Characterization of anisotropic pore structure and dense selective layer of capillary membranes for long-term ECMO by cross-sectional ion-milling method.
Makoto FukudaKazunori SadanoTomoki MaedaEri MurataNaoyuki MiyashitaTsutomu TanakaTomohiro MoriAkane SaitoKiyotaka SakaiPublished in: Journal of artificial organs : the official journal of the Japanese Society for Artificial Organs (2024)
Since the COVID-19 pandemic of 2020-2023, extracorporeal membrane oxygenator (ECMO) has attracted considerable attention worldwide. It is expected that ECMO with long-term durability is put into practical use in order to prepare for next emerging infectious diseases and to facilitate manufacturing for novel medical devices. Polypropylene (PP) and polymethylpentene (PMP) capillary membranes are currently the mainstream for gas exchange membrane for ECMO. ECMO support days for COVID-19-related acute hypoxemic respiratory failure have been reported to be on average for 14 or 24 days. It is necessary to improve opposing functions such that promoting the permeation of oxygen and carbon dioxide and inhibiting the permeation of water vapor or plasma to develop sufficient durability for long-term use. For this purpose, accurately controlling the anisotropy of the pore structure of the entire cross section and functions of capillary membrane is significant. In this study, we focused on the cross-sectional ion-milling (CSIM) method, to precisely clarify the pore structure of the entire cross section of capillary membrane for ECMO, because there is less physical stress on the porous structure applied during the preparation of cross-sectional samples of porous capillary membranes. We attempted to observe the cross sections of commercially available PMP membranes using the CSIM method. As a result, we succeeded in fabricating fine-scale flat cross-sectional samples of PMP capillary membranes. The pore structures and the degree of anisotropy of the cross sections are quantitatively clarified. The achievements and the approaches of this study are being applied to the development of next-generation gas exchange membranes.
Keyphrases
- respiratory failure
- cross sectional
- extracorporeal membrane oxygenation
- carbon dioxide
- acute respiratory distress syndrome
- mechanical ventilation
- infectious diseases
- coronavirus disease
- sars cov
- signaling pathway
- air pollution
- intensive care unit
- mental health
- liver failure
- respiratory syndrome coronavirus
- highly efficient