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This review highlights characteristics of extracellular fluid (ECF) that are often overlooked. ECF has, in addition to plasma and interstitial fluid (ISF) surrounding cells, a third large compartment, the ISF of skin and connective tissue. This acts as a reservoir that gives up ECF to plasma volume (PV) in order to sustain circulation in the event of either shock or dehydration. While Starling forces drive filtration, ECF is returned to PV more by lymph and less by Starling forces than previously appreciated. Lymph return to PV is dependent on physical activity and muscle contraction to overcome gravity. Regional change in metabolic rate alters the need for oxygen and nutrients that is met by a regional increase in capillary blood flow. Blood flow is controlled by vasoactive compounds released in response to a drop in PO(2); these relax capillary smooth muscle to increase blood flow and delivery of oxygen and nutrients. Plasma proteins, including albumin, are filtered into the interstitium through larger pores than those filtering ECF. The rate of protein filtration is set by size and charge of these larger endothelial pores and by size and charge of proteins. Charge of these pores, hence albumin permeability, is regulated by many of the same vasoactive compounds that control capillary flow. As a consequence, in response to gravitational stress and other forms of shock that reduce effective circulation, albumin as well as ECF is rapidly shifted from plasma and sequestered in ISF. When this has occurred, as in burn shock, restoration is better effected by generous expansion of ECF with Ringer's solution alone, rather than with Ringer's solution supplemented with human serum albumin or other colloid. Restoring both PV and ISF volume restores lymph circulation and returns sequestered albumin to PV.

Single parenteral administration of ketorolac tromethamine produced a lymphotropic effect, which was manifested in acceleration of lymph flow in the thoracic duct and increase in contractile activity of the wall and valves in mesenteric lymphatic microvessels of rats with fever. These changes improved lymph circulation.

Single injection of mexidol (drug with antioxidant and membranotropic effects) to animals with reactive fever produces a multicomponent effect on the lymph circulation. The drug increased the number of functioning lymph capillaries and contractile activity of wall and valvular leaflets in rat small intestinal mesenteric lymphangion, accelerated lymph drainage, thus stimulating lymph formation and lymph flow.

Lymphoedema is managed most successfully when advice and treatment are provided at an early stage of its development. This book provides all the necessary knowledge and the skills required to identify risk factors for the development of the disease and to equip the health care professional in providing the best advice to the patient.

We measured lymph flow rate in the thoracic lymphatic duct of dogs with anaphylactic shock receiving mono- or combination therapy with norepinephrine and hydrocortisone. Intensification of lymph circulation improved resorption and transport of metabolic products from the interstitial space through lymphatic vessels and stimulated exchange processes in the blood and tissues during allergic alterations.

Metastatic tumor cells are thought to reach distant organs by traveling through the blood circulation or the lymphatic system. Two studies of mouse models now suggest a hybrid route for tumor cell dissemination. Pereira et al. and Brown et al. used distinct methodologies to monitor the fate of tumor cells in lymph nodes. They found that tumor cells could invade local blood vessels within a node, exit the node by entering the blood circulation, then go on to colonize the lung. Whether this dissemination route occurs in cancer patients is unknown; the answer could potentially change the way that affected lymph nodes are treated in cancer. Science , this issue p. 1403 , p. 1408 In mice, tumor cells can metastasize via lymph node blood vessels. During metastasis, malignant cells escape the primary tumor, intravasate lymphatic vessels, and reach draining sentinel lymph nodes before they colonize distant organs via the blood circulation. Although lymph node metastasis in cancer patients correlates with poor prognosis, evidence is lacking as to whether and how tumor cells enter the bloodstream via lymph nodes. To investigate this question, we delivered carcinoma cells into the lymph nodes of mice by microinfusing the cells into afferent lymphatic vessels. We found that tumor cells rapidly infiltrated the lymph node parenchyma, invaded blood vessels, and seeded lung metastases without involvement of the thoracic duct. These results suggest that the lymph node blood vessels can serve as an exit route for systemic dissemination of cancer cells in experimental mouse models. Whether this form of tumor cell spreading occurs in cancer patients remains to be determined.

Metastatic tumor cells are thought to reach distant organs by traveling through the blood circulation or the lymphatic system. Two studies of mouse models now suggest a hybrid route for tumor cell dissemination. Pereira et al. and Brown et al. used distinct methodologies to monitor the fate of tumor cells in lymph nodes. They found that tumor cells could invade local blood vessels within a node, exit the node by entering the blood circulation, then go on to colonize the lung. Whether this dissemination route occurs in cancer patients is unknown; the answer could potentially change the way that affected lymph nodes are treated in cancer. Science , this issue p. 1403 , p. 1408 In mice, tumor cells can metastasize to distant organs by entering blood vessels within the local lymph node. Lymph node metastases in cancer patients are associated with tumor aggressiveness, poorer prognoses, and the recommendation for systemic therapy. Whether cancer cells in lymph nodes can seed distant metastases has been a subject of considerable debate. We studied mice implanted with cancer cells (mammary carcinoma, squamous cell carcinoma, or melanoma) expressing the photoconvertible protein Dendra2. This technology allowed us to selectively photoconvert metastatic cells in the lymph node and trace their fate. We found that a fraction of these cells invaded lymph node blood vessels, entered the blood circulation, and colonized the lung. Thus, in mouse models, lymph node metastases can be a source of cancer cells for distant metastases. Whether this mode of dissemination occurs in cancer patients remains to be determined.

The clinical importance of metastatic spread of cancer has been recognized for centuries, and melanoma has loomed large in historical descriptions of metastases, as well as the numerous mechanistic theories espoused. The “fatal black tumor” described by Hippocrates in 5000 BC that was later termed “melanose” by Rene Laennec in 1804 was recognized to have the propensity to metastasize by William Norris in 1820. And while the prognosis of melanoma was uniformly acknowledged to be dire, Samuel Cooper described surgical removal as having the potential to improve prognosis. Subsequent to this, in 1898 Herbert Snow was the first to recognize the potential clinical benefit of removing clinically normal lymph nodes at the time of initial cancer surgery. In describing “anticipatory gland excision,” he noted that “it is essential to remove, whenever possible, those lymph glands which first receive the infective protoplasm, and bar its entrance into the blood, before they have undergone increase in bulk”. This revolutionary concept marked the beginning of a debate that rages today: are regional lymph nodes the first stop for metastases (“incubator” hypothesis) or does their involvement serve as an indicator of aggressive disease with inherent metastatic potential (“marker” hypothesis). Is there a better way to improve prediction of disease outcome? This article attempts to address some of the resultant questions that were the subject of the session “Novel Frontiers in the Diagnosis of Cancer” at the 8th International Congress on Cancer Metastases, held in San Francisco, CA in October 2019. Some of these questions addressed include the significance of sentinel node metastasis in melanoma, and the optimal method for their pathologic analysis. The finding of circulating tumor cells in the blood may potentially supplant surgical techniques for detection of metastatic disease, and we are beginning to perfect techniques for their detection, understand how to apply the findings clinically, and develop clinical followup treatment algorithms based on these results. Finally, we will discuss the revolutionary field of machine learning and its applications in cancer diagnosis. Computer-based learning algorithms have the potential to improve efficiency and diagnostic accuracy of pathology, and can be used to develop novel predictors of prognosis, but significant challenges remain. This review will thus encompass latest concepts in the detection of cancer metastasis via the lymphatic system, the circulatory system, and the role of computers in enhancing our knowledge in this field.

Little is known regarding lymph node (LN)-homing of immune cells via afferent lymphatics. Here, we show, using a photo-convertible Dendra-2 reporter, that recently activated CD4 T cells enter downstream LNs via afferent lymphatics at high frequencies. Intra-lymphatic immune cell transfer and live imaging data further show that activated T cells come to an instantaneous arrest mediated passively by the mechanical 3D-sieve barrier of the LN subcapsular sinus (SCS). Arrested T cells subsequently migrate randomly on the sinus floor independent of both chemokines and integrins. However, chemokine receptors are imperative for guiding cells out of the SCS, and for their subsequent directional translocation towards the T cell zone. By contrast, integrins are dispensable for LN homing, yet still contribute by increasing the dwell time within the SCS and by potentially enhancing T cell sensing of chemokine gradients. Together, these findings provide fundamental insights into mechanisms that control homing of lymph-derived immune cells. Immune cells mostly enter lymph nodes (LN) from blood circulation, but whether afferent lymphatics contributes to LN entry is unclear. Here, the authors show, using a photo-convertible reporter, that T cells in afferent lymphatics frequently enter LN and become arrested in the subcapsular sinus, with chemokines and integrins further guiding their migration in the LN.