Stability analysis and optimal control of tumour-immune interaction problem using fractional order derivative

被引：0

作者：

Dinku, Tarekegn ^{[1
]}

Kumsa, Boka ^{[2
]}

Rana, Jyotirmoy ^{[3
]}

Srinivasan, Aiyappan ^{[3
]}

机构：

[1] Dambi Dollo Univ, Dept Math, Addis Ababa 1000, Oromia, Ethiopia

[2] Wollega Univ, Dept Math, Addis Ababa 1000, Oromia, Ethiopia

[3] Indian Inst Technol Hyderabad, Dept Math, Sangareddy 502284, Telangana, India

来源：

MATHEMATICS AND COMPUTERS IN SIMULATION | 2025年 / 233卷

关键词：

Fractional-order differential equation; Cancer model; Stability analysis; Spectral collocation; Optimal control; CANCER SELF-REMISSION; DIFFERENTIAL-EQUATIONS; NUMERICAL-SOLUTION; MODEL; CAPUTO; SYSTEM; CHAOS;

D O I：

10.1016/j.matcom.2024.12.028

中图分类号：

TP39 [计算机的应用];

学科分类号：

081203 ; 0835 ;

摘要：

In this study, we propose a tumour-immune interaction model using Caputo-Fabrizio fractional order derivative. The conditions for the well-posedness of the solution are examined. The stability of the endemic equilibrium point is derived and its stability is proved using Routh-Hurwitz criteria. The solution is approximated using a shifted Legendre polynomial at Gauss-Legendre collocation points, which is compared with the numerical results of the Adams-Bashforth scheme in the interval [0,1]. We have also proposed a fractional optimal control problem and proved the necessary optimality conditions. The optimal system is solved using the forward- backward sweep method (FBSM) with the Adams-Bashforth predictor-corrector numerical method. We have demonstrated that the antigenicity of tumours plays a crucial role in activating immune cells, suggesting that enhancing tumour antigenicity could improve immunotherapeutic outcomes. The effects of fractional-order derivatives and the proliferation rate of the Michaelis- Menten term are observed. Moreover, the impact of other model parameters on the system is highlighted through numerical results. Finally, the reduction in tumour cells and the increase of active immune cells are demonstrated in the presence of optimal control.

引用

页码：187 / 207

页数：21

共 49 条

[1] WEF, 9 new breakthroughs in the fight against cancer report of world economic forum, (2023)
[2] Banerjee S., Sarkar R.R., Delay-induced model for tumor–immune interaction and control of malignant tumor growth, Biosystems, 91, 1, pp. 268-288, (2008)
[3] Sarkar R.R., Banerjee S., Cancer self remission and tumor stability–a stochastic approach, Math. Biosci., 196, 1, pp. 65-81, (2005)
[4] El-Gohary A., Chaos and optimal control of cancer self-remission and tumor system steady states, Chaos Solitons Fractals, 37, 5, pp. 1305-1316, (2008)
[5] Sharma S., Samanta G., Dynamical behaviour of a tumor-immune system with chemotherapy and optimal control, J. Nonlinear Dyn., (2013)
[6] Kaur G., Ahmad N., On study of immune response to tumor cells in prey-predator system, Int. Sch. Res. Not., 2014, (2014)
[7] Ozkose F., Yilmaz S., Yavuz M., Ozturk I., Senel M.T., Bagci B.S., Dogan M., Onal O., A fractional modeling of tumor–immune system interaction related to Lung cancer with real data, Eur. Phys. J. Plus, 137, pp. 1-28, (2022)
[8] Baleanu D., Jajarmi A., Sajjadi S.S., Mozyrska D., A new fractional model and optimal control of a tumor-immune surveillance with non-singular derivative operator, Chaos, 29, 8, (2019)
[9] Baleanu D., Shekari P., Torkzadeh L., Ranjbar H., Jajarmi A., Nouri K., Stability analysis and system properties of Nipah virus transmission: A fractional calculus case study, Chaos Solitons Fractals, 166, (2023)
[10] Kuznetsov V.A., Knott G.D., Modeling tumor regrowth and immunotherapy, Math. Comput. Modelling, 33, 12-13, pp. 1275-1287, (2001)

← 1 2 3 4 5 →