Abstract
Lymphatic contractions play a fundamental role in maintaining tissue and organ homeostasis. The lymphatic system relies on orchestrated contraction of collecting lymphatic vessels, via lymphatic muscle cells and one-way valves, to transport lymph from the interstitial space back to the great veins, against an adverse pressure gradient. Circumferential stretch is known to regulate contractile function in collecting lymphatic vessels; however, less is known about the role of axial stretch in regulating contraction. It is likely that collecting lymphatic vessels are under axial strain in vivo and that the opening and closing of lymphatic valves leads to significant changes in axial strain throughout the pumping cycle. The purpose of this paper is to quantify the responsiveness of lympatic pumping to altered axial stretch. In situ measurements suggest that rat tail collecting lymphatic vessels are under an axial stretch of ~1.24 under normal physiological loads. Ex vivo experiments on isolated rat tail collecting lymphatics showed that the contractile metrics such as contractile amplitude, frequency, ejection fraction, and fractional pump flow are sensitive to axial stretch. Multiphoton microscopy showed that the predominant orientation of collagen fibers is in the axial direction, while lymphatic muscle cell nuclei and actin fibers are oriented in both circumferential and longitudinal directions, suggesting an axial component to contraction. Taken together, these results demonstrate the significance of axial stretch in lymphatic contractile function, suggest that axial stretch may play an important role in regulating lymph transport, and demonstrate that changes in axial strains could be an important factor in disease progression.
Highlights
Similar to circumferential stretch, axial stretch may be a modulator of lymphatic function
The measured in situ axial stretch, λin situ = 1.24 ± 0.03 (n = 5), demonstrates that rat tail lymphatic vessels are under significant axial stretch (Fig. 1)
Similar trends were observed for the frequency, which decreased from 15 min−1 to
Summary
Axial stretch may be a modulator of lymphatic function. An increase in the axial load with both pressure and axial stretch has been reported for the rat thoracic duct[33]; there is no experimental evidence to show lymphatic vessels experience axial stretch in situ. Towards this end, the goal of this study is to quantify the in situ axial stretch of rat tail lymphatics and axial stretch-mediated modulation of lymphatic contractility in an ex vivo platform. The distribution of collagen and LMCs’s of rat tail lymphatics in the circumferential-axial plane were quantified to understand the axial contributions of these structural constituents
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