Immobilized carbonic anhydrase on hollow fiber membranes accelerates CO2 removal from blood

Arazawa, David T.; Oh, Heung-Il; Ye, Sang‐Ho; Johnson, C. Anderson; Woolley, Joshua R.; Wagner, William R.; Federspiel, William J.

doi:10.1016/j.memsci.2012.02.006

Cited by 72 publications

(52 citation statements)

References 39 publications

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“…S5) arranged in parallel and fitted into a 1/8 inch acrylic tube, similar to previous designs (Kaar et al, 2007;Arazawa et al, 2012). The volume surrounding the fibres (0.6 ml) was perfused with water coming from the measuring chamber that was circulated in a closed loop by a peristaltic pump (Gilson MINIPULS 3, Middleton, WI, USA).…”

Section: Methodsmentioning

confidence: 99%

“…Water was circulated in a closed loop indicated by the blue arrows, and CO 2 -free purge-gas is represented by the dashed arrows. The interface between water and air was a hollow fibre membrane (HFM) gas exchanger, in which water was circulated on the outside of a bundle of gas permeable fibres and CO 2 -free purge-gas was circulated through the lumen of the fibres in a counter-current fashion, similar to previous designs (Kaar et al, 2007;Arazawa et al, 2012). See Materials and methods, Experimental setup for specifications of system components.…”

Section: Calculations and Data Analysismentioning

confidence: 99%

See 1 more Smart Citation

A novel technique for the precise measurement of CO2 production rate in small aquatic organisms as validated on Aeshnid dragonfly nymphs

Harter

Brauner

Matthews

2017

Journal of Experimental Biology

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The present study describes and validates a novel yet simple system for simultaneous in vivo measurements of rates of aquatic CO 2 production (Ṁ CO2 ) and oxygen consumption (Ṁ O2 ), thus allowing the calculation of respiratory exchange ratios (RER). Diffusion of CO 2 from the aquatic phase into a gas phase, across a hollow fibre membrane, enabled aquatic Ṁ CO2 measurements with a highprecision infrared gas CO 2 analyser. Ṁ O2 was measured with a P O2 optode using a stop-flow approach. Injections of known amounts of CO 2 into the apparatus yielded accurate and highly reproducible measurements of CO 2 content (R 2 =0.997, P<0.001). The viability of in vivo measurements was demonstrated on aquatic dragonfly nymphs (Aeshnidae; wet mass 2.17 mg-1.46 g, n=15) and the apparatus produced precise Ṁ CO2 (R 2 =0.967, P<0.001) and Ṁ O2 (R 2 =0.957, P<0.001) measurements; average RER was 0.73± 0.06. The described system is scalable, offering great potential for the study of a wide range of aquatic species, including fish.

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Section: Methodsmentioning

confidence: 99%

Section: Calculations and Data Analysismentioning

confidence: 99%

A novel technique for the precise measurement of CO2 production rate in small aquatic organisms as validated on Aeshnid dragonfly nymphs

Harter

Brauner

Matthews

2017

Journal of Experimental Biology

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“…Previous work by our group to chemically increase trans-HFM CO 2 pressure utilized bioactive CA-HFMs for a 31–37% improvement in blood CO 2 removal efficiency [27], [28]. In this work, the addition of SO 2 to an oxygen sweep gas increased CO 2 removal of unmodified PMP HFMs up to 17%, and for bioactive CA-PMP HFMs up to 109% (Figure 2).…”

Section: Discussionmentioning

confidence: 67%

“…Our lung tissues face the same diffusional challenges as HFMs, however they employ the enzyme carbonic anhydrase (CA) within red blood cells and on the endothelial surfaces of lung capillaries to accelerate diffusion by catalyzing the reversible dehydration of HCO 3 − (bicarbonate) to gaseous carbon dioxide:

{CO}_{2} + H_{2} normalO \overset{C A}{\Leftrightarrow} {HCO}_{3}^{-} + H^{+}

. We reported development of CA immobilized bioactive HFMs which converts bicarbonate to CO 2 directly at the HFM surface, restoring the trans-HFM CO 2 gradient as it is depleted in the diffusional boundary layer, and increasing CO 2 removal rates from blood by 36% in model gas exchange devices [27]–[29]. The main impediment to CO 2 removal by bioactive HFMs is diffusional boundary layer resistance which restricts transport of CO 2 and bicarbonate from the bulk fluid to the HFM surface, not the CA catalyzed conversion of bicarbonate to CO 2 [28].…”

Section: Introductionmentioning

confidence: 99%

Acidic sweep gas with carbonic anhydrase coated hollow fiber membranes synergistically accelerates CO2 removal from blood

et al. 2015

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The use of extracorporeal carbon dioxide removal (ECCO2R) is well established as a therapy for patients suffering from acute respiratory failure. Development of next generation low blood flow (< 500 mL/min) ECCO2R devices necessitates more efficient gas exchange devices. Since over 90% of blood CO2 is transported as bicarbonate (HCO3−), we previously reported development of a carbonic anhydrase (CA) immobilized bioactive hollow fiber membrane (HFM) which significantly accelerates CO2 removal from blood in model gas exchange devices by converting bicarbonate to CO2 directly at the HFM surface. This present study tested the hypothesis that dilute sulfur dioxide (SO2) in oxygen sweep gas could further increase CO2 removal by creating an acidic microenvironment within the diffusional boundary layer adjacent to the HFM surface, facilitating dehydration of bicarbonate to CO2. CA was covalently immobilized onto poly (methyl pentene) (PMP) HFMs through glutaraldehyde activated chitosan spacers, potted in model gas exchange devices (0.0151m2) and tested for CO2 removal rate with oxygen (O2) sweep gas and a 2.2% SO2 in oxygen sweep gas mixture. Using pure O2 sweep gas, CA-PMP increased CO2 removal by 31% (258 mL/min/m2) compared to PMP (197 mL/min/m2) (P < 0.05). Using 2.2% SO2 acidic sweep gas increased PMP CO2 removal by 17% (230 mL/min/m2) compared to pure oxygen sweep gas control (P < 0.05); device outlet blood pH was 7.38 units. When employing both CA-PMP and 2.2% SO2 sweep gas, CO2 removal increased by 109% (411 mL/min/m2) (P < 0.05); device outlet blood pH was 7.35 units. Dilute acidic sweep gas increases CO2 removal, and when used in combination with bioactive CA-HFMs has a synergistic effect to more than double CO2 removal while maintaining physiologic pH. Through these technologies the next generation of intravascular and paracorporeal respiratory assist devices can remove more CO2 with smaller blood contacting surface areas.

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“…We previously demonstrated enhanced CO 2 removal by covalently immobilizing CA directly on the surface of hollow fiber membranes (HFMs), which locally converts bicarbonate to gaseous CO 2 at the fiber surface, resulting in increased blood-side CO 2 partial pressure and accelerated CO 2 flux through the membrane [12, 13]. In this work, we developed a new coating technology using glutaraldehyde activated chitosan to covalently tether CA to the surface of HFMs used in a commercial ECCO 2 R device (Hemolung, ALung Technologies).…”

Section: Introductionmentioning

confidence: 99%

Carbonic anhydrase immobilized on hollow fiber membranes using glutaraldehyde activated chitosan for artificial lung applications

Kimmel

Arazawa

et al. 2013

J Mater Sci: Mater Med

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Extracorporeal CO2 removal from circulating blood is a promising therapeutic modality for the treatment of acute respiratory failure. The enzyme carbonic anhydrase accelerates CO2 removal within gas exchange devices by locally catalyzing HCO3− into gaseous CO2 within the blood. In this work, we covalently immobilized carbonic anhydrase on the surface of polypropylene hollow fiber membranes using glutaraldehyde activated chitosan tethering to amplify the density of reactive amine functional groups for enzyme immobilization. XPS and a colorimetric amine assay confirmed higher amine densities on the chitosan coated fiber compared to control fiber. Chitosan/CA coated fibers exhibited accelerated CO2 removal in scaled-down gas exchange devices in buffer and blood (115 % enhancement vs. control, 37 % enhancement vs. control, respectively). Carbonic anhydrase immobilized directly on hollow fiber membranes without chitosan tethering resulted in no enhancement in CO2 removal. Additionally, fibers coated with chitosan/carbonic anhydrase demonstrated reduced platelet adhesion when exposed to blood compared to control and heparin coated fibers.

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Immobilized carbonic anhydrase on hollow fiber membranes accelerates CO2 removal from blood

Cited by 72 publications

References 39 publications

A novel technique for the precise measurement of CO2 production rate in small aquatic organisms as validated on Aeshnid dragonfly nymphs

A novel technique for the precise measurement of CO2 production rate in small aquatic organisms as validated on Aeshnid dragonfly nymphs

Acidic sweep gas with carbonic anhydrase coated hollow fiber membranes synergistically accelerates CO2 removal from blood

Carbonic anhydrase immobilized on hollow fiber membranes using glutaraldehyde activated chitosan for artificial lung applications

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