(J Cardiac Fail 2013;19:80-86)”
“Aim:

A prospective study was conducted to determine whether any relationship exits between skin erythema, fatigue and biological factors during and after adjuvant radiotherapy for early breast cancer.

Methods:

Breast erythema was assessed objectively using reflectance spectrophotometry. Fatigue was recorded utilising the functional assessment of cancer therapy fatigue subscale. A number of potential systemic

indicators (biological factors) of the effects of radiotherapy was measured, including circulating cytokines, coagulation factors, peripheral selleck screening library blood indices and biochemistry. Measurements for erythema, fatigue and biological factors were taken at baseline and intervals during and following completion of radiotherapy.

Results:

A total of 52 eligible patients was included in the analysis. Breast erythema was shown to progressively increase during treatment, peaking on day 36 and returning to baseline by 4 months post-irradiation. Fatigue also

progressively increased during treatment, reaching a plateau between day 22 and 2 weeks post-radiotherapy. A statistically significant association was demonstrated between total breast erythema and fatigue at days 4, 8, 22 and 29 of irradiation and 2 and 6 weeks post-radiotherapy. Eltanexor Transmembrane Transporters inhibitor When only the increase in erythema attributable to radiotherapy was considered, statistically significant associations remained for day 4 of irradiation and 2 and 6 weeks post-radiotherapy. When multiple time points were considered together, an association between increased erythema and fatigue was present only post-radiotherapy. No relationship was demonstrated between the biological KU-60019 inhibitor factors and erythema or fatigue during radiotherapy.

Conclusion:

This study demonstrates a significant and consistent relationship between radiotherapy-induced breast erythema and fatigue, particularly in the period immediately following breast irradiation.”
“Temperature-dependent modulation characteristics of 1.3

mu m InAs/GaAs quantum dot (QD) lasers under small signals have been carefully studied at various bias currents. Based on experimental observations, it is found that the modulation bandwidth significantly increases when excited state (ES) lasing emerges at high temperature. This is attributed to additional photons emitted by ES lasing which contribute to the modulation response. A rate equation model including two discrete electron energy levels and the level of wetting layer has been used to investigate the temperature-dependent dynamic behavior of the QD lasers. Numerical investigations confirm that the significant jump for the small signal modulation response is indeed caused by ES photons.