Outcome Analysis of Metacarpal and Phalangeal Fixation Techniques at Bellevue Hospital.

PURPOSE: Phalangeal fractures represent a significant portion of upper extremity injuries but are not well studied as a single entity. We define our approach at a level 1 trauma center and determine whether plating or lag screws (ie, rigid fixation) have superior functional outcomes compared with Kirschner wire fixation for phalangeal or metacarpal fractures. METHODS: We performed a systematic review of all surgically managed hand fracture cases at Bellevue Hospital during 2012 and 2013. Demographics, type of fixation, length of operation, period of immobilization, range of motion, time to return to work, and complications including reoperation were noted. Comparisons were assessed for significance using Student t tests and Fisher exact test (P < 0.05 considered significant). RESULTS: One hundred ninety-two fractures (158 patients) were treated and followed for an average of 113 days. Rigid fixation was used for 17 (19%) of 90 metacarpal fractures and 5 (5%) of 102 phalangeal fractures. Operative times were significantly shorter (59 vs 135 minutes, 84 vs 149 minutes), and period of immobilization was longer (37 vs 15 days, 34 vs 18 days) when Kirschner wires were used for metacarpal and phalangeal fractures, respectively (P > 0.05). Total active motion and return to work were similar regardless of type of intervention in both fracture types. No patients treated with rigid fixation required reoperation. CONCLUSIONS: To our best knowledge, this is the first review to study phalangeal fractures concurrently but also separately from metacarpal fractures. Despite shorter periods of immobilization, rigid fixation does not appear to lead to improved total active motion or time to return to work.

Optimizing Safety of Iliac Bone Harvest Using an Acumed Drill: A Simulated Radiographic Study of 100 Patients.

OBJECTIVE: To determine the potential risk of visceral injury during Acumed drill iliac crest cancellous bone graft harvest. DESIGN: Radiographic iliac crest anatomic analysis with simulated drill course to measure cancellous bone available for harvest and proximity of vulnerable pelvic structures. SETTING: Single institution, tertiary care university hospital. PATIENTS AND PARTICIPANTS: One hundred pelvic computed tomography scans performed on children 8 to 12 years old without traumatic or neoplastic pathology. INTERVENTIONS: Radiographic simulation of Acumed drill course within iliac bone. MAIN OUTCOME MEASURES: (1) Potential for pelvic visceral injury. (2) Volume of cancellous bone safely available for harvest. RESULTS: Superior and medial cortical thickness at the reference point remained stable across age groups; however, lateral cortical thickness increased with age (3.13 to 3.74 mm, P < .001). Cancellous bone width increased with age at all depths measured (P < .001). Through radiographic simulation, the drill could reach the bowel in 4% of cases and only through gross deviation (>30°) from the plane of the ilium. There were no cases of simulated bowel perforation within 3 cm of the reference point. The maximum cancellous volume safely harvested increased with age: 24 cc in 8-year-olds to 36 cc in 12-year-olds (P < .001). CONCLUSIONS: Acumed assisted iliac crest bone graft harvest is a safe technique in which substantial amount of cancellous bone can be obtained. The low risk of bowel perforation can be further minimized by limiting the depth of drill bit penetration to less than 3 cm.

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.

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.

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.

Tissue engineering and regeneration of lymphatic structures.

Tissue engineering is the process by which biological structures are recreated using a combination of molecular signals, cellular components and scaffolds. Although the perceived potential of this approach to reconstruct damaged or missing tissues is seemingly limitless, application of these ideas in vivo has been more difficult than expected. However, despite these obstacles, important advancements have been reported for a number of organ systems, including recent reports on the lymphatic system. These advancements are important since the lymphatic system plays a central role in immune responses, regulation of inflammation, lipid absorption and interstitial fluid homeostasis. Insights obtained over the past two decades have advanced our understanding of the molecular and cellular mechanisms that govern lymphatic development and function. Utilizing this knowledge has led to important advancements in lymphatic tissue engineering, which is the topic of this review.

Interrupting Negative-pressure Wound Therapy with Dakin's Solution Is Associated with Increased Skin Graft Survival.

Negative-pressure wound therapy (NPWT) has improved split-thickness skin graft (STSG) survival rates, but prolonged application increases bacterial bioburden. Antimicrobial NPWT adjuncts have demonstrated efficacy, but strong evidence is lacking. We hypothesized that simultaneously replacing NPWT dressings within 48-72 hours and cleansing with Dakin's solution-a well-known antimicrobial agent-would increase STSG take. Methods: We performed a controlled retrospective case series on three groups of STSG patients treated between January 2014 and December 2020: bolster dressings, continuous NPWT (C-NPWT), and Dakin's NPWT (D-NPWT). Patients with documented measurements of STSG survival were included. The primary outcome was the percentage of STSG take calculated by survival area using surgical tape measures 2 weeks after surgery. Results: Fifty-nine patients were followed up for greater than or equal to 3 months. Average wound size for bolsters was smaller than that for D-NPWT (83 cm2 versus 204 cm2; P < 0.05). Average treatment time was 6.4 ± 2.4 days (bolsters), 6.5 ± 0.9 days (C-NPWT), and 2.8 ± 0.9 days (D-NPWT; P < 0.01). Average percentage of STSG take was 92% ± 0% (bolsters), 82% ± 0% (C-NPWT), and 99% ± 0% (D-NPWT; P < 0.01); there were significant differences between bolsters versus C-NPWT (P < 0.05) and C-NPWT versus D-NPWT (P < 0.05), but not between bolsters and D-NPWT. Conclusions: Interrupting NPWT with 0.125% Dakin's solution cleansing is associated with increased STSG survival compared with standard NPWT protocols, but not bolster dressings. These findings warrant further investigation due to limitations of this retrospective case series.

Development of vaginal erosion and vesicocutaneous fistula following midurethral transvaginal tape with PelviLace for treatment of stress urinary incontinence.

Stress urinary incontinence (SUI) is a common diagnosis that greatly impacts quality of life for many women. Current therapies implement the use of suburethral slings, either synthetic or xenografts, to remedy this condition. In this study, we report on a patient with SUI, treated with PelviLace Biourethral Support, who suffered multiple issues postoperatively.

Small Numbers of CD4+ T Cells Can Induce Development of Lymphedema.

BACKGROUND: CD4 T cells have been implicated in the pathology of lymphedema. Interestingly, however, there have been case reports of lymphedema development in patients with low levels of CD4 T cells because of immunosuppression. In this study, the authors sought to delineate the effect of relative CD4 T-cell deficiency on the development of lymphedema in a mouse model. METHODS: A mouse model of relative CD4 T-cell deficiency was created through lethal total body irradiation of wild-type mice that then underwent bone marrow transplantation with progenitors harvested from CD4 knockout mice (wild-type/CD4 knockout). Irradiated CD4 knockout mice reconstituted with wild-type mouse-derived progenitors (CD4 knockout/wild-type), and unirradiated CD4 knockout and wild-type mice were used as controls. All mice underwent tail skin and lymphatic excision to induce lymphedema, and analysis was performed 6 weeks later. RESULTS: Wild-type/CD4 knockout chimeras were not protected from developing lymphedema. Despite a global deficit in CD4 T cells, these mice had swelling, fibrosis, inflammation, and impaired lymphatic transport function indistinguishable from that in wild-type and CD4 knockout/wild-type mice. In contrast, unirradiated CD4 knockout mice had no features of lymphedema after lymphatic injury. CONCLUSIONS: Relatively small numbers of bone marrow and peripheral CD4 T cells are sufficient to induce the development of lymphedema. These findings suggest that lymphatic injury results in expansion of CD4 T-cell populations in lymphedematous tissues.

CD4+ T cells are activated in regional lymph nodes and migrate to skin to initiate lymphedema.

T cell-mediated responses have been implicated in the development of fibrosis, impaired lymphangiogenesis, and lymphatic dysfunction in secondary lymphedema. Here we show that CD4+ T cells are necessary for lymphedema pathogenesis by utilizing adoptive transfer techniques in CD4 knockout mice that have undergone tail skin and lymphatic excision or popliteal lymph node dissection. We also demonstrate that T cell activation following lymphatic injury occurs in regional skin-draining lymph nodes after interaction with antigen-presenting cells such as dendritic cells. CD4+ T cell activation is associated with differentiation into a mixed T helper type 1 and 2 phenotype, as well as upregulation of adhesion molecules and chemokines that promote migration to the skin. Most importantly, we find that blocking T cell release from lymph nodes using a sphingosine-1-phosphate receptor modulator prevents lymphedema, suggesting that this approach may have clinical utility.

Inhibition of Inflammation and iNOS Improves Lymphatic Function in Obesity.

Although recent studies have shown that obesity decreases lymphatic function, the cellular mechanisms regulating this response remain unknown. In the current study, we show that obesity results in perilymphatic accumulation of inflammatory cells and that local inhibition of this response with topical tacrolimus, an inhibitor of T cell differentiation, increases lymphatic vessel density, decreases perilymphatic iNOS expression, increases lymphatic vessel pumping frequency, and restores lymphatic clearance of interstitial fluid to normal levels. Although treatment of obese mice with 1400W, a selective inhibitor of iNOS, also improved lymphatic collecting vessel contractile function, it did not completely reverse lymphatic defects. Mice deficient in CD4(+) cells fed a high fat diet also gained weight relative to controls but were protected from lymphatic dysfunction. Taken together, our findings suggest that obesity-mediated lymphatic dysfunction is regulated by perilymphatic accumulation of inflammatory cells and that T cell inflammatory responses are necessary to initiate this effect.

Decellularized Lymph Nodes as Scaffolds for Tissue Engineered Lymph Nodes.

BACKGROUND: The lymphatic system is commonly injured during cancer treatment. However, despite the morbidity of these injuries, there are currently no options for replacing damaged lymphatics. The purpose of this study was to optimize methods for decellularization of murine lymph nodes (LN) and to determine if these scaffolds can be used to tissue engineer lymph node-like structures. METHODS AND RESULTS: LNs were harvested from adult mice and subjected to various decellularization protocols. The degree of decellularization and removal of nuclear material was analyzed histologically and quantitatively using DNA isolation. In addition, we analyzed histological architecture by staining for matrix proteins. After the optimal method of decellularization was identified, decellularized constructs were implanted in the renal capsule of syngeneic or allogeneic recipient mice and analyzed for antigenicity. Finally, to determine if decellularized constructs could deliver lymphocytes to recipient animals, the matrices were repopulated with splenocytes, implanted in submuscular pockets, and harvested 14 days later. Decellularization was best accomplished with the detergent sodium dodecyl sulfate (SDS), resulting in negligible residual cellular material but maintenance of LN architecture. Implantation of decellularized LNs into syngeneic or allogeneic mice did not elicit a significant antigenic response. In addition, repopulation of decellularized LNs with splenocytes resulted in successful in vivo cellular delivery. CONCLUSIONS: We show, for the first time, that LNs can be successfully decellularized and that these matrices have preserved extracellular matrix architecture and the potential to deliver leukocytes in vivo. Future studies are needed to determine if tissue engineered lymph nodes maintain immunologic function.

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-ß1 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.

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.

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 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.

Fluoroscopic radiation burn after embolization of a spinal arteriovenous malformation.

Fluoroscopic radiation burns are being reported with increasing frequency because of the rise in number and duration of procedures performed under fluoroscopic guidance. We report a fluoroscopic radiation burn to a patient's back after three separate attempts to embolize a symptomatic spinal arteriovenous malformation, requiring fasciocutaneous flaps to ultimately close the wound. Risk factors, physiology, and modifications to decrease fluoroscopic radiation burns are discussed.