Effect of Foliar Application of Iron, Zinc and Manganese on Quantitative and Qualitative Characteristics of Two Varieties of Grain Millet

In order to study the effect of foliar application of Fe, Zn and Mn on yield, yield components and protein content of two varieties of grain millet an experiment was conducted as factorial based on randomized complete block design with three replications in research field of Birjand branch, Islamic Azad University at 2010.  In this study two millet varieties including Bastan (Setaria italica) and Pishahang (Panicum miliaceum), and six levels of foliar micronutrient fertilizer including control, Fe, Zn, Mn, (Fe+Zn), (Fe+Zn+Mn) were investigated. The results indicated that, panicle length, 1000 grain weight and panicle number per m2 were higher in Pishahang than Bastan, but grain yield, number of seeds per panicle, harvest index and protein yield were higher in Bastan. Characteristics such as panicle length, biological yield and harvest index and protein percentage were affected by foliar micronutrient fertilizer but grain yield remained unchanged. Foliar application with (Fe+Zn+Mn) increased protein content compared to the control, but it did not affect protein yield. According to the results of this experiment, Bastan millet variety and foliar application of Zn is potent to produce the maximum grain yield, albeit it warrants further studies

Poststimulation time interval-dependent effects of motor cortex anodal tDCS on reaction-time task performance

Anodal transcranial direct current stimulation (tDCS) induces long-term potentiation-like plasticity, which is associated with longlasting effects on different cognitive, emotional, and motor performances. Specifically, tDCS applied over the motor cortex is considered to improve reaction time in simple and complex tasks. The timing of tDCS relative to task performance could determine the efficacy of tDCS to modulate performance. The aim of this study was to compare the effects of a single session of anodal tDCS (1.5 mA, for 15 min) applied over the left primary motor cortex (M1) versus sham stimulation on performance of a go/no-go simple reaction-time task carried out at three different time points after tDCS—namely, 0, 30, or 60 min after stimulation. Performance zero min after anodal tDCS was improved during the whole course of the task. Performance 30 min after anodal tDCS was improved only in the last block of the reaction-time task. Performance 60 min after anodal tDCS was not significantly different throughout the entire task. These findings suggest that the motor cortex excitability changes induced by tDCS can improve motor responses, and these effects critically depend on the time interval between stimulation and task performance