To identify markers of non-response to neoadjuvant chemotherapy (NAC) that could be used in the adjuvant setting. Sixteen pathologists of the European Working Group for Breast Screening Pathology reviewed the core biopsies of breast cancers treated with NAC and recorded the clinico-pathological findings (histological type and grade; estrogen, progesterone receptors, and HER2 status; Ki67; mitotic count; tumor-infiltrating lymphocytes; necrosis) and data regarding the pathological response in corresponding surgical resection specimens. Analyses were carried out in a cohort of 490 cases by comparing the groups of patients showing pathological complete response (pCR) and partial response (pPR) with the group of non-responders (pathological non-response: pNR). Among other parameters, the lobular histotype and the absence of inflammation were significantly more common in pNR (p < 0.001). By ROC curve analyses, cut-off values of 9 mitosis/2 mm2 and 18 % of Ki67-positive cells best discriminated the pNR and pCR + pPR categories (p = 0.018 and < 0.001, respectively). By multivariable analysis, only the cut-off value of 9 mitosis discriminated the different response categories (p = 0.036) in the entire cohort. In the Luminal B/HER2− subgroup, a mitotic count <9, although not statistically significant, showed an OR of 2.7 of pNR. A lobular histotype and the absence of inflammation were independent predictors of pNR (p = 0.024 and <0.001, respectively). Classical morphological parameters, such as lobular histotype and inflammation, confirmed their predictive value in response to NAC, particularly in the Luminal B/HER2− subgroup, which is a challenging breast cancer subtype from a therapeutic point of view. Mitotic count could represent an additional marker but has a poor positive predictive value.Electronic supplementary materialThe online version of this article (doi:10.1007/s10549-014-3192-3) contains supplementary material, which is available to authorized users.
For rehabilitation training it is recommended that the intensity of exercise should be distinctly below the individual anaerobic threshold (IAT). We investigated platelet activity, reactivity and platelet-leukocyte conjugate formation following a stardardized treadmill (TR) ergometer test at 90% IAT for 60-120 min. Seventeen healthy male non-smokers underwent TR. Blood samples were taken after a 30-min rest, immediately after exercise, and 2 h after exercise completion. Platelets were detected flow cytometrically by CD41 in whole blood, activated platelets by CD62P. In addition, stimulation of platelets in vitro with 7.5 microM TRAP-6 was performed. For testing platelet-leukocyte conjugates, antibodies against CD45 and CD41 were used. After TR the percent of non-stimulated CD62P-positive platelets (%PC) remained unchanged (1.65 +/- 0.56 to 1.73 +/- 0.79%PC) (mean +/- SD). In contrast, an increase (P<0.05) from 31.9 +/- 13.5 to 37.4 +/- 15.0 %PC in CD62P, TRAP-6 stimulated and enhanced (P<0.01) platelet-leukocyte conjugates (11.7 +/- 3.7 to 16.1 +/- 6.9, CD41-%PC) after TR were observed. Both changes were independent of thrombin generation measured by F1+2 and TAT, and reversible after 2 h. Long-term exercise (90% IAT) on a treadmill ergometer only leads to a moderate increase of platelet reactivity and platelet-leukocyte conjugates. The determination of platelet-leukocyte conjugates may offer the possibility to detect an early activation stage of platelets in vivo.
Exhaustive exercise leads to an activation of blood coagulation, but the implications of this activation are still unclear. The aim of this study was to investigate if a hypercoagulant stage exists after exhaustive treadmill- or cycle exercise; intrinsic and extrinsic endogenous thrombin potential (ETP) were measured by using the method of Hemker et al. Thirteen healthy male subjects underwent an exhaustive treadmill (TR) or cycle (CY) ergometer test and a control-day in random order. Blood samples were taken, repeatedly, after a 30 min rest, immediately before and after, and 1 h after exercise for measuring intrinsic and extrinsic total thrombin potential (TTPin, TTPex) (including free and alpha 2 -macroglobulin-bound thrombin) and endogenous thrombin potential (ETPin, ETPex), aPTT, PT, F1 + 2 and TAT. In comparison to the pre-value taken immediately before the exercise, the intrinsic TTP was significantly (p < 0.05) increased directly after exercise (TR-TTPin, + 11.6 %; CY-TTPin, + 11.5 %). In contrast, ETPin remained unchanged after both exercises. Additionally for TTPex and ETPex, no changes after exercise were detectable. aPTT was significantly (p < 0.05) shorter after exercise (TR-aPTT, - 16.2 %; CY-aPTT - 17.5 %), F1 + 2-concentrations were higher (p < 0.05) (TR-F1 + 2, + 21.2 %; CY-F1 + 2, + 9.8 %), but TAT remained unchanged. Differences between TR or CY could not be determined. These results show the expected shortening of aPTT and the increase of F1 + 2 indicating an activation of the coagulation system during exercise. However, the unchanged intrinsic and extrinsic ETP lead to the conclusion that in healthy young male subjects the potential for thrombin generation is insignificant, is directly counterbalanced by alpha 2-macroglobulin and is independent of the type of exhaustive exercise done.
For rehabilitation training it is recommended that the intensity of exercise should be clearly below the individual anaerobic threshold (IAT). We investigated blood coagulation, particularly endogenous thrombin potential (ETP) and fibrinolysis following a standardized treadmill (TR) ergometer test at 90% IAT for 60-120 min. Sixteen healthy male non-smokers underwent the TR test. Blood samples were taken after a 30-min rest, immediately after exercise, and 2 h after exercise completion. Extrinsic and intrinsic total (TTP(ex+in)) and endogenous (ETP(ex+in)) thrombin potential, prothrombin fragment 1+2 (F1+2), thrombin-antithrombin complex (TAT), plasmin-alpha2-antiplasmin complex (PAP), D-dimer, tissue plasminogen activator antigen and activity (tPA-AG and tPA-ACT) and plasminogen activator inhibitor type 1 antigen and activity (PAI-1-AG and PAI-1-ACT) were measured. Immediately after TR, F1+2, TAT and TTP(ex+in) were increased ( P<0.05) while ETP(ex+in) remained unchanged. In contrast, PAP, D-dimer, tPA-AG, tPA-ACT ( P<0.05) were distinctly enhanced while PAI-1-ACT was decreased ( P<0.05) immediately after exercise. The changes in tPA-AG, tPA-ACT, and PAI-1-ACT were reversed to nearly baseline while the enhancement in PAP and D-dimer was prolonged by more than 2 h after exercise. Long-duration exercise between 60 and 120 min controlled by IAT (90%) on a TR ergometer only implicates a small increase in thrombin generation markers and total (free and alpha(2)-macroglubulin-bound thrombin), but not in endogenous (free) thrombin potential alone. In contrast, fibrinolysis is distinctly increased after this type of exercise. Endurance exercise with an intensity below 90% IAT and a duration below 2 h generates a more favourable condition for fibrinolysis than for blood coagulation in healthy young subjects. Data are given as mean (SD).
To clarify stress-induced immunological reactions and molecular events during exercise and the potential relevance to exercise-induced bronchoconstriction, transcriptional responses to standardized physical stress were determined. Six healthy, young volunteers underwent an endurance exercise of 90% of their individual anaerobic threshold for 90 min. Time-dependent alterations in the expression pattern of leukocytes from healthy, trained subjects were analyzed by DNA microarrays before and 2 h and 6 h after exercise. Starting out from a large collection of cDNA library clones comprising more than 70,000 human expressed sequence tags, we selected, designed, and immobilized oligonucleotide probes (60-70mers) for transcripts of 5000 stress- and inflammation-relevant genes. Exercise-induced stress provoked changes in the expression of 433 gene activities 2 h and/or 6 h after exercise, which could be grouped into six clusters. The most prominent feature was an enhanced transcription of two genes, coding for 5-lipoxygenase (ALOX5) and ALOX5-activating protein. Moreover, enhanced levels of leukotriene B4 (LTB4) and LTC4 (P<0.05) were detected in plasma after exercise. Our data demonstrate that exercise alters the activities of a distinct number of genes. In particular, they possibly provide novel insights into the molecular mechanisms of exercise-induced bronchoconstriction and suggest that enhanced transcription of ALOX5 and its activating protein together with a present predisposition of the subject critically contribute to exercise-induced asthma.
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