Networked lymphatic endothelial cells in a transplanted cell sheet contribute to form functional lymphatic vessels

Tissue-Engineered Therapeutics for Lymphatic Regeneration: Solutions for Myocardial Infarction and Secondary Lymphedema

The lymphatic system, which regulates inflammation and fluid homeostasis, is damaged in various diseases including myocardial infarction (MI) and breast-cancer-related lymphedema (BCRL). Mounting evidence suggests that restoring tissue fluid drainage and clearing excess immune cells by regenerating damaged lymphatic vessels can aid in cardiac repair and lymphedema amelioration. Current treatments primarily address symptoms rather than underlying causes due to a lack of regenerative therapies, highlighting the importance of the lymphatic system as a promising novel therapeutic target. Here cutting-edge research on engineered lymphatic tissues, growth factor therapies, and cell-based approaches designed to enhance lymphangiogenesis and restore lymphatic function is explored. Special focus is placed on how therapies with potential for immediate lymphatic reconstruction, originally designed for treating BCRL, can be applied to MI to augment cardiac repair and reduce heart failure risk. The integration of these novel treatments can significantly improve patient outcomes by promoting lymphatic repair, preventing pathological remodeling, and offering new avenues for managing lymphatic-associated diseases.

Development of a rat model of lymphedema and the implantation of a collagen-based medical device for therapeutic intervention

Secondary lymphedema is a common condition among cancer survivors, and treatment strategies to prevent or treat lymphedema are in high demand. The development of novel strategies to diagnose or treat lymphedema would benefit from a robust experimental animal model of secondary lymphedema. The purpose of this methods paper is to describe and summarize our experience in developing and characterizing a rat hindlimb model of lymphedema. Here we describe a protocol to induce secondary lymphedema that takes advantage of micro computed tomography imaging for limb volume measurements and visualization of lymph drainage with near infrared imaging. To demonstrate the utility of this preclinical model for studying the therapeutic benefit of novel devices, we apply this animal model to test the efficacy of a biomaterials-based implantable medical device.