TY - GEN
T1 - Estimating the Impact of Peritoneal Perfluorocarbon Perfusion on Carbon Dioxide Transport Dynamics in a Laboratory Animal
AU - Doosthosseini, Mahsa
AU - Moon, Yejin
AU - Commins, Annina
AU - Wood, Sam
AU - Naselsky, Warren
AU - Culligan, Melissa J.
AU - Aroom, Kevin
AU - Aroom, Majid
AU - Shah, Akash
AU - Bittle, Gregory J.
AU - Thamire, Chandrasekhar
AU - Zaleski, Nadia
AU - Fang, Catherine
AU - O'Leary, Joseph
AU - Hopkins, Grace
AU - Friedberg, Joseph S.
AU - Hahn, Jin Oh
AU - Fathy, Hosam K.
N1 - Publisher Copyright:
© 2022 American Automatic Control Council.
PY - 2022
Y1 - 2022
N2 - This paper identifies a state-space model of the impact of the peritoneal perfusion of an oxygenated perfluorocarbon (PFC) on the dynamics of carbon dioxide (CO2) transport in a large laboratory animal. Previous research shows that such perfusion has the potential to enable the peritoneal cavity to serve as a "third lung"that supplements oxygenation during hypoxia. However, the effect of this potential treatment modality on CO2 transport dynamics remains relatively unexplored. The paper addresses this gap by: (i) proposing a three-compartment model of CO2 transport dynamics; (ii) utilizing time scale separation to simplify it into a residualized single-compartment model; and (iii) parameterizing the model using experimental data. Two experimental datasets are used for parameterization, involving the use of reduced minute ventilation to induce hypercarbia both (i) with and (ii) without PFC perfusion. Fisher analysis is used for quantifying the resulting model parameter uncertainties. The outcomes of this analysis strongly suggest a positive impact of perfusion on CO2 clearance, with further validation experiments planned as future work.
AB - This paper identifies a state-space model of the impact of the peritoneal perfusion of an oxygenated perfluorocarbon (PFC) on the dynamics of carbon dioxide (CO2) transport in a large laboratory animal. Previous research shows that such perfusion has the potential to enable the peritoneal cavity to serve as a "third lung"that supplements oxygenation during hypoxia. However, the effect of this potential treatment modality on CO2 transport dynamics remains relatively unexplored. The paper addresses this gap by: (i) proposing a three-compartment model of CO2 transport dynamics; (ii) utilizing time scale separation to simplify it into a residualized single-compartment model; and (iii) parameterizing the model using experimental data. Two experimental datasets are used for parameterization, involving the use of reduced minute ventilation to induce hypercarbia both (i) with and (ii) without PFC perfusion. Fisher analysis is used for quantifying the resulting model parameter uncertainties. The outcomes of this analysis strongly suggest a positive impact of perfusion on CO2 clearance, with further validation experiments planned as future work.
UR - http://www.scopus.com/inward/record.url?scp=85138493106&partnerID=8YFLogxK
U2 - 10.23919/ACC53348.2022.9867437
DO - 10.23919/ACC53348.2022.9867437
M3 - Conference contribution
AN - SCOPUS:85138493106
T3 - Proceedings of the American Control Conference
SP - 3000
EP - 3005
BT - 2022 American Control Conference, ACC 2022
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2022 American Control Conference, ACC 2022
Y2 - 8 June 2022 through 10 June 2022
ER -