Effect of an Acute Bout of Low-, Moderate, and High-Intensity Aerobic Exercise on Immediate and Delayed Fractionated Response Time

In the present investigation, we investigated the role of three intensities of aerobic exercise (Low Intensity [LI], Moderate Intensity [MI], High Intensity [HI]) on IPC using a unique method to fractionate RPT into three components: (1) RT, which is the interval between the onset of the stimulus signal and the onset of muscle activity in the responding muscle (cognitive-decision making component), (2) movement time (MT), which is the time interval between the onset of muscle activation and completion of the required motor response, and (3) RPT, which encompasses both RT and MT. Movement time reflects more the muscular components of the stimulus-response action, whereas RT reflects the duration of all earlier stages of information processing

Physics-based multiscale coupling for full core nuclear reactor simulation

Numerical simulation of nuclear reactors is a key technology in the quest for improvements in efficiency, safety, and reliability of both existing and future reactor designs. Historically, simulation of an entire reactor was accomplished by linking together multiple existing codes that each simulated a subset of the relevant multiphysics phenomena. Recent advances in the MOOSE (Multiphysics Object Oriented Simulation Environment) framework have enabled a new approach: multiple domain-specific applications, all built on the same software framework, are efficiently linked to create a cohesive application. This is accomplished with a flexible coupling capability that allows for a variety of different data exchanges to occur simultaneously on high performance parallel computational hardware. Examples based on the KAIST-3A benchmark core, as well as a simplified Westinghouse AP-1000 configuration, demonstrate the power of this new framework for tackling—in a coupled, multiscale manner—crucial reactor phenomena such as CRUD-induced power shift and fuel shuffle.Massachusetts Institute of Technology. Department of Nuclear Science and EngineeringIdaho National Laboratory (Contract DE-AC07-05ID14517

Exercise Intensity and Fractionated Response Time

We investigated the role of three intensities of aerobic exercise (Low Intensity [LI], Moderate Intensity [MI], High Intensity [HI]) on information processing and cognition (IPC) by analyzing response time (RPT) and its fractionated components (1) reaction time (RT, interval between stimulus onset and muscle activation, and (2) movement time (MT, time interval between muscle activation and completion of the required motor response). Twenty-seven participants (16, male; 11, female) between the ages of 18-25 (mean age = 21.9 years) took part in 1-choice, 5-choice, and dual-task (DT, counting backwards by 3) conditions prior to and 1-min and 20-min postexercise. Based on the statistical analyses, three major findings emerged: (1) participants improved RT and RPT in the more complex 5-Choice & DT tasks but not in the simple 1-Choice task; (2) improvement in RPT occurred primarily as a result of decreased RT and not MT; and (3) all exercise intensities improved RT and RPT in 5-Choice and DT tasks both immediately postexercise (1-min) and short-term (20-min). As RT represents more CNS mechanisms than movement per se, the facilitatory effects of exercise on RPT involved more speed of cortical processing than speed in completing the task. Each of these effects were discussed