Anatomy of the lymph vessels and nodes of the head and neck in green marmosets]

In 50 mature green monkeys, the lymphatic system of the skin on the hairy part of the skull (occipital, parietal, frontal) and on the face was studied. The lymphatic vessels of cranial and cervical organs flow into submental, submandibular (anterior, medial, posterior) lymph nodes and into profound cervical (cranial, medial, caudal) lymph nodes. Lymph nodes together with efferent lymphatic vessels form lymph collectors of the neck which follow the blood vessels branching: superficial jugular, profound jugular and paratracheal network.     

Contractile activity of pectoral channel and lymph nodes in rats under antiorthostatic influences

It has been established that during short term body antiorthostatic positions lymphatic system carries out compensatory function, unloading the cardiovascular system from redundant exercise. The contractile activity of pectoral channel and lymphatic nodes in weightlessness (antiorthostatic influence) was studied. The functional role of neck lymph nodes is expressed by depositing of liquid during redistribution of the blood. The atony of neck lymph nodes as well as loss of pectoral channel and lymph nodes decrease the receptor sensitivity of vessels and nodes to the action of vasoactive substances.     

Motheaten, an immunodeficient mutant of the mouse. I. Genetics and pathology.

A new recessive mutation, motheaten (me), is on chromosome 6, 21.9 +/- 4.3 recombination units distal to white (Miwh). Mice homozygous for the new mutation have neutrophilic lesions of the skin beginning as early as day 1, and pneumonitis with many macrophages in the alveoli as early as day 3. They suffer high mortality from birth onward and none has survived longer than 8 weeks. The lymph nodes may be enlarged, but the thymus, Reyer's patches, and lymphatic tissue of the spleen are much reduced in size. Lymph nodes, spleen, and Peyer's patches lack lymphatic nodules. The lymph nodes and spleen contain many plasma cells. There are increased numbers of neutrophils and monocytes in the peripheral blood, and increased numbers of neutrophils in bone marrow at the expense of red cell precursors. Hematopoietic tissue in the spleen is increased and appears more active than normal. Motheaten mice appear to have an immune deficiency beginning very shortly after birth.     

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.     

Dynamics of changes in cell composition in the lymphoid tissue of somatic lymph nodes during total overheating of the body

At total overheating a manifested macrophagal reaction is observed in the rat somatic lymph nodes. Concentration of autoantigens in tissues increases, that results in transformation of small lymphocytes towards lymphoblasts and plasma cells. When manifested disorders of hemo- and lymphocirculation are present, eosinophils and mast cells, being tissue regulators of microcirculation and wall permeability of blood capillaries and lymphatic sinuses++., increase in number.     

Adrenergic innervation of lymph nodes and the thoracic duct

By means of incubation of slices in 2% solution of glyoxylic acid distribution of adrenergic fibers in the rabbit lymph nodes and in the thoracic lymphatic duct has been studied. Adrenergic fibers get into parenchyma of the lymph nodes via two ways. The first--the perivascular, when the nervous fibers make a plexus and get into the node along the blood vessels, the second--diffuse nervous fibers get together with trabecules in between the lymphoid nodules. The distribution density of the adrenergic fibers is not the same in different groups of the lymph nodes. In the lumbar nodes it is the highest. In the lymph nodes of the cervical part the density of the sympathetic fibers is, as a rule, lower than in the lumbar, but higher than in the axillary nodes. The lowest density of th adrenergic fibers is in the mesenteric, superficial inguinal lymph nodes and in the lymph nodes, situating near the thoracic part of the aorta. In the lymphatic duct wall small amount of adrenergic fibers are revealed, they form a plexus, predominantly in the cranial part.     

The presence of pinworms (Enterobius sp.) in the mesenteric lymph nodes, liver and lungs of a chimpanzee, Pan troglodytes

This report describes a case of fatal enterobiasis caused by Enterobius sp. in the mesenteric lymph nodes, lymphatic vessels of mesentery, blood vessels of the liver and lungs of a chimpanzee from Qingdao Zoo, China. Based on pathological findings, it is likely that the pinworms obtained access to these organs via the lymphatic or haematogenous pathway. As far as we are aware, this is the first reported case of Enterobius sp. in the mesenteric lymph nodes and blood vessels of the lungs and veins of the hepatic triad in a chimpanzee.     

Epinephrine causes a reduction in lymph node cell output in sheep

The lymphatic system has a critical role in the return of fluids, proteins, and cells to the circulatory system. However, the effects of stress, including exercise, on this system have not been adequately studied. We investigated the effect of a physiological dose (1 mg) of epinephrine (Epi) on lymph flow, cell concentration, and lymphocyte subsets in efferent subcutaneous lymph in sheep. Blood leukocyte numbers, differential, lymphocyte subsets, and blood and lymph pools of lymphocytes were determined simultaneously. A significant acute increase in lymph flow was followed by a post-injection decrease in flow and cellular output. No changes in lymphocyte subsets or pools of lymphocytes were seen in either blood or lymph. The timing of elevated plasma and lymph concentrations of Epi and norepinephrine (NE) corresponded with the increased lymph flow. In conclusion, Epi injection caused no change in lymphocyte subset distribution, leukocyte concentration, or pools of lymphocytes. A decrease in lymph flow and cellularity was documented post-injection, indicating that lymphatic tissue has no role in the leukocytosis seen after Epi injection. Lymphocyte retention by lymph nodes, however, may contribute to post-injection lymphopenia.     

Transdiaphragmatic lymphatic transport of intraperitoneally administered marker in hamsters.

OBJECTIVE: To determine whether transdiaphragmatic transport in hamsters is similar to that described in other animals by examining transport of an intraperitoneally administered marker. METHODS: Monastral blue B suspension was administered intraperitoneally to 28 male Syrian hamsters (Mesocricetus auratus). Four hamsters each were euthanized 7, 15, and 30 min, and 1, 2, 3, and 24 h later. Specimens were examined microscopically for presence of marker. RESULTS: Marker was present in intrathoracic lymphatic vessels and cranial and caudal mediastinal lymph nodes by 7 min after its administration. The amount of marker in lymph nodes increased with time. The subcapsular distribution of marker was consistent with lymphatic transport. By 1 h after its administration, marker was present in the liver, spleen, bone marrow, and mesenteric and mandibular lymph nodes. Patterns of marker distribution in these tissues were consistent with hematogenous transport, but the amount of marker was considerably less than that in the intrathoracic lymph nodes at corresponding times. CONCLUSIONS: Particulates were most likely translocated from the hamster peritoneal cavity to intrathoracic lymph nodes via transdiaphragmatic lymphatic vessels. A portion of the translocated particulates entered the blood, where they were distributed to a variety of tissues within a short time.     

Ontogeny of human fetal lymph nodes.

Developing lymph nodes from 30 human embryos and fetuses with crown-rump lengths (CRL) of 18 mm (5.6 wk) to 245 mm (26 wk) were examined by light microscopy. The nodes were embedded in araldite, and the sections examined were approximately 1 mu in thickness. The development of nodes was divided into three stages: 1. the lymphatic plexus and connective tissue invagination (30 mm to 67 mm CRL); 2. the early fetal lymph node (43 mm to ,5 mm CRL); and 3. the late fetal lymph node (CRL greater than 75 mm). The lymphatic plexus was formed by connective tissue invaginations and bridges which divided a lymph sac into a meshwork of channels and spaces. Connective tissue invaginations were endothelially-lined and were surrounded by lymphatic space. Reticular cells, macrophages, and blood vessels were found in these invaginations. Early fetal lymph nodes were formed from invaginations when the cellular density and lymphocyte content increased. The lymphatic space surrounding the early node was the developing subcapsular sinus. With further development the early node became packed with lymphocytes, increasing the cellular density and size of the node. The connective tissue surrounding the subcapsular sinus condensed to form the capsule. Afferent lymphatic vessels pierced the capsule. Capillaries, veins, postcapillary venules, and occasional arteries were found in early and late nodes.     

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.     

AN ELECTRON MICROSCOPE STUDY OF LYMPHATIC TISSUE IN RUNT DISEASE

The thymus, spleen, and lymph nodes were studied in runt disease induced by a graft of intravenously injected homologous splenic cells into newborn rats and mice. Adult Long-Evans cells (70 x 10⁶) were injected into Sprague-Dawley rats. Adult DBA cells (7 x 10⁶) were injected into C57BL/6 mice. Runted rats were sacrificed at 14 to 28 days of age; mice at 10 to 20 days. The thymic cortex is depleted of small lymphocytes. Those remaining are severely damaged and phagocytized. Evidence of damage includes swelling of mitochondria, myelin figure formation, margination of chromatin, and sharp angulation in nuclear contour. Large numbers of macrophages are present. Epithelial-reticular cells which envelop small cortical blood vessels are often retracted, with the result that the most peripheral layer in the thymic-blood barrier suffers abnormally large gaps. Lymphocytes of the periarterial lymphatic sheaths of spleen and of the cortex of lymph nodes are reduced in number and damaged. Vast numbers of plasma cells and many lymphocytes are evident throughout lymph nodes, in the periarterial lymphatic sheaths, and in the marginal zone and red pulp of the spleen. Plasma cells are of different sizes, the larger having dilated sacs of endoplasmic reticulum. Lymphocytes are small to medium in size. They contain, in varying quantity, ribosomes and smooth membrane-bounded cytoplasmic vesicles approximately 350 to 500 A in diameter. Most plasma cells and lymphocytes are damaged and many of these are phagocytized. Many lymphocytes in lymph nodes, however, show no evidence of damage. Reticular cells and other fixed cells of the connective tissues seldom appear affected. Thus, the major cell types reacting in runt disease are lymphocytes, plasma cells, and histiocytes or macrophages. It appears, therefore, that both the delayed and immediate types of sensitivity play a part in this disease.     

Topographo-anatomic basis for the reconstruction of lymphatic passages and the reinnervation of transplanted kidneys

Topographic anatomy of the deferent lymphatic vessels and the regional lymph nodes of the kidneys have been studied in 35 dogs. Basing on the topographoanatomical investigations performed the authors suggest a rational technique for restoring the lymph outflow combined with the reinnervation of the renal transplant. They suggest to take the right kidney together with the dorsocaval lymph nodes, and the left--with the left lateroaortal lymph nodes simultaneously cutting out the fascial-fatty graft with the nerves situating over the ventral surface of the renal hilar vessels. The lymph outflow is suggested to be restorted by means of anastomosis between the regional lymph nodes of the renal transplant and the iliac node, or the nearest vein, and to innervate the transplant--by means of stitching the fascial-fatty grafts of the anostomized blood vessels.     

The lymphatic vasculature in disease

Blood vessels form a closed circulatory system, whereas lymphatic vessels form a one-way conduit for tissue fluid and leukocytes. In most vertebrates, the main function of lymphatic vessels is to collect excess protein-rich fluid that has extravasated from blood vessels and transport it back into the blood circulation. Lymphatic vessels have an important immune surveillance function, as they import various antigens and activated antigen-presenting cells into the lymph nodes and export immune effector cells and humoral response factors into the blood circulation. Defects in lymphatic function can lead to lymph accumulation in tissues, dampened immune responses, connective tissue and fat accumulation, and tissue swelling known as lymphedema. This review highlights the most recent developments in lymphatic biology and how the lymphatic system contributes to the pathogenesis of various diseases involving immune and inflammatory responses and its role in disseminating tumor cells.     

A novel monoclonal antibody specific for lymphatic endothelium

The difficulty of identifying and differentiating lymphatic and blood microvessels in tissue sections can be overcome by a monoclonal antibody specific for lymphatic endothelium. Unfortunately, the only known antibody also reacts with the endothelium of some blood vessels. The technique of double immunization (passive, with an antiserum to blood endothelium, and active, with a suspension of lymphatic endothelial cells) was, therefore, used to increase the chances of recognizing specific lymphatic antigens by the mouse immune system. The monoclonal antibody obtained, LyMAb, a G₁ immunoglobulin, reacted strongly with the endothelium of bovine thoracic duct, mesenteric collecting vessels and lymphatic vessels of gall-bladder and lymph nodes and moderately with those of the intestinal wall. Blood vessels (intercostal arteries, azygos vein and blood microvessels of all organs tested) were consistently negative. The antibody was species-specific and did not react with formalin-fixed, paraffin-embedded sections. Cross-reactivity was limited to some connective tissue fibres and scattered cells in the lymph node parenchyma, intestinal villi and hepatic lobules.     

Topography of lymphatic collectors and regional lymph nodes of the canine heart and their morphological characteristics

In 40 dogs lymphatic vessels and regional lymph nodes of the heart have been prepared. Morphology of the regional lymph nodes have been studied by means of various histological techniques. Lymph outflow from the canine ventricles is realized by three (less often), or by two (more often) collectors. In very rare cases one collector is formed. From the right atrium lymph flows out in two collectors (cranial and left). Lymphatic vessels of the left atrium get into the left collector of the ventricles, or into the tracheobronchial lymph nodes. Into the same nodes gets the lymphatic vessel, forming at the border of the left and right atrii. Cranial, medial, caudal mediastinal nodes (lymphatic mediastinal system) and right, middle and left tracheobronchial lymph nodes (tracheobronchial system) are regional lymph nodes of the canine heart. In the lymph nodes of the tracheobronchial system of puppies older than one month presence of exogenic pigment and signs of fibrous degeneration of parenchyma are noted.     

Dynamic imaging of lymphatic vessels and lymph nodes using a bimodal nanoparticulate contrast agent

BACKGROUND: Evaluation of lymphedema and lymph node metastasis in humans has relied primarily on invasive or radioactive modalities. While noninvasive technologies such as magnetic resonance imaging (MRI) offer the potential for true three-dimensional imaging of lymphatic structures, invasive modalities, such as optical fluorescence microscopy, provide higher resolution and clearer delineation of both lymph nodes and lymphatic vessels. Thus, contrast agents that image lymphatic vessels and lymph nodes by both fluorescence and MRI may further enhance our understanding of the structure and function of the lymphatic system. Recent applications of bimodal (fluorescence and MR) contrast agents in mice have not achieved clear visualization of lymphatic vessels and nodes. Here the authors describe the development of a nanoparticulate contrast agent that is taken up by lymphatic vessels to draining lymph nodes and detected by both modalities. METHODS: A unique nanoparticulate contrast agent composed of a polyamidoamine dendrimer core conjugated to paramagnetic contrast agents and fluorescent probes was synthesized. Anesthetized mice were injected with the nanoparticulates in the hind footpads and imaged by MR and fluorescence microscopy. High resolution MR and fluorescence images were obtained and compared to traditional techniques for lymphatic visualization using Evans blue dye. RESULTS: Lymph nodes and lymphatic vessels were clearly observed by both MRI and fluorescence microscopy using the bimodal nanoparticulate contrast agent. Characteristic tail-lymphatics were also visualized by both modalities. Contrast imaging yielded a higher resolution than the traditional method employing Evans blue dye. MR data correlated with fluorescence and Evans blue dye imaging. CONCLUSION: A bimodal nanoparticulate contrast agent facilitates the visualization of lymphatic vessels and lymph nodes by both fluorescence microscopy and MRI with strong correlation between the two modalities. This agent may translate to applications such as the assessment of malignancy and lymphedema in humans and the evaluation of lymphatic vessel function and morphology in animal models.     

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.     

Anatomy and topography of external iliac lymph nodes in adults]

The investigation of the external iliac lymph nodes has been performed in 152 preparations of corpses of mature persons of both sex, who died from causes not connected with any disease of the lymphatic system, lower extremities and pelvic organs. The external iliac lymph nodes and their afferent and efferent lymphatic vessels have been revealed by means of interstitial injection of the lower extremities and pelvic organs, as well as by means of direct injection of Gerota mass into the lymphatic vessels. Form, amount, dimensions and topography of common iliac lymph nodes have been studied. Lymphatic vessels, running from certain parts and organs of the body to various subgroups of the external iliac lymph nodes have been described, as well as efferent lymph vessels of these nodes. The external iliac lymph nodes are constant formations; the largest of them--lymph nodes of the lacuna--are nodes of the I step for the lower extremity lymph vessels. In 54% of cases in persons of both sex positive (right-sided) asymmetry has been revealed. Total amount of the iliac lymph nodes prevails in men, while their size is greater in women. The size of these nodes in persons of both sex is greater to the left than to the right. There are connections (in 3% of cases) between the external iliac lymph nodes and aortal and lumbar nodes of the opposite side.     

Individual and sexual characteristics of the common iliac lymph nodes in elderly persons

The common iliac lymph nodes (CILN) have been investigated on 24 preparations from corpses of elderly persons (5 male and 7 female corpses), died from the causes not connected with the lymphatic system diseases, lower extremities and pelvic organs. The CILN with their afferent and deferent lymphatic vessels are revealed by means of interstitial injection into the lower extremities and pelvic organs, as well as by means of direct injection into lymphatic vessels. The form, amount, size and topography of CILN are studied. Lymphatic vessels, running from certain parts of the body and organs to various subgroups of CILN are described, as well as lymphatic vessels, connecting the nodes both within each subgroup and between the subgroups. There is a tendency in prevalence of amount and size of the lateral subgroup of the lymph nodes over the nodes of other subgroups of CILN; tendency in prevalence of amount of the lymph nodes in men, and their size--in women; prevalence of amount of right CILN and their size in the left--in persons of both sex; in 70% of the cases the amount of afferent lymphatic vessels to CILN prevails over that of the deferent lymph nodes.