 pandemic and lessons learned as the world comes out of this situation. The first order of business in the future of lung support is solving the problems with existing mechanical devices. Interestingly, challenges identified during the early days of development persist today. These challenges include device-related infection, bleeding, thrombosis, cost, and patient quality of life. The main approaches of the future directions are to repair, restore, replace, or regenerate the lungs. Engineering improvements to hollow fiber membrane gas exchangers are enabling longer term wearable systems and can be used to bridge lung failure patients to transplantation. Progress in the development of microchannel-based devices has provided the concept of biomimetic devices that may even enable intracorporeal implantation. Tissue engineering and cell-based technologies have provided the concept of bioartificial lungs with properties similar to the native organ. Recent progress in artificial lung technologies includes continued advances in both engineering and biology. The final goal is to achieve a truly implantable and durable artificial lung that is applicable to destination therapy.

Published

2020

20. Development of a Model of Pediatric Lung Failure Pathophysiology

Author

Alvaro Rojas-Pena, Alice Xu, Robert H. Bartlett, Ronald B. Hirschl, Kristopher B. Deatrick, John M. Trahanas, Marie S. Cornell, Fares Alghanem, Hayley R. Hoffman, and Catalina Ceballos-Muriel

Subjects

medicine.medical_specialty, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Tachypnea, Artificial lung, Article, Pulmonary hypertension, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, Occlusion, medicine, Animals, Humans, Child, Ligation, Lung, Mortalidad del niño, Tourniquet, Sheep, business.industry, General Medicine, Perioperative, medicine.disease, Right pulmonary artery, Prótesis e implantes, Disease Models, Animal, medicine.anatomical_structure, trasplante de pulmón, 030228 respiratory system, lung failure, Cardiology, Artificial Organs, medicine.symptom, Animal mode, business, Respiratory Insufficiency

Abstract

A pediatric artificial lung (PAL) is under development as a bridge to transplantation or lung remodeling for children with end-stage lung failure (ESLF). In order to evaluate the efficiency of a PAL, a disease model mimicking the physiologic derangements of pediatric ESLF is needed. Our previous right pulmonary artery ligation (rPA-LM) ovine model achieved that goal, but caused immediate mortality in nearly half of the animals. In this study, we evaluated a new technique of gradual postoperative right pulmonary artery (rPA) occlusion using a Rummel tourniquet (rPA-RT) in seven (25–40 Kg) sheep. This technique created a stable model of ESLF pathophysiology, characterized by high alveolar dead space (58.0±3.8 %), pulmonary hypertension (38.4±2.2 mmHg), tachypnea (79±20 breaths per minute), and intermittent supplemental oxygen requirement. This improvement to our technique provides the necessary physiologic derangements for testing a PAL, while avoiding the problem of high immediate perioperative mortality.

Published

2020

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

Author

Benjamin D. Carr, Joseph A. Potkay, Peter C. Schlanstein, Alvaro Rojas-Pena, Robert H. Bartlett, Uditha Piyumindri Fernando, McKenzie Hayes, Alex J. Thompson, Felix Hesselmann, Clinton J Poling, Ronald B. Hirschl, Andreas Kaesler, Jutta Arens, and Skylar Buchan

Subjects

medicine.medical_specialty, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Concentric, Artificial lung, Article, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, medicine, Lung transplantation, Humans, Stage (cooking), Child, Lung, business.industry, General Medicine, Equipment Design, respiratory system, medicine.anatomical_structure, 030228 respiratory system, Lung disease, Cardiology, Hollow fiber oxygenator, Artificial Organs, Low resistance, business, Respiratory Insufficiency, Lung Transplantation

Abstract

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.

Published

2020

22. Pharmacological prophylaxis of delirium in cardiosurgery

Author

Yu. L. Shevchenko, Yu. I. Gorokhovatskii, M. N. Zamiatin, A. R. Sedrakian, A. V. Vakhliaev, and G. G. Borshchev

Subjects

RD1-811, genetic structures, Bypass grafting, behavioral disciplines and activities, Artificial lung, 03 medical and health sciences, delirium, 0302 clinical medicine, 030202 anesthesiology, mental disorders, medicine, Haloperidol, Dexmedetomidine, business.industry, cardiosurgery, 030208 emergency & critical care medicine, General Medicine, Perioperative, medicine.anatomical_structure, Anesthesia, Breathing, Delirium, Surgery, prophylaxis, medicine.symptom, business, Artery, medicine.drug

Abstract

The objective of the study is to evaluate the effect of perioperative administration of dexmedetomidine on the frequency of delirium after myocardial revascularization.Material and methods.A retrospective analysis of the results of 1733 operations of myocardial revascularization was performed, as well as a prospective comparative study of postoperative period features in 568 patients.Results.The use of perioperative administration of dexmedetomidine at a rate of 0.2–0.4 μg/(kg•min) resulted in a significant (3.4 times,) decrease in the frequency of delirium, and in the case of the development of a syndrome resulted in the reducing its duration from (3,24±1,6) to (1,6±0,7) days and the need for prolonged artificial lungs ventilation (ALV), a decrease in the dose of haloperidol for arresting excitation.Conclusion.Perioperative infusion of dexmedetomidine reduces the frequency of delirium after coronary artery bypass grafting (CABG). In the case of delirium progression, the inclusion of dexmedetomidine in therapy reduces the duration of delirium, the need for ALV, and reduces the need for neuroleptics.

Published

2018

23. Technical Advances in the Field of ECMO

Author

Peter Betit

Subjects

Pulmonary and Respiratory Medicine, Technology Assessment, Biomedical, business.industry, medicine.medical_treatment, Wearable computer, General Medicine, Troubleshooting, 030204 cardiovascular system & hematology, Manikins, Critical Care and Intensive Care Medicine, Biocompatible material, Artificial lung, Field (computer science), Simulation training, 03 medical and health sciences, Extracorporeal Membrane Oxygenation, 0302 clinical medicine, 030228 respiratory system, Risk analysis (engineering), Extracorporeal membrane oxygenation, medicine, Humans, Technical skills, business, Simulation Training

Abstract

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.

Published

2018

24. Computational Modeling of Oxygen Transfer in Artificial Lungs

Author

Andreas Kaesler, Marius Rosen, Ulrich Steinseifer, Jutta Arens, and Thomas Schmitz-Rode

Subjects

Materials science, business.industry, 0206 medical engineering, Biomedical Engineering, Mass diffusivity, Medicine (miscellaneous), chemistry.chemical_element, Bioengineering, 02 engineering and technology, General Medicine, Mechanics, Blood flow, 030204 cardiovascular system & hematology, Computational fluid dynamics, Thermal diffusivity, 020601 biomedical engineering, Oxygen, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, chemistry, Mass transfer, Fiber, business

Abstract

Under physiological conditions, up to 97% of the oxygen in blood that is transported from lungs to tissue is bound to hemoglobin. To predict oxygen transfer in artificial lungs on a membrane fiber level with computational fluid dynamics (CFD), previous investigators have incorporated the hemoglobin-oxygen interaction into an effective diffusivity coefficient to modify the convection-diffusion equation. Based on our own simulations and experiments, these approaches tend to significantly overestimate the oxygen transfer. The present study introduces a novel approach to model the oxygen transfer in blood on a fiber level with CFD. Plasma and red blood cells were implemented as two phases and the reaction of hemoglobin and oxygen to oxyhemoglobin was included in the convection-diffusion equation in form of a source term. The model was implemented with the commercial software Ansys CFX 18.1. CFD simulations were compared with in vitro experiments on three micro oxygenators with a staggered fiber configuration under multiple blood flow conditions. To calibrate the model, a reaction rate R0 was introduced and experimental data was fitted to a blood flow of 50 mL/h. Our model approximated the oxygen transfer rates with a difference, relative to in vitro results, of -23.7 and +6.3% for blood flows of 20 and 90 mL/h, respectively. The effective diffusivity model, used by previous authors, was implemented for comparison and approximated oxygen transfer rates with a difference, relative to in vitro data, of +13.7, +68.8, and +121.0% for blood flows of 20, 50, and 90 mL/h, respectively. A well-established numerical mass transfer correlation approximated the gas transfer with a difference, referenced on the average in vitro data, of 31.8, 13.1, and 5.0% for blood flows of 20, 50, and 90 mL/h, respectively. Even though results are promising, a thorough validation of the model will require extensive CFD and in vitro studies of multiple fiber arrangements, fiber diameters, and therefore fiber bundle porosities in the future. This article should be understood as a first feasibility study to evaluate the potential of the novel oxygen transfer model.

Published

2018

25. Fourteen Day In Vivo Testing of a Compliant Thoracic Artificial Lung

Author

Kelly L. Koch, David S. Demos, David J. Skoog, Rebecca E. Schewe, Ahmed B. Suhaib, Amit Iyengar, Keith E. Cook, Joshua R. Pohlmann, and Christopher N. Scipione

Subjects

medicine.medical_specialty, medicine.drug_class, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, Atelectasis, 030204 cardiovascular system & hematology, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, medicine.artery, medicine, Lung transplantation, business.industry, Anticoagulant, General Medicine, Blood flow, Heparin, Pulmonary edema, medicine.disease, Surgery, 030228 respiratory system, Anesthesia, Pulmonary artery, business, medicine.drug

Abstract

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 anticoagulant coatings was attached to sheep (n = 5) via the pulmonary artery and left atrium for 14 days. Systemic heparin anticoagulation was used. Compliant thoracic artificial lung resistance, cTAL gas exchange, hematologic parameters, and organ function were recorded. Two sheep were euthanized for nondevice-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 14 day experiment, the cTAL without anticoagulant coatings exhibited minimal clot formation. Sheep physiology was largely unchanged except for device attachment-related hemodilution. This suggests that patients treated with the cTAL should not require multiple blood transfusions. Once tested with anticoagulant coatings and plasma resistant gas exchange fiber, the cTAL could serve as a bridge to transplantation.

Published

2017

26. A Membrane Lung Design Based on Circular Blood Flow Paths

Author

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

Subjects

medicine.medical_specialty, Lung, Chemistry, Biomedical Engineering, Biophysics, Thrombogenicity, Bioengineering, General Medicine, Blood flow, 030204 cardiovascular system & hematology, Concentric, Article, Artificial lung, Surgery, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, 030228 respiratory system, Volume (thermodynamics), Hollow fiber membrane, medicine, Current (fluid), Biomedical engineering

Abstract

Current hollow fiber membrane lungs feature a predominantly straight blood path length across the fiber bundle, resulting in limited oxygen transfer efficiency due to the diffusion boundary layer effect. Using computational fluid dynamics and optical flow visualization methods, a hollow fiber membrane lung was designed comprising unique concentric circular blood flow paths connected by gates. The prototype lung, comprising a fiber surface area of 0.28 m2, has a rated flow of 2 L/min and the oxygenation efficiency is 357 mL/min/m2. The CO2 clearance of the lung is 200 mL/min at the rated blood flow. Given its high gas transfer efficiency, as well as its compact size, low priming volume, and propensity for minimal thrombogenicity, this lung design has the potential to be used in a range of acute and chronic respiratory support applications, including providing total respiratory support for infants and small children and CO2 clearance in adults.

Published

2017

27. Silicon Micropore-Based Parallel Plate Membrane Oxygenator

Author

Charles Blaha, Nathan Wright, Benjamin J. Feinberg, Shuvo Roy, Willieford Moses, Ajay Dharia, Emily Abada, Torin Yeager, Benjamin E. Padilla, and Jaehyun Park

Subjects

Materials science, Membrane oxygenator, medicine.medical_treatment, 0206 medical engineering, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, 030204 cardiovascular system & hematology, Artificial lung, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Extracorporeal membrane oxygenation, medicine, Heart bypass, Oxygenator, Polydimethylsiloxane, technology, industry, and agriculture, Oxygen transport, General Medicine, 020601 biomedical engineering, Membrane, chemistry, Biomedical engineering

Abstract

Extracorporeal membrane oxygenation (ECMO) is a life support system that circulates the blood through an oxygenating system to temporarily (days to months) support heart or lung function during cardiopulmonary failure until organ recovery or replacement. Currently, the need for high levels of systemic anticoagulation and the risk for bleeding are main drawbacks of ECMO that can be addressed with a redesigned ECMO system. Our lab has developed an approach using microelectromechanical systems (MEMS) fabrication techniques to create novel gas exchange membranes consisting of a rigid silicon micropore membrane (SμM) support structure bonded to a thin film of gas-permeable polydimethylsiloxane (PDMS). This study details the fabrication process to create silicon membranes with highly uniform micropores that have a high level of pattern fidelity. The oxygen transport across these membranes was tested in a simple water-based bench-top set-up as well in a porcine in vivo model. It was determined that the mass transfer coefficient for the system using SµM-PDMS membranes was 3.03 ± 0.42 mL O2 min−1 m−2 cm Hg−1 with pure water and 1.71 ± 1.03 mL O2 min−1 m−2 cm Hg−1 with blood. An analytic model to predict gas transport was developed using data from the bench-top experiments and validated with in vivo testing. This was a proof of concept study showing adequate oxygen transport across a parallel plate SµM-PDMS membrane when used as a membrane oxygenator. This work establishes the tools and the equipoise to develop future generations of silicon micropore membrane oxygenators.

Published

2017

28. INFLUENCE OF ARTIFICIAL LUNG VENTILATION ON REAL ENERGY EXPENDITURE VALUE OF SURGICAL INTENSIVE CARE UNIT PATIENTS

Author

I. V. Polyakov, K. N. Zolotukhin, and I. N. Leyderman

Subjects

indirect calorimetry, medicine.medical_specialty, RD1-811, Critically ill, business.industry, Organ dysfunction, nutritional support, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Surgical intensive care unit, General Medicine, energy balance, Artificial lung, Clinical Practice, Critical illness, Emergency medicine, medicine, Breathing, critical illness, Surgery, medicine.symptom, Prospective cohort study, business, RC254-282

Abstract

Elective or emergence surgery often is closely connected with development of hypercatabolism-hypermetabolism syndrome. Non-effective and late nutritional support in surgical critically ill patients lead to several consequences and complications such as: wound and nosocomial infectons, gastric stress ulcers, pressure ulcers, prolonged artificial lung ventilation, increased length of stay in ICU and hospital. Energy deficit is one of the important components of critical illness and it corresponds with multiple organ dysfunction progression. Prospective study was provided in 18 beds surgical intensive care unit (SICU). 106 patient medical cards were divided into 4 groupstwo control and two basic with espiratory support (subgroup with artificial lung ventilation and subgroup without artificial lung ventilation). We compared the effectiviness of two methods for the estimation of patients energy needsspecial equations and indirect calorimetry. As a result we found out that main markers of energy and protein metabolism and nutritive status were significantly higher in indirect calorimetry groupswith and without artificial lung ventilation. Conclusion: Indirect calorimetry method usage for the estimation of energy needs in surgical ICU patients is more effective than special equations method during first 7 days of critical illness and may be recommended for clinical practice implication.

Published

2017

29. Development of a self-pumping extracorporeal blood oxygenation device characterized by a rotating shaft with embedded fiber packages

Author

Antonino Rinaudo, Salvatore Pasta, Rinaudo A., and Pasta S.

Subjects

Lung Diseases, lung disease, 0206 medical engineering, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, 030204 cardiovascular system & hematology, Heart-Lung Machine, Extracorporeal, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Medicine, Humans, Computational analysis, Fiber, Lung, artificial lung, Oxygenators, Membrane, business.industry, Respiratory support, Hemodynamics, General Medicine, Oxygenation, Equipment Design, 020601 biomedical engineering, Oxygen, computational analysi, Lung disease, Blood oxygenation, Artificial Organs, business, Biomedical engineering

Abstract

Introduction: To offer respiratory support for patients with lung disease, a novel technological solution for blood pumping and oxygenation is being developed. The pump–lung system was designed to integrate fiber membranes into six packages radially embedded in a rotating hollow shaft placed along the longitudinal axis of the device. Fiber packages are inclined with respect to the rotation axis so that the rotational motion of the rotating shaft allows a self-pumping system to be obtained. Method: Both hemodynamic and gas transfer performances were investigated using both in vitro experiments and in silico flow analyses. Results: The predicted flow velocity in the pump chamber was smooth and characterized by high peripheral velocities near the housing wall. As the blood flow enters the inlet, the static pressure increased with the angular momentum imparted to the fiber packages. Experiments confirmed that the proposed pump–lung system can provide adequate blood flow and oxygen transfer over the range of intended operating conditions (0.5–5 L/min and 500–1500 r/min). Conclusion: Although the study did not include animal testing, the novel pump-oxygenator solution is feasible for respiratory support in patients with lung diseases.

Published

2019

30. Blood Recirculation Enhances Oxygenation Efficiency of Artificial Lungs

Author

Shalv P. Madhani, Brian J. Frankowski, Alexandra G. May, Greg W. Burgreen, and William J. Federspiel

Subjects

Materials science, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Extracorporeal Membrane Oxygenation, Gas transfer, Co2 removal, Extracorporeal membrane oxygenation, medicine, Animals, Lung, Ventilators, Mechanical, General Medicine, Blood flow, Oxygenation, Equipment Design, Models, Theoretical, Volumetric flow rate, 030228 respiratory system, Hollow fiber membrane, Hydrodynamics, Cattle, Biomedical engineering

Abstract

Ambulating patients on extracorporeal membrane oxygenation (ECMO) or extracorporeal CO2 removal (ECCO2R) improves outcomes. These systems would further simplify ambulation if made more compact. This study investigates blood recirculation to decrease device size by increasing efficiency. The required hollow fiber membrane (HFM) area was determined by numerically modeling gas transfer. An oxygenation device with recirculating blood flow was designed using computational fluid dynamics (CFD). Hydrodynamic performance and shear stresses of the device were analyzed using CFD at 2,000, 2,250 and 2,500 RPM. A prototype (0.38 m) was manufactured for in-vitro oxygenation testing. Oxygenation was measured at a constant 3.5 L/min blood flow while recirculation flow rate varied up to 6.5 L/min. Hemolysis was measured at 3.5 L/min blood flow and 6.5 L/min recirculation flow. A 0.3 m prototype device was used to test in-vitro ECCO2R recirculation at a constant 500 ml/min blood flow rate and recirculation flow rates up to 5.5 L/min. Computational fluid dynamics analysis showed that the oxygenation device could produce over 250 mm Hg while maintaining 3.5 L/min blood flow and 6.5 L/min recirculation flow. The model predicted oxygenation within 8% and overestimated ECCO2R by up to 32%. Measured gas transfer was 180 ml O2/min and 62 ml CO2/min. Normalized index of hemolysis contribution of the HFM was 0.012 gm/100 L.

Published

2019

31. A Model of Pediatric End-Stage Lung Failure in Small Lambs20 kg

Author

Clinton J Poling, Matias Caceres Quinones, Ronald B. Hirschl, Jennifer S. McLeod, Alvaro Rojas-Pena, Pavel Hala, Benjamin D. Carr, Aaron Prater, and Robert H. Bartlett

Subjects

medicine.medical_specialty, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Artificial lung, Article, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, medicine.artery, Occlusion, medicine, Animals, Sheep, Domestic, Lung, Ejection fraction, Sheep, business.industry, General Medicine, medicine.disease, Pulmonary hypertension, Disease Models, Animal, medicine.anatomical_structure, 030228 respiratory system, Animals, Newborn, Ventricle, Pulmonary artery, Cardiology, Female, business, Respiratory Insufficiency, Perfusion

Abstract

One in five children with end-stage lung failure (ESLF) die while awaiting lung transplant. No suitable animal model of ESLF exists for the development of artificial lung devices for bridging to transplant. Small lambs weighing 15.7 ± 3.1 kg (n = 5) underwent ligation of the left anterior pulmonary artery (PA) branch, and gradual occlusion of the right main PA over 48 hours. All animals remained hemodynamically stable. Over seven days of disease model conditions, they developed pulmonary hypertension (mean PA pressure 20 ± 5 vs. 33 ± 4 mm Hg), decreased perfusion (SvO2 66 ± 3 vs. 55 ± 8%) with supplemental oxygen requirement, and severe tachypneic response (45 ± 9 vs. 82 ± 23 breaths/min) (all p < 0.05). Severe right heart dysfunction developed (tricuspid annular plane systolic excursion 13 ± 3 vs. 7 ± 2 mm, fractional area change 36 ± 6 vs. 22 ± 10 mm, ejection fraction 51 ± 9 vs. 27 ± 17%, all p < 0.05) with severe tricuspid regurgitation and balloon-shaped dilation of the right ventricle. This model of pediatric ESLF reliably produces pulmonary hypertension, right heart strain, and impaired gas exchange, and will be used to develop a pediatric artificial lung.

Published

2019

32. De novo lung biofabrication: clinical need, construction methods, and design strategy

Author

Wai Hoe Ng, Keith E. Cook, Xi Ren, Erica M. Comber, and Rachelle N. Palchesko

Subjects

0301 basic medicine, Scaffold, medicine.medical_treatment, Artificial lung, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, Physiology (medical), medicine, Humans, Lung, Mechanical ventilation, Tissue Engineering, Tissue Scaffolds, business.industry, Biochemistry (medical), Public Health, Environmental and Occupational Health, General Medicine, respiratory system, respiratory tract diseases, Donor lungs, 030104 developmental biology, medicine.anatomical_structure, Lung disease, 030220 oncology & carcinogenesis, Artificial Organs, business, Biomedical engineering, Biofabrication

Abstract

Chronic lung disease is the 4th leading cause of death in the United States. Due to a shortage of donor lungs, alternative approaches to support failing, native lungs have been attempted, including mechanical ventilation and various forms of artificial lungs. However, each of these support methods causes significant complications when used for longer than a few days and are thus not capable of long-term support. For artificial lungs, complications arise due to interactions between the artificial materials of the device and the blood of the recipient. A potential new approach is the fabrication of lungs from biological materials, such that the gas exchange membranes provide a more biomimetic blood-contacting interface. Recent advancements with three-dimensional, soft-tissue biofabrication methods and the engineering of thin, basement membranes demonstrate the potential of fabricating a lung scaffold from extracellular matrix materials. This scaffold could then be seeded with endothelial and epithelial cells, matured within a bioreactor, and transplanted. In theory, this fully biological lung could provide improved, long-term biocompatibility relative to artificial lungs, but significant work is needed to perfect the organ design and construction methods. Like artificial lungs, biofabricated lungs do not need to follow the shape and structure of a native lung, allowing for simpler manufacture. However, various functional requirements must still be met, including stable, efficient gas exchange for a period of years. Design decisions depend on the disease state, how the organ is implanted, and the latest biofabrication methods available in a rapidly evolving field.

Published

2019

33. Experimental Approach to Visualize Flow in a Stacked Hollow Fiber Bundle of an Artificial Lung With Particle Image Velocimetry

Author

Dorothee Roggenkamp, Ulrich Steinseifer, Peter C. Schlanstein, Michael Klaas, Felix Hesselmann, Martin Büsen, Andreas Kaesler, Jutta Arens, and Thomas Schmitz-Rode

Subjects

Flow visualization, Engineering, business.industry, 0206 medical engineering, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, General Medicine, Mechanics, 030204 cardiovascular system & hematology, Computational fluid dynamics, 020601 biomedical engineering, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Particle image velocimetry, Flow (mathematics), Hollow fiber membrane, Fiber bundle, Fiber, business, Simulation

Abstract

Flow distribution is key in artificial lungs, as it directly influences gas exchange performance as well as clot forming and blood damaging potential. The current state of computational fluid dynamics (CFD) in artificial lungs can only give insight on a macroscopic level due to model simplification applied to the fiber bundle. Based on our recent work on wound fiber bundles, we applied particle image velocimetry (PIV) to the model of an artificial lung prototype intended for neonatal use to visualize flow distribution in a stacked fiber bundle configuration to (i) evaluate the feasibility of PIV for artificial lungs, (ii) validate CFD in the fiber bundle of artificial lungs, and (iii) give a suggestion how to incorporate microscopic aspects into mainly macroscopic CFD studies. To this end, we built a fully transparent model of an artificial lung prototype. To increase spatial resolution, we scaled up the model by a factor of 5.8 compared with the original size. Similitude theory was applied to ensure comparability of the flow distribution between the device of original size and the scaled-up model. We focused our flow investigation on an area (20 × 70 × 43 mm) in a corner of the model with a Stereo-PIV setup. PIV data was compared to CFD data of the original sized artificial lung. From experimental PIV data, we were able to show local flow acceleration and declaration in the fiber bundle and meandering flow around individual fibers, which is not possible using state-of-the-art macroscopic CFD simulations. Our findings are applicable to clinically used artificial lungs with a similar stacked fiber arrangement (e.g., Novalung iLa and Maquet QUADROX-I). With respect to some limitations, we found PIV to be a feasible experimental flow visualization technique to investigate blood-sided flow in the stacked fiber arrangement of artificial lungs.

Published

2016

34. Flow Preconditioning of Endothelial Cells on Collagen-Immobilized Silicone Fibers Enhances Cell Retention and Antithrombotic Function

Author

Behdad Pouran, Ghassem Amoabediny, Nasim Salehi-Nik, Mohammad Ali Shokrgozar, Seyedeh Parnian Banikarimi, Jenneke Klein-Nulend, and Behrouz Zandieh-Doulabi

Subjects

0206 medical engineering, Cell, Biomedical Engineering, Medicine (miscellaneous), Prostaglandin, Bioengineering, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Artificial lung, Nitric oxide, Biomaterials, Endothelial stem cell, chemistry.chemical_compound, medicine.anatomical_structure, Silicone, chemistry, Shear stress, medicine, 0210 nano-technology, Biomedical engineering, Carbodiimide

Abstract

Stability and antithrombotic functionality of endothelial cells on silicone hollow fibers (SiHFs) are critical in the development of biohybrid artificial lungs. Here we aimed to enhance endothelial cell retention and anti-thrombotic function by low (12 dyn/cm2 , 24 h) fluid shear stress ("flow") preconditioning of endothelial cells seeded on collagen-immobilized SiHFs. The response of endothelial cells without preconditioning (48 h static culture) and with preconditioning (24 h static culture followed by 24 h flow preconditioning) on hollow fibers to high fluid shear stress (30 dyn/cm2 , 1 h) was assessed in a parallel-plate flow chamber. Finite element (FE) modeling was used to simulate shear stress within the flow chamber. We found that collagen immobilization on hollow fibers using carbodiimide bonds provided sufficient stability to high shear stress. Flow preconditioning for 24 h before treatment with high shear stress for 1 h on collagen-immobilized hollow fibers increased cell retention (1.3-fold). The FE model showed that cell flattening due to flow preconditioning reduced maximum shear stress on cells by 32%. Flow preconditioning prior to exposure to high fluid shear stress enhanced the production of nitric oxide (1.3-fold) and prostaglandin I2 (1.2-fold). In conclusion, flow preconditioning of endothelial cells on collagen-immobilized SiHFs enhanced cell retention and antithrombotic function, which could significantly improve current biohybrid artificial lungs.

Published

2016

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

Author

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

Subjects

Mechanical ventilation, Lung, business.industry, medicine.medical_treatment, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, General Medicine, 030204 cardiovascular system & hematology, Lung injury, Artificial lung, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, 030228 respiratory system, Respiratory failure, Intravenous anesthesia, Anesthesia, Extracorporeal membrane oxygenation, medicine, medicine.symptom, business, Hypercapnia

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 O2 transfer and CO2 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.

Published

2016

36. Effect of Inhaled Nitrogen Oxide on the Plasma Concentration of Cytokines and Endogenous Nitrogen Oxide

Author

Vladimir Vladimirovich Estrin and Marina Gaevna Pukhtinskaya

Subjects

Mechanical ventilation, Inhalation, business.industry, medicine.medical_treatment, General Medicine, medicine.disease, Artificial lung, Sepsis, chemistry.chemical_compound, chemistry, Intensive care, Anesthesia, Breathing, Medicine, Nitrogen oxide, Respiratory system, business

Abstract

Rationale. The nitrogen oxide molecule (NO) is a fundamental factor of the anti-infectious resistance of an organism. Research objective. To evaluate the effectiveness and safety of the prevention of sepsis by the inhalation of nitrogen oxide (iNO) in newborns with respiratory pathology on artificial pulmonary ventilation. Methods. Controlled, randomized, blind clinical trial included 97 newborns with respiratory pathology for artificial pulmonary ventilation. Patients received standard intensive therapy. The main group (n=44) received inhaled nitrogen oxide. The control group (n=53) did not receive inhaled nitrogen oxide. On Days 1, 3, and 20, the plasma concentrations of IL-1s, IL-6, IL-8, TNF-α, G-CSF, s-Fas, FGF, and nitrogen oxide were measured by capture ELISA. Results. Inhaled nitrogen oxide as a part of intensive care decreased the rate of sepsis development, the duration of mechanical ventilation, and the period of hospitalization. It provided a tendency towards a decrease in the rate of lethal outcomes and reduced cytokine aggression. Conclusions. Inhaled nitrogen oxide in standard intensive care effectively and safely prevented the development of sepsis in newborns with respiratory pathology on artificial lung ventilation. A decrease in the concentration of pro-inflammatory cytokines, including IL-6, against the background of nitrogen oxide inhalation, confirmed the possibility of using inhaled nitrogen oxide as a therapy for COVID-19.

Published

2021

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

Author

Shaoyi Jiang, Neil M. Carleton, Chi Chi Do-Nguyen, Keith E. Cook, Xiaojie Lin, Rei Ukita, Noritsugu Naito, Kan Wu, Caitlin T. Demarest, and Angela Lai

Subjects

Blood Platelets, Biocompatibility, Surface Properties, 0206 medical engineering, Activated clotting time, Biomedical Engineering, 02 engineering and technology, engineering.material, Biochemistry, Artificial lung, Fibrin, Article, Biomaterials, Coating, Coated Materials, Biocompatible, In vivo, medicine, Animals, Thrombus, Molecular Biology, Lung, Sheep, medicine.diagnostic_test, biology, Atom-transfer radical-polymerization, Chemistry, Photoelectron Spectroscopy, Biomaterial, Thrombosis, General Medicine, medicine.disease, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Betaine, medicine.anatomical_structure, Hollow fiber membrane, engineering, biology.protein, Rabbits, 0210 nano-technology, Biotechnology, Protein adsorption, Biomedical engineering

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.

Published

2018

38. In Vivo 5 Day Animal Studies of a Compact, Wearable Pumping Artificial Lung

Author

William R. Wagner, Jonathan D'Cunha, William J. Federspiel, Greg W. Burgreen, Sang-Ho Ye, Robert L. Kormos, Brian J. Frankowski, and Shalv P. Madhani

Subjects

medicine.medical_specialty, Extracorporeal Circulation, Oxygenators, Biomedical Engineering, Biophysics, Wearable computer, Bioengineering, 030204 cardiovascular system & hematology, Artificial lung, Article, Biomaterials, 03 medical and health sciences, Wearable Electronic Devices, 0302 clinical medicine, In vivo, medicine, Animals, Intensive care medicine, Oxygenators, Membrane, Lung, Sheep, business.industry, Hemodynamics, General Medicine, Equipment Design, respiratory system, Respiratory support, medicine.anatomical_structure, 030228 respiratory system, Ambulatory, Animal studies, business, Respiratory Insufficiency

Abstract

Recent studies show improved outcomes in ambulated lung failure patients. Ambulation still remains a challenge in these patients. This necessitates development of more compact and less cumbersome respiratory support specifically designed to be wearable. The Paracorporeal Ambulatory Assist Lung (PAAL) is being designed for providing ambulatory support in lung failure patients during bridge to transplant or recovery. We previously published in vitro and acute in vivo results of the PAAL. This study further evaluates the PAAL for 5 days. Five-day in vivo studies with the PAAL were conducted in 50-60 kg sheep after heparinization (activated clotting time range: 190-250 s) and cannulation with a 27 Fr. Avalon Elite dual-lumen cannula. The animals were able to move freely in a stanchion while device flow, resistance, and hemodynamics were recorded hourly. Oxygenation and hemolysis were measured daily. Platelet activation, blood chemistry, and comprehensive blood counts are reported for preoperatively, on POD 0, and POD 5. Three animals survived for 5 days. No study termination resulted from device failure. One animal was terminated on POD 0 and one animal was terminated at POD 3. The device was operated between 1.93 and 2.15 L/min. Blood left the device 100% oxygenated. Plasma-free hemoglobin ranged 10.8-14.5 mg/dl. CD62-P expression was under 10%. Minimal thrombus was seen in devices at explant. Chronic use of the PAAL in awake sheep is promising based on our study. There were no device-related complications over the study course. This study represents the next step in our pathway to eventual clinical translation.

Published

2017

39. Extracorporeal lung support for advanced lung failure: a new era in thoracic surgery and translational science

Author

N. Shigemura

Subjects

Pulmonary and Respiratory Medicine, endocrine system, medicine.medical_specialty, medicine.medical_treatment, 030204 cardiovascular system & hematology, Extracorporeal, Artificial lung, 03 medical and health sciences, 0302 clinical medicine, Extracorporeal Membrane Oxygenation, medicine, Extracorporeal membrane oxygenation, Lung transplantation, Humans, Intensive care medicine, Mechanical ventilation, Lung, business.industry, Patient Selection, Thoracic Surgery, General Medicine, respiratory system, Respiration, Artificial, respiratory tract diseases, medicine.anatomical_structure, 030228 respiratory system, Respiratory failure, Cardiothoracic surgery, Surgery, Cardiology and Cardiovascular Medicine, business, Respiratory Insufficiency, Lung Transplantation

Abstract

For the patients with progressively decompensating acute or acute-on-chronic respiratory failure, the first-choice treatment remains as mechanical ventilation. Despite the consistent value of mechanical ventilation, the majority of lung specialists are aware of its limitations, in particular for the patients with advanced lung failure, and inherent drawbacks that augment disease progression. More recently, the concept of allowing the lungs to 'rest and recover' has been supported by quite a few clinical studies. The pressure and volume of gas delivered to the lungs are reduced compared with mechanical ventilation. Based on recent remarkable evidence and experiences using extracorporeal lung support (ECLS) before, during and after lung transplant, there is growing interest in and expectations for the use of ECLS beyond lung transplant to encompass the entire field of pulmonary medicine. The purpose of this review article is to provide an update on evolving ECLS technologies and their effectiveness and discuss the future of ECLS for advanced lung failure as a new subspecialty in cardiothoracic surgery.

Published

2017

40. Revised protocol of extracorporeal membrane oxygenation (ECMO) therapy in severe ARDS. Recommendations of the Veno-venous ECMO Expert Panel appointed in February 2016 by the national consultant on anesthesiology and intensive care

Author

Dariusz Maciejewski, Romuald Lango, Andrzej W. Sosnowski, Zbigniew Szkulmowski, and Krzysztof Kusza

Subjects

Adult, medicine.medical_specialty, ARDS, Critical Care, medicine.medical_treatment, Ventilator-Induced Lung Injury, Lung injury, Critical Care and Intensive Care Medicine, Artificial lung, Extracorporeal, Hypoxemia, 03 medical and health sciences, 0302 clinical medicine, Extracorporeal Membrane Oxygenation, Anesthesiology, Intensive care, Extracorporeal membrane oxygenation, medicine, Humans, Intensive care medicine, Respiratory Distress Syndrome, business.industry, 030208 emergency & critical care medicine, General Medicine, Carbon Dioxide, medicine.disease, Respiration, Artificial, Oxygen, surgical procedures, operative, Anesthesiology and Pain Medicine, Practice Guidelines as Topic, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Extracorporeal Membrane Oxygenation (ECMO) has become well established technique of the treatment of severe acute respiratory failure (Veno-Venous ECMO) or circulatory failure (Veno-Arterial ECMO) which enables effective blood oxygenation and carbon dioxide removal for several weeks. Veno-Venous ECMO (V-V ECMO ) is a lifesaving treatment of patients in whom severe ARDS makes artificial lung ventilation unlikely to provide satisfactory blood oxygenation for preventing further vital organs damage and progression to death. The protocol below regards exclusively veno-venous ECMO treatment as a support for blood gas conditioning by means of extracorporeal circuit in adult patients with severe ARDS. V-V ECMO does not provide treatment for acutely and severely diseased lungs, but it enables patient to survive the critical phase of severe ARDS until recovery of lung function. Besides avoiding patients death from hypoxemia, this technique can also prevent further progression of the lung damage due to artificial ventilation. Recent experience of ECMO treatment since the outbreak of AH1N1 influenza pandemic in 2009, along with technical progress and advancement in understanding pathophysiology of ventilator-induced lung injury, have contributed to significant improvement of the results of ECMO treatment. Putative factors related to increased survival include patients retrieval after connecting them to ECMO, and less intensive anticoagulation protocols. The aim of presenting this revised protocol was to improve the effects of ECMO treatment in patients with severe ARDS, to enhance ECMO accessibility for patients who might possibly benefit from this treatment, to reduce time until patient's connection to ECMO, and to avoid ECMO treatment in futile cases. The authors believe that this protocol, based on recent papers and their own experience, can provide help and advice both for the centers which develop V-V ECMO program, and for doctors who will refer their patients for the treatment in an ECMO center.

Published

2017

41. Evaluation of a Nasal Cannula in Noninvasive Ventilation Using a Lung Simulator

Author

Narayan P. Iyer and Robert L Chatburn

Subjects

Pulmonary and Respiratory Medicine, Leak, Catheters, Nostril, Critical Care and Intensive Care Medicine, medicine.disease_cause, Models, Biological, Artificial lung, Positive-Pressure Respiration, medicine, Humans, Computer Simulation, Respiratory system, Lung, Nose, Noninvasive Ventilation, Ventilators, Mechanical, business.industry, Infant, Newborn, Equipment Design, General Medicine, respiratory system, Cannula, Equipment Failure Analysis, medicine.anatomical_structure, Anesthesia, Respiratory Mechanics, Nasal Cavity, business, Airway, Nasal cannula

Abstract

BACKGROUND: Nasal noninvasive ventilation (NIV) is a common form of noninvasive respiratory mode used in newborn infants. A next-generation nasal cannula (Neotech RAM cannula) has recently been used to provide nasal NIV. The impact of the Neotech RAM cannula on the delivery of pressure needs to be studied. METHODS: In this ex vivo experimental design, a lung simulator (IngMar ASL 5000, version 3.4) was programmed to model a neonate (∼1–3 kg of body weight) with normal-to-moderately affected lungs. We used a Covidien PB840 ventilator with NIV software activated to compensate for leaks. Nasal NIV was set at peak airway pressures of 15, 20, and 25 cm H2O and PEEP of 5, 6, and 7 cm H2O. Three sizes of the Neotech RAM cannula were used (prong outer diameters of 3.0, 3.5, and 4.0 mm). The nose was designed to keep the leak of the nares by the prongs to 30%. We also created a worst case leak (58% leak) by using the largest simulated nostril diameter with the smallest diameter Neotech RAM cannula prong. The outcome measure was the difference in pressures, referred to as leak effect, measured by the lung simulator relative to the set peak airway pressure and PEEP on the ventilator. RESULTS: For the interface with 30% leak, leak effects of peak airway pressure during simulated nasal NIV were similar with all Neotech RAM cannula sizes, with 63–75% of peak airway pressure and 70–90% of PEEP being transmitted across the nasal interface. The worst case scenario produced a 92% leak effect in peak airway pressure and PEEP. CONCLUSIONS: When used with ≤ 30% leak, the Neotech RAM cannula interface results in clinically acceptable transmission of pressures. With > 50% leak, a clinically negligible amount of pressure is transmitted to the artificial lungs.

Published

2014

42. Influence of substance πQ1983 on evoked potentials of somatosensory cortex during acute hypoxia development

Author

Denis Vladimirovich Sosin, Andrey Viktorovich Yevseyev, Marina Anatolyevna Yevseyeva, Petr Dmitriyevich Shabanov, and Vitaliy Andreyevich Pravdivtsev

Subjects

CATS, Stomach, chemistry.chemical_element, General Medicine, Somatosensory system, Oxygen, Artificial lung, medicine.anatomical_structure, chemistry, Anesthesia, Cortex (anatomy), Respiration, medicine, Breathing

Abstract

The influence of selenium-containing metal-complex substance πQ1983 on somatosensory cortex bioelectrical activity has been studied on cats (n = 22) during development of acute hypoxia. The condition of acute hypoxia was performed by making of loop including an animal, an apparatus for artificial lung ventilation, and a reservoir for respiration with 5 liter volume. Evoked activities of neurons were provided by direct electrical current irritations applied to the radial nerve of right superior extremity. Couple needle-shaped electrodes were used for mean evoked potentials registration. 100 mg/kg of the substance πQ1983 was introduced in the stomach 180 min before experiment. Also on any steps of the experiments ECG was registered. Containing of oxygen and carbon dioxide were determined by method of gas analysis in air enabled for respiration. It have been established that the substance πQ1983 taking internally increases cortex neurons functional activity period more than triple during acute hypoxia, stabilizes myocardial electrical activity, and helps animals to sustain the action of critical oxygen and carbon dioxide concentrations. Finally, the substance πQ1983 may be related to the high effectively antihypoxants because it significantly rises the resistance of animals with high CNS organization level (cats) to the acute hypoxia even after introduction per os.

Published

2014

43. Microporous Polypropylene Hollow Fiber Membrane Application in Membrane Oxygenator Model

Author

Yu Feng Zhang, Lei Ni, and Hong Ming Zhao

Subjects

Membrane, Materials science, Membrane oxygenator, Hollow fiber membrane, Extracorporeal circulation, General Medicine, Partial pressure, Oxygenation, Artificial lung, Biomedical engineering, Membrane technology

Abstract

In order to test the performance of the resulting membrane oxygenator, a model was constructed to simulate the inner and extracorporeal gas exchange of the human body. The oxygenation capacity of the membrane oxygenator was studied using fresh bovine blood with added anticoagulants as the test medium. The oxygenation performance of the prepared membrane was equal to that of the commercial membrane. After six hours of operation, the oxygen saturation (SaO2) was above 95%, and the partial pressure of oxygen (PaO2) was over 13.5 kPa (100 mmHg). This model was constructed in accordance with the basic principles of extracorporeal circulation, and could be used to investigate the oxygenation performance of a membrane oxygenator, as well as to study the basic principles of extracorporeal circulation.

Published

2014

44. ECMO for Adult Respiratory Failure

Author

Cara Agerstrand, Matthew Bacchetta, and Daniel Brodie

Subjects

Adult, medicine.medical_specialty, ARDS, Hypertension, Pulmonary, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, Artificial lung, Extracorporeal, Hypercapnia, Biomaterials, Pulmonary Disease, Chronic Obstructive, Extracorporeal Membrane Oxygenation, medicine, Extracorporeal membrane oxygenation, Humans, Lung transplantation, Intensive care medicine, Mechanical ventilation, Respiratory Distress Syndrome, business.industry, General Medicine, Carbon Dioxide, medicine.disease, Respiration, Artificial, Respiratory failure, medicine.symptom, Respiratory Insufficiency, business, Lung Transplantation

Abstract

Extracorporeal membrane oxygenation (ECMO) is increasingly being used to support adults with severe forms of respiratory failure. Fueling the explosive growth is a combination of technological improvements and accumulating, although controversial, evidence. Current use of ECMO extends beyond its most familiar role in the support of patients with severe acute respiratory distress syndrome (ARDS) to treat patients with various forms of severe hypoxemic or hypercapnic respiratory failure, ranging from bridging patients to lung transplantation to managing pulmonary hypertensive crises. The role of ECMO used primarily for extracorporeal carbon dioxide removal (ECCO2R) in the support of patients with hypercapnic respiratory failure and less severe forms of ARDS is also evolving. Select patients with respiratory failure may be liberated from invasive mechanical ventilation altogether and some may undergo extensive physical therapy while receiving extracorporeal support. Current research may yield a true artificial lung with the potential to change the paradigm of treatment for adults with chronic respiratory failure.

Published

2014

45. Effect of Impeller Design and Spacing on Gas Exchange in a Percutaneous Respiratory Assist Catheter

Author

William J. Federspiel, R. Garrett Jeffries, Greg W. Burgreen, and Brian J. Frankowski

Subjects

Materials science, business.industry, Biomedical Engineering, Medicine (miscellaneous), Water gas, Bioengineering, General Medicine, Computational fluid dynamics, Artificial lung, Biomaterials, Impeller, Catheter, Bundle, Anesthesia, Blood oxygenator, Respiratory system, business, Biomedical engineering

Abstract

Providing partial respiratory assistance by removing carbon dioxide (CO2 ) can improve clinical outcomes in patients suffering from acute exacerbations of chronic obstructive pulmonary disease and acute respiratory distress syndrome. An intravenous respiratory assist device with a small (25 Fr) insertion diameter eliminates the complexity and potential complications associated with external blood circuitry and can be inserted by nonspecialized surgeons. The impeller percutaneous respiratory assist catheter (IPRAC) is a highly efficient CO2 removal device for percutaneous insertion to the vena cava via the right jugular or right femoral vein that utilizes an array of impellers rotating within a hollow-fiber membrane bundle to enhance gas exchange. The objective of this study was to evaluate the effects of new impeller designs and impeller spacing on gas exchange in the IPRAC using computational fluid dynamics (CFD) and in vitro deionized water gas exchange testing. A CFD gas exchange and flow model was developed to guide a progressive impeller design process. Six impeller blade geometries were designed and tested in vitro in an IPRAC device with 2- or 10-mm axial spacing and varying numbers of blades (2-5). The maximum CO2 removal efficiency (exchange per unit surface area) achieved was 573 ± 8 mL/min/m(2) (40.1 mL/min absolute). The gas exchange rate was found to be largely independent of blade design and number of blades for the impellers tested but increased significantly (5-10%) with reduced axial spacing allowing for additional shaft impellers (23 vs. 14). CFD gas exchange predictions were within 2-13% of experimental values and accurately predicted the relative improvement with impellers at 2- versus 10-mm axial spacing. The ability of CFD simulation to accurately forecast the effects of influential design parameters suggests it can be used to identify impeller traits that profoundly affect facilitated gas exchange.

Published

2014

46. The development of the bioartificial lung

Author

Fatemeh Ajalloueian, Greg Lemon, Paolo Macchiarini, and Mei Ling Lim

Subjects

Lung Diseases, Pathology, medicine.medical_specialty, medicine.medical_treatment, Models, Biological, Artificial lung, Tissue engineering, medicine, Humans, Lung transplantation, Computer Simulation, Progenitor cell, Lung, Bioartificial Organs, Tissue Engineering, Tissue Scaffolds, business.industry, General Medicine, respiratory system, Embryonic stem cell, respiratory tract diseases, medicine.anatomical_structure, Lung disease, Chronic Disease, Stem cell, business, Lung Transplantation, Stem Cell Transplantation

Abstract

The incidence of chronic lung disease is increasing worldwide due to the spread of risk factors and ageing population. An important advance in treatment would be the development of a bioartificial lung where the blood-gas exchange surface is manufactured from a synthetic or natural scaffold material that is seeded with the appropriate stem or progenitor cells to mimic the functional tissue of the natural lung.Articles relating to bioartificial lungs were sourced through PubMed and ISI Web of Knowledge.There is a consensus that advances in bioartificial lung engineering will be beneficial to patients with chronic lung failure. Ultimate success will require the concerted efforts of researchers drawn from a broad range of disciplines, including clinicians, cell biologists, materials scientists and engineers.As a source of cells for use in bioartificial lungs it is proposed to use human embryonic stem cells; however, there are ethical and safety concerns regarding the use of these cells.There is a need to identify the optimum strategies for differentiating progenitor cells into functional lung cells; a need to better understand cell-biomaterial/ECM interactions and a need to understand how to harness the body's natural capacity to regenerate the lung.Biomaterial technologies for recreating the natural lung ECM and architecture need further development. Mathematical modelling techniques should be developed for determining optimal scaffold seeding strategies and predicting gas exchange performance.

Published

2013

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

Author

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

Subjects

Lung, Biocompatibility, business.industry, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, General Medicine, medicine.disease, Thrombosis, Artificial lung, Biomaterials, medicine.anatomical_structure, medicine.artery, Pulmonary artery, medicine, Platelet, Platelet activation, Thrombus, business, Biomedical engineering

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 (CD62P) 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.

Published

2013

48. Fiber bundle design for an integrated wearable artificial lung

Author

William J. Federspiel, Brian J. Frankowski, and Shalv P. Madhani

Subjects

medicine.medical_specialty, ARDS, medicine.medical_treatment, Biomedical Engineering, Biophysics, Bioengineering, 030204 cardiovascular system & hematology, Artificial lung, Article, Biomaterials, 03 medical and health sciences, Pulmonary Disease, Chronic Obstructive, 0302 clinical medicine, Extracorporeal Membrane Oxygenation, Internal medicine, medicine, Extracorporeal membrane oxygenation, Humans, Lung, Mechanical ventilation, COPD, Respiratory Distress Syndrome, business.industry, General Medicine, Blood flow, Oxygenation, respiratory system, medicine.disease, Respiration, Artificial, respiratory tract diseases, Oxygen, 030228 respiratory system, Bundle, Cardiology, Artificial Organs, business, Respiratory Insufficiency

Abstract

Mechanical ventilation (MV) and extracorporeal membrane oxygenation (ECMO) are the only viable treatment options for lung failure patients at the end-stage, including acute respiratory distress syndrome (ARDS) and chronic obstructive pulmonary disease (COPD). These treatments, however, are associated with high morbidity and mortality because of long wait times for lung transplant. Contemporary clinical literature has shown ambulation improves post-transplant outcomes in lung failure patients. Given this, we are developing the Pittsburgh Ambulatory Assist Lung (PAAL), a truly wearable artificial lung that allows for ambulation. In this study, we targeted 180 ml/min oxygenation and determined the form factor for a hollow fiber membrane (HFM) bundle for the PAAL. Based on a previously published mass transfer correlation, we modeled oxygenation efficiency as a function of fiber bundle diameter. Three benchmark fiber bundles were fabricated to validate the model through in vitro blood gas exchange at blood flow rates from 1 to 4 L/min according to ASTM standards. We used the model to determine a final design, which was characterized in vitro through a gas exchange as well as a hemolysis study at 3.5 L/min. The percent difference between model predictions and experiment for the benchmark bundles ranged from 3% to 17.5% at the flow rates tested. Using the model, we predicted a 1.75 in diameter bundle with 0.65 m surface area would produce 180 ml/min at 3.5 L/min blood flow rate. The oxygenation efficiency was 278 ml/min/m and the Normalized Index of Hemolysis (NIH) was less than 0.05 g/100 L. Future work involves integrating this bundle into the PAAL for which an experimental prototype is under development in our laboratory.

Published

2017

49. A Novel and Experimental Design for Mechanical Ventilation with Optimal Spontaneous Flow Pattern and WOB Feedback Control

Author

Hsing-Cheng Chang, San-Shan Hung, Ching Kun Chen, and Shyan-Lung Lin

Subjects

Mechanical ventilation, Engineering, business.industry, medicine.medical_treatment, Airflow, Process (computing), General Medicine, Respiratory physiology, Artificial lung, Work of breathing, Control theory, medicine, Breathing, business, Simulation

Abstract

In this study, we proposed an innovative design for mechanical ventilation by applying the previously implemented optimal respiratory control simulator as the controller of an experimental ventilation device. Instead of providing a fixed airflow pattern, an optimal spontaneous flow pattern was optimized by the simulator based on patient’s estimated respiratory mechanics and was applied to drive a ventilation device. We also implemented an experimental ventilation control system, including the simulator, a ventilation device, an artificial lung, and a feedback control mechanism to attain minimum work of breathing during mechanical ventilation. The experiments were elaborated to verify that once patient’s respiratory physiology was significant changed, the breathing signals and measured respiratory mechanics were instantaneously monitored, and the optimization process was renewed by the simulator under the feedback control strategy.

Published

2013

50. A Non-Invasive Method for Estimating Cardiopulmonary Variables Using Breath-by-Breath Injection of Two Tracer Gases

Author

Lei Clifton, A. D. Farmeryy, David A. Clifton, and Clive E.W. Hahn

Subjects

lcsh:Medical technology, Dead space, Biomedical Engineering, tracer gas, lcsh:Computer applications to medicine. Medical informatics, Article, Artificial lung, law.invention, breath-by-breath, 03 medical and health sciences, 0302 clinical medicine, 030202 anesthesiology, law, TRACER, cardiopulmonary variables, Medicine, Lung volumes, Non-invasive, Simulation, Critical condition, tidal ventilation, model, business.industry, Non invasive, General Medicine, Intensive care unit, lcsh:R855-855.5, Anesthesia, Ventilation (architecture), lcsh:R858-859.7, business, 030217 neurology & neurosurgery

Abstract

Conventional methods for estimating cardiopulmonary variables usually require complex gas analyzers and the active co-operation of the patient. Therefore, they are not compatible with the crowded environment of the intensive care unit (ICU) or operating theatre, where patient co-operation is typically impossible. However, it is these patients that would benefit the most from accurate estimation of cardiopulmonary variables, because of their critical condition. This paper describes the results of a collaborative development between an anesthesiologists and biomedical engineers to create a compact and non-invasive system for the measurement of cardiopulmonary variables such as lung volume, airway dead space volume, and pulmonary blood flow. In contrast with conventional methods, the compact apparatus and non-invasive nature of the proposed method allow it to be used in the ICU, as well as in general clinical settings. We propose the use of a non-invasive method, in which tracer gases are injected into the patient's inspired breath, and the concentration of the tracer gases is subsequently measured. A novel breath-by-breath tidal ventilation model is then used to estimate the value of a patient's cardiopulmonary variables. Experimental results from an artificial lung demonstrate minimal error in the estimation of known parameters using the proposed method. Results from analysis of a cohort of 20 healthy volunteers (within the Oxford University Hospitals NHS Trust) show that the values of estimated cardiopulmonary variables from these subjects lies within the expected ranges. Advantages of this method are that it is non-invasive, compact, portable, and can perform analysis in real time with less than 1 min of acquired respiratory data.

Published

2013