Probing the effect of morphology on lymphatic valve dynamic function

The lymphatic system is vital to the circulatory and immune systems, performing a range of important functions such as transport of interstitial fluid, fatty acid, and immune cells. Lymphatic vessels are composed of contractile walls and lymphatic valves, allowing them to pump lymph against adverse pressure gradients and to prevent backflow. Despite the importance of the lymphatic system, the contribution of mechanical and geometric changes of lymphatic valves and vessels in pathologies of lymphatic dysfunction, such as lymphedema, is not well understood. We develop a fully coupled fluid–solid, three-dimensional computational model to interrogate the various parameters thought to influence valve behavior and the consequences of these changes to overall lymphatic function. A lattice Boltzmann model is used to simulate the lymph, while a lattice spring model is used to model the mechanics of lymphatic valves. Lymphatic valve functions such as enabling lymph flow and preventing backflow under varied lymphatic valve geometries and mechanical properties are investigated to provide an understanding of the function of lymphatic vessels and valves. The simulations indicate that lymphatic valve function is optimized when valves are of low aspect ratio and bending stiffness, so long as these parameters are maintained at high enough values to allow for proper valve closing. This suggests that valve stiffening could have a profound effect on overall lymphatic pumping performance. Furthermore, dynamic valve simulations showed that this model captures the delayed response of lymphatic valves to dynamic flow conditions, which is an essential feature of valve operation. Thus, our model enhances our understanding of how lymphatic pathologies, specifically those exhibiting abnormal valve morphologies such as has been suggested to occur in cases of primary lymphedema, can lead to lymphatic dysfunctions.     

Transmural pressure in rat initial subpleural lymphatics during spontaneous or mechanical ventilation

The role played by the mechanical tissue stress in supporting lymph formation and propulsion in thoracic tissues was studied in deeply anesthetized rats (n = 13) during spontaneous breathing or mechanical ventilation. After arterial and venous catheterization and insertion of an intratracheal cannula, fluorescent dextrans were injected intrapleurally to serve as lymphatic markers. After 2 h, the fluorescent intercostal lymphatics were identified, and the hydraulic pressure in lymphatic vessels (P lymph) and adjacent interstitial space (P int) was measured using micropuncture. During spontaneous breathing, end-expiratory P lymph and corresponding P int were -2.5 +/- 1.1 (SE) and 3.1 +/- 0.7 mmHg (P < 0.01), which dropped to -21.1 +/- 1.3 and -12.2 +/- 1.3 mmHg, respectively, at end inspiration. During mechanical ventilation with air at zero end-expiratory alveolar pressure, P lymph and P int were essentially unchanged at end expiration, but, at variance with spontaneous breathing, they increased at end inspiration to 28.1 +/- 7.9 and 28.2 +/- 6.3 mmHg, respectively. The hydraulic transmural pressure gradient (DeltaP tm = P lymph - P int) was in favor of lymph formation throughout the whole respiratory cycle (DeltaP tm = -6.8 +/- 1.2 mmHg) during spontaneous breathing but not during mechanical ventilation (DeltaP tm = -1.1 +/- 1.8 mmHg). Therefore, data suggest that local tissue stress associated with the active contraction of respiratory muscles is required to support an efficient lymphatic drainage from the thoracic tissues.     

Morphofunctional changes in the hemo- and lymphomicrocirculatory bed of the uterus and its regional lymph nodes in venous congestion during pregnancy

Interrelations of the blood and lymphatic systems of the uterus have been examined in rats at pregnancy complicated with the ++phlebo-occlusive syndrome. Blood stream impediment in the caudal vena cava results in increasing diameter of the arterioles, capillaries and venules of the endo- and myometrium. Certain disturbances of blood circulation in the uterus at the ++phlebo-cclusive syndrome in the pregnancy animals, as a rule, reflect in the uterine lymph outflow; this is demonstrated as dilatation and deformity of the lymphatic vessels and capillaries, appearance of protrusions of the lymphatic vessels wall. There is a definite co-ordination in the reaction to the caudal vena cava occlusion in the intra-, ++extra-organic uterine lymphatic bed and in its regional lymph nodes, manifested as the following morphological signs: decreasing relative volume, that the lymphoid tissue occupies and increasing relative volume of the cortical and medullary intermediate sinuses.     

Observations on the prenatal development of human lymphatic vessels with focus on basic structural elements of lymph flow

BACKGROUND: The prenatal development of human lymphatic systems has not attracted enough attention by lymphatic researchers in the past. Yet clearly these critical, early events determine the fate and function of the human lymphatic system. METHODS AND RESULTS: The main focus of these studies was to investigate the embryonic development of human lymphangions including lymphatic valves and muscle cells, to better understand the prenatal formation of basic structural elements of lymph flow. This review in most of its parts is a short summary of the findings. It provides important information necessary for understanding the development and functioning of the human lymphatic system. CONCLUSIONS: The structural basis of the active lymph transport system--the lymphatic muscle cells and lymphatic valves--which is absolutely necessary for all functions of lymphatic system, is already formed during the first half of the prenatal development in humans. During the second half of this development maturation of this system is already underway. The enlargement of lymphatic muscle cells together with increases in their quantity leads to formation of the multi-layered lymphatic vessel wall, able to develop contractions strong enough to propel lymph downstream of the lymphatic channels against gravity in bipedal humans. The development of the competent valves in lymphatic vessels occurs at the same time creating the ground for effective net, unidirectional lymph flow. The data summarized here represents some of the first systematic studies of the prenatal development of lymphatic muscle cells and valves in humans.     

A lumped parameter model of mechanically mediated acute and long-term adaptations of contractility and geometry in lymphatics for characterization of lymphedema

A primary purpose of the lymphatic system is to transport fluid from peripheral tissues to the central venous system in order to maintain tissue–fluid balance. Failure to perform this task results in lymphedema marked by swelling of the affected limb as well as geometric remodeling and reduced contractility of the affected lymphatic vessels. The mechanical environment has been implicated in the regulation of lymphatic contractility, but it is unknown how changes in the mechanical environment are related to loss of contractile function and remodeling of the tissue. The purpose of this paper was to introduce a new theoretical framework for acute and long-term adaptations of lymphatic vessels to changes in mechanical loading. This theoretical framework combines a simplified version of a published lumped parameter model for lymphangion function and lymph transport, a published microstructurally motivated constitutive model for the active and passive mechanical behavior of isolated rat thoracic ducts, and novel models for acute mechanically mediated vasoreactive adaptations and long-term volumetric growth to simulate changes in muscle contractility and geometry of a single isolated rat thoracic duct in response to a sustained elevation in afterload. The illustrative examples highlight the potential role of the mechanical environment in the acute maintenance of contractility and long-term geometric remodeling, presumably aimed at meeting fluid flow demands while also maintaining mechanical homeostasis. Results demonstrate that contractility may adapt in response to shear stress to meet fluid flow demands and show that pressure-induced long-term geometric remodeling may attenuate these adaptations and reduce fluid flow. The modeling framework and illustrative simulations help suggest relevant experiments that are necessary to accurately quantify and predict the acute and long-term adaptations of lymphangions to altered mechanical loading.     

Active lymphatic pumping and sheep lung lymph flow

Active (intrinsic) lymphatic pumping may be an important factor determining lymph flow from the lungs. Unfortunately, in most experiments, it is very difficult to determine the influence of active pumping vs. passive factors on lymph flow. However, 1) the pumping activity (stroke volume and frequency) of isolated lymphatic segments varies nonlinearly with transmural pressure, and 2) the lung lymph flow from awake sheep varies nonlinearly with lymphatic outflow pressure. Accordingly, if lymphatic pumping significantly influences lung lymph flow, then it should be possible to describe the sheep lung lymph flow vs. outflow pressure data with the pumping activity data. To test this, we used published lymphatic pumping activity data to develop a mathematical model of the lymphatic pump for a segment of lymphatic vessel. Flow vs. outflow pressure relationships obtained from simulations with this model were very similar to the data from sheep. Our results indicate that both passive factors and active lymphatic pumping contribute to lymph flow, and our model may allow investigators to distinguish the effects of active pumping vs. passive factors in the regulation of lymph flow.     

Various characteristics of the structure of the cardiac lymphatic bed and the morphofunctional basis of its insufficiency

Structural peculiarities of the cardiac lymphatic bed have been studied, as well as its adaptive and pathological changes under physical load, acute and recurrent coronary insufficiency under conditions of mechanical blockade of the lymph outflow from the organ, which have been modelled in dogs and rabbits. The cardiac lymphatic bed is injected with various staining masses and investigated stereoangioscopically in translucent preparations, in semithin slices and electron microscopically. The rearrangement of lymphatic capillaries and vessels revealed is of stereotypical character. The degree of manifestation and correlation of morphofunctional reactions, characterizing development of insufficiency of the cardiac lymphatic vessels is mainly determined by intensity and exposition of pathological effects, exercised on it, while etiologic factors are of less importance.     

Lymphatic mapping and sentinel lymph node biopsy in patients with melanoma of the lower extremity

Lymphatic mapping and sentinel lymph node biopsy is a new technique used in the surgical treatment of patients with malignant melanoma. The purpose of this study was to evaluate the results of this approach for patients with melanoma of the lower extremity. Between May of 1994 and June of 1997 at the H. Lee Moffitt Cancer Center and Research Institute, 85 consecutive patients with clinical stage I and II melanoma of the lower extremity underwent lymphatic mapping and sentinel lymph node biopsy. These nodes were identified in all 85 patients by intraoperative lymphatic mapping with both radiolymphoscintigraphy and a vital blue dye injection. Eleven patients (12.9 percent) had histologically positive sentinel lymph nodes, and 10 patients underwent inguinal complete lymph node dissections. All 10 patients had no further histologically positive lymph nodes confirmed by subsequent complete dissection. Among 74 patients with histologically negative sentinel lymph nodes, only 2 patients (2.7 percent) developed inguinal nodal metastases during a mean follow-up period of 21.8 months (range, 13.5 to 58.3 months). The sensitivity of lymphatic mapping and sentinel lymph node biopsy in this series was 100 percent and the specificity was 97.3 percent. Therefore, we conclude that the use of lymphatic mapping and sentinel lymph node biopsy can accurately stage patients with melanoma of the lower extremity and provide a rational surgical approach for these patients.     

肿瘤淋巴管入侵与无淋巴结转移膀胱癌复发及预后的相关性分析

目的:分析肿瘤淋巴管入侵与无淋巴结转移膀胱癌复发和预后之间的关系。方法:选取临床资料完整的膀胱癌病例72例,分为淋巴结转移组(32例)和无淋巴结转移组(40例)。采用Spearman相关分析探讨淋巴管入侵与膀胱癌复发和预后的相关性,应用Kaplan-Meier法描绘生存曲线,Cox比例危险度模型筛选影响膀胱癌患者预后的因素。结果:在72例膀胱癌组织中,淋巴管入侵的阳性率是48.6%(35/72),淋巴管入侵的阳性率随肿瘤分期和分级增加而显著升高(P0.05);淋巴结转移组的淋巴管入侵阳性率为68.8%(22/32),显著高于无淋巴结转移的32.5%(13/40)。淋巴管入侵与膀胱癌的临床分期、分级、淋巴结转移以及无淋巴结转移膀胱癌复发均显著相关(P0.05)。淋巴管入侵阴性的患者的五年总体生存率显著高于淋巴管入侵阳性者,淋巴管入侵是无淋巴结转移膀胱癌复发和预后不良的危险因素。结论:肿瘤淋巴管入侵与膀胱癌临床分期和淋巴结转移密切相关,并影响膀胱癌患者的总体生存率,可作为无淋巴结转移膀胱癌复发和预后的预测因素。     

The renal cortical lymphatic system in the rat, hamster, and rabbit

Rat, hamster, and rabbit renal cortical lymphatics were examined by light and electron microscopy. Rat and hamster kidneys possessed both intra- and interlobular lymphatics that were structurally similar at the light microscopic level. Ultrastructural examination of the hamster lymphatic endothelium, however, revealed an unusual arrangement of cytoplasmic extensions not seen in the other two species. The intralobular lymphatics were related primarily to tubules, afferent arterioles, and renal corpuscles and were consistent with lymph formation from both plasma filtrate and tubular reabsorbate. Interlobular lymphatics were seen in connective tissue associated with the interlobular blood vessels. Rabbit cortex contained only interlobular lymphatics. Cross-sectional area, maximum diameter, volume density, and profile density were determined by stereological measurements using a computer-based image analyzer. The morphological data from the rat were used, in combination with published values for lymph flow, to calculate the rate of lymph formation per unit area of endothelium in lymphatics of the renal cortex. Among kidneys fixed by retrograde perfusion, the cortical lymphatic system was most extensive in maximum diameter, volume density, and profile density. It was smallest in the rabbit and intermediate in the rat. Lower volume and profile density were found for rat kidneys fixed by the dripping technique. It was concluded that: tubular reabsorbate probably contributes to renal lymph in the rat and hamster, but not in the rabbit; significant differences exist in the extent of the renal lymphatic systems among the three species, with the hamster kidney having the richest network and the rabbit the poorest; the method of fixation influences the measured size and density of renal cortical lymphatics; and the estimated rate of lymph formation in the kidney of the rat is roughly comparable to that in the dog.     

Observations upon rhinoceros cervical lymphatics

As an initial contribution to rhinoceros lymphangiology observations are presented upon the disposition of the lymphatic vessels and nodes associated with the larynx, thyroid gland and parathyroid glands of an adult male Indian rhinoceros (Rhinoceros unicornis). A detailed account is given of the topography and connexions of the anterior and intermediate groups of cervical lymph nodes and of the lymph drainage of certain cervical organs. The presence is reported, upon inter-nodal afferent pathways, of specialised and hitherto undescribed formations of a lympho-haemal nature and the functional significance of these is suggested.     

MMP2和MMP9在粘膜内胃癌中表达及其临床病理意义

目的:观察基质金属蛋白酶(MMP)家族成员MMP2和MMP9在粘膜内胃癌中的表达及其与淋巴结转移的相关性。方法:研究病例为病理诊断为粘膜内胃癌的档案病例,应用免疫组织化学技术检测MMP2和MMP9在粘膜内胃癌中表达的临床病理意义,特别是与淋巴结转移的相关性。结果:临床病理分析结果显示有淋巴结转移的IMGC病例肿块直径要显著大于无淋巴结转移的IMGC。有淋巴结转移IMGC中低分化腺癌发生率要显著高于无淋巴结转移组。有淋巴结转移IMGC中淋巴管侵犯发生率要显著高于无淋巴结转移组。免疫组化结果显示,MMP2在正常胃粘膜上皮和粘膜内胃癌中的阳性表达率分别是7%和43.93%,有显著性差异(P0.01),MMP9在正常胃粘膜上皮和粘膜内胃癌中的阳性表达率分别为和23%和48.48%,无显著性差异(P0.05)。MMP9在淋巴结转移组中的阳性率(87.5%)显著高于无淋巴结转移组(36%),在有淋巴管侵犯病例中的表达率(83.3%)显著高于无淋巴管侵犯的病例(30%),差异均有统计意义(P0.05);而MMP2的表达与有无淋巴结转移及淋巴管侵犯均无显著相关性(P0.05)。结论:MMP9可能作为预测粘膜内胃癌是否有淋巴结转移的标志物,但需要结合组织分化、肿块大小和淋巴管侵犯等临床病理特点综合判断。MMP2可能与粘膜内胃癌的发生有关而作为早期诊断的指标。     

Molecular and cellular basis of the regulation of lymphatic contractility and lymphatic absorption

Lymphatic absorption is a highly regulated process driven by both an extrinsic mechanism (external force) and an intrinsic mechanism (lymphatic vessel contractility). The lymphatic muscle is a specialized smooth muscle with unique mechanical properties. To understand the molecular mechanism and relative contribution of smooth muscle contraction in lymphatic absorption, we analyzed mice with a smooth muscle-specific deletion of Mylk, a critical gene for smooth muscle contraction. Interestingly, the knockout mice were significantly resistant to anesthesia reagents. Upon injection in the feet with FITC-dextran, the mutant mice displayed a 2-fold delay of the absorption peak in the peripheral circulation. Examining the ear lymphatic vessels of the mutant mice revealed a reduction in the amount of fluid in the lumens of the lymphangions, suggesting an impairment of lymph formation. The Mylk-deficient lymphatic muscle exhibited a significant reduction of peristalsis and of myosin light chain phosphorylation in response to depolarization. We thus concluded that MLCK and myosin light chain phosphorylation are required for lymphatic vessel contraction. Lymphatic contractility is not an exclusive requirement for lymphatic absorption, and external force appears to be necessary for absorption.     

Anatomy and topography of the common iliac lymph nodes in human beings in the 1st period of maturity

The investigation of common iliac lymph nodes has been performed in 20 corpses of the first mature age of both sex (5 male and 5 female corpses) of persons died from causes not connected with the lymphatic system diseases, the lower extremities and the pelvic organs. The common iliac lymph nodes with their afferent and efferent lymphatic vessels are revealed by means of interstitial injection into the lower extremities and the pelvic organs and with direct injection into the lymphatic vessels. The form, amount, size and topography of the common iliac lymphatic vessels have been studied. The lymphatic vessels, that go from certain body parts and organs to various subgroups of the common iliac lymph nodes, as well as the lymphatic vessels that connect the nodes both within the subgroup and also between the subgroups. The amount and size of the lymphatic nodes of the lateral subgroup predominate over the nodes of other subgroups of the common iliac lymph nodes; the amount of the common iliac lymph nodes predominates in men, and their size--in women. Amount of these nodes in the right and their size in the left predominate in both sex. Among the common iliac lymph nodes there are no teniform nodes, and efferent lymphatic vessels of the lateral and medial subgroup of the common iliac lymph nodes in 15% of cases run towards the lumbar nodes in the opposite side.     

Multiscale modeling of lymphatic drainage from tissues using homogenization theory

Lymphatic capillary drainage of interstitial fluid under both steady-state and inflammatory conditions is important for tissue fluid balance, cancer metastasis, and immunity. Lymphatic drainage function is critically coupled to the fluid mechanical properties of the interstitium, yet this coupling is poorly understood. Here we sought to effectively model the lymphatic-interstitial fluid coupling and ask why the lymphatic capillary network often appears with roughly a hexagonal architecture. We use homogenization method, which allows tissue-scale lymph flow to be integrated with the microstructural details of the lymphatic capillaries, thus gaining insight into the functionality of lymphatic anatomy. We first describe flow in lymphatic capillaries using the Navier-Stokes equations and flow through the interstitium using Darcy's law. We then use multiscale homogenization to derive macroscale equations describing lymphatic drainage, with the mouse tail skin as a basis. We find that the limiting resistance for fluid drainage is that from the interstitium into the capillaries rather than within the capillaries. We also find that between hexagonal, square, and parallel tube configurations of lymphatic capillary networks, the hexagonal structure is the most efficient architecture for coupled interstitial and capillary fluid transport; that is, it clears the most interstitial fluid for a given network density and baseline interstitial fluid pressure. Thus, using homogenization theory, one can assess how vessel microstructure influences the macroscale fluid drainage by the lymphatics and demonstrate why the hexagonal network of dermal lymphatic capillaries is optimal for interstitial tissue fluid clearance.     

Effects of arachidonic acid and its cyclo-oxygenase and lipoxygenase products on lymphatic vessel contracility in vitro

Lymphatic vessels exhibit rhythmical contractility $\text{in vivo}$ and $\text{in vitro}$ and this activity appears ti regulate lymph flow. A technique for measuring the cicurlar muscle contractions of isolated bovine mesenteric lymphatic vessel segments has been devised and utilized to study the pharmacological properties of these vessels. Non-contracting lympahtic vessels can be induced to contract rhythmically with a variety of mediators, the most potent being a stable PGH₂ analogue (compound U46619), and the leukotrienes B₄, C₄ and D₄ (threshold concentrations in the nanomolar range). Prostagladin F_2α, noradrenaline, serotonin and histamine also elicited rhythmical activity but much higher concentrations were required. PGE₂ and PGE₁ were potent inhibitors of spontaneous contractions or those induced with U46619. In keeping with the diverse pharmacological effects of the metabolites of arachidonic acid, the addition of arachidonate to an isolated lymphatic vessel generated both stimulatory and inhibitory activities.It is concluded that arachidonic acid products (produced in the lymphatic vessel or entering the vessel in lymph draining the tissues) regulate lymph flow through their effects on lymphatic smooth muscle.     

Receptor mechanisms of prenodal lymphatic constriction by dopamine

It has been proposed that alterations in lymphatic smooth muscle activity significantly impact lymphatic function. Numerous endogenous vasoactive agents are known to constrict prenodal lymph vessels. In this study, we assessed the ability of dopamine to alter lymphatic smooth muscle tone in perfused prenodal lymph vessels. Additionally, the receptor mechanisms of dopamine's actions were elucidated. Both intralymphatic (i.l.) and intra-arterial (i.a.) dopamine significantly increased lymphatic perfusion pressure. The increase in lymphatic pressure was completely blocked by i.a. phentolamine, suggesting involvement of alpha(1)- and/or alpha(2)-adrenoreceptors. Intra-arterial infusion of the specific alpha(1)-receptor antagonist prazosin completely abolished the constriction seen during i.l. phenylephrine but only attenuated that produced by dopamine. Intralymphatic infusion of the DA(1)-receptor agonist SKF 82526-J and the DA(2)-receptor agonist LY 171555 caused significant relaxation of lymph vessels that had been previously constricted by i.a. norepinephrine infusion. These data indicate that the constriction produced by dopamine, in the concentrations employed in this study, is mediated by both alpha(1)- and alpha(2)-adrenoreceptors. These lymph vessels do contain both DA(1)- and DA(2)-receptors but stimulation of these receptors results in lymphatic smooth muscle relaxation.     

Segmental territories along the cardinal veins generate lymph sacs via a ballooning mechanism during embryonic lymphangiogenesis in mice

During lymphangiogenesis in the mammalian embryo, a subset of vascular endothelial cells in the cardinal veins is reprogrammed to adopt a lymphatic endothelial fate. The prevailing model of lymphangiogenesis contends that these lymphatic precursor cells migrate away from the cardinal veins and reassemble peripherally as lymph sacs from which a lymphatic vasculature is generated. However, this model fails to account for a number of observations that, as a result, have remained anecdotal. Here, we use optical projection tomography, confocal microscopy and in vivo live imaging to uncover three key stages of lymphatic vascular morphogenesis in the mouse embryo at high resolution. First, we define territories or "pre-lymphatic clusters" of Prox1-positive lymphatic endothelial progenitor cells along the antero-posterior axis of the cardinal veins. Second, these pre-lymphatic clusters undergo progressive extrusion ("ballooning") to generate primitive lymph sacs. Third, lymphatic vessels emerge by a combination of mechanisms including sprouting from the lymph sacs and direct delamination of streams of cells from the cardinal veins. Our data support a new model for lymphatic vascular patterning and morphogenesis, as a basis for identifying the molecular cues governing these processes.     

Anatomical variants of the lymphatic vessels connecting the inguinal lymph nodes]

The study of anatomical variants of lymphatic vessels connecting inguinal lymph nodes was carried out on 56 corpses of adult persons of both sex whose deaths were not connected with lesions in the lymphatic system of the pelvis and lower extremities. The inguinal lymph nodes and their afferent and efferent lymphatic vessels were detected by the method of intradermal injection and by the method of direct injection into the lymphatic vessels. It was stated that groups of the inguinal lymph nodes, as well as the nodes in every group determined, can serve as nodes of different stages for afferent lymphatic vessels running from different parts of the body and organs.