Computational Model for Tumor Oxygenation Applied to Clinical Data on Breast Tumor Hemoglobin Concentrations Suggests Vascular Dilatation and Compression

Welter, Michael; Fredrich, Thierry; Rinneberg, H.; Rieger, Heiko

doi:10.1371/journal.pone.0161267

Cited by 39 publications

(85 citation statements)

References 89 publications

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“…In [15] we showed that the equation for the vascular oxygen distribution together with 104 the diffusion equation for the tissue form a complicated nonlinear system of equations 105 with the partial pressure values of oxygen as unknowns. For the longitudinal transport a 106 bisection search is used to gather the partial oxygen pressure values within each vessel.…”

Section: Finite Elements Methods 103mentioning

confidence: 99%

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Tumorcode - A framework to simulate vascularized tumors

Fredrich

Welter

Rieger

2017

Preprint

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During the past years our group published several articles using computer simulations to address the complex interaction of tumors and the vasculature as underlying transport network. Advances in imaging and lab techniques pushed in vitro research of tumor spheroids forward and animal models as well as clinical studies provided more insights to single processes taking part in tumor growth, however, an overall picture is still missing. Computer simulations are a none-invasive option to cumulate current knowledge and form a quasi in vivo system. In our software, several known models were assembled into a multi-scale approach which allows to study length scales relevant for clinical applications.We release our code to the public domain, together with a detailed description of the implementation and several examples, with the hope of usage and futher development by the community. Justification for the included algorithms and the biological models was obtained in previous publications, here we summarize technical aspects following the workflow of a typical simulation procedure.

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Section: Finite Elements Methods 103mentioning

confidence: 99%

“…Secondly, an elaborated model of blood and tissue oxygenation was developed [15]. 181 Similarly to 'submitIff', 'submitDetailedO2' needs a parameter set, a tumor simulation 182 and a specified time point as input.…”

mentioning

confidence: 99%

Tumorcode - A framework to simulate vascularized tumors

Fredrich

Welter

Rieger

2017

Preprint

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“…The authors investigated the structural adaptation of tumour vasculature and its pruning in response to haemodynamic and metabolic stimuli as well as spatial patterns and frequency distributions of both oxygen and VEGF concentrations around vascular networks of distinct topologies (figure 2c). Welter and co-workers [87,97] modelled the complex hierarchical tree-like vascular structures via a hybrid model combining a discrete triangular grid-based vascular network and a continuous description of a homogeneous medium representing host or tumour cells. The authors investigated the relation between the morphology of tumour vasculature and the intra-and extravascular transport characteristics of blood flow, oxygen distribution, interstitial fluid pressure and drug delivery efficiency.…”

Section: Mathematical Models Of Vascularized Tumours and Angiogenesismentioning

confidence: 99%

Towards personalized computational oncology: from spatial models of tumour spheroids, to organoids, to tissues

Karolak

Markov

McCawley

et al. 2018

J. R. Soc. Interface.

114

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A main goal of mathematical and computational oncology is to develop quantitative tools to determine the most effective therapies for each individual patient. This involves predicting the right drug to be administered at the right time and at the right dose. Such an approach is known as precision medicine. Mathematical modelling can play an invaluable role in the development of such therapeutic strategies, since it allows for relatively fast, efficient and inexpensive simulations of a large number of treatment schedules in order to find the most effective. This review is a survey of mathematical models that explicitly take into account the spatial architecture of three-dimensional tumours and address tumour development, progression and response to treatments. In particular, we discuss models of epithelial acini, multicellular spheroids, normal and tumour spheroids and organoids, and multicomponent tissues. Our intent is to showcase how these in silico models can be applied to patient-specific data to assess which therapeutic strategies will be the most efficient. We also present the concept of virtual clinical trials that integrate standard-of-care patient data, medical imaging, organ-on-chip experiments and computational models to determine personalized medical treatment strategies.

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“…Second, the position of the capillaries within the volume is optimized towards a homogeneous capillary volume density using a hierarchical iteration scheme. For the scope of this paper, we consider only a root node configuration (RC) where one artery is opposite to one vein on the same axis (figure 2, compare also RC5 in figure 4 75 of [24]) and a single hierarchical iteration. Since the construction algorithm in the Tumorcode fixes the radii of all capillaries ( 2.5 µm in presented case) and determines the radii of all intermittent vessels between root nodes and capillaries by Murray's law, all radii at the intersections fulfill Murray's law by construction.…”

Section: The Artificial Blood Vessel Networkmentioning

confidence: 99%

“…In solid tumors, topological 240 modifications are an essential part of the growth procedure and therefore considered in our simulation framework [21]. In [24], we simulated the oxygen distribution in breast carcinoma and found that an additional vessel dilation is required to obtain oxygen distributions in agreement with the clinical measurements. We conjectured that the adaptation algorithm could possibly 245 provide a physiological mechanism for this vessel dilation.…”

Section: Application To Cancerous Networkmentioning

confidence: 99%

Adaption of artificial microvascular networks

Fredrich

Welter

Rieger

2018

Preprint

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Blood vessel networks of living organisms continuously adapt their structure under the influence of hemodynamic and metabolic stimuli. For a fixed vessel arrangement, blood flow characteristics still depend crucially on the morphology of each vessel. Vessel diameters adapt dynamically according to internal and external stimuli: endothelial wall shear stress, intravascular pressure, flow-dependent metabolic stimuli, and electrical stimuli conducted from distal to proximal segments along vascular walls. Pries et al. formulated a theoretical model involving these four local stimuli to simulate long-term changes of vessel diameters during structural adaption of microvascular networks. Here we apply this vessel adaptation algorithm to synthetic arteriovenous blood vessel networks generated by our simulation framework "Tumorcode". We fixed the free model parameters by an optimization method combined with the requirement of homogeneous flow in the capillary bed. We find that the local blood volume, surface to volume ratio and branching ratio differs from networks with radii fulfilling Murray's law exactly to networks with radii obtained by the adaptation algorithm although their relation is close to Murray's law. In addition, we find that the application of the vessel adaptation algorithm to synthetic tumor vascularture does not lead to a stable radii distributions due to emerging short cuts between arteries and veins.

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Computational Model for Tumor Oxygenation Applied to Clinical Data on Breast Tumor Hemoglobin Concentrations Suggests Vascular Dilatation and Compression

Cited by 39 publications

References 89 publications

Tumorcode - A framework to simulate vascularized tumors

Tumorcode - A framework to simulate vascularized tumors

Towards personalized computational oncology: from spatial models of tumour spheroids, to organoids, to tissues

Adaption of artificial microvascular networks

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