Adipose Cells Induce Escape from an Engineered Human Breast Microtumor Independently of their Obesity Status.

Introduction: Obesity is associated with increased breast cancer incidence, recurrence, and mortality. Adipocytes and adipose-derived stem cells (ASCs), two resident cell types in adipose tissue, accelerate the early stages of breast cancer progression. It remains unclear whether obesity plays a role in the subsequent escape of malignant breast cancer cells into the local circulation. Methods: We engineered models of human breast tumors with adipose stroma that exhibited different obesity-specific alterations. We used these models to assess the invasion and escape of breast cancer cells into an empty, blind-ended cavity (as a mimic of a lymphatic vessel) for up to sixteen days. Results: Lean and obese donor-derived adipose stroma hastened escape to similar extents. Moreover, a hypertrophic adipose stroma did not affect the rate of adipose-induced escape. When admixed directly into the model tumors, lean and obese donor-derived ASCs hastened escape similarly. Conclusions: This study demonstrates that the presence of adipose cells, independently of the obesity status of the adipose tissue donor, hastens the escape of human breast cancer cells in multiple models of obesity-associated breast cancer. Supplementary Information: The online version contains supplementary material available at 10.1007/s12195-022-00750-y.

Role of Lymphatic Endothelium in Vascular Escape of Engineered Human Breast Microtumors.

Introduction: Lymphatic vasculature provides a route for metastasis to secondary sites in the body. The role of the lymphatic endothelium in mediating the entry of breast cancer cells into the vasculature remains unclear. Methods: In this study, we formed aggregates of MDA-MB-231 human breast carcinoma cells next to human microvascular lymphatic endothelial cell (LEC)-lined cavities in type I collagen gels to model breast microtumors and lymphatic vessels, respectively. We tracked invasion and escape of breast microtumors into engineered lymphatics or empty cavities under matched flow rates for up to sixteen days. Results: After coming into contact with a lymphatic vessel, tumor cells escape by moving between the endothelium and the collagen wall, between endothelial cells, and/or into the endothelial lumen. Over time, tumor cells replace the LECs within the vessel wall and create regions devoid of endothelium. The presence of lymphatic endothelium slows breast tumor invasion and escape, and addition of LEC-conditioned medium to tumors is sufficient to reproduce nearly all of these inhibitory effects. Conclusions: This work sheds light on the interactions between breast cancer cells and lymphatic endothelium during vascular escape and reveals an inhibitory role for the lymphatic endothelium in breast tumor invasion and escape. Supplementary Information: The online version contains supplementary material available at 10.1007/s12195-022-00745-9.

Adipose Stroma Accelerates the Invasion and Escape of Human Breast Cancer Cells from an Engineered Microtumor.

INTRODUCTION: Approximately 20-25% of human breast tumors are found within an adipose, rather than fibrous, stroma. Adipose stroma is associated with an increased risk of lymph node metastasis, but the causal association between adipose stroma and metastatic progression in human breast cancer remains unclear. METHODS: We used micropatterned type I collagen gels to engineer ~3-mm-long microscale human breast tumors within a stroma that contains adipocytes and adipose-derived stem cells (ASCs) (collectively, "adipose cells"). Invasion and escape of human breast cancer cells into an empty 120-µm-diameter lymphatic-like cavity was used to model interstitial invasion and vascular escape in the presence of adipose cell-derived factors for up to 16 days. RESULTS: We found that adipose cells hasten invasion and escape by 1-2 days and 2-3 days, respectively. These effects were mediated by soluble factors secreted by the adipose cells, and these factors acted directly on tumor cells. Surprisingly, tumor invasion and escape were more strongly induced by ASCs than by adipocytes. CONCLUSIONS: This work reveals that both adipocytes and ASCs accelerate the interstitial invasion and escape of human breast cancer cells, and sheds light on the link between adipose stroma and lymphatic metastasis in human breast cancer. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s12195-021-00697-6.

Interstitial Hypertension Suppresses Escape of Human Breast Tumor Cells Via Convection of Interstitial Fluid.

INTRODUCTION: Interstitial hypertension, a rise in interstitial fluid pressure, is a common feature of many solid tumors as they progress to an invasive state. It is currently unclear whether this elevated pressure alters the probability that tumor cells eventually escape into a neighboring blood or lymphatic vessel. METHODS: In this study, we analyze the escape of MDA-MB-231 human breast tumor cells from a ~3-mm-long preformed aggregate into a 120-µm-diameter empty cavity in a micromolded type I collagen gel. The "micro-tumors" were located within ~300 µm of one or two cavities. Pressures of ~0.65 cm H2O were applied only to the tumor ("interstitial hypertension") or to its adjacent cavity. RESULTS: This work shows that interstitial hypertension suppresses escape into the adjacent cavity, but not because tumor cells respond directly to the pressure profile. Instead, hypertension alters the chemical microenvironment at the tumor margin to one that hampers escape. Administration of tumor interstitial fluid phenocopies the effects of hypertension. CONCLUSIONS: This work uncovers a link between tumor pressure, interstitial flow, and tumor cell escape in MDA-MB-231 cells, and suggests that interstitial hypertension serves to hinder further progression to metastatic escape. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (10.1007/s12195-020-00661-w) contains supplementary material, which is available to authorized users.

Microfluidic Biomaterials.

Since their initial description in 2005, biomaterials that are patterned to contain microfluidic networks ("microfluidic biomaterials") have emerged as promising scaffolds for a variety of tissue engineering and related applications. This class of materials is characterized by the ability to be readily perfused. Transport and exchange of solutes within microfluidic biomaterials is governed by convection within channels and diffusion between channels and the biomaterial bulk. Numerous strategies have been developed for creating microfluidic biomaterials, including micromolding, photopatterning, and 3D printing. In turn, these materials have been used in many applications that benefit from the ability to perfuse a scaffold, including the engineering of blood and lymphatic microvessels, epithelial tubes, and cell-laden tissues. This article reviews the current state of the field and suggests new areas of exploration for this unique class of materials.

Matrix Pore Size Governs Escape of Human Breast Cancer Cells from a Microtumor to an Empty Cavity.

How the extracellular matrix (ECM) affects the progression of a localized tumor to invasion of the ECM and eventually to vascular dissemination remains unclear. Although many studies have examined the role of the ECM in early stages of tumor progression, few have considered the subsequent stages that culminate in intravasation. In the current study, we have developed a three-dimensional (3D) microfluidic culture system that captures the entire process of invasion from an engineered human micro-tumor of MDA-MB-231 breast cancer cells through a type I collagen matrix and escape into a lymphatic-like cavity. By varying the physical properties of the collagen, we have found that MDA-MB-231 tumor cells invade and escape faster in lower-density ECM. These effects are mediated by the ECM pore size, rather than by the elastic modulus or interstitial flow speed. Our results underscore the importance of ECM structure in the vascular escape of human breast cancer cells.