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Mathematical Biosciences and Engineering

2015, Volume 12, Issue 5: 1127-1139. doi: 10.3934/mbe.2015.12.1127
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Combining robust state estimation with nonlinear model predictive control to regulate the acute inflammatory response to pathogen

  • 1.
    Department of Mathematics, University of California, Irvine, 340 Rowland Hall, Bldg #400, Irvine, CA 92697-3875
  • 2.
    Electrical Engineering and Computer Science Department, Masdar Institute of Science and Technology, Masdar City, Abu Dhabi
  • 3.
    Department of Mathematics, University of Tennessee, 1403 Circle Dr, Ayres Hall 227, Knoxville, TN, 37996-2250
  • Received: 01 September 2014 Accepted: 29 June 2018 Published: 01 June 2015

  • MSC : Primary: 92C50, 93C15; Secondary: 93C83.

  • The inflammatory responseaims to restore homeostasis by means of removing a biological stress, such as an invading bacterial pathogen.In cases of acute systemic inflammation, the possibility of collateral tissuedamage arises, which leads to a necessary down-regulation of the response.A reduced ordinary differential equations (ODE) model of acute inflammation was presented and investigated in [10]. That system contains multiple positive and negative feedback loops and is a highly coupled and nonlinear ODE. The implementation of nonlinear model predictive control (NMPC) as a methodology for determining proper therapeutic intervention for in silico patients displaying complex inflammatory states was initially explored in [5]. Since direct measurements of the bacterial population and the magnitude of tissue damage/dysfunction are not readily available or biologically feasible, the need for robust state estimation was evident. In this present work, we present resultson the nonlinear reachability of the underlying model, and then focus our attention on improving the predictability of the underlying model by coupling the NMPC with a particle filter. The results, though comparable to the initial exploratory study, show that robust state estimation of this highly nonlinear model can provide an alternative to prior updating strategies used when only partial access to the unmeasurable states of the system are available.

    Citation: Gregory Zitelli, Seddik M. Djouadi, Judy D. Day. Combining robust state estimation with nonlinear model predictive control to regulate the acute inflammatory response to pathogen[J]. Mathematical Biosciences and Engineering, 2015, 12(5): 1127-1139. doi: 10.3934/mbe.2015.12.1127

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  • The inflammatory responseaims to restore homeostasis by means of removing a biological stress, such as an invading bacterial pathogen.In cases of acute systemic inflammation, the possibility of collateral tissuedamage arises, which leads to a necessary down-regulation of the response.A reduced ordinary differential equations (ODE) model of acute inflammation was presented and investigated in [10]. That system contains multiple positive and negative feedback loops and is a highly coupled and nonlinear ODE. The implementation of nonlinear model predictive control (NMPC) as a methodology for determining proper therapeutic intervention for in silico patients displaying complex inflammatory states was initially explored in [5]. Since direct measurements of the bacterial population and the magnitude of tissue damage/dysfunction are not readily available or biologically feasible, the need for robust state estimation was evident. In this present work, we present resultson the nonlinear reachability of the underlying model, and then focus our attention on improving the predictability of the underlying model by coupling the NMPC with a particle filter. The results, though comparable to the initial exploratory study, show that robust state estimation of this highly nonlinear model can provide an alternative to prior updating strategies used when only partial access to the unmeasurable states of the system are available.


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    2. M. S. Vinogradova, S. B. Tkachev, O. S. Tkacheva, Using an Observer in a Sliding Mode for Modeling Antiangiogenic Therapy, 2019, 2412-5911, 52, 10.24108/mathm.0618.0000165
    3. Ouassim Bara, Michel Fliess, Cédric Join, Judy Day, Seddik M. Djouadi, Toward a model-free feedback control synthesis for treating acute inflammation, 2018, 448, 00225193, 26, 10.1016/j.jtbi.2018.04.003
    4. Ouassim Bara, Michel Fliess, Cedric Join, Judy Day, Seddik M. Djouadi, 2016, Model-free immune therapy: A control approach to acute inflammation, 978-1-5090-2591-6, 2102, 10.1109/ECC.2016.7810602
    5. O. Bara, S.M. Djouadi, J.D. Day, S. Lenhart, Immune therapeutic strategies using optimal controls with L 1 and L 2 type objectives, 2017, 290, 00255564, 9, 10.1016/j.mbs.2017.05.010
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    7. Jan Ewald, Patricia Sieber, Ravindra Garde, Stefan N. Lang, Stefan Schuster, Bashar Ibrahim, Trends in mathematical modeling of host–pathogen interactions, 2020, 77, 1420-682X, 467, 10.1007/s00018-019-03382-0
    8. Olivier Joannes-Boyau, A. Dewitte, Patrick M. Honoré, 2019, 9780323449427, 1034, 10.1016/B978-0-323-44942-7.00171-0
    9. David Jaurès Fotsa-Mbogne, Estimation of anthracnose dynamics by nonlinear filtering, 2018, 11, 1793-5245, 1850005, 10.1142/S1793524518500055
    10. Judy D. Day, Chase Cockrell, Rami Namas, Ruben Zamora, Gary An, Yoram Vodovotz, Inflammation and disease: Modelling and modulation of the inflammatory response to alleviate critical illness, 2018, 12, 24523100, 22, 10.1016/j.coisb.2018.08.008
    11. G. Rigatos, K. Busawon, M. Abbaszadeh, Nonlinear optimal control of the acute inflammatory response, 2020, 55, 17468094, 101631, 10.1016/j.bspc.2019.101631
    12. Judy D. Day, Soojin Park, Benjamin L. Ranard, Harinder Singh, Carson C. Chow, Yoram Vodovotz, Divergent COVID-19 Disease Trajectories Predicted by a DAMP-Centered Immune Network Model, 2021, 12, 1664-3224, 10.3389/fimmu.2021.754127
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  • © 2015 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)
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