Pages that link to "Item:Q1624237"

The following pages link to Mathematical modelling of the Warburg effect in tumour cords (Q1624237):

Displaying 21 items.

• On the biomechanics and mechanobiology of growing skin (Q285227) (← links)
• On computational modeling in tumor growth (Q346212) (← links)
• A mathematical model for the glucose-lactate metabolism of in vitro cancer cells (Q417386) (← links)
• Glucose-lactate metabolic cooperation in cancer: insights from a spatial mathematical model and implications for targeted therapy (Q485684) (← links)
• A quantitative theoretical model for the development of malignancy in ductal carcinoma \textit{in situ} (Q1629083) (← links)
• Adaptation to stochastic temporal variations in intratumoral blood flow: the Warburg effect as a bet hedging strategy (Q1648955) (← links)
• Deterministic and stochastic aspects of VEGF-A production and the cooperative behavior of tumoral cell colony (Q1670617) (← links)
• Patient-calibrated agent-based modelling of ductal carcinoma in situ (DCIS): from microscopic measurements to macroscopic predictions of clinical progression (Q1784325) (← links)
• A review of mathematical models for the formation of vascular networks (Q1790801) (← links)
• Initial/boundary-value problems of tumor growth within a host tissue (Q1937886) (← links)
• A mathematical study of the influence of hypoxia and acidity on the evolutionary dynamics of cancer (Q2035804) (← links)
• Effective interface conditions for continuum mechanical models describing the invasion of multiple cell populations through thin membranes (Q2060800) (← links)
• Travelling wave analysis of cellular invasion into surrounding tissues (Q2077797) (← links)
• Spatio-temporal modelling of phenotypic heterogeneity in tumour tissues and its impact on radiotherapy treatment (Q2109231) (← links)
• A mathematical model for imaging and killing cancer cells by using concepts of the Warburg effect in designing a graphene system (Q2130362) (← links)
• Evolutionary dynamics of the Warburg effect: glycolysis as a collective action problem among cancer cells (Q2632381) (← links)
• The moving boundary node method: A level set-based, finite volume algorithm with applications to cell motility (Q2638253) (← links)
• Nonlinear multi-objective flux balance analysis of the Warburg Effect (Q2676057) (← links)
• The Steady State of Multicellular Tumour Spheroids: A Modelling Challenge (Q2820380) (← links)
• A theoretical explanation of the laws of Warburg and Sigmond (Q4353824) (← links)
• (Q5108285) (← links)