A Computational Model for Predicting Nanoparticle Accumulation in Tumor Vasculature

Vascular targeting of malignant tissues with systemically injected nanoparticles (NPs) holds promise in molecular imaging and anti-angiogenic therapies. Here, a computational model is presented to predict the development of tumor neovasculature over time and the specific, vascular accumulation of blood-borne NPs. A multidimensional tumor-growth model is integrated with a mesoscale formulation for the NP adhesion to blood vessel walls. The fraction of injected NPs depositing within the diseased vasculature and their spatial distribution is computed as a function of tumor stage, from 0 to day 24 post-tumor inception. As the malignant mass grows in size, average blood flow and shear rates increase within the tumor neovasculature, reaching values comparable with those measured in healthy, pre-existing vessels already at 10 days. The NP vascular affinity, interpreted as the likelihood for a blood-borne NP to firmly adhere to the vessel walls, is a fundamental parameter in this analysis and depends on NP size and ligand density, and vascular receptor expression. For high vascular affinities, NPs tend to accumulate mostly at the inlet tumor vessels leaving the inner and outer vasculature depleted of NPs. For low vascular affinities, NPs distribute quite uniformly intra-tumorally but exhibit low accumulation doses. It is shown that an optimal vascular affinity can be identified providing the proper balance between accumulation dose and uniform spatial distribution of the NPs. This balance depends on the stage of tumor development (vascularity and endothelial receptor expression) and the NP properties (size, ligand density and ligand-receptor molecular affinity). Also, it is demonstrated that for insufficiently developed vascular networks, NPs are transported preferentially through the healthy, pre-existing vessels, thus bypassing the tumor mass. The computational tool described here can effectively select an optimal NP formulation presenting high accumulation doses and uniform spatial intra-tumor distributions as a function of the development stage of the malignancy.

[1]  M. Chaplain,et al.  Continuous and discrete mathematical models of tumor-induced angiogenesis , 1998, Bulletin of mathematical biology.

[2]  R. Auerbach Vascular endothelial cell differentiation: organ-specificity and selective affinities as the basis for developing anti-cancer strategies. , 1991, International journal of radiation biology.

[3]  A. Pries,et al.  Structural adaptation and stability of microvascular networks: theory and simulations. , 1998, American journal of physiology. Heart and circulatory physiology.

[4]  Vittorio Cristini,et al.  Three-dimensional multispecies nonlinear tumor growth-II: Tumor invasion and angiogenesis. , 2010, Journal of theoretical biology.

[5]  Rakesh K. Jain,et al.  Normalizing tumor vasculature with anti-angiogenic therapy: A new paradigm for combination therapy , 2001, Nature Medicine.

[6]  S. McDougall,et al.  Mathematical modelling of flow through vascular networks: Implications for tumour-induced angiogenesis and chemotherapy strategies , 2002, Bulletin of mathematical biology.

[7]  S. McDougall,et al.  Multiscale modelling and nonlinear simulation of vascular tumour growth , 2009, Journal of mathematical biology.

[8]  V. Torchilin Recent advances with liposomes as pharmaceutical carriers , 2005, Nature Reviews Drug Discovery.

[9]  V. Cristini,et al.  Nonlinear simulation of tumor growth , 2003, Journal of mathematical biology.

[10]  P. Cullis,et al.  Drug Delivery Systems: Entering the Mainstream , 2004, Science.

[11]  R K Jain,et al.  Delivery of molecular medicine to solid tumors: lessons from in vivo imaging of gene expression and function. , 2001, Journal of controlled release : official journal of the Controlled Release Society.

[12]  H. Frieboes,et al.  An integrated computational/experimental model of tumor invasion. , 2006, Cancer research.

[13]  Vittorio Cristini,et al.  Predictions of tumour morphological stability and evaluation against experimental observations , 2011, Journal of The Royal Society Interface.

[14]  Daniel A Hammer,et al.  Effect of microvillus deformability on leukocyte adhesion explored using adhesive dynamics simulations. , 2005, Biophysical journal.

[15]  Mauro Ferrari,et al.  Rapid tumoritropic accumulation of systemically injected plateloid particles and their biodistribution. , 2012, Journal of controlled release : official journal of the Controlled Release Society.

[16]  H. Maeda,et al.  A new concept for macromolecular therapeutics in cancer chemotherapy: mechanism of tumoritropic accumulation of proteins and the antitumor agent smancs. , 1986, Cancer research.

[17]  Min Wu,et al.  The effect of interstitial pressure on tumor growth: coupling with the blood and lymphatic vascular systems. , 2013, Journal of theoretical biology.

[18]  Mauro Ferrari,et al.  Prediction of drug response in breast cancer using integrative experimental/computational modeling. , 2009, Cancer research.

[19]  M Ferrari,et al.  The adhesive strength of non-spherical particles mediated by specific interactions. , 2006, Biomaterials.

[20]  Laird Ak Dynamics of Tumour Growth , 1964 .

[21]  Laird Ak DYNAMICS OF TUMOR GROWTH. , 1964 .

[22]  R. Jain,et al.  Delivering nanomedicine to solid tumors , 2010, Nature Reviews Clinical Oncology.

[23]  Shelton D Caruthers,et al.  Molecular imaging of angiogenesis in nascent Vx-2 rabbit tumors using a novel alpha(nu)beta3-targeted nanoparticle and 1.5 tesla magnetic resonance imaging. , 2003, Cancer research.

[24]  D. Papahadjopoulos,et al.  Optimizing liposomes for delivery of chemotherapeutic agents to solid tumors. , 1999, Pharmacological reviews.

[25]  A. Pries,et al.  Blood viscosity in tube flow: dependence on diameter and hematocrit. , 1992, The American journal of physiology.

[26]  J. Karp,et al.  Nanocarriers as an Emerging Platform for Cancer Therapy , 2022 .

[27]  Thomas B. L. Kirkwood,et al.  Deciphering death: a commentary on Gompertz (1825) ‘On the nature of the function expressive of the law of human mortality, and on a new mode of determining the value of life contingencies’ , 2015, Philosophical Transactions of the Royal Society B: Biological Sciences.

[28]  W. Arap,et al.  Display technologies: Application for the discovery of drug and gene delivery agents , 2006, Advanced Drug Delivery Reviews.

[29]  Sei-Young Lee,et al.  Shaping nano-/micro-particles for enhanced vascular interaction in laminar flows , 2009, Nanotechnology.

[30]  M. Ferrari Cancer nanotechnology: opportunities and challenges , 2005, Nature Reviews Cancer.

[31]  Mauro Ferrari,et al.  Integrated intravital microscopy and mathematical modeling to optimize nanotherapeutics delivery to tumors. , 2012, AIP advances.

[32]  H. Frieboes,et al.  Computer simulation of glioma growth and morphology , 2007, NeuroImage.

[33]  S. McDougall,et al.  Mathematical modelling of dynamic adaptive tumour-induced angiogenesis: clinical implications and therapeutic targeting strategies. , 2006, Journal of theoretical biology.

[34]  H. Maeda,et al.  Tumor vascular permeability and the EPR effect in macromolecular therapeutics: a review. , 2000, Journal of controlled release : official journal of the Controlled Release Society.

[35]  Robert Sinclair,et al.  Real-time intravital imaging of RGD-quantum dot binding to luminal endothelium in mouse tumor neovasculature. , 2008, Nano letters.

[36]  R K Jain,et al.  Physiological barriers to delivery of monoclonal antibodies and other macromolecules in tumors. , 1990, Cancer research.

[37]  Vittorio Cristini,et al.  Physical oncology: a bench-to-bedside quantitative and predictive approach. , 2011, Cancer research.

[38]  Mauro Ferrari,et al.  Intravascular Delivery of Particulate Systems: Does Geometry Really Matter? , 2008, Pharmaceutical Research.

[39]  B. Schrefler,et al.  Optimizing particle size for targeting diseased microvasculature: from experiments to artificial neural networks , 2011, International journal of nanomedicine.

[40]  Mauro Ferrari,et al.  Predicting drug pharmacokinetics and effect in vascularized tumors using computer simulation , 2008, Journal of mathematical biology.

[41]  C. Winsor,et al.  The Gompertz Curve as a Growth Curve. , 1932, Proceedings of the National Academy of Sciences of the United States of America.