Survival outcomes and interval between lymphoscintigraphy and SLNB in cutaneous melanoma- findings of a large prospective cohort study.

INTRODUCTION: Sentinel lymph node biopsy (SLNB) in cutaneous melanoma (CM) is performed to identify patient at risk of regional and distant relapse. We hypothesized that timing of lymphoscintigraphy may influence the accuracy of SLNB and patient outcomes. METHODS: We reviewed prospective data on patients undergoing SLNB for CM at a large university cancer-center between 2008 and 2015, examining patient and tumor demographics and time between lymphoscintigraphy (LS) and SLNB. Kaplan-Meier survival analysis assessed disease-specific (DSS) and overall-survival (OS), stratified by timing of LS. Cox multivariate regression analysis assessed independent risk factors for survival. RESULTS: We identified 1015 patients. Median follow-up was 45 months (IQR 26-68 months). Univariate analysis showed a 6.8% absolute DSS (HR 1.6 [1.03-2.48], p = 0.04) benefit and a 10.7% absolute OS (HR 1.64 [1.13-2.38], p = 0.01) benefit for patients whose SLNB was performed < 12 h of LS (n = 363) compared to those performed >12 h (n = 652). Multivariate analysis identified timing of LS as an independent predictor of OS (p = 0.007) and DSS (p = 0.016) when competing with age, sex, Breslow thickness (BT) and SLN status. No difference in nodal relapse rates (5.2% v 4.6%; p = 0.67) was seen. Both groups were matched for age, sex, BT and SLN status. CONCLUSION: These data have significant implications for SLNB services, suggesting delaying SLNB >12 h after LS using a Tc99-labelled nanocolloid has a significant negative survival impact for patients and should be avoided. We hypothesise that temporal tracer migration is the underlying cause and advocate further trials investigating alternative, 'stable' tracer-agents.

Phospho-flow cytometry based analysis of differences in T cell receptor signaling between regulatory T cells and CD4+ T cells.

CD4+ T regulatory cells (Tregs) are activated during auto-immune, injury, and inflammatory responses, however, the molecular events that trigger Treg activation are poorly understood. The purpose of this study was to investigate whether Tregs (FoxP3+ CD4+ T cells) and non-Treg CD4+ T cells might display differences in T cell receptor (TCR) dependent signaling responses following in vitro or in vivo stimulation. This study used phospho-flow cytometry as a tool to profile the kinetics and extent of TCR signaling (ZAP-70 and PKC-θ phosphorylation and expression) in Tregs and non-Tregs. We found that in vitro stimulation with anti-CD3ε induces early and transient activation of ZAP-70 and PKC-θ in both Tregs and non-Tregs. However, the response in Tregs was more rapid and higher in magnitude than responses seen in non-Tregs. In contrast, bacterial superantigen or antigen-specific TCR stimulation did not significantly activate these signaling pathways in Tregs or non-Tregs. Additional experiments tested the kinetics of in vivo TCR signaling in Tregs and non-Tregs in mice challenged with bacterial superantigen. The results of these experiments showed that superantigen rapidly activated ZAP-70 and PKC-θ in lymph node Tregs, but not in non-Tregs. In summary, we demonstrate the versatility of using phospho-flow cytometry to measure cell signaling in CD4+ T cells. The results of these in vitro and in vivo studies demonstrate that Tregs and non-Treg CD4+ T cells show marked differences in their reactivity to TCR-dependent stimulation and contribute new insights into basic mechanisms that lead to Treg activation.

Injury-induced GR-1+ macrophage expansion and activation occurs independently of CD4 T-cell influence.

Burn injury initiates an enhanced inflammatory condition referred to as the systemic inflammatory response syndrome or the two-hit response phenotype. Prior reports indicated that macrophages respond to injury and demonstrate a heightened reactivity to Toll-like receptor stimulation. Since we and others observed a significant increase in splenic GR-1 F4/80 CD11b macrophages in burn-injured mice, we wished to test if these macrophages might be the primary macrophage subset that shows heightened LPS reactivity. We report here that burn injury promoted higher level TNF-α expression in GR-1, but not GR-1 macrophages, after LPS activation both in vivo and ex vivo. We next tested whether CD4 T cells, which are known to suppress injury-induced inflammatory responses, might control the activation and expansion of GR-1 macrophages. Interestingly, we found that GR-1 macrophage expansion and LPS-induced TNF-α expression were not significantly different between wild-type and CD4 T cell-deficient CD4(-/-) mice. However, further investigations showed that LPS-induced TNF-α production was significantly influenced by CD4 T cells. Taken together, these data indicate that GR-1 F4/80 CD11b macrophages represent the primary macrophage subset that expands in response to burn injury and that CD4 T cells do not influence the GR-1 macrophage expansion process, but do suppress LPS-induced TNF-α production. These data suggest that modulating GR-1 macrophage activation as well as CD4 T cell responses after severe injury may help control the development of systemic inflammatory response syndrome and the two-hit response phenotype.

Regulatory T cells suppress antigen-driven CD4 T cell reactivity following injury.

Injury initiates local and systemic host responses and is known to increase CD4 Treg activity in mice and humans. This study uses a TCR transgenic T cell adoptive transfer approach and in vivo Treg depletion to determine specifically the in vivo influence of Tregs on antigen-driven CD4 T cell reactivity following burn injury in mice. We report here that injury in the absence of recipient and donor Tregs promotes high antigen-driven CD4 T cell expansion and increases the level of CD4 T cell reactivity. In contrast, CD4 T cell expansion and reactivity were suppressed significantly in injured Treg-replete mice. In additional experiments, we found that APCs prepared from burn- or sham-injured, Treg-depleted mice displayed significantly higher antigen-presenting activity than APCs prepared from normal mice, suggesting that Tregs may suppress injury responses by controlling the intensity of APC activity. Taken together, these findings demonstrate that Tregs can actively control the in vivo expansion and reactivity of antigen-stimulated, naïve CD4 T cells following severe injury.

Alcohol hand gel--a potential fire hazard.

Alcohol hand gel and wipes are the common method of disinfecting the hands of healthcare workers and working surfaces in clinical settings. We present a case of a 40-year-old health care support worker who was referred acutely to our burns unit following flame burns in association with alcohol gel use. Fortunately she was able to extinguish the flames without sustaining a significant thermal injury however this case highlights the potential danger associated with alcohol gel use, especially with smokers. With the ever increasing use of alcohol hand gel, not only in healthcare settings but also in the general population there needs to be clearer warnings regarding the potential for ignition after use. Alcohol hand gel and wipes are the common method of disinfecting the hands of healthcare workers and working surfaces in clinical settings. Most trusts have strict policies regarding mandatory sanitisation of hands before and after patient contact. This is most easily achieved by the use of alcohol gel due to its ease of use and quick drying properties. As a result alcohol hand disinfectant is available is a variety of formats including foam, gel and wipes. It is also now widely available for use to the general public.

Injury induces early activation of T-cell receptor signaling pathways in CD4+ regulatory T cells.

Although it is known that injury enhances the regulatory activity of CD4 regulatory T cells (Tregs), the cellular and molecular mechanisms responsible for injury-induced Treg activation remain unclear. This study was designed to investigate and compare injury-induced T-cell receptor (TCR) signaling in Tregs, non-Tregs, and CD8 T cells. Specifically, we used phospho-flow cytometry to measure the expression and phosphorylation of ZAP-70, protein kinase C θ, nuclear factor of activated T cells, and glycogen synthase kinase 3ß in FoxP3 Tregs versus FoxP3 non-Tregs versus CD8 T cells. Groups of male C57BL/6J mice underwent burn or sham injury, and lymph nodes and spleens were harvested at early time points-15, 30, 60, 120, and 240 min-to measure TCR signaling. As early as 15 min after burn injury, we observed a significant upregulation and phosphorylation of ZAP-70, protein kinase C θ, nuclear factor of activated T cells, and glycogen synthase kinase 3ß in Tregs prepared from injury-site-draining lymph nodes. Burn injury did not activate TCR signaling in Tregs from the spleen or in CD4 non-Tregs and CD8 T cells. In conclusion, the results of this study demonstrate that burn injury activates TCR signaling in Tregs, but not non-Tregs or CD8 T cells. These findings suggest that injury provides an early TCR-activating signal to Tregs and supply new insights into how injury influences the adaptive immune system.