Human thoracic duct in vitro: diameter-tension properties, spontaneous and evoked contractile activity

Telinius, Niklas; Drewsen, Nanna; Pilegaard, Hans K.; Kold-Petersen, Henrik; Leval, Marc de; Aalkjær, Christian; Hjortdal, Vibeke E.; Boedtkjer, Donna Briggs

doi:10.1152/ajpheart.01089.2009

Cited by 58 publications

(80 citation statements)

References 30 publications

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“…It is important to note that the thoracic ducts came from aged patients with a malignancy; thus, local and systemic changes as potential influencers of our results cannot be excluded. Tissue harvest was performed as previously described (5,25,26). In brief, a separate tissue block at level T7-T9 was removed and immediately placed in cold (4°C) physiological saline solution (PSS), and the thoracic duct was subsequently dissected free from the surrounding connective tissue and fat under a stereomicroscope.…”

Section: Tissue Preparationmentioning

confidence: 99%

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The contribution of K⁺ channels to human thoracic duct contractility

Telinius

Kim

Pilegaard

et al. 2014

American Journal of Physiology-Heart and Circulatory Physiology

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Telinius N, Kim S, Pilegaard H, Pahle E, Nielsen J, Hjortdal V, Aalkjaer C, Boedtkjer DB. The contribution of K ϩ channels to human thoracic duct contractility. Am J Physiol Heart Circ Physiol 307: H33-H43, 2014. First published April 28, 2014 doi:10.1152/ajpheart.00921.2013In smooth muscle cells, K ϩ permeability is high, and this highly influences the resting membrane potential. Lymph propulsion is dependent on phasic contractions generated by smooth muscle cells of lymphatic vessels, and it is likely that K ϩ channels play a critical role in regulating contractility in this tissue. The aim of this study was to investigate the contribution of distinct K ϩ channels to human lymphatic vessel contractility. Thoracic ducts were harvested from 43 patients and mounted in a wire myograph for isometric force measurements or membrane potential recordings with an intracellular microelectrode. Using K ϩ channel blockers and activators, we demonstrate a functional contribution to human lymphatic vessel contractility from all the major classes of K ϩ channels [ATP-sensitive K ϩ (KATP), Ca 2ϩ -activated K ϩ , inward rectifier K ϩ , and voltage-dependent K ϩ channels], and this was confirmed at the mRNA level. Contraction amplitude, frequency, and baseline tension were altered depending on which channel was blocked or activated. Microelectrode impalements of lymphatic vessels determined an average resting membrane potential of Ϫ43.1 Ϯ 3.7 mV. We observed that membrane potential changes of Ͻ5 mV could have large functional effects with contraction frequencies increasing threefold. In general, KATP channels appeared to be constitutively open since incubation with glibenclamide increased contraction frequency in spontaneously active vessels and depolarized and initiated contractions in previously quiescent vessels. The largest change in membrane voltage was observed with the KATP opener pinacidil, which caused 24 Ϯ 3 mV hyperpolarization. We conclude that K ϩ channels are important modulators of human lymphatic contractility. lymphatic vessels; membrane potential; potassium channels; thoracic duct; human LYMPHATIC COLLECTING VESSELS have an intrinsic capacity to generate phasic contractions that enable lymph to be pumped away from tissue and eventually back to the venous circulation. The intrinsic contractile activity of lymphatic vessels is triggered by an underlying electrical activity in lymphatic smooth muscle cells (LSMCs) of the vessel wall. The electrical activity of LSMCs has been measured by various techniques in several animal species but has not yet been demonstrated in human lymphatic vessels. Animal LSMCs produce spontaneous depolarization and action potentials consisting of a rapid depolarization and repolarization of the LSMC membrane potential (V m ) without a plateau phase (30). Intracellular microelectrode impalements of bovine and guinea pig mesenteric collecting lymphatic vessels (70 -500 m in diameter) have shown that the resting membrane potential (RMP) of LSMCs averages around Ϫ60 mV (27-29, 32, 33), whe...

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Section: Tissue Preparationmentioning

confidence: 99%

“…Each ring segment was normalized by setting them to an internal diameter where the wall tension was equivalent to a transmural pressure of 21 mmHg [the value at which vessels were determined to produce peak active tension (26)] using the DMT Normalization module for Chart software.…”

Section: Isometric Tension Measurementsmentioning

confidence: 99%

The contribution of K⁺ channels to human thoracic duct contractility

Telinius

Kim

Pilegaard

et al. 2014

American Journal of Physiology-Heart and Circulatory Physiology

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“…water-immersion objective (LD C-Apocromat, N.A.1.1). SMCs were examined by staining with rhodamine-labeled phalloidin, as described previously [Telinius et al, 2010]. In all instances, scanning was initiated from the luminal side.…”

Section: Whole-mount Immunofluorescencementioning

confidence: 99%

“…Given the volume of chyle they have to transport postprandially, the hydrostatic pressure gradient created by gravity and the need to develop pressure higher than the venous pressure in order to empty into the venous system, the TD lymphangions represent those most likely to generate the strongest propulsion in the human lymphatic system. Indeed, our previous functional study of isolated human TD demonstrates that this vessel can generate contractile tone that would result in an equivalent transmural pressure of approximately 70 mm Hg [Telinius et al, 2010].…”

Section: Introductionmentioning

confidence: 99%

“…Spontaneous activity independent of heart or respiratory activity, nervous or humoral inputs, or flow and pressure changes has also been observed in animal TD [Reddy and Staub, 1981;Onizuka et al, 1997;Moffatt and Cocks, 2004] and in human TD in situ under anesthesia [Kinmonth and Taylor, 1956;Kinmonth and Sharpey-Schafer, 1959;Edwards et al, 1965] and ex vivo [Sjoberg and Steen, 1991;Telinius et al, 2010]. The cellular mechanism responsible for the spontaneous and autoregulatory activity of the lymphatic vasculature has been debated since the very first experimental observations of this activity in animals.…”

Section: Introductionmentioning

confidence: 99%

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Identification of Interstitial Cajal-Like Cells in the Human Thoracic Duct

Rumessen¹,

Baandrup²,

Mikkelsen³

et al. 2012

Cells Tissues Organs

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Interstitial Cajal-like cells (ICLCs) are speculated to be pacemakers in smooth muscle tissues. While the human thoracic duct (TD) is spontaneously active, the origin of this activity is unknown. We hypothesized that ICLCs could be present in the TD and using histological techniques, immunohistochemistry and immunofluorescence we have investigated the presence of ICLCs, protein markers for ICLCs and the cellular morphology of the human TD. Transmission electron microscopy was employed to investigate ultrastructure. Methylene blue staining, calcium-dependent fluorophores and confocal microscopy were used to identify ICLCs in live tissue. Methylene blue stained cells with morphology suggestive of ICLCs in the TD. Immunoreactivity localized the ICLC protein markers c-kit, CD34 and vimentin to many cells and processes associated with smooth muscle cells (SMCs): coexpression of c-kit with vimentin or CD34 was observed in some cells. Electron microscopy analysis confirmed ICLCs as a major cell type of the human TD. Lymphatic ICLCs possess caveolae, dense bands, a patchy basal lamina, intermediate filaments and specific junctions to SMCs. ICLCs were ultrastructurally differentiable from other interstitial cells observed: fibroblasts, mast cells, macrophages and pericytes. Lymphatic ICLCs were localized to the subendothelial region of the wall as well as in intimate association with smooth muscle bundles throughout the media. ICLCs were morphologically distinct with multiple processes and also spindle shapes. Confocal imaging with calcium-dependent fluorophores corroborated cell morphology and localization observed in fixed tissues. Lymphatic ICLCs thus constitute a significant cell type of the human TD and physically interact with lymphatic SMCs.

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Lymphatic Vessel Network Structure and Physiology

Breslin

Yang

Scallan

et al. 2018

Comprehensive Physiology

274

258

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The lymphatic system is comprised of a network of vessels interrelated with lymphoid tissue, which has the holistic function to maintain the local physiologic environment for every cell in all tissues of the body. The lymphatic system maintains extracellular fluid homeostasis favorable for optimal tissue function, removing substances that arise due to metabolism or cell death, and optimizing immunity against bacteria, viruses, parasites, and other antigens. This article provides a comprehensive review of important findings over the past century along with recent advances in the understanding of the anatomy and physiology of lymphatic vessels, including tissue/organ specificity, development, mechanisms of lymph formation and transport, lymphangiogenesis, and the roles of lymphatics in disease.

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Human thoracic duct in vitro: diameter-tension properties, spontaneous and evoked contractile activity

Cited by 58 publications

References 30 publications

The contribution of K⁺ channels to human thoracic duct contractility

The contribution of K⁺ channels to human thoracic duct contractility

Identification of Interstitial Cajal-Like Cells in the Human Thoracic Duct

Lymphatic Vessel Network Structure and Physiology

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Human thoracic duct in vitro: diameter-tension properties, spontaneous and evoked contractile activity

Cited by 58 publications

References 30 publications

The contribution of K+ channels to human thoracic duct contractility

The contribution of K+ channels to human thoracic duct contractility

Identification of Interstitial Cajal-Like Cells in the Human Thoracic Duct

Lymphatic Vessel Network Structure and Physiology

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The contribution of K⁺ channels to human thoracic duct contractility

The contribution of K⁺ channels to human thoracic duct contractility