Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments
Sweilam, N., Al-Mekhlafi, S., Abdel Kareem, W., Alqurishi, G. (2025). Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments. EKB Journal Management System, (), -. doi: 10.21608/fsrt.2025.397370.1170
Nasser Sweilam; Seham Al-Mekhlafi; Waleed Abdel Kareem; Ghader Alqurishi. "Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments". EKB Journal Management System, , , 2025, -. doi: 10.21608/fsrt.2025.397370.1170
Sweilam, N., Al-Mekhlafi, S., Abdel Kareem, W., Alqurishi, G. (2025). 'Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments', EKB Journal Management System, (), pp. -. doi: 10.21608/fsrt.2025.397370.1170
Sweilam, N., Al-Mekhlafi, S., Abdel Kareem, W., Alqurishi, G. Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments. EKB Journal Management System, 2025; (): -. doi: 10.21608/fsrt.2025.397370.1170

Piecewise Cancer Tumor Disease of Partial Differential Equations Based on Exponential and Non-Singular Kernel; Numerical Treatments

Frontiers in Scientific Research and Technology
Articles in Press, Accepted Manuscript, Available Online from 06 September 2025  XML PDF (1021.97 K)
Document Type: Original Article
DOI: 10.21608/fsrt.2025.397370.1170
View on SCiNiTO View on SCiNiTO
Authors
Nasser Sweilam email orcid 1; Seham Al-Mekhlafi2; Waleed Abdel Kareem3; Ghader Alqurishi4
1Cairo university, faculty of science, Cairo, Egypt
2Mathematics Department, Faculty of Education, Sana’a University, Yemen
3Department of Mathematics Suez University, Suez, Egypt
4Department of Mathematics, Faculty of Science, Suez University, Suez, Egypt
Abstract
This work presents a novel fractional-stochastic reaction–diffusion model for simulating cancer dynamics, incorporating the Caputo–Fabrizio derivative and additive Gaussian noise within a temporally piecewise framework. The model captures the nonlinear spatiotemporal interactions among normal cells, tumor cells, immune responses, and chemotherapeutic agents. By employing fractional-order derivatives with exponential kernels, the model accounts for biological memory and nonlocal effects, while the stochastic component reflects environmental and treatment-related uncertainties. In the early phase, memory-driven deterministic dynamics dominate, transitioning to stochastic behavior in later stages to simulate real-world perturbations. A hybrid numerical scheme, combining finite difference discretization of the Caputo–Fabrizio operator with the Euler–Maruyama method, is developed to simulate system behavior under varying fractional orders and noise intensities. Simulation results reveal that lower fractional orders correspond to delayed immune responses, persistent tumor presence, and slower drug clearance, highlighting the biological impact of memory. Conversely, higher fractional orders accelerate therapeutic effects. Stochastic noise introduces fluctuations that can destabilize outcomes, emphasizing the need for robust modeling in clinical contexts. Sensitivity analyses confirm the dominant influence of fractional parameters on system dynamics. The proposed framework offers a biologically informed, predictive platform for optimizing cancer treatment strategies and exploring the role of memory and randomness in tumor evolution.
Keywords
Cancer tumor; additive Gaussian; chemotherapy drugs; Nonlinear partial differential equation; Caputo–Fabrizio operator
Statistics
Article View: 2
PDF Download: 2