Regulation of Cell Proliferation and Migration in Glioblastoma: New Therapeutic Approach

Kim, Yangjin

doi:10.3389/fonc.2013.00053

Cited by 45 publications

(58 citation statements)

References 85 publications

(97 reference statements)

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“…circadian clocks, cell cycle oscillators) and space (e.g., periodic waves of Dictyostelium cells aggregation, embryonic patterning). [19][20][21][22] However, theoretical models -for example those of eukaryotic cell cycle regulation 23 or of effects of glucose concentration on glucose-regulated miRNA levels in tumor cells 24 -show that some parameters of a system of metabolic reactions mutually linked by regulatory feedback relationships may also exhibit complex, non-monotonic responses as a function of parameters other than time or space, such as e.g. cell size or concentration of one of the systems components.…”

Section: E1062198-2mentioning

confidence: 99%

Complex, non-monotonic dose-response curves with multiple maxima: Do we (ever) sample densely enough?

Cvrčková

Luštinec

Žárský

2015

Plant Signaling & Behavior

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Section: E1062198-2mentioning

confidence: 99%

Complex, non-monotonic dose-response curves with multiple maxima: Do we (ever) sample densely enough?

Cvrčková

Luštinec

Žárský

2015

Plant Signaling & Behavior

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“…Oscilla(on In Figure 12, we investigate the effect of constant drug injection on the dynamics of the DDE system (52)- (55) in the presence of large time delays (τ 1 = τ 2 = 3.5). Figure 12C) significantly enhances the immune activity and eliminates both harmful and beneficial pathogens (B s 1 = 0, B s 2 = 0).…”

Section: Therapeutic Approachesmentioning

confidence: 99%

“…Hybrid approaches may be used to take into account these intracellular signaling pathways in addition to the mechanical interactions of cells with microenvironment for detailed proteolytic activities, growth and invasion at the cellular level and viscoelastic response of the whole tissue [23,[53][54][55][56][57]. Yet a more comprehensive understanding of the role of the microenvironment in epidermal homeostasis may lead to the development of new therapeutic agents.…”

mentioning

confidence: 99%

Chronic Inflammation in the Epidermis: A Mathematical Model

et al. 2016

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Abstract:The epidermal tissue is the outmost component of the skin that plays an important role as a first barrier system in preventing the invasion of various environmental agents, such as bacteria. Recent studies have identified the importance of microbial competition between harmful and beneficial bacteria and the diversity of the skin surface on our health. We develop mathematical models (M1 and M2 models) for the inflammation process using ordinary differential equations and delay differential equations. In this paper, we study microbial community dynamics via transcription factors, protease and extracellular cytokines. We investigate possible mechanisms to induce community composition shift and analyze the vigorous competition dynamics between harmful and beneficial bacteria through immune activities. We found that the activation of proteases from the transcription factor within a cell plays a significant role in the regulation of bacterial persistence in the M1 model. The competition model (M2) predicts that different cytokine clearance levels may lead to a harmful bacteria persisting system, a bad bacteria-free state and the co-existence of harmful and good bacterial populations in Type I dynamics, while a bi-stable system without co-existence is illustrated in the Type II dynamics. This illustrates a possible phenotypic switch among harmful and good bacterial populations in a microenvironment. We also found that large time delays in the activation of immune responses on the dynamics of those bacterial populations lead to the onset of oscillations in harmful bacteria and immune activities. The mathematical model suggests possible annihilation of time-delay-driven oscillations by therapeutic drugs.

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“…We extend the model of miR-451-AMPK core control system developed in [25] and related works [26,27] to include regulation by glucose and influence of drug use and thus additional components are added. Figure 1a shows the conceptual model dynamics adapted from Godlewski et al [7] with possible drugdriven intervention of inhibitory pathways of miR-451 from the AMPK complex.…”

Section: Model Of Regulation In Core Control Systemmentioning

confidence: 99%

“…Thus, the core control system of miR-451 and AMPK complex plays an integral role in the regulation of balance between proliferation and invasion of glioma cells. Kim et al [25][26][27] developed a mathematical model that shows how the dynamics of the core miR-451-AMPK control system affects cell proliferation and migration in glioblastoma. It provides an explanation for up-and downregulation of miR-451 in response to high and low glucose levels and known mutual antagonism between miR-451 levels and AMPK complex activities [7].…”

Section: Introductionmentioning

confidence: 99%

Optimal control strategies of eradicating invisible glioblastoma cells after conventional surgery

Reyes

Jung

Kim

2015

J. R. Soc. Interface.

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Glioblastoma, the most aggressive type of brain cancer, has median survival time of 1 year after diagnosis. It is characterized by alternating modes of rapid proliferation and aggressive invasion in response to metabolic stress in the microenvironment. A particular microRNA, miR-451, and its downstream signalling molecules, AMPK complex, are known to be key determinants in switching cell fate. These components form a core control system determining a balance between cell growth and migration which is regulated by fluctuating glucose levels in the microenvironment. An important factor from the treatment point of view is that low levels of glucose affect metabolism and activate cell migration through the miR-451-AMPK control system, creating 'invisible' migratory cells and making them inaccessible by conventional surgery. In this work, we apply optimal control theory to deal with the problem of maintaining upregulated miR-451 levels that prevent cell infiltration to surrounding brain tissue and thus induce localization of these cancer cells at the surgical site. The model also considers the effect of a drug that blocks inhibitive pathways of miR-451 from AMPK complex. Glucose infusion control and drug infusion control are chosen to represent dose rates of glucose and drug intravenous administrations, respectively. The characteristics of optimal control lead us to investigate the structure of optimal intravenous infusion regimen under various circumstances and predict best clinical outcomes with minimum expense possible.

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Regulation of Cell Proliferation and Migration in Glioblastoma: New Therapeutic Approach

Cited by 45 publications

References 85 publications

Complex, non-monotonic dose-response curves with multiple maxima: Do we (ever) sample densely enough?

Complex, non-monotonic dose-response curves with multiple maxima: Do we (ever) sample densely enough?

Chronic Inflammation in the Epidermis: A Mathematical Model

Optimal control strategies of eradicating invisible glioblastoma cells after conventional surgery

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