BACKGROUND: Although fat deposition is a defining clinical characteristic of lymphedema, the cellular mechanisms that regulate this response remain unknown. The goals of this two-part study were to determine the effect of lymphatic fluid stasis on adipogenesis and inflammation (part I) and how these changes regulate the temporal and spatial expression of fat differentiation genes (part II). METHODS: Adult female mice underwent tail lymphatic ablation and were euthanized 6 weeks after surgery (n = 20). Fat deposition, fibrosis, and inflammation were then analyzed in the regions of the tail exposed to lymphatic fluid stasis as compared with normal lymphatic flow. RESULTS: Lymphatic fluid stasis in the tail resulted in significant subcutaneous fat deposition, with a 2-fold increase in fat thickness (p < 0.01). In addition, lymphatic stasis was associated with subcutaneous fat fibrosis and collagen deposition. Adipogenesis in response to lymphatic fluid stasis was associated with a marked mononuclear cell inflammatory response (5-fold increase in CD45 cells; p < 0.001). In addition, the authors noted a significant increase in the number of monocytes/macrophages as identified by F4/80 immunohistochemistry (p < 0.001). CONCLUSIONS: The mouse-tail model has pathologic findings that are similar to clinical lymphedema, including fat deposition, fibrosis, and inflammation. Adipogenesis in response to lymphatic fluid stasis closely resembles this process in obesity. This model therefore provides an excellent means with which to study the molecular mechanisms that regulate the pathophysiology of lymphedema.
BACKGROUND: Although fat deposition is a defining clinical characteristic of lymphedema, the cellular mechanisms that regulate this response remain unknown. The goals of this two-part study were to determine the effect of lymphatic fluid stasis on adipogenesis and inflammation (part I) and how these changes regulate the temporal and spatial expression of fat differentiation genes (part II). METHODS: Adult female mice underwent tail lymphatic ablation and were euthanized 6 weeks after surgery (n = 20). Fat deposition, fibrosis, and inflammation were then analyzed in the regions of the tail exposed to lymphatic fluid stasis as compared with normal lymphatic flow. RESULTS: Lymphatic fluid stasis in the tail resulted in significant subcutaneous fat deposition, with a 2-fold increase in fat thickness (p < 0.01). In addition, lymphatic stasis was associated with subcutaneous fat fibrosis and collagen deposition. Adipogenesis in response to lymphatic fluid stasis was associated with a marked mononuclear cell inflammatory response (5-fold increase in CD45 cells; p < 0.001). In addition, the authors noted a significant increase in the number of monocytes/macrophages as identified by F4/80 immunohistochemistry (p < 0.001). CONCLUSIONS: The mouse-tail model has pathologic findings that are similar to clinical lymphedema, including fat deposition, fibrosis, and inflammation. Adipogenesis in response to lymphatic fluid stasis closely resembles this process in obesity. This model therefore provides an excellent means with which to study the molecular mechanisms that regulate the pathophysiology of lymphedema.
Authors: Jerome W Breslin; Ying Yang; Joshua P Scallan; Richard S Sweat; Shaquria P Adderley; Walter L Murfee Journal: Compr Physiol Date: 2018-12-13 Impact factor: 9.090
Authors: Geunwon Kim; Martin P Smith; Kevin J Donohoe; Anna Rose Johnson; Dhruv Singhal; Leo L Tsai Journal: Eur Radiol Date: 2020-03-27 Impact factor: 5.315