Single Institution Experience with Lymphatic Microsurgical Preventive Healing Approach (LYMPHA) for the Primary Prevention of Lymphedema.

BACKGROUND: As many as 40 % of breast cancer patients undergoing axillary lymph node dissection (ALND) and radiotherapy develop lymphedema. We report our experience performing lymphatic-venous anastomosis using the lymphatic microsurgical preventive healing approach (LYMPHA) at the time of ALND. This technique was described by Boccardo, Campisi in 2009. METHODS: LYMPHA was offered to node-positive women with breast cancer requiring ALND. Afferent lymphatic vessels, identified by injection of blue dye in the ipsilateral arm, were sutured into a branch of the axillary vein distal to a competent valve. Follow-up was with pre- and postoperative lymphoscintigraphy, arm measurements, and (L-Dex®) bioimpedance spectroscopy. RESULTS: Over 26 months, 37 women underwent attempted LYMPHA, with successful completion in 27. Unsuccessful attempts were due to lack of a suitable vein (n = 3) and lymphatic (n = 5) or extensive axillary disease (n = 1). There were no LYMPHA-related complications. Mean follow-up time was 6 months (range 3-24 months). Among completed patients, 10 (37%) had a body mass index of ≥30 kg/m(2) (mean 27.9 ± 6.8 kg/m(2), range 17.4-47.6 kg/m(2)), and 17 (63%) received axillary radiotherapy. Excluding two patients with preoperative lymphedema and those with less than 3-month follow-up, the lymphedema rate was 3 (12.5%) of 24 in successfully completed and 4 (50 %) of 8 in unsuccessfully treated patients. CONCLUSIONS: Our transient lymphedema rate in this high-risk cohort of patients was 12.5%. Early data show that LYMPHA is feasible, safe, and effective for the primary prevention of breast cancer-related lymphedema.

Optimizing surgical margins in breast conservation.

Adequate surgical margins in breast-conserving surgery for breast cancer have traditionally been viewed as a predictor of local recurrence rates. There is still no consensus on what constitutes an adequate surgical margin, however it is clear that there is a trade-off between widely clear margins and acceptable cosmesis. Preoperative approaches to plan extent of resection with appropriate margins (in the setting of surgery first as well as after neoadjuvant chemotherapy,) include mammography, US, and MRI. Improvements have been made in preoperative lesion localization strategies for surgery, as well as intraoperative specimen assessment, in order to ensure complete removal of imaging findings and facilitate margin clearance. Intraoperative strategies to accurately assess tumor and cavity margins include cavity shave techniques, as well as novel technologies for margin probes. Ablative techniques, including radiofrequency ablation as well as intraoperative radiation, may be used to extend tumor-free margins without resecting additional tissue. Oncoplastic techniques allow for wider resections while maintaining cosmesis and have acceptable local recurrence rates, however often involve surgery on the contralateral breast. As systemic therapy for breast cancer continues to improve, it is unclear what the importance of surgical margins on local control rates will be in the future.

Options and considerations in the timing of breast reconstruction after mastectomy.

Timing of breast reconstruction after mastectomy is determined primarily by patient factors and the need for postmastectomy radiation therapy. If the risk of needing postmastectomy radiation is low, then immediate reconstruction produces the optimal aesthetic result. If the risk of needing postmastectomy radiation is high, then delayed reconstruction is preferable to optimize both radiation delivery and aesthetic outcome. For patients with an increased risk of needing postmastectomy radiation, "delayed-immediate" reconstruction, which involves placing a tissue expander at the time of mastectomy and awaiting pathology results to determine the need for radiation and guide reconstruction scheduling, is a viable approach. Thorough and informed physician counseling about the pros and cons of these options is critical for all women undergoing mastectomy.

Sex hormones affect bone marrow dysfunction after trauma and hemorrhagic shock.

OBJECTIVE: Bone marrow (BM) dysfunction after trauma and hemorrhagic shock (T/HS) results in a decrease in clonogenic growth of BM progenitors through a plasma-mediated process. Although sex hormones have been shown to modulate some end-organ injury after shock, post-T/HS BM dysfunction has only been studied in male animals. Therefore, the present study examines the effects of sex hormones on post-T/HS BM dysfunction by measuring clonogenic growth of BM progenitors in castrated male rats and in ovariectomized and proestrus female rats. DESIGN: Laboratory experiment. SETTING: University surgical research laboratory. SUBJECT: Castrated and noncastrated male and ovariectomized and proestrus female Sprague-Dawley rats. INTERVENTION: All rats were subjected to either T/HS or sham shock with laparotomy (n = 3-5 per group). At 3 hrs after resuscitation, the rats were killed and plasma and BM mononuclear cells from bilateral femurs were harvested. MEASUREMENTS AND MAIN RESULTS: BM mononuclear cells were cultured for erythroid burst-forming unit and granulocyte-macrophage colony-forming unit colonies to assess the extent of progenitor BM dysfunction. BM from noncastrated male rats subjected to T/HS demonstrated a significant decrease in granulocyte-macrophage colony-forming unit and erythroid burst-forming unit colony formation compared with BM of all the sham shock groups and with the castrated male and both female rat groups subjected to T/HS. In addition, plasma from noncastrated shocked male rats incubated in vitro with BM cells from unmanipulated male rats caused a significant suppression of BM granulocyte-macrophage colony-forming unit and erythroid burst-forming unit colonies compared with plasma from castrated rats subjected to either sham shock with laparotomy or T/HS. CONCLUSION: The profound BM dysfunction observed in noncastrated male rats after T/HS is not observed in proestrus female rats and castrated male rats. In addition, the in vitro plasma-mediated BM suppression present in male rats after T/HS is also lost in castrated male rats. Sex hormones seem to play a significant role in BM dysfunction after T/HS.

Neutrophil activation is modulated by sex hormones after trauma-hemorrhagic shock and burn injuries.

Recent literature indicates that females are more resistant to shock-, trauma-, and sepsis-induced immune dysfunction and organ injury than are males. Consequently, using trauma-hemorrhagic shock (T/HS) and burn models, we tested whether the neutrophil response to trauma occurred in a sexually dimorphic fashion and, if so, the role of sex hormones. Neutrophil activation, as reflected by CD11b expression and respiratory burst activity, was increased to a greater extent in male rats than in female rats after T/HS or burn injury. Testosterone appeared to potentiate neutrophil activation, because castration reduced neutrophil activation, whereas ovariectomy had little effect. Mechanistically, this sexually dimorphic neutrophil response appeared to be due to both cellular and humoral factors. Evidence for a cellular difference between male and female neutrophils is based on the observation that naive female neutrophils were more resistant to activation by burn or T/HS plasma and lymph than naive male neutrophils and that this resistance varied over the estrus cycle. Additionally, the humoral environment was more neutrophil activating in male rats, because burn and T/HS plasma and lymph from male rats activated naive male neutrophils to a greater extent than comparable samples from females. Last, on the basis of in vitro experiments examining the effects of estrogen on calcium signaling, it appears that estrogen limits trauma-induced neutrophil activation, at least in part, by limiting the entry of calcium into the cell via store-operated calcium entry mechanisms. In conclusion, there is a striking sexual dimorphism in neutrophil responses after trauma, and these changes reflect both cellular resistance to activation as well as a less activating humoral environment.

Bone marrow failure in male rats following trauma/hemorrhagic shock (T/HS) is mediated by mesenteric lymph and modulated by castration.

Bone marrow (BM) suppression occurs following trauma/hemorrhagic shock (T/HS) in experimental animals as well as following severe injury in humans. Although the pathophysiology of BM suppression remains poorly understood, mesenteric lymph is thought to play an important role in T/HS-induced BM suppression; however, the direct effect of mesenteric lymph on BM in vitro has never been studied. In addition, recent studies in rats have also shown that female and castrated male rats are protected against T/HS-induced BM failure. We therefore hypothesized that mesenteric lymph is a source of factor(s) causing direct BM suppression and that the effects of mesenteric lymph are gender dependent. To test this hypothesis, we subjected noncastrated (NC) and castrated (C) male and proestrus female rats to T/HS or trauma sham shock (T/SS). Mesenteric lymph collected 3 h postshock was plated (4% v/v) with BM cells collected from unmanipulated male or female rats for granulocyte-macrophage colony-forming units (CFU-GM) and erythroid burst-forming units (BFU-E) colony growth. The T/HS lymph collected from NC-male rats but not from female rats caused a 50% inhibition of CFU-GM and BFU-E colony growth compared with cells cultured without lymph (P < 0.05 versus all other groups (ANOVA + Tukey). T/HS lymph collected from C-male rats also caused no significant inhibition of CFU-GM and BFU-E colony growth compared with cells cultured without lymph. Female and male BM progenitor cells had a similar response to mesenteric lymph from all groups tested. These results show that mesenteric lymph from NC-male rats suppresses CFU-GM and BFU-E progenitor growth in vitro, whereas the lymph from C-male and female rats did not. The effects of mesenteric lymph were the same regardless of whether the target BM was from male or female rats. The results therefore indicate that BM failure in male rats is directly mediated by factors present within the mesenteric lymph that appear to be modulated by castration, and protection against BM failure in female rats occurs at a systemic rather than a local level. Further studies are needed to elucidate potential therapeutic effects of lymph manipulation in hematopoiesis after injury.

Sex hormones modulate distant organ injury in both a trauma/hemorrhagic shock model and a burn model.

BACKGROUND: Emerging data suggest a gender dimorphism in resistance and susceptibility to distant organ injury after mechanical and thermal trauma. The aim of this study was to determine the role that testosterone and estradiol play in modulating resistance or susceptibility to distant organ injury, and whether their effects were associated with differences in the production of nitric oxide. METHODS: Adult male, female, castrated male, and ovariectomized female Sprague-Dawley rats were given intraperitoneal pentobarbital sodium anesthesia and subjected to trauma/sham shock or trauma/hemorrhagic shock (T/HS). A second set of animals were subjected to a 40% total body surface area, third-degree burn or sham burn. At 3 hours after resuscitation, plasma levels of nitrite/nitrate were measured, and the extent of lung injury (permeability to Evans Blue dye and neutrophil sequestration by myeloperoxidase) and intestinal injury (morphology) were determined. RESULTS: Proestrus females showed resistance to lung and gut injury after both T/HS and burns, and had low levels of nitrite/nitrate production. This resistance to injury was abrogated by ovariectomy with an associated increase in nitric oxide production. Males showed increased lung and gut injury after both T/HS and burns associated with increased production of nitrite/nitrate. Castration decreased susceptibility to both lung and gut injury, and decreased production of nitrite/nitrate. A correlation was noted between intestinal and lung injury, and both intestinal and lung injury correlated with plasma nitrite/nitrate levels. CONCLUSIONS: Male sex hormones potentiate, while female hormones reduce T/HS and burn-induced lung and gut injury. Production of nitric oxide is associated with increased lung and gut injury after T/HS and burns.

Burn-induced red blood cell deformability and shape changes are modulated by sex hormones.

BACKGROUND: Burns are known to cause changes in red blood cell (RBC) deformability and resting shape. However, it is unclear whether sex and sex hormones can influence the severity of these alterations. METHODS: Red blood cell deformability and shape were examined in proestrus and diestrus female rats, ovariectomized female rats, as well as castrated and non-castrated male rats (6 animals per group) subjected to scald burn. Red blood cell deformability was measured by laser ektacytometry and erythrocyte shape was evaluated by scanning electron microscopy. RESULTS: Burn-induced RBC deformability changes (decrease in elongation index) and shape alterations (increase in the percentage of reversibly and irreversibly changed cells) were less severe in proestrus females than in diestrus females or males. Ovariectomized rats demonstrated more severe RBC changes than non-ovariectomized ones. The degree of RBC damage was the same in castrated and non-castrated males. CONCLUSIONS: Removal of female sex hormones increases the severity of burn-induced RBC, indicating that female sex hormones protect against burn-induced RBC dysfunction. In contrast, male sex hormones do not appear to modulate burn-induced RBC dysfunction.