Two separate decay timescales of a detonation wave modeled by the Burgers equation and their relation to its chaotic dynamics.

This study uses a simplified detonation model to investigate the behavior of detonations with galloping-like pulsations. The reactive Burgers equation is used for the hydrodynamic equation, coupled to a pulsed source whereby all the shocked reactants are simultaneously consumed at fixed time intervals. The model mimics the short periodic amplifications of the shock front followed by relatively lengthy decays seen in galloping detonations. Numerical simulations reveal a sawtooth evolution of the front velocity with a period-averaged detonation speed equal to the Chapman-Jouguet velocity. The detonation velocity exhibits two distinct groups of decay timescales, punctuated by reaction pulses. At each pulse, a rarefaction wave is created at the reaction front's last position. A characteristic investigation reveals that characteristics originating from the head of this rarefaction take 1.57 periods to reach and attenuate the detonation front, while characteristics at the tail take an additional period. The leading characteristics are amplified twice, by passing through the reaction fronts of subsequent pulses, before arriving at the shock front, while the trailing characteristics are amplified three times. This leads to the two distinct groups of timescales seen in the detonation front speed.

Instrumented staircase for kinetic analyses of upper- and lower-limb function during stair gait.

The paper describes the design, technical characteristics and first results of an adjustable staircase with commercial force plates embedded in the steps and custom force transducers as part of the handrail supports. For the railing assembly, the greatest errors (< 10% of maximum signal) and cross-talk range (0.58-6.74%) were in the medial-lateral direction and were corrected using a calibration matrix. Power spectral density analyses showed free vibration frequency responses for both the railing (15 Hz) and steps (38.6 Hz) that were relatively distinct from lower applied forces recorded during stair ascent. The creation of standardised filtering protocols was therefore possible to provide step reaction force signals identical to the literature and examples of upper-limb reaction forces that have not been shown before. Such a staircase will allow a more complete study of full body contributions to stair walking across various subject populations.

Locomotor rehabilitation in a complex virtual environment.

Virtual reality (VR) technology offers a new and safe way to increase practice time and provide the varied environments and constraints needed to optimize locomotor training. Our specific objectives are (1) to create a virtual environment (VE) coupled with a self-paced treadmill for locomotor training; (2) to compare temporal and distance measurements of gait during treadmill walking while looking at different scenarios of VE; and (3) to develop a protocol optimized for the training of locomotor disorders after stroke. A motorized treadmill was mounted on a six-degree-of-freedom motion platform. VEs were created using commercial software (SoftImage) and projected on a large screen, while system control was administered through the CAREN software (Motek BV). The instantaneous treadmill speed and scene progression were servo-controlled. Preliminary results show that healthy subjects are able to have full control of their own walking speed both on the treadmill and within the virtual scene, while experiencing a strong sense of presence. A street crossing training protocol has been developed for locomotor training. It is expected that locomotor training with increasingly complex VEs will allow persons with stroke to increase progressively their locomotor capacity, as required and entrained by the VE.

Energy balance and lipid metabolism in transgenic mice bearing an antisense GCR gene construct.

Energy balance and lipid metabolism were investigated in transgenic mice bearing an antisense glucocorticoid receptor (GCR) gene construct that impairs the normal expression of the GCR gene. Food intake was recorded during the 15 days preceding decapitation of adult normal and transgenic mice, and feces were collected to derive the digestible energy intake. Body composition measurements consisted of the determination of energy, protein, and fat content of the carcass. Carcass energy was determined by bomb calorimetry, whereas carcass protein was measured by the Kjeldahl procedure. Energy expenditure was estimated from the continuous oxygen consumption (VO2) monitoring over a 24-h period. Lipoprotein lipase (LPL) activity was quantified in epididymal white adipose tissue (WAT), heart, and vastus lateralis muscle (VLM) by measuring the in vitro hydrolysis of labeled triolein in the presence of tissue homogenates. Norepinephrine (NE) content of both interscapular brown adipose tissue (BAT) and heart were determined by high-performance liquid chromatography (HPLC). Energy intake and expenditure were significantly lower in transgenic mice than in controls. Concurrently, both fat content and total energy of the carcasses were significantly higher in the transgenic animals. In comparison with normal mice, heart and VLM LPL activity was significantly reduced in transgenic mutants. There was no difference between groups in LPL activity in WAT. Finally, heart and BAT NE contents were lower in transgenic animals than in control mice. These results suggest that a defective GCR system may affect energy balance through increasing energetic efficiency, and they emphasize the modulatory effects of hypothalamic-pituitary-adrenal axis changes on muscle LPL activity.