Simulating interactive effects of symbiotic nitrogen fixation, carbon dioxide elevation, and climatic change on legume growth.

The underlying mechanisms of interaction between the symbiotic nitrogen-fixation process and main physiological processes, such as assimilation, nutrient allocation, and structural growth, as well as effects of nitrogen fixation on plant responses to global change, are important and still open to more investigation. Appropriate models have not been adequately developed. A dynamic ecophysiological model was developed in this study for a legume plant [Glycine max (L.) Merr.] growing in northern China. The model synthesized symbiotic nitrogen fixation and the main physiological processes under variable atmospheric CO2 concentration and climatic conditions, and emphasized the interactive effects of these processes on seasonal biomass dynamics of the plant. Experimental measurements of ecophysiological quantities obtained in a CO2 enrichment experiment on soybean plants, were used to parameterize and validate the model. The results indicated that the model simulated the experiments with reasonable accuracy. The R2 values between simulations and observations are 0.94, 0.95, and 0.86 for total biomass, green biomass, and nodule biomass, respectively. The simulations for various combinations of atmospheric CO2 concentration, precipitation, and temperature, with or without nitrogen fixation, showed that increasing atmospheric CO2 concentration, precipitation, and efficiency of nitrogen fixation all have positive effects on biomass accumulation. On the other hand, an increased temperature induced lower rates of biomass accumulation under semi-arid conditions. In general, factors with positive effects on plant growth tended to promote each other in the simulation range, except the relationship between CO2 concentration and climatic factors. Because of the enhanced water use efficiency with a higher CO2 concentration, more significant effects of CO2 concentration were associated with a worse (dryer and warmer in this study) climate.

An Internet-based simulation model for nitrogen management in agricultural settings.

Complex chemical, physical, and biological processes mediate nitrogen (N) transformations and movement during agricultural production, making the optimization of fertilizer use and environmental protection exceedingly difficult. Various computer models have been developed to simulate the site-specific fate and transport of N resulting from different crop production scenarios, but these models are very complex and difficult to use for most farmers, consultants, and conservationists. In an effort to facilitate access and simplify the use of sophisticated models, the U.S. Department of Agriculture (USDA) has developed an Internet-based nitrogen analysis tool. Based on the Nitrate Leaching and Economic Analysis Package (NLEAP), the Web site allows a user to conduct multiyear N simulation modeling specific to a crop field. Servers handle much of the required data assembly and formatting, thus sparing the user"s resources. Model runs are executed on the servers and the results are transmitted to the user. This new tool is presented along with early implementation results.

Ontogeny of neuroepithelial bodies: correlations with mitogenesis and innervation.

This paper summarizes current knowledge and advances speculation about the formation of the neuroendocrine system of mammalian lungs (comprising uninnervated solitary and clustered small-granule cells and innervated neuroepithelial bodies). It relates the initial appearance of neuroendocrine cells to regulation of mitotic activity in the epithelium during the development of the lung and pays special attention to the later in growth of nerves that converts some of them into neuroepithelial bodies, structures considered ideally adapted to function as chemoreceptors. A few original observations from ongoing immunohistochemical, electron microscopic, and analytical studies have been included here and there to point the discussion. The neuroendocrine cells are derived from undifferentiated precursors present in the endodermal pulmonary epithelium. At an early pseudoglandular stage of lung development these precursors begin to differentiate into neuroendocrine small-granule cells, commencing in the larynx and upper trachea, and expanding centrifugally into pulmonary airways almost as rapidly as these are laid down. Subsequently many of the intrapulmonary small-granule cell clusters become innervated. This event, the delayed appearance of small-granule cells synthesizing other than the dominant peptides and amines (calcitonin gene-related peptide and serotonin in rodents, gastrin-releasing peptide and serotonin in human beings), and other regional adjustments yield the population distribution present in the lungs of adults. Neuroendocrine cell precursors normally differentiate into typical serotonin- or peptide-synthesizing small-granule cells without requiring direct contact by nerves, and dissociated cells from a previously innervated population continue to exhibit physiological characteristics of oxygen sensors despite the loss of contact with nerves. Development of the innervation occurs in stages. Small-granule cell clusters are reached first by ganglion cells derived from pulmonary neuroblasts and later on by processes of extrinsic sensory nerves. The latter not only convey information to the central nervous system but also serve in a variety of ways to extend the neuroepithelial bodies' sphere of influence within the lung itself.

Autoradiographic identification of brain angiotensin IV binding sites and differential c-Fos expression following intracerebroventricular injection of angiotensin II and IV in rats.

A unique angiotensin binding site specific for the hexapeptide, angiotensin II(3-8) (AngIV), has been previously reported by our laboratory in the guinea pig brain and is presently described in the rat brain. This angiotensin receptor subtype has been termed AT4 and is prominently distributed in cerebral cortex, piriform cortex, hippocampus, habenulae, colliculi, septum, periaqueductal gray, several thalamic nuclei, the arcuate nucleus of the hypothalamus and cerebellum. In the second part of the present investigation, separate groups of rats received i.c.v. injections of angiotensin II (AngII), AngIV or artificial cerebrospinal fluid (aCSF) and were euthanized 2 h later for the purpose of evaluating for brain c-Fos expression. After i.c.v.-injected AngIV, Fos-like immunoreactivity was present in the hippocampus and piriform cortex. This immunoreactivity was unaffected by i.c.v. pretreatment with the AT1 angiotensin receptor antagonist DuP 753 (losartan) or the AT2 receptor ligand PD123177 but was blocked by the AT4 angiotensin receptor antagonist, divalanal-AngIV. I.c.v. injection of AngII resulted in Fos-like immunoreactivity in the dorsal third and lateral ventricles, subfornical organ, lateral hypothalamus and amygdala. Pretreatment with losartan or PD123177 significantly interfered with this AngII-induced immunoreactivity while divalanal-AngIV did not. These results indicate that in both guinea pig and rat brains the AT4 receptor has a distribution different than that previously reported for AT1 and AT2 receptor subtypes. The c-Fos expression results suggest that different brain neuronal pathways are activated by i.c.v. injection of AngII and AngIV.

Technical support for biomedical equipment decision making.

Biomedical equipment in a hospital is diagnostic, therapeutic, monitoring, communication, and recordkeeping equipment that is directly or indirectly connected to the patient. This equipment continues to proliferate as developments in microcircuitry allow it to be smaller, more flexible, and thus more adaptable. One result of the equipment's increased flexibility is the ability to integrate individual equipment, clinician-users, patients, and hospital facilities into complex systems that enable the hospital to enhance patient care. Therefore, decision making regarding the acquisition and use of new equipment in the hospital must take into account the potential impact of the equipment on all the other elements of the system, including clinical and support staffs.

The role of clinical engineers in hospitals: essential or expedient?

This article explores the capabilities of those technicians and clinical engineers who manage biomedical equipment. Equipment technicians maintain the equipment in hospitals and may participate in some basic equipment management. Clinical engineers, on the other hand, may augment this management effort in equipment-intensive hospitals by designing the specifications and procedures needed to integrate equipments into properly working systems and to maintain them under local conditions. In addition, clinical engineers can improve equipment management by providing an engineering viewpoint to such areas as technology assessment, computer applications, quality improvement, and in-service education.

Angiotensin II(3-8) (ANG IV) hippocampal binding: potential role in the facilitation of memory.

The present research characterizes a newly discovered ANG II(3-8) (ANG IV) binding site localized in structures associated with memory function (hippocampus, neocortex, cerebellum), as well as other brain stem structures (thalamus, inferior olivary nucleus). This site is not the AT1 or AT2 site that binds angiotensins II (ANG II) and III (ANG III) nor does it bind the nonpeptide AT1 or AT2 receptor antagonists DuP753 and PD123177, respectively. The intracerebroventricular (ICV) infusion of ANG IV was ineffective at inducing drinking in rats as compared with equivalent doses of ANG II and III. Although not as effective as ANG II or ANG III, ICV infusion of ANG IV did provoke a pressor response at the highest dose (100 pmol/min), which appeared to be mediated by ANG II (AT1)-type receptors and not the specific AIV binding site described here. By contrast, the ICV infusion of ANG IV resulted in greater effects upon retention and retrieval of a passive avoidance task as compared with ANG II. Specifically, ANG II was not different from the ICV infusion of artificial cerebrospinal fluid, while ANG IV improved retention and retrieval of this task.