Examination of Acute Care Nurses Ability to Engage in Patient Education Related to Physical Activity as a Health Behavior

Physical activity is important for management and prevention of chronic disease. The current physical activity guidelines recommend engaging in physical activity for at least 30 minutes per day on at least 5 days a week. Acute care settings may present opportunities for patient education about physical activity. PURPOSE: The purpose of this study was to examine the ability of acute care nurses to engage in patient education regarding physical activity as a health behavior. Additionally, this study examined the influence of level of nurse training, age, personal physical activity and years of experience on these outcomes. METHODS: Nurses from an academic medical center (N=194) were surveyed. Knowledge of current physical activity guidelines, rank of importance of physical activity as a patient care activity and a healthy lifestyle behavior, and confidence to counsel patients about physical activity were queried. RESULTS: Of nurses queried, 32.5% reported days per week and 83% reported minutes per day to engage in physical activity consistent with current guidelines. Physical activity counseling was ranked least important of ten patient care activities and fifth as a healthy lifestyle behavior. The majority of nurses (51%) felt some degree of confidence to counsel patients regarding physical activity. Baccalaureate level nurses were more likely to be consistent with physical activity guidelines than master’s level nurses. Nurses <25 years of age were more current in knowledge of physical activity guidelines than nurses ≥41 years of age. Nurses who exercised were more likely to report knowing current physical activity guidelines. Reported time spent counseling patientsregarding physical activity averaged 6 minutes per patient per day. CONCLUSION: Acute care nurses are counseling patients regarding physical activity although it is ranked least important of ten patient care activities. Future research should include studying: a variety of patient populations; other hospital settings; objective measures of evaluation; and nurses’ training regarding physical activity

Correlation of qEEG with PET in schizophrenia

PET relative metabolism was correlated with quantitative EEG in 9 schizophrenic patients. The PET metabolic regions of interest were the frontal lobes, thalamus and basal ganglia, and right and left temporal lobes. Significant positive correlations were seen for the frontal lobes and delta EEG power, and alpha power with subcortical metabolism. The physiologic plausibility of those correlations is discussed with reference to the possible effect of neuroleptic medication

Enhancing Seed Availability For the Hard Clam (Mercenaria mercenaria) Aquaculture Industry By Applying Remote Setting Techniques

The goal of this study was to test a technology that may help ensure a reliable and consistent supply of high quality and inexpensive clam seed to growers, thus fostering an emerging aquaculture industry by eliminating a seed shortage that limits sustainability. The overall objectives were to develop, test and demonstrate technical procedures and determine the financial feasibility of transferring remote setting technology from the Pacific Northwest molluscan shellfish industry to the hard clam aquaculture industry in Florida. (PDF has 44 pages.

Ground Systems Development Environment (GSDE) interface requirements analysis

A set of procedural and functional requirements are presented for the interface between software development environments and software integration and test systems used for space station ground systems software. The requirements focus on the need for centralized configuration management of software as it is transitioned from development to formal, target based testing. This concludes the GSDE Interface Requirements study. A summary is presented of findings concerning the interface itself, possible interface and prototyping directions for further study, and results of the investigation of the Cronus distributed applications environment

A genetic and molecular model for flower development in Arabidopsis thaliana

Cells in developing organisms do not only differentiate, they differentiate in defined patterns. A striking example is the differentiation of flowers, which in most plant families consist of four types of organs: sepals, petals, stamens and carpels, each composed of characteristic cell types. In the families of flowering plants in which these organs occur, they are patterned with the sepals in the outermost whorl or whorls of the flower, with the petals next closest to the center, the stamens even closer to the center, and the carpels central. In each species of flowering plant the disposition and number (or range of numbers) of these organs is also specified, and the floral 'formula' is repeated in each of the flowers on each individual plant of the species. We do not know how cells in developing plants determine their position, and in response to this determination differentiate to the cell types appropriate for that position. While there have been a number of speculative proposals for the mechanism of organ specification in flowers (Goethe, 1790; Goebel, 1900; Heslop-Harrison, 1964; Green, 1988), recent genetic evidence is inconsistent with all of them, at least in the forms in which they were originally presented (Bowman et al. 1989; Meyerowitz et al. 1989). We describe here a preliminary model, based on experiments with Arabidopsis thaliana. The model is by and large consistent with existing evidence, and has predicted the results of a number of genetic and molecular experiments that have been recently performed

How release of phosphate from mammalian F1-ATPase generates a rotary substep.

The rotation of the central stalk of F1-ATPase is driven by energy derived from the sequential binding of an ATP molecule to its three catalytic sites and the release of the products of hydrolysis. In human F1-ATPase, each 360° rotation consists of three 120° steps composed of substeps of about 65°, 25°, and 30°, with intervening ATP binding, phosphate release, and catalytic dwells, respectively. The F1-ATPase inhibitor protein, IF1, halts the rotary cycle at the catalytic dwell. The human and bovine enzymes are essentially identical, and the structure of bovine F1-ATPase inhibited by IF1 represents the catalytic dwell state. Another structure, described here, of bovine F1-ATPase inhibited by an ATP analog and the phosphate analog, thiophosphate, represents the phosphate binding dwell. Thiophosphate is bound to a site in the α(E)β(E)-catalytic interface, whereas in F1-ATPase inhibited with IF1, the equivalent site is changed subtly and the enzyme is incapable of binding thiophosphate. These two structures provide a molecular mechanism of how phosphate release generates a rotary substep as follows. In the active enzyme, phosphate release from the β(E)-subunit is accompanied by a rearrangement of the structure of its binding site that prevents released phosphate from rebinding. The associated extrusion of a loop in the β(E)-subunit disrupts interactions in the α(E)β(E-)catalytic interface and opens it to its fullest extent. Other rearrangements disrupt interactions between the γ-subunit and the C-terminal domain of the α(E)-subunit. To restore most of these interactions, and to make compensatory new ones, the γ-subunit rotates through 25°-30°