Characterization of intact mesenteric lymphatic pump and its responsiveness to acute edemagenic stress

Benoit, Joseph N.; Zawieja, David C.; Goodman, A. H.; Granger, Harris J.

doi:10.1152/ajpheart.1989.257.6.h2059

Cited by 178 publications

(306 citation statements)

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“…Our conclusion is consistent with previous studies (3,14,15) of rat mesenteric lymphatics, where calculated pump output was maintained over a pressure range from 1 to 5 cmH 2 O because increases in contraction FREQ counterbalanced decreases in SV; likewise, measurements of SV, EF, and/or flow from bovine and ovine lymphatics suggest that optimal EDP in those vessels is between 2 and 8 cmH 2 O (12,14,15,22,24,26,28,34). An upper end of 8 cmH 2 O is likely to correlate with the diminished pump capacity observed in human peripheral lymphatic vessels during chronic lymphedema (31).…”

Section: Comparison With Previous Lymphatic Studiessupporting

confidence: 92%

“…Rapid, step-wise increases in P in were imposed in ascending order to determine the speed of the adaptation and the time course over which intrinsic, secondary adjustments, if any, occurred. First, cumulative, step-wise increases in Pin from the baseline level to 1,3,5,8,12, and 16 cmH 2O were imposed by the servo controller, with pressure elevation maintained for 1-2 min at each pressure. Second, the same P in levels were tested (either randomized or sequential) but with Pin returned to the baseline level after each step; in these cases, each step and recovery period lasted ϳ5 min.…”

Section: Protocolsmentioning

confidence: 99%

“…Simultaneous increases in preload and afterload simulate changes that might occur during edemagenic stress in vivo (3,18). A slow pressure ramp in both P in and Pout, from baseline pressure to 12 or 16 cmH2O, was imposed.…”

Section: Protocolsmentioning

confidence: 99%

“…First, this is one of only three studies to characterize the relationship between diastolic pressure and function for a single, isolated lymphangion. With the exception of two short reports in untranslated Russian journals (18,27), previous studies (3,12,14,15,26,28) used multiple chains of lymphangions where, due to intrinsic contractile behavior that could be synchronized or nonsynchronized, P in was controlled only for the first segment of the chain and P out only for the last segment. Hence, the results presented here provide insights into the effect of preload on the function of the fundamental pumping unit of the lymphatic system: the lymphangion.…”

Section: Comparison With Previous Lymphatic Studiesmentioning

confidence: 99%

“…Notably, two studies have made use of cardiac-style analyses to study lymphatic pump function. Plots of intraluminal pressure (P L ) as a function of volume (calculated from internal diameter measurements) were characterized by counterclockwise loops that shifted to the right after systemic volume expansion (3) or simultaneous elevation of P in and P out (26). While those studies provided valuable information about the adaptation of the intact lymphatic pump to edemagenic loads, the effects of selectively changing preload at low and high levels of afterload were not assessed.…”

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confidence: 99%

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Independent and interactive effects of preload and afterload on the pump function of the isolated lymphangion

Scallan

Wolpers

Muthuchamy³

et al. 2012

American Journal of Physiology-Heart and Circulatory Physiology

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Scallan JP, Wolpers JH, Muthuchamy M, Zawieja DC, Gashev AA, Davis MJ. Independent and interactive effects of preload and afterload on the pump function of the isolated lymphangion. Am J Physiol Heart Circ Physiol 303: H809 -H824, 2012. First published August 3, 2012; doi:10.1152/ajpheart.01098.2011We tested the responses of single, isolated lymphangions to selective changes in preload and the effects of changing preload on the response to an imposed afterload. The methods used were similar to those described in our companion paper.Step-wise increases in input pressure (Pin; preload) over a pressure range between 0.5 and 3 cmH2O, at constant output pressure (Pout), led to increases in end-diastolic diameter, decreases in endsystolic diameter, and increases in stroke volume. From a baseline of 1 cmH 2O, Pin elevation by 2-7 cmH2O consistently produced an immediate fall in stroke volume that subsequently recovered over a time course of 2-3 min. Surprisingly, this adaptation was associated with an increase in the slope of the end-systolic pressure-volume relationship, indicative of an increase in contractility. Lymphangions subjected to Pout levels exceeding their initial ejection limit would often accommodate by increasing diastolic filling to strengthen contraction sufficiently to match Pout. The lymphangion adaptation to various pressure combinations (Pin ramps with low or high levels of Pout, Pout ramps at low or intermediate levels of Pin, and combined Pin ϩ Pout ramps) were analyzed using pressure-volume data to calculate stroke work. Under relatively low imposed loads, stroke work was maximal at low preloads (Pin ϳ2 cmH2O), whereas at more elevated afterloads, the optimal preload for maximal work displayed a broad plateau over a Pin range of 5-11 cmH2O. These results provide new insights into the normal operation of the lymphatic pump, its comparison with the cardiac pump, and its potential capacity to adapt to increased loads during edemagenic and/or gravitational stress. pressure-volume loop; isolated vessel; edema; heterometric regulation; homeometric regulation; stroke work; contractility IN OUR COMPANION PAPER (10), we investigated the effects of selective afterload elevation on the pump function of single lymphangions isolated from the rat mesentery. Elevating output pressure (P out ), at constant preload [input pressure (P in )], led to an intrinsic increase in lymphatic muscle contractility (i.e., positive inotropy), as characterized by a leftward shift in the end systolic pressure-volume relationship (ESPVR), increased peak dP/dt, and the development of higher peak systolic pressure. We concluded that the enhancement in contractility enables the vessel to eject against the adverse pressure gradient that normally exists in most parts of the lymphatic system and that becomes substantially elevated in lymphatic vessels of dependent extremities, including those of humans (31).As in the heart, preload is a significant determinant of lymphatic pump function. Previous studies using isolated chains of seri...

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Section: Comparison With Previous Lymphatic Studiessupporting

confidence: 92%

Section: Protocolsmentioning

confidence: 99%

Section: Protocolsmentioning

confidence: 99%

Section: Comparison With Previous Lymphatic Studiesmentioning

confidence: 99%

mentioning

confidence: 99%

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Independent and interactive effects of preload and afterload on the pump function of the isolated lymphangion

Scallan

Wolpers

Muthuchamy³

et al. 2012

American Journal of Physiology-Heart and Circulatory Physiology

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In vivoImage Flow Cytometry

Tuchin¹,

Galanzha²,

Zharov³

2011

Advanced Optical Flow Cytometry

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Nitric Oxide and the Cardiovascular System

Bohlen

2015

Comprehensive Physiology

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Nitric oxide (NO) generated by endothelial cells to relax vascular smooth muscle is one of the most intensely studied molecules in the past 25 years. Much of what is known about NO regulation of NO is based on blockade of its generation and analysis of changes in vascular regulation. This approach has been useful to demonstrate the importance of NO in large scale forms of regulation but provides less information on the nuances of NO regulation. However, there is a growing body of studies on multiple types of in vivo measurement of NO in normal and pathological conditions. This discussion will focus on in vivo studies and how they are reshaping the understanding of NO's role in vascular resistance regulation and the pathologies of hypertension and diabetes mellitus. The role of microelectrode measurements in the measurement of [NO] will be considered because much of the controversy about what NO does and at what concentration depends upon the measurement methodology. For those studies where the technology has been tested and found to be well founded, the concept evolving is that the stresses imposed on the vasculature in the form of flow-mediated stimulation, chemicals within the tissue, and oxygen tension can cause rapid and large changes in the NO concentration to affect vascular regulation. All these functions are compromised in both animal and human forms of hypertension and diabetes mellitus due to altered regulation of endothelial cells and formation of oxidants that both damage endothelial cells and change the regulation of endothelial nitric oxide synthase.

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Characterization of intact mesenteric lymphatic pump and its responsiveness to acute edemagenic stress

Cited by 178 publications

References 0 publications

Independent and interactive effects of preload and afterload on the pump function of the isolated lymphangion

Independent and interactive effects of preload and afterload on the pump function of the isolated lymphangion

In vivoImage Flow Cytometry

Nitric Oxide and the Cardiovascular System

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