Pages that link to "Item:Q5485822"

The following pages link to MODELLING THE RESPONSE OF VASCULAR TUMOURS TO CHEMOTHERAPY: A MULTISCALE APPROACH (Q5485822):

Displaying 29 items.

• An integrated multiscale mechanistic model for cancer drug therapy (Q355938) (← links)
• Foundational aspects of multiscale modeling of biological systems with process algebras (Q418838) (← links)
• Numerical solutions for a model of tissue invasion and migration of tumour cells (Q629157) (← links)
• From the mathematical kinetic theory for active particles on the derivation of hyperbolic macroscopic tissue models (Q734479) (← links)
• Vascular phenotype identification and anti-angiogenic treatment recommendation: a pseudo-multiscale mathematical model of angiogenesis (Q738575) (← links)
• Modelling tumour cell proliferation from vascular structure using tissue decomposition into avascular elements (Q738696) (← links)
• The impact of cell crowding and active cell movement on vascular tumour growth (Q875636) (← links)
• Multiscale modelling of tumour growth and therapy: the influence of vessel normalisation on chemotherapy (Q883747) (← links)
• Qualitative analysis of second-order models of tumor-immune system competition (Q949504) (← links)
• A theoretical study of the response of vascular tumours to different types of chemotherapy (Q955502) (← links)
• Mathematical tools of the kinetic theory of active particles with some reasoning on the modelling progression and heterogeneity (Q1029169) (← links)
• An advanced discrete state-discrete event multiscale simulation model of the response of a solid tumor to chemotherapy: mimicking a clinical study (Q1722806) (← links)
• A mathematical model of the growth of uterine myomas (Q2254677) (← links)
• Predicting drug pharmacokinetics and effect in vascularized tumors using computer simulation (Q2339991) (← links)
• Mathematical modeling of chemotherapy strategies in vascular tumor growth using nanopar\-ti\-cles (Q2383634) (← links)
• Multiscale cancer modeling: In the line of fast simulation and chemotherapy (Q2390175) (← links)
• From the mathematical kinetic theory of active particles to multiscale modelling of complex biological systems (Q2425473) (← links)
• Modelling the role of angiogenesis and vasculogenesis in solid tumour growth (Q2426387) (← links)
• Modelling the response of spatially structured tumours to chemotherapy: drug kinetics (Q2473150) (← links)
• Modelling the effects of cell-cycle heterogeneity on the response of a solid tumour to chemotherapy: biological insights from a hybrid multiscale cellular automaton model (Q2632026) (← links)
• A computational framework to assess the efficacy of cytotoxic molecules and vascular disrupting agents against solid tumours (Q2896934) (← links)
• A MODEL AT THE MACROSCOPIC SCALE OF PROSTATE TUMOR GROWTH UNDER INTERMITTENT ANDROGEN SUPPRESSION (Q3400124) (← links)
• ON THE FOUNDATIONS OF CANCER MODELLING: SELECTED TOPICS, SPECULATIONS, AND PERSPECTIVES (Q3521624) (← links)
• On the unsteady Darcy–Forchheimer–Brinkman equation in local and nonlocal tumor growth models (Q4973296) (← links)
• PREFACE — CHALLENGING MATHEMATICAL PROBLEMS IN CANCER MODELLING (Q5386707) (← links)
• MULTICELLULAR BIOLOGICAL GROWING SYSTEMS: HYPERBOLIC LIMITS TOWARDS MACROSCOPIC DESCRIPTION (Q5386709) (← links)
• MODELLING SCAFFOLD OCCUPATION BY A GROWING, NUTRIENT-RICH TISSUE (Q5386712) (← links)
• On the stability of an ellipsoidal tumour (Q5741505) (← links)
• A mathematical model of prostate tumor growth under hormone therapy with mutation inhibitor (Q5962228) (← links)