Changes in tissue mechanical properties are often the first indication of malignant disease, with the detection of a stiff lump by a patient. These changes include growth-induced solid stresses, increased matrix stiffness, high fluid pressure, and increased interstitial flow, which in turn enhance fluid flux away from the tumor to downstream lymph nodes (LNs). But in addition to changing the way a tumor feels to a patient, altered tumor tissue mechanics promote cancer cell invasion into lymphatic vessels, allowing their metastatic dissemination to draining LNs. LN swelling and stiffening is another common indicator of tumor growth, and the presence of metastatic cells in the sentinel LN, or tumor draining lymph node (TDLN), is used clinically to stage disease. Recent studies indicate the LN microenvironment determines whether metastatic cancers can spread to the sentinel LNs. Yet despite the known correlation of LN swelling and stiffening with tumorigenesis and the role of the LN microenvironment in metastasis, our understanding of how changes in LN mechanical properties relate to tumor progression, anti-tumor immune response and metastatic colonization of the LN is limited. This lack of a quantitative understanding limits functional analyses of the role of LN mechanics in determining cancer cell colonization of the TDLN, their influence on immune suppression taking place within the TDLN, as well as the development of strategies to mitigate these effects.
- Bioengineering Division
Tumors Change the Elastic and Viscoelastic Properties of Draining Lymph Node Tissues
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McClain, J, Tuell, SL, & Thomas, SN. "Tumors Change the Elastic and Viscoelastic Properties of Draining Lymph Node Tissues." Proceedings of the ASME 2013 Summer Bioengineering Conference. Volume 1B: Extremity; Fluid Mechanics; Gait; Growth, Remodeling, and Repair; Heart Valves; Injury Biomechanics; Mechanotransduction and Sub-Cellular Biophysics; MultiScale Biotransport; Muscle, Tendon and Ligament; Musculoskeletal Devices; Multiscale Mechanics; Thermal Medicine; Ocular Biomechanics; Pediatric Hemodynamics; Pericellular Phenomena; Tissue Mechanics; Biotransport Design and Devices; Spine; Stent Device Hemodynamics; Vascular Solid Mechanics; Student Paper and Design Competitions. Sunriver, Oregon, USA. June 26–29, 2013. V01BT45A001. ASME. https://doi.org/10.1115/SBC2013-14419
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