The Effects of Deep Breathing and Positive Imagery on Stress and Coherence Levels among College-Age Women

Stress is steadily becoming a problem of epidemic proportions in American society. Diseases and other health problems that are a direct result of high, chronic stress levels are on the rise. As bad as they are, the physical effects of stress are not the only concern. There are also mental and emotional concerns to increased and continuous stress levels. It is therefore vitally important for people to learn effective methods for reducing stress. This study investigates two techniques done together, deep breathing and positive imagery, for their effectiveness in reducing stress and increasing coherence. The sample consisted of thirty 18-26 year-old female college students at Liberty University who volunteered and were randomly placed into either an experimental group or a control group. The hypothesis was that the techniques would increase coherence, which occurs when the heart and brain are perfectly synchronized, and thereby reduce stress. Results showed that the techniques effectively reduced low coherence levels and increased high coherence levels, indicating a reduction in stress

Microencapsulated Dopamine (DA)-Induced Restitution of Function in 6-OHDA-Denervated Rat Striatum in vivo: Comparison Between Two Microsphere Excipients

Biodegradable controlled-release microsphere systems made with the biocompatible biodegradable polyester excipient poly [DL lactide-co-glycolide] constitute an exciting new technology for drug delivery to the central nervous system (CNS). The present study describes functional observations indicating that implantation of dopamine (DA) microspheres encapsulated within two different polymer excipients into denervated- striatal tissue assures a prolonged release of the transmitter in vivo. Moreover, in this regard, the results show that there were clear cut temporal differences in the effect of the two DA microsphere formulations compared in this study, probably reflecting variations in the actual composition (i.e., lactide to glycolide ratio) of the two copolymer excipients examined. This technology has considerable potential for basic research with possible clinical application

Experimental test of scaling of mixing by chaotic advection in droplets moving through microfluidic channels

This letter describes an experimental test of a simple argument that predicts the scaling of chaotic mixing in a droplet moving through a winding microfluidic channel. Previously, scaling arguments for chaotic mixing have been described for a flow that reduces striation length by stretching, folding, and reorienting the fluid in a manner similar to that of the baker’s transformation. The experimentally observed flow patterns within droplets (or plugs) resembled the baker’s transformation. Therefore, the ideas described in the literature could be applied to mixing in droplets to obtain the scaling argument for the dependence of the mixing time, t ∼ (aw/U)log(Pe), where w [m] is the cross-sectional dimension of the microchannel, a is the dimensionless length of the plug measured relative to w, U [m s^−1] is the flow velocity, Pe is the Péclet number (Pe = wU/D), and D [m^2 s^−1] is the diffusion coefficient of the reagent being mixed. Experiments were performed to confirm the scaling argument by varying the parameters w, U, and D. Under favorable conditions, submillisecond mixing has been demonstrated in this system