Data on a simple method for producing a solution that contains a high partial pressure of oxygen and a low partial pressure of carbon dioxide

The data presented here shows a simple method for producing a solution that contains a high partial pressure of oxygen (pO2) and a low partial pressure of carbon dioxide (pCO2). This novel solution was created by simply injecting oxygen gas into conventional supplemental bicarbonate fluid for renal replacement therapy. We compared the gas profiles of the novel solution and the conventional fluid in vitro. There was a significant increase in pO2 and pH, and a significant decrease in pCO2 in the experimental solution, in each of which an additional volume of oxygen was injected. The method shown here is capable of facilitating an increase of pO2 and decrease of pCO2 by using a closed fluid bag without any special devices.


a b s t r a c t
The data presented here shows a simple method for producing a solution that contains a high partial pressure of oxygen (pO 2 ) and a low partial pressure of carbon dioxide (pCO 2 ). This novel solution was created by simply injecting oxygen gas into conventional supplemental bicarbonate fluid for renal replacement therapy. We compared the gas profiles of the novel solution and the conventional fluid in vitro. There was a significant increase in pO 2 and pH, and a significant decrease in pCO 2 in the experimental solution, in each of which an additional volume of oxygen was injected. The method shown here is capable of facilitating an increase of pO 2 and decrease of pCO 2 by using a closed fluid bag without any special devices.
& 2018 The Authors. Published by Elsevier Inc. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

Subject area
Medicine More specific subject area

Biotechnology
Type of data

How data was acquired
Gas profiles measured by EG6þ cartridge (Abbott Japan Co., Ltd, Osaka, Japan) with an i-STAT system (300F, Abbott, Japan)

Data format
Analysed data Experimental factors Simply injected oxygen gas into supplemental fluid bag.

Experimental features
Samples were prepared by injecting oxygen gas via a syringe into conventional bicarbonate supplemental fluid (sublood BSG, Fuso, Osaka, Japan). The volumes of oxygen injected into the fluid were zero for the control solution, and 500, 1000, and 1400 mL into 2020 mL of the supplemental fluid for the experimental solution.

Data source location
Nobeoka City, Miyazaki, Japan Data accessibility All data are included in this document.

Value of the data
A solution with high pO 2 and low pCO 2 was obtained using a simple method. This method only requires oxygen gas. This method did not require any special devices, unlike those previously reported.

Data
Intravenous fluid with a high partial pressure of oxygen (pO 2 ) was shown to improve hypoxia in several animal models [1][2][3]. Further studies demonstrated that fluids containing high amounts of dissolved oxygen achieved supersaturated oxygen levels in the bloodstream, but special devices were needed to create these fluids [4,5]. If such fluids were simpler to create, they could be used easily at the bedside. The data presented here shows a simple method for producing a solution that contains a high pO 2 and a low pCO 2 , using the supplemental fluid.

Materials
Samples were prepared using a conventional bicarbonate supplemental fluid (sublood BSG, Fuso, Osaka, Japan); the air was removed using a syringe (Nipro, Osaka, Japan). The composition of supplemental fluid is shown in Table 1.

Methods
The samples were injected with oxygen gas via a syringe connected to an oxygen piping line. The volumes of oxygen injected into the fluid were zero for the control solution, and 500, 1000, and 1400 mL into 2020 mL of supplemental fluid for the experimental solution. To determine the gas profile in the supplemental fluid, we sampled the fluid in bags containing dissolved oxygen after shaking them for one minute. We determined the pO 2 , pCO 2 , and pH values using an EG6 þ cartridge (Abbott Japan Co., Ltd, Osaka, Japan) with an i-STAT system (300F, Abbott, Japan). Samples were analysed immediately after the injection of oxygen for obtaining the baseline data, and for up to 72 h subsequently (n ¼ 6). The room temperature was set at 24 7 0.5°C. Figs. 1-3 show the changes in the gas profiles of the solutions. The values for the supplemental fluid immediately after the injection of 500, 1000, and 1400 mL of oxygen were set as the baseline values.  The time course of the experimental and control solutions was compared using repeated-measures analysis of variance, and the groups were compared with Bonferroni correction, as appropriate.