Stability Analysis of a Feedback Model for the Action of the Immune System in Leukemia

Balea, Silvia; Halanay, A.; Jardan, D.; Neamţu, Mihaela; Safta, Carmen-Anca

doi:10.1051/mmnp/20149108

Cited by 7 publications

(7 citation statements)

References 26 publications

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“…Although CML is one of the most studied types of leukemia (see [13], [3], [25], [12], [19]), only relatively recently has the immune system been included in models (see [8], [21], [22], [23], [26], [27]). This is mainly due to the fact that the immune system is very complex and its mechanism is not completely understood.…”

Section: Introductionmentioning

confidence: 99%

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A Complex Model of Cell Evolution in Leukemia Including Competition and the Action of the Immune System

Badralexi¹,

Balea²,

Halanay³

et al. 2020

AnnalsARSciMath

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Section: Introductionmentioning

confidence: 99%

“…A description of the activation of the immune system and the effect of the immune system on the population of malignant cells can be found in [8]. The model presented in this paper is an extension of the model from [8].…”

Section: Introductionmentioning

confidence: 99%

A Complex Model of Cell Evolution in Leukemia Including Competition and the Action of the Immune System

Badralexi¹,

Balea²,

Halanay³

et al. 2020

AnnalsARSciMath

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“…Tumour antigen expression and the effects of epigenetic and genetic events have been modelled through differential equation models (Asatryan and Komarova, 2016;Lorenzi et al, 2016;Johnston et al, 2007;Tomasetti and Levy, 2010) and cellularautomaton (CA) models (Bouchnita et al, 2017;Manem et al, 2014). Traditionally, tumour antigen expression and recognition by the immune system have been implicitly modelled by tuning the rates of T cell recruitment, T cell proliferation or tumour cell removal (Arciero et al, 2004;Balea et al, 2014;Besse et al, 2018;De Boer et al, 1985;de Pillis et al, 2009;Köse et al, 2017;Mallet and de Pillis, 2006). More recently, these processes have been explicitly captured by mathematical models formulated in terms of either ordinary differential equations (Balachandran et al, 2017;d'Onofrio and Ciancio, 2011;Luksza et al, 2017) or integro-differential equations Kolev et al, 2013;Lorenzi et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

A stochastic individual-based model to explore the role of spatial interactions and antigen recognition in the immune response against solid tumours

Macfarlane

Chaplain

Lorenzi

2019

Journal of Theoretical Biology

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Spatial interactions between cancer and immune cells, as well as the recognition of tumour antigens by cells of the immune system, play a key role in the immune response against solid tumours. The existing mathematical models generally focus only on one of these key aspects. We present here a spatial stochastic individual-based model that explicitly captures antigen expression and recognition. In our model, each cancer cell is characterised by an antigen profile which can change over time due to either epimutations or mutations. The immune response against the cancer cells is initiated by the dendritic cells that recognise the tumour antigens and present them to the cytotoxic T cells. Consequently, T cells become activated against the tumour cells expressing such antigens. Moreover, the differences in movement between inactive and active immune cells are explicitly taken into account by the model. Computational simulations of our model clarify the conditions for the emergence of tumour clearance, dormancy or escape, and allow us to assess the impact of antigenic heterogeneity of cancer cells on the efficacy of immune action. Ultimately, our results highlight the complex interplay between spatial interactions and adaptive mechanisms that underpins the immune response against solid tumours, and suggest how this may be exploited to further develop cancer immunotherapies.

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“…Cyclical platelet disease was a subject of mathematical modeling in Santillan et al [43] and was enriched in Apostu et al [3]. Leukemia and other blood disorders were studied in [2,4,27,28,39,45].…”

Section: Introductionmentioning

confidence: 99%

Hybrid Models in Erythropoiesis and in Megakaryopoiesis

Eymard

Kurbatova

2015

Math. Model. Nat. Phenom.

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Hematopoiesis is a complex process which results in production of erythrocytes, platelets and white blood cells from pluripotent stem cells located in the bone marrow. We will present hybrid models of hematopoiesis and will use them to study the lineage choice of bipotent erythro-megakaryocytic progenitors and erythroid lineage of hematopoiesis. Biological cells will be considered as individual objects, intracellular regulatory networks will be described with ordinary differential equations and biochemical substances in the extracellular matrix with partial differential equations.

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Stability Analysis of a Feedback Model for the Action of the Immune System in Leukemia

Cited by 7 publications

References 26 publications

A Complex Model of Cell Evolution in Leukemia Including Competition and the Action of the Immune System

A Complex Model of Cell Evolution in Leukemia Including Competition and the Action of the Immune System

A stochastic individual-based model to explore the role of spatial interactions and antigen recognition in the immune response against solid tumours

Hybrid Models in Erythropoiesis and in Megakaryopoiesis

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