Research article

Simulation of tumor density evolution upon chemotherapy alone or combined with a treatment to reduce lactate levels

  • Received: 30 October 2023 Revised: 12 January 2024 Accepted: 19 January 2024 Published: 26 January 2024
  • MSC : 35Q92, 35Q93, 92C50, 65M60, 35K51, 35K58

  • In this study, we introduced a mathematical model mimicking as much as possible the evolutions and interactions between glioma and lactate in the brain, in order to test different therapies and administration protocols. We simulated both glioma cell density evolution and lactate concentration, and considered two therapies: chemotherapy and a treatment targeting lactate production. Three different protocols for administrating the therapies were tested. We compared the efficiency of the combined therapies, depending on the administration protocols and the dosage of the drugs, in order to evaluate the importance of controlling lactate production. Results show that the use of an agent to reduce lactate concentration permits one to significantly reduce the dose of the chemotherapeutic drug.

    Citation: Hussein Raad, Cyrille Allery, Laurence Cherfils, Carole Guillevin, Alain Miranville, Thomas Sookiew, Luc Pellerin, Rémy Guillevin. Simulation of tumor density evolution upon chemotherapy alone or combined with a treatment to reduce lactate levels[J]. AIMS Mathematics, 2024, 9(3): 5250-5268. doi: 10.3934/math.2024254

    Related Papers:

  • In this study, we introduced a mathematical model mimicking as much as possible the evolutions and interactions between glioma and lactate in the brain, in order to test different therapies and administration protocols. We simulated both glioma cell density evolution and lactate concentration, and considered two therapies: chemotherapy and a treatment targeting lactate production. Three different protocols for administrating the therapies were tested. We compared the efficiency of the combined therapies, depending on the administration protocols and the dosage of the drugs, in order to evaluate the importance of controlling lactate production. Results show that the use of an agent to reduce lactate concentration permits one to significantly reduce the dose of the chemotherapeutic drug.



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