Contraction-initiated NO-dependent lymphatic relaxation: a self-regulatory mechanism in rat thoracic duct

doi:10.1113/jphysiol.2006.115212

CARDIOVASCULAR

Contraction-initiated NO-dependent lymphatic relaxation: a self-regulatory mechanism in rat thoracic duct

Olga Yu. Gasheva¹, David C. Zawieja¹ and Anatoliy A. Gashev¹

¹ Department of Systems Biology and Translational Medicine, College of Medicine, Cardiovascular Research Institute Division of Lymphatic Biology, Texas A & M Health Science Center, 336 Reynolds Medical Bldg, College Station, TX 77843-1114, USA

The objectives of this study were to evaluate the physiologicalimportance of the flow and shear generated by phasic contractionsof lymphatic vessels and the mechanisms responsible for theinfluences of such shear on lymphatic pumping. Lymphatic segmentsof the rat thoracic duct were isolated, cannulated and pressurized.The diastolic diameters were measured in phasically non-activesegments. The diastolic and systolic diameters, half-relaxationtime (HRT), contraction frequency, ejection fraction and fractionalpump flow were determined in phasically active segments. Sinceimposed flow was excluded, flow and shear occurred only as aresult of the intrinsic contractions in phasically active segmentswhereas in phasically non-active segments contraction-generatedflow and shear were absent. The influences of incrementallyincreased transmural pressure (from 1 to 5 cmH₂O) were examinedin control conditions and after NO synthase blockade (L-NAME10^–4 M) or cyclooxygenase blockade (indomethacin10^–5 M). The spontaneous phasic contractions produceda flow-dependent diastolic relaxation. This reduction of thelymphatic tone is a regulatory mechanism that maintains pumpingin thoracic duct in an energy-saving/efficient mode: it improvesdiastolic filling (enhanced lusitropy – lowering HRT),makes lymphatic contractions stronger (enhanced inotropy –higher contraction amplitude) and propels more fluid forwardduring each contraction (elevated ejection fraction) while decreasingcontraction frequency (reduced chronotropy). The findings alsodemonstrated that the NO pathway, not the cyclooxygenase pathwayis responsible for this reduction of lymphatic tone and is theprevailing pathway responsible for the self-regulatory adjustmentof thoracic duct pumping to changes in lymph flow pattern.

(Received 9 June 2006; accepted after revision 22 June 2006; first published online 29 June 2006)
Corresponding author A. A. Gashev: Department of Systems Biology and Translational Medicine, College of Medicine, Cardiovascular Research Institute Division of Lymphatic Biology, Texas A & M Health Science Center, 336 Reynolds Medical Bldg, College Station, TX 77843-1114, USA. Email: gashev{at}tamu.edu

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