An in vitro model of the tumor-lymphatic microenvironment with simultaneous transendothelial and luminal flows reveals mechanisms of flow enhanced invasion.

The most common cancers, including breast and skin, disseminate initially through the lymphatic system, yet the mechanisms by which tumor cells home towards, enter and interact with the lymphatic endothelium remain poorly understood. Transmural and luminal flows are important biophysical cues of the lymphatic microenvironment that can affect adhesion molecules, growth factors and chemokine expression as well as matrix remodeling, among others. Although microfluidic models are suitable for in vitro reconstruction of highly complex biological systems, the difficult assembly and operation of these systems often only allows a limited throughput. Here we present and characterize a novel flow chamber which recapitulates the lymphatic capillary microenvironment by coupling a standard Boyden chamber setup with a micro-channel and a controlled fluidic environment. The inclusion of luminal and transmural flow renders the model more biologically relevant, combining standard 3D culture techniques with advanced control of mechanical forces that are naturally present within the lymphatic microenvironment. The system can be monitored in real-time, allowing continuous quantification of different parameters of interest, such as cell intravasation and detachment from the endothelium, under varied biomechanical conditions. Moreover, the easy setup permits a medium-high throughput, thereby enabling downstream quantitative analyses. Using this model, we examined the kinetics of tumor cell (MDA-MB-231) invasion and transmigration dynamics across lymphatic endothelium under varying flow conditions. We found that luminal flow indirectly upregulates tumor cell transmigration rate via its effect on lymphatic endothelial cells. Moreover, we showed that the addition of transmural flow further increases intravasation, suggesting that distinct flow-mediated mechanisms regulate tumor cell invasion.

[1]  Marissa Nichole Rylander,et al.  Microfluidic culture models to study the hydrodynamics of tumor progression and therapeutic response , 2013, Biotechnology and bioengineering.

[2]  M. Skobe,et al.  Molecular characterization of lymphatic endothelial cells , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[3]  B. Konforti,et al.  More than the sum of its parts. , 2012, Cell reports.

[4]  Melody A Swartz,et al.  Autologous chemotaxis as a mechanism of tumor cell homing to lymphatics via interstitial flow and autocrine CCR7 signaling. , 2007, Cancer cell.

[5]  Nitzan Resnick,et al.  Fluid shear stress and the vascular endothelium: for better and for worse. , 2003, Progress in biophysics and molecular biology.

[6]  Roger D Kamm,et al.  Mechanisms of tumor cell extravasation in an in vitro microvascular network platform. , 2013, Integrative biology : quantitative biosciences from nano to macro.

[7]  Melody A. Swartz,et al.  Dendritic-cell trafficking to lymph nodes through lymphatic vessels , 2005, Nature Reviews Immunology.

[8]  S. Parsons,et al.  Studying leukocyte recruitment under flow conditions. , 2013, Methods in molecular biology.

[9]  V. Engelhard,et al.  Lymphatic endothelial cells induce tolerance via PD-L1 and lack of costimulation leading to high-level PD-1 expression on CD8 T cells. , 2012, Blood.

[10]  G. Schmid-Schönbein Nitric oxide (NO) side of lymphatic flow and immune surveillance , 2011, Proceedings of the National Academy of Sciences.

[11]  M. Swartz,et al.  Lymphatic and interstitial flow in the tumour microenvironment: linking mechanobiology with immunity , 2012, Nature Reviews Cancer.

[12]  Ulrike Haessler,et al.  Migration dynamics of breast cancer cells in a tunable 3D interstitial flow chamber. , 2012, Integrative biology : quantitative biosciences from nano to macro.

[13]  J. Breslin,et al.  Lymphatic endothelial cells adapt their barrier function in response to changes in shear stress. , 2009, Lymphatic research and biology.

[14]  R. Kamm,et al.  Cell migration into scaffolds under co-culture conditions in a microfluidic platform. , 2009, Lab on a chip.

[15]  Blair D. Johnson,et al.  Mechanotransduction of shear in the endothelium: Basic studies and clinical implications , 2011, Vascular medicine.

[16]  William J. Polacheck,et al.  Interstitial flow influences direction of tumor cell migration through competing mechanisms , 2011, Proceedings of the National Academy of Sciences.

[17]  G. Goodhill,et al.  Assays for eukaryotic cell chemotaxis. , 2009, Combinatorial chemistry & high throughput screening.

[18]  Melody A Swartz,et al.  Interstitial fluid and lymph formation and transport: physiological regulation and roles in inflammation and cancer. , 2012, Physiological reviews.

[19]  Melody A. Swartz,et al.  Transmural Flow Modulates Cell and Fluid Transport Functions of Lymphatic Endothelium , 2010, Circulation research.

[20]  N. van Bruggen,et al.  Inhibition of VEGF-C Modulates Distal Lymphatic Remodeling and Secondary Metastasis , 2013, PloS one.

[21]  M. Swartz,et al.  VEGF-C promotes immune tolerance in B16 melanomas and cross-presentation of tumor antigen by lymph node lymphatics. , 2012, Cell reports.

[22]  G. Dubini,et al.  Microfluidics for in vitro biomimetic shear stress-dependent leukocyte adhesion assays. , 2013, Journal of biomechanics.

[23]  M. Swartz,et al.  Steady-State Antigen Scavenging, Cross-Presentation, and CD8+ T Cell Priming: A New Role for Lymphatic Endothelial Cells , 2014, The Journal of Immunology.

[24]  S. Simon,et al.  Hydrodynamic Shear Rate Regulates Melanoma-Leukocyte Aggregation, Melanoma Adhesion to the Endothelium, and Subsequent Extravasation , 2008, Annals of Biomedical Engineering.

[25]  J. Sleeman,et al.  Tumor metastasis and the lymphatic vasculature , 2009, International journal of cancer.

[26]  J. Ando,et al.  New molecular mechanisms for cardiovascular disease:blood flow sensing mechanism in vascular endothelial cells. , 2011, Journal of pharmacological sciences.

[27]  R. Kamm,et al.  In Vitro Model of Tumor Cell Extravasation , 2013, PloS one.

[28]  P. Koumoutsakos,et al.  The Fluid Mechanics of Cancer and Its Therapy , 2013 .

[29]  Y. Kawai,et al.  Shear stress-induced ATP-mediated endothelial constitutive nitric oxide synthase expression in human lymphatic endothelial cells. , 2010, American journal of physiology. Cell physiology.

[30]  R. Kamm,et al.  Microfluidic models of vascular functions. , 2012, Annual review of biomedical engineering.

[31]  Gerard L Cote,et al.  Lymph Flow, Shear Stress, and Lymphocyte Velocity in Rat Mesenteric Prenodal Lymphatics , 2006, Microcirculation.

[32]  A. Andrews,et al.  Direct, real-time measurement of shear stress-induced nitric oxide produced from endothelial cells in vitro. , 2010, Nitric oxide : biology and chemistry.

[33]  Beum Jun Kim,et al.  A contact line pinning based microfluidic platform for modelling physiological flows. , 2013, Lab on a chip.

[34]  D. Rader,et al.  Lymphatics as a new active player in reverse cholesterol transport. , 2013, Cell metabolism.

[35]  Mark S. Cohen,et al.  Role of the lymphatics in cancer metastasis and chemotherapy applications. , 2011, Advanced drug delivery reviews.

[36]  Hyungil Jung,et al.  Integration of intra- and extravasation in one cell-based microfluidic chip for the study of cancer metastasis. , 2011, Lab on a chip.

[37]  M. Swartz,et al.  The physiology of the lymphatic system. , 2001, Advanced drug delivery reviews.

[38]  J. Hay,et al.  Lymph flow and lymphatic drainage of inflammatory cells from the peritoneal cavity in a casein-peritonitis model in sheep. , 1994, Lymphology.

[39]  Toshio Ohhashi,et al.  Pivotal roles of shear stress in the microenvironmental changes that occur within sentinel lymph nodes , 2012, Cancer science.