Nicholas J. Albano

Obesity impairs lymphatic fluid transport and dendritic cell migration to lymph nodes.

Introduction Obesity is a major cause of morbidity and mortality resulting in pathologic changes in virtually every organ system. Although the cardiovascular system has been a focus of intense study, the effects of obesity on the lymphatic system remain essentially unknown. The purpose of this study was to identify the pathologic consequences of diet induced obesity (DIO) on the lymphatic system. Methods Adult male wild-type or RAG C57B6-6J mice were fed a high fat (60%) or normal chow diet for 8–10 weeks followed by analysis of lymphatic transport capacity. In addition, we assessed migration of dendritic cells (DCs) to local lymph nodes, lymph node architecture, and lymph node cellular make up. Results High fat diet resulted in obesity in both wild-type and RAG mice and significantly impaired lymphatic fluid transport and lymph node uptake; interestingly, obese wild-type but not obese RAG mice had significantly impaired migration of DCs to the peripheral lymph nodes. Obesity also resulted in significant changes in the macro and microscopic anatomy of lymph nodes as reflected by a marked decrease in size of inguinal lymph nodes (3.4-fold), decreased number of lymph node lymphatics (1.6-fold), loss of follicular pattern of B cells, and dysregulation of CCL21 expression gradients. Finally, obesity resulted in a significant decrease in the number of lymph node T cells and increased number of B cells and macrophages. Conclusions Obesity has significant negative effects on lymphatic transport, DC cell migration, and lymph node architecture. Loss of T and B cell inflammatory reactions does not protect from impaired lymphatic fluid transport but preserves DC migration capacity. Future studies are needed to determine how the interplay between diet, obesity, and the lymphatic system modulate systemic complications of obesity.

Lymph Node Transplantation Results in Spontaneous Lymphatic Reconnection and Restoration of Lymphatic Flow

Background: Although lymph node transplantation has been shown to improve lymphatic function, the mechanisms regulating lymphatic vessel reconnection and functional status of lymph nodes remains poorly understood. Methods: The authors developed and used LacZ lymphatic reporter mice to examine the lineage of lymphatic vessels infiltrating transferred lymph nodes. In addition, the authors analyzed lymphatic function, expression of vascular endothelial growth factor (VEGF)-C, maintenance of T- and B-cell zone, and anatomical localization of lymphatics and high endothelial venules. Results: Reporter mice were specific and highly sensitive in identifying lymphatic vessels. Lymph node transfer was associated with rapid return of lymphatic function and clearance of technetium-99 secondary to a massive infiltration of recipient mouse lymphatics and putative connections to donor lymphatics. T- and B-cell populations in the lymph node were maintained. These changes correlated with marked increases in the expression of VEGF-C in the perinodal fat and infiltrating lymphatics. Newly formed lymphatic channels in transferred lymph nodes were in close anatomical proximity to high endothelial venules. Conclusions: Transferred lymph nodes have rapid infiltration of functional host lymphatic vessels and maintain T- and B-cell populations. This process correlates with increased endogenous expression of VEGF-C in the perinodal fat and infiltrating lymphatics. Anatomical proximity of newly formed lymphatics and high endothelial venules supports the hypothesis that lymph node transfer can improve lymphedema by exchanges with the systemic circulation.

Obesity increases inflammation and impairs lymphatic function in a mouse model of lymphedema

Although obesity is a major clinical risk factor for lymphedema, the mechanisms that regulate this effect remain unknown. Recent reports have demonstrated that obesity is associated with acquired lymphatic dysfunction. The purpose of this study was to determine how obesity-induced lymphatic dysfunction modulates the pathological effects of lymphatic injury in a mouse model. We used a diet-induced model of obesity in adult male C57BL/6J mice in which experimental animals were fed a high-fat diet and control animals were fed a normal chow diet for 8-10 wk. We then surgically ablated the superficial and deep lymphatics of the midportion of the tail. Six weeks postoperatively, we analyzed changes in lymphatic function, adipose deposition, inflammation, and fibrosis. We also compared responses to acute inflammatory stimuli in obese and lean mice. Compared with lean control mice, obese mice had baseline decreased lymphatic function. Lymphedema in obese mice further impaired lymphatic function and resulted in increased subcutaneous adipose deposition, increased CD45(+) and CD4(+) cell inflammation (P < 0.01), and increased fibrosis, but caused no change in the number of lymphatic vessels. Interestingly, obese mice had a significantly increased acute inflammatory reaction to croton oil application. In conclusion, obese mice have impaired lymphatic function at baseline that is amplified by lymphatic injury. This effect is associated with increased chronic inflammation, fibrosis, and adipose deposition. These findings suggest that obese patients are at higher risk for lymphedema due to impaired baseline lymphatic clearance and an increased propensity for inflammation in response to injury.

Regulation of Inflammation and Fibrosis by Macrophages in Lymphedema

Lymphedema, a common complication of cancer treatment, is characterized by inflammation, fibrosis, and adipose deposition. We have previously shown that macrophage infiltration is increased in mouse models of lymphedema. Because macrophages are regulators of lymphangiogenesis and fibrosis, this study aimed to determine the role of these cells in lymphedema using depletion experiments. Matched biopsy specimens of normal and lymphedema tissues were obtained from patients with unilateral upper extremity breast cancer-related lymphedema, and macrophage accumulation was assessed using immunohistochemistry. In addition, we used a mouse tail model of lymphedema to quantify macrophage accumulation and analyze outcomes of conditional macrophage depletion. Histological analysis of clinical lymphedema biopsies revealed significantly increased macrophage infiltration. Similarly, in the mouse tail model, lymphatic injury increased the number of macrophages and favored M2 differentiation. Chronic macrophage depletion using lethally irradiated wild-type mice reconstituted with CD11b-diphtheria toxin receptor mouse bone marrow did not decrease swelling, adipose deposition, or overall inflammation. Macrophage depletion after lymphedema had become established significantly increased fibrosis and accumulation of CD4(+) cells and promoted Th2 differentiation while decreasing lymphatic transport capacity and VEGF-C expression. Our findings suggest that macrophages home to lymphedematous tissues and differentiate into the M2 phenotype. In addition, our findings suggest that macrophages have an antifibrotic role in lymphedema and either directly or indirectly regulate CD4(+) cell accumulation and Th2 differentiation. Finally, our findings suggest that lymphedema-associated macrophages are a major source of VEGF-C and that impaired macrophage responses after lymphatic injury result in decreased lymphatic function.

Roll, Spin, Wash, or Filter? Processing of Lipoaspirate for Autologous Fat Grafting: An Updated, Evidence-Based Review of the Literature.

Background: The use of autologous adipose tissue harvested through liposuction techniques for soft-tissue augmentation has become commonplace among cosmetic and reconstructive surgeons alike. Despite its longstanding use in the plastic surgery community, substantial controversy remains regarding the optimal method of processing harvested lipoaspirate before grafting. This evidence-based review builds on prior examinations of the literature to evaluate both established and novel methods for lipoaspirate processing. Methods: A comprehensive, systematic review of the literature was conducted using Ovid MEDLINE in January of 2015 to identify all relevant publications subsequent to the most recent review on this topic. Randomized controlled trials, clinical trials, and comparative studies comparing at least two of the following techniques were included: decanting, cotton gauze (Telfa) rolling, centrifugation, washing, filtration, and stromal vascular fraction isolation. Results: Nine articles comparing various methods of processing human fat for autologous grafting were selected based on inclusion and exclusion criteria. Five compared established processing techniques (i.e., decanting, cotton gauze rolling, centrifugation, and washing) and four publications evaluated newer proprietary technologies, including washing, filtration, and/or methods to isolate stromal vascular fraction. Conclusions: The authors failed to find compelling evidence to advocate a single technique as the superior method for processing lipoaspirate in preparation for autologous fat grafting. A paucity of high-quality data continues to limit the clinician’s ability to determine the optimal method for purifying harvested adipose tissue. Novel automated technologies hold promise, particularly for large-volume fat grafting; however, extensive additional research is required to understand their true utility and efficiency in clinical settings.

IL-6 regulates adipose deposition and homeostasis in lymphedema

Lymphedema (LE) is a morbid disease characterized by chronic limb swelling and adipose deposition. Although it is clear that lymphatic injury is necessary for this pathology, the mechanisms that underlie lymphedema remain unknown. IL-6 is a known regulator of adipose homeostasis in obesity and has been shown to be increased in primary and secondary models of lymphedema. Therefore, the purpose of this study was to determine the role of IL-6 in adipose deposition in lymphedema. The expression of IL-6 was analyzed in clinical tissue specimens and serum from patients with or without LE, as well as in two mouse models of lymphatic injury. In addition, we analyzed IL-6 expression/adipose deposition in mice deficient in CD4(+) cells (CD4KO) or IL-6 expression (IL-6KO) or mice treated with a small molecule inhibitor of IL-6 or CD4 depleting antibodies to determine how IL-6 expression is regulated and the effect of changes in IL-6 expression on adipose deposition after lymphatic injury. Patients with LE and mice treated with lymphatic excision of the tail had significantly elevated tissue and serum expression of IL-6 and its downstream mediator. The expression of IL-6 was associated with adipose deposition and CD4(+) inflammation and was markedly decreased in CD4KO mice. Loss of IL-6 function resulted in significantly increased adipose deposition after tail lymphatic injury. Our findings suggest that IL-6 is increased as a result of adipose deposition and CD4(+) cell inflammation in lymphedema. In addition, our study suggests that IL-6 expression in lymphedema acts to limit adipose accumulation.

Lymphaticovenous Bypass Decreases Pathologic Skin Changes in Upper Extremity Breast Cancer-Related Lymphedema

INTRODUCTION Recent advances in microsurgery such as lymphaticovenous bypass (LVB) have been shown to decrease limb volumes and improve subjective symptoms in patients with lymphedema. However, to date, it remains unknown if these procedures can reverse the pathological tissue changes associated with lymphedema. Therefore, the purpose of this study was to analyze skin tissue changes in patients before and after LVB. METHODS AND RESULTS Matched skin biopsy samples were collected from normal and lymphedematous limbs of 6 patients with unilateral breast cancer-related upper extremity lymphedema before and 6 months after LVB. Biopsy specimens were fixed and analyzed for inflammation, fibrosis, hyperkeratosis, and lymphangiogenesis. Six months following LVB, 83% of patients had symptomatic improvement in their lymphedema. Histological analysis at this time demonstrated a significant decrease in tissue CD4(+) cell inflammation in lymphedematous limb (but not normal limb) biopsies (p<0.01). These changes were associated with significantly decreased tissue fibrosis as demonstrated by decreased collagen type I deposition and TGF-β1 expression (all p<0.01). In addition, we found a significant decrease in epidermal thickness, decreased numbers of proliferating basal keratinocytes, and decreased number of LYVE-1(+) lymphatic vessels in lymphedematous limbs after LVB. CONCLUSIONS We have shown, for the first time, that microsurgical LVB not only improves symptomatology of lymphedema but also helps to improve pathologic changes in the skin. These findings suggest that the some of the pathologic changes of lymphedema are reversible and may be related to lymphatic fluid stasis.

Obesity but not high-fat diet impairs lymphatic function

Background/Objectives:High-fat diet (HFD)-induced obesity has significant negative effects on lymphatic function, but it remains unclear whether this is a direct effect of HFD or secondary to adipose tissue deposition.Methods:We compared the effects of HFD on obesity-prone and obesity-resistant mice and analyzed lymphatic function in vivo and in vitro.Results:Only obesity-prone mice had impaired lymphatic function, increased perilymphatic inflammation and accumulation of lipid droplets surrounding their lymphatic endothelial cells (LECs). LECs isolated from obesity-prone mice, in contrast to obesity-resistant animals, had decreased expression of VEGFR-3 and Prox1. Exposure of LECs to a long-chain free fatty acid increased cellular apoptosis and decreased VEGFR-3 expression, while inhibition of intracellular inhibitors of VEGFR-3 signaling pathways increased cellular viability.Conclusions:Collectively, our studies suggest that HFD-induced obesity decreases lymphatic function by increasing perilymphatic inflammation and altering LEC gene expression. Reversal of diminished VEGFR-3 signaling may rescue this phenotype and improve lymphatic function.

Lymphatic Function Regulates Contact Hypersensitivity Dermatitis in Obesity

Obesity is a major risk factor for inflammatory dermatologic diseases, including atopic dermatitis and psoriasis. In addition, recent studies have shown that obesity impairs lymphatic function. As the lymphatic system is a critical regulator of inflammatory reactions, we tested the hypothesis that obesity-induced lymphatic dysfunction is a key regulator of cutaneous hypersensitivity reactions in obese mice. We found that obese mice have impaired lymphatic function, characterized by leaky capillary lymphatics and decreased collecting vessel pumping capacity. In addition, obese mice displayed heightened dermatitis responses to inflammatory skin stimuli, resulting in both higher peak inflammation and a delayed clearance of inflammatory responses. Injection of recombinant vascular endothelial growth factor-C remarkably increased lymphangiogenesis, lymphatic function, and lymphatic endothelial cell expression of chemokine (C-C motif) ligand 21, while decreasing inflammation and expression of inducible nitrous oxide synthase. These changes resulted in considerably decreased dermatitis responses in both lean and obese mice. Taken together, our findings suggest that obesity-induced changes in the lymphatic system result in an amplified and a prolonged inflammatory response.

Sterile inflammation after lymph node transfer improves lymphatic function and regeneration.

Background: The aim of this study was to determine whether sterile inflammatory reactions can serve as a physiologic means of augmenting lymphangiogenesis in transplanted lymph nodes using a murine model. Methods: The authors used their previously reported model of lymph node transfer to study the effect of sterile inflammation on lymphatic regeneration. Mice were divided into three groups: group 1 (controls) underwent lymphadenectomy followed by immediate lymph node transplantation without inflammation; group 2 (inflammation before transfer) underwent transplantation with lymph nodes harvested from donor animals in which a sterile inflammatory reaction was induced in the ipsilateral donor limb; and group 3 (inflammation after transfer) underwent transplantation with lymph nodes and then inflammation was induced in the ipsilateral limb. Lymphatic function, lymphangiogenesis, and lymph node histology were examined 28 days after transplantation and compared with those of normal lymph nodes. Results: Animals that had sterile inflammation after transplantation (group 3) had significantly improved lymphatic function (>2-fold increase) on lympho scintigraphy, increased perinodal lymphangiogenesis, and functional lymphatics compared with the groups with no inflammation and inflammation before transplantation (p < 0.01). Inflammation after transplantation was associated with a more normal lymph node architecture, expansion of B-cell zones, and decreased percentage of T cells compared with the other experimental groups. Conclusions: Sterile inflammation is a potent method of augmenting lymphatic function and lymphangiogenesis after lymph node transplantation and is associated with maintenance of lymph node architecture. Induction of inflammation after transplantation is the most effective method and promotes maintenance of normal lymph node B- and T-cell architecture.