In Vitro Irradiation of Lymphatic Vessels Enhances Lymphatic Pump Function.

Active lymphatic pumping is critical for propulsion of lymph against a pressure gradient as well as transport of lipids and immune cells to the central venous circulation. When lymphatic pumping is impaired, diminished lymph flow leads to interstitial edema, immune cell accumulation and sustained inflammation. However, a majority of radiation biology research has primarily focused on the effects of ionizing radiation (IR) on blood vessels. These studies reported that IR induces imbalance between vaso-dilatory and -constrictive pathways and impairs vascular tone. Only a handful of the studies have investigated the acute effects of IR on lymphatic vessels. Furthermore, the studies evaluating IR-induced changes in lymphatic tone and pumping in vivo are limited because, in addition to the intrinsic contractility of the lymphatic muscle, lymphatic tone and pumping in vivo is modulated by a variety of substances present in the luminal lymph and the surrounding interstitial fluid. Therefore, the goal of the present study was to characterize the effects of IR on lymphatic tone and pumping independent of the confounding effects of IR on the other tissues. Mesenteric lymphatic vessels (MLVs), isolated from male Sprague Dawley rats, were randomly divided into SHAM and IR groups and were placed in chilled APSS. MLVs from the IR group were then irradiated with X-rays at 10 Gray Dose. Immediately after irradiation, MLVs from both groups were placed in chilled APSS until further use. MLVs were then cannulated and perfused with warm APSS. Lymphatic pumping was assessed in spontaneously contracting vessels. Role of nitric oxide (NO) and cyclooxygenase (COX) pathways was evaluated by assessing pump function in separate MLVs before and after incubation in N(ω)-nitro-L-arginine methyl ester (L-NAME; 100 µM) and Indomethacin (INDO; 10 µM). Evaluation of the lymphatic pumping in response to changes in transmural pressure revealed significantly increased contraction frequency and calculated active lymph flow in IR MLVs compared to those in SHAM MLVs. However, stroke volume normalized to passive volume and diastolic tone were not significantly different between the IR and SHAM MLVs. The increase in contraction frequency in IR MLVs was partially restored by the blockade of COX pathways with INDO. Blockade of NOS with L-NAME, however, led to further increase in contraction frequency of IR MLVs, which was significantly higher than that in SHAM MLVs. Early studies investigating the IR effects on lymphatic endothelial cells reported that lymphatic endothelium is resistant to IR. Conflicting findings of the in vivo lymphatic studies have further confounded the insights into the lymphatic responses to IR. It has been widely believed that lymphatic vessels are unaffected by IR, and therefore, the role of the lymphatic system- the other half of the circulatory system, in radiation injury has been mostly ignored. However, it is evident from the findings of the present study that lymphatic vessels are indeed affected by IR. Furthermore, IR-induced increase in contraction frequency observed in the present study suggests that lymphatic acute responses to IR differ from the blood vessel responses.