Search Advanced

Mathematical Biosciences and Engineering

2013, Volume 10, Issue 3: 787-802. doi: 10.3934/mbe.2013.10.787
Previous Article Next Article

On optimal chemotherapy with a strongly targeted agent for a model of tumor-immune system interactions with generalized logistic growth

  • 1.
    Dept. of Mathematics and Statistics, Southern Illinois University Edwardsville, Edwardsville, Illinois, 62026-1653
  • 2.
    Dept. of Electrical and Systems Engineering, Washington University, St. Louis, Mo 63130
  • Received: 01 September 2012 Accepted: 29 June 2018 Published: 01 April 2013

  • MSC : Primary: 49K15, 92C50; Secondary: 93C95.

  • In this paper, a mathematical model for chemotherapy that takestumor immune-system interactions into account is considered for astrongly targeted agent. We use a classical model originallyformulated by Stepanova, but replace exponential tumor growth with ageneralised logistic growth model function depending on a parameter$\nu$. This growth function interpolates between a Gompertzian model(in the limit $\nu\rightarrow0$) and an exponential model (in thelimit $\nu\rightarrow\infty$). The dynamics is multi-stable andequilibria and their stability will be investigated depending on theparameter $\nu$. Except for small values of $\nu$, the system hasboth an asymptotically stable microscopic (benign) equilibrium pointand an asymptotically stable macroscopic (malignant) equilibriumpoint. The corresponding regions of attraction are separated by thestable manifold of a saddle. The optimal control problem of movingan initial condition that lies in the malignant region into thebenign region is formulated and the structure of optimal singularcontrols is determined.

    Citation: Urszula Ledzewicz, Omeiza Olumoye, Heinz Schättler. On optimal chemotherapy with a strongly targeted agent for a model of tumor-immune system interactions with generalized logistic growth[J]. Mathematical Biosciences and Engineering, 2013, 10(3): 787-802. doi: 10.3934/mbe.2013.10.787

    Related Papers:

  • In this paper, a mathematical model for chemotherapy that takestumor immune-system interactions into account is considered for astrongly targeted agent. We use a classical model originallyformulated by Stepanova, but replace exponential tumor growth with ageneralised logistic growth model function depending on a parameter$\nu$. This growth function interpolates between a Gompertzian model(in the limit $\nu\rightarrow0$) and an exponential model (in thelimit $\nu\rightarrow\infty$). The dynamics is multi-stable andequilibria and their stability will be investigated depending on theparameter $\nu$. Except for small values of $\nu$, the system hasboth an asymptotically stable microscopic (benign) equilibrium pointand an asymptotically stable macroscopic (malignant) equilibriumpoint. The corresponding regions of attraction are separated by thestable manifold of a saddle. The optimal control problem of movingan initial condition that lies in the malignant region into thebenign region is formulated and the structure of optimal singularcontrols is determined.


    加载中
    [1] Biology Direct, 7 (2012), 31.
    [2] Physics of Life Reviews, 5 (2008), 183-206.
    [3] Mathematical and Computational Modelling, 32 (2000), 413-452.
    [4] Springer Verlag, Series: Mathematics and Applications, 40 (2003).
    [5] American Institute of Mathematical Sciences, 2007.
    [6] Annual Review of Immunology, 22 (2004), 322-360.
    [7] Mathematical Modelling of Natural Phenomena, 7 (2012), 1-26.
    [8] Springer Verlag, New York, 1983.
    [9] J. of Theoretical Biology, 220 (2003), 545-554.
    [10] W. H. Freeman, 2006.
    [11] J. of Mathematical Biology, 37 (1998), 235-252.
    [12] Nature, 450 (2007), 903-905.
    [13] Bulletin of Mathematical Biology, 56 (1994), 295-321.
    [14] Proceedings of the 51st IEEE Proceedings on Decision and Control, Maui, Hawaii, (2012), 7492-7497.
    [15] Proceedings of the 8th AIMS Conference, Dresden, Germany, (2010), 971-980.
    [16] J. of Mathematical Biology, 64 (2012), 557-577.
    [17] Mathematical Biosciences and Engineering (MBE), 2 (2005), 561-578.
    [18] Mathematical Medicine and Biology, 21 (2004), 1-34.
    [19] Physica D, 208 (2005), 220-235.
    [20] Mathematical Models and Methods in Applied Sciences, 16 (2006), 1375-1401.
    [21] Chaos, Solitons and Fractals, 31 (2007), 261-268.
    [22] Mathematical and Computational Modelling, 47 (2008), 614-637.
    [23] Chaos, Solitons and Fractals, 41 (2009), 875-880.
    [24] Physical Review E, 84 (2011).
    [25] Cell Proliferation, 42 (2009), 317-329.
    [26] Annual Reviews of Immunology, 21 (2003), 807-839.
    [27] Nature Reviews$|$ Clinical Oncology, 7 (2010), 455-465.
    [28] J. of Clinical Oncology, 23, (2005), 939-952.
    [29] Cancer Research, 65 (2005), 7950-7958.
    [30] MacMillan, New York, 1964.
    [31] Springer Verlag, 2012.
    [32] Biophysics, 24 (1980), 917-923.
    [33] J. of Clinical Investigations, 117 (2007), 1137-1146.
    [34] J. of Theoretical Biology, 227 (2004), 335-348.
    [35] J. of Clinical Oncology, 11 (1993), 820-821.
  • Reader Comments
  • © 2013 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)
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索
Mathematical Biosciences and Engineering
2.6 3.9

Metrics

Article views(2065) PDF downloads(566) Cited by(12)

Preview PDF
Download XML
Export Citation
Article outline

Other Articles By Authors

Related pages

Tools

/

DownLoad:  Full-Size Img  PowerPoint
Return
Return

Catalog