Recent estimates suggest that the prevalence of lymphedema in developed countries is as high as 1.44 per thousand persons. Consequences of the disease include an increase in chronic pain and fatigue, higher incidence of dermal infections, severe anxiety and depression, a 10 year decrease in life expectancy with doubled health care costs. Yet in spite of the growing burden of this disease, clinical options available fr most suffering patients are the same today as 30 years ago: namely proper skin care and various methods of tissue compression. Such approaches have the goal of reducing symptomatic severity, while failing to understand or correct the underlying dysfunction. Lymphatic function is highly sensitive to the forces imposed on the vessels, and lymphedema drastically alters the local mechanical environment of the interstitium surrounding lymphatics through substantial collagen and lipid accumulation. A comprehensive understanding of the crosstalk between this environment and lymphatic function, particularly in the context of lymphedema, would therefore have significant clinical benefits not only for patients suffering from lymphedema, but also for patients with other diseases where lymphatics have been implicated, such as impaired immune cell trafficking, severe obesity, atherosclerosis, and cancer metastasis. The objective of this project is to develop a predictive framework that quantitatively describes the interplay between mechanical loading, lymphatic growth and remodeling, and lymphatic function by using experimental approaches at the animal, tissue and cellular levels. Our central hypothesis is that sustained abnormally elevated mechanical loading on a collecting lymphatic vessel induces a remodeling response by the vessel, which promotes cell proliferation and increased matrix deposition until it reaches a threshold at which this response negatively affects lymphatic transport, altering the tissue microenvironment and further compromising fluid, protein, and lipid transport by the lymphatic system. This hypothesis will be tested through two Specific Aims: 1) Quantify the growth and remodeling response of the lymphatic microstructure to sustained mechanical loading; and 2) Quantify the effects of this growth and remodeling response on lymphatic function and vessel mechanics. The rationale for this work is that it will provide mechanistic insight into the progression of lymphedema, identifying pathways for intervention that will restore lymphatic function. We anticipate that the findings from these studies will have an impact on the treatment of lymphatic disease by paving the way for patient specific modeling and for prediction of lymphedema risk through the use of integrated lymphatic imaging and computational modeling toolsets.

Public Health Relevance

Patients with lymphedema or other related lymphatic diseases continue to suffer from the debilitating nature of the disease, with very few therapies available to treat or manage the side effects. Often the disease results in drastic and irreversibl remodeling of the tissue in the affected limb. We therefore seek to develop an experimental understanding of disease progression and of the role that biomechanics and tissue growth and remodeling play in this process, which will provide insight into new approaches for intervention and treatment.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL113061-03
Application #
8851663
Study Section
Hypertension and Microcirculation Study Section (HM)
Program Officer
Tolunay, Eser
Project Start
2013-08-01
Project End
2016-05-31
Budget Start
2015-06-01
Budget End
2016-05-31
Support Year
3
Fiscal Year
2015
Total Cost
Indirect Cost
Name
Georgia Institute of Technology
Department
Engineering (All Types)
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
097394084
City
Atlanta
State
GA
Country
United States
Zip Code
30318
Hooks, Joshua S T; Clement, Cristina C; Nguyen, Hoang-Dung et al. (2018) In vitro model reveals a role for mechanical stretch in the remodeling response of lymphatic muscle cells. Microcirculation :e12512
Razavi, Mohammad S; Nelson, Tyler S; Nepiyushchikh, Zhanna et al. (2017) The relationship between lymphangion chain length and maximum pressure generation established through in vivo imaging and computational modeling. Am J Physiol Heart Circ Physiol 313:H1249-H1260
Kassis, Timothy; Yarlagadda, Sri Charan; Kohan, Alison B et al. (2016) Postprandial lymphatic pump function after a high-fat meal: a characterization of contractility, flow, and viscosity. Am J Physiol Gastrointest Liver Physiol 310:G776-89
Caulk, Alexander W; Dixon, J Brandon; Gleason Jr, Rudolph L (2016) A lumped parameter model of mechanically mediated acute and long-term adaptations of contractility and geometry in lymphatics for characterization of lymphedema. Biomech Model Mechanobiol 15:1601-1618
Caulk, Alexander W; Nepiyushchikh, Zhanna V; Shaw, Ryan et al. (2015) Quantification of the passive and active biaxial mechanical behaviour and microstructural organization of rat thoracic ducts. J R Soc Interface 12:20150280
Kornuta, Jeffrey A; Nepiyushchikh, Zhanna; Gasheva, Olga Y et al. (2015) Effects of dynamic shear and transmural pressure on wall shear stress sensitivity in collecting lymphatic vessels. Am J Physiol Regul Integr Comp Physiol 309:R1122-34
Dixon, J Brandon; Weiler, Michael J (2015) Bridging the divide between pathogenesis and detection in lymphedema. Semin Cell Dev Biol 38:75-82
Kornuta, Jeffrey A; Dixon, J Brandon (2014) Ex vivo lymphatic perfusion system for independently controlling pressure gradient and transmural pressure in isolated vessels. Ann Biomed Eng 42:1691-704