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Abstract

Background:

There are very little scientific data on occlusion pressure for superficial lymphatic collectors. Given its importance in determining the transport capacity of lymphatic vessels, it is crucial to know its value. The novel method of near-infrared fluorescence lymphatic imaging (NIRFLI) can be used to visualize lymphatic flow in real time. The goal of this study was to see if this method could be used to measure the lymphatic occlusion pressure.

Methods:

We observed and recorded lymph flow in the upper limb of healthy volunteers through a transparent cuff using near-infrared fluorescence lymphatic imaging. After obtaining a baseline of the lymph flow without pressure inside the cuff, the cuff was inflated by increments of 10 mm Hg starting at 30 mm Hg. A NIRFLI guided manual lymphatic drainage technique named “Fill & Flush Drainage Method” was performed during the measurement to promote lymph flow. Lymphatic occlusion pressure was determined by observing when lymph flow stopped under the cuff.

Results:

We measured the lymphatic occlusion pressure on 30 healthy volunteers (11 men and 19 women). Mean lymphatic occlusion pressure in the upper limb was 86 mm Hg (CI ±3.7 mm Hg, α = 0.5%). No significant differences were found between age groups (p = 0.18), gender (p = 0.12), or limb side (p = 0.85).

Conclusions:

NIRFLI, a transparent sphygmomanometer cuff and the “Fill and Flush” manual lymphatic drainage method were used to measure the lymphatic occlusion pressure in 30 healthy humans. That combination of these techniques allows the visualization of the lymph flow in real time, while ensuring the continuous filling of the lymph collectors during the measurement session, reducing false negative observations. The measured occlusion pressures are much higher than previously described in the medical literature.

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References

Woodcock

, Woodcock

. Revised Starling equation and the glycocalyx model of transvascular fluid exchange: An improved paradigm for prescribing intravenous fluid therapy. Brit J Anaesth, 2012; 108:384–394.

von der Weid

, Zawieja

. Lymphatic smooth muscle: The motor unit of lymph drainage. Int J Biochem Cell Biol, 2004; 36:1147–1153.

Modi

, Stanton

, Svensson

, Peters

, Mortimer

, Levick

. Human lymphatic pumping measured in healthy and lymphoedematous arms by lymphatic congestion lymphoscintigraphy. J Physiol, 2007; 583:271–285.

Olszewski

, Engeset

. Intrinsic contractility of prenodal lymph vessels and lymph flow in human leg. Am J Physiol, 1980; 239:H775–783.

Scallan

, Davis

, Huxley

. Permeability and contractile responses of collecting lymphatic vessels elicited by atrial and brain natriuretic peptides. J Physiol, 2013; 591:5071–5081.

Breslin

. Mechanical forces and lymphatic transport. Microvasc Res, 2014; 96:46–54.

Tourani

, Taylor

, Ashton

. Anatomy of the superficial lymphatics of the abdominal wall and the upper thigh and its implications in lymphatic microsurgery. JPRAS, 2013; 66:1390–1395.

Huxley

, Scallan

. Lymphatic fluid: exchange mechanisms and regulation. J Physiol, 2011; 589:2935–2943.

Gasheva

, Zawieja

, Gashev

. Contraction-initiated NO-dependent lymphatic relaxation: A self-regulatory mechanism in rat thoracic duct. J Physiol, 2006; 575:821–832.

10.

Gashev

. Lymphatic vessels: Pressure- and flow-dependent regulatory reactions. Ann NY Acad Sci, 2008; 1131:100–109.

11.

Briggs Boedtkjer

, Rumessen

, Baandrup

, et al. Identification of interstitial Cajal-like cells in the human thoracic duct. Cells Tissues Organs, 2013; 197:145–158.

12.

Ikomi

, Zweifach

, Schmid-Schonbein

. Fluid pressures in the rabbit popliteal afferent lymphatics during passive tissue motion. Lymphology, 1997; 30:13–23.

13.

Olszewski

, Engeset

. Lymphatic contractions. New Engl J Med, 1979; 300:316.

14.

Miller

, Seale

. The recovery of terminal lymph flow following occlusion. J Biomechan Engineer, 1987; 109:7.

15.

Rasmussen

, Tan

, Marshall

, Fife

, Sevick-Muraca

. Lymphatic imaging in humans with near-infrared fluorescence. Curr Opin Biotechnol, 2009; 20:74–82.

16.

Tan

, Maus

, Rasmussen

, et al. Assessment of lymphatic contractile function after manual lymphatic drainage using near-infrared fluorescence imaging. Arch Phys Med Rehabil, 2011; 92:756–64.e1.

17.

Unno

, Nishiyama

, Suzuki

, et al. A novel method of measuring human lymphatic pumping using indocyanine green fluorescence lymphography. J Vasc Surg, 2010; 52:946–952.

18.

Eliska

, Eliskova

. Are peripheral lymphatics damaged by high pressure manual massage?. Lymphology, 1995; 28:21–30.

19.

Casley-Smith

, Boris

, Weindorf

, Lasinski

. Treatment for lymphedema of the arm—the Casley-Smith method: A noninvasive method produces continued reduction. Cancer, 1998; 83:2843–2860.

20.

Lymphology ISo. The diagnosis and treatment of peripheral lymphedema. 2009 Concensus Document of the International Society of Lymphology. Lymphology, 2009; 42:51–60.

21.

ILF. Lymphoedema Framework. Best Practice for the Management of Lymphoedema. International Consensus. London: MEP Ltd, 2006.

22.

Belgrado

, Bourgeois

, Röh

, Moraine

. Intermittent pneumatic compression in the treatment of lymphedema: Current state of knowledge. Eur J Lymphology Relat Prob, 2007; 17:4–10.

23.

Theys

, Deltombe

, Jamart

, Schoevaerdts

, Buche

. 30 or 90 mm Hg—manual or pneumatic—drainage in primary limb lymphedema: A comparative plethysmographic study. Eur J Lymphol Relat Prob, 2004; 12.

24.

Zaleska

, Olszewski

, Jain

, et al. Pressures and timing of intermittent pneumatic compression devices for efficient tissue fluid and lymph flow in limbs with lymphedema. Lymphat Res Biol, 2013; 11:227–232.

25.

Boccardo

, De Cian

, Campisi

, et al. Surgical prevention and treatment of lymphedema after lymph node dissection in patients with cutaneous melanoma. Lymphology, 2013; 46:20–26.

26.

Bourgeois

, Leduc

, Belgrado

, Leduc

. Effect of lateralization and handedness on the function of the lymphatic system of the upper limbs. Lymphology, 2010; 43:78–84.

27.

Tan

, Maus

, Rasmussen

, et al. Assessment of lymphatic contractile function after manual lymphatic drainage using near-infrared fluorescence imaging. Arch Phys Med Rehabil, 2011; 92:756–764.e1.

28.

Proulx

, Luciani

, Derzsi

, et al. Quantitative imaging of lymphatic function with liposomal indocyanine green. Cancer Res, 2010; 70:7053–7062.

29.

Unno

, Inuzuka

, Suzuki

, et al. Preliminary experience with a novel fluorescence lymphography using indocyanine green in patients with secondary lymphedema. J Vasc Surg, 2007; 45:1016–1021.

30.

Rasmussen

, Tan

I-C

, Marshall

, et al. Human lymphatic architecture and dynamic transport imaged using near-infrared fluorescence. Translational Oncol, 2010; 3:362–372.

31.

Aldrich

, Davies-Venn

, Angermiller

, et al. Concentration of indocyanine green does not significantly influence lymphatic function as assessed by near-infrared imaging. Lymphat Res Biol, 2012; 10:20–24.

32.

Benya

, Quintana

, Brundage

. Adverse reactions to indocyanine green: A case report and a review of the literature. Cathet Cardiovasc Diagn, 1989; 17:231–233.

33.

Toczylowska

, Zieminska

, Goch

, Milej

, Gerega

, Liebert

. Neurotoxic effects of indocyanine green. Cerebellar granule cell culture viability study. Biomed Optics Express, 2014; 5:800–816.

34.

Olszewski

, Engeset

. Intrinsic contractility of leg lymphatics in man. Preliminary communication. Lymphology, 1979; 12:81–84.

35.

Scallan

, Huxley

, Korthuis

, eds. Capillary Fluid Exchange Regulation, Functions and Pathology. Columbia. 2010.

36.

Földi

, Földi

, Kubik

, eds. Textbook of Lymphology for Physicians and Lymphedema Therapists: Urban & Fischer; 2003.

37.

O'Mahony

, Rose

, Chilvers

, et al. Finding an optimal method for imaging lymphatic vessels of the upper limb. Eur J Nuclear Med Mol Imag, 2004; 31:555–563.

38.

Bourgeois

, Leduc

, Belgrado

, Leduc

. Scintigraphic investigations of the superficial lymphatic system: Quantitative differences between intradermal and subcutaneous injections. Nucl Med Commun, 2009; 30:270–274.

39.

Levick

, Michel

. Microvascular fluid exchange and the revised Starling principle. Cardiovasc Res, 2010; 87:198–210.

40.

Cheng

, Deitch

, Haines

, Porter

, Kilbreath

. Do medical procedures in the arm increase the risk of lymphoedema after axillary surgery? A review. ANZ J Surg, 2014; 84:510–514.

41.

Segers

, Belgrado

, Leduc

, Verdonck

. Excessive pressure in multichambered cuffs used for sequential compression therapy. Phys Ther, 2002; 82:1000–1008.

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Near-Infrared Fluorescence Lymphatic Imaging to Reconsider Occlusion Pressure of Superficial Lymphatic Collectors in Upper Extremities of Healthy Volunteers

Abstract

Abstract

Background:

Methods:

Results:

Conclusions:

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References

Supplementary Material