The Test Engineer's Assistant: a design environment for testableand diagnosable systems

The Test Engineer's Assistant (TEA) is a set of computer-aided design (CAD) tools that helps the system design engineer meet testability requirements by construction. TEA addresses system design for testability at all levels of the design hierarchy, the lowest level being the board level. The design is represented as a graph where each node indicates a hardware component (or chip on a board) and each arc represents intercomponent connections. Attributes associated with the graph nodes and a set of rules and testing techniques that are incorporated in the tool databases are used to determine the design features that have to be incorporated into the design to meet test and diagnostic requirements. The tool operates on a design using a combination of algorithmic and heuristic techniques. The authors present the design methodology supported by TEA, discuss the techniques used by the TEA tools to obtain solutions for different design for testability requirements, and present an example of the use of TEA with a real system     

Biological hydrogen production; fundamentals and limiting processes

Biological hydrogen production has been known for over a century and research directed at applying this process to a practical means of hydrogen fuel production has been carried out for over a quarter century. The various approaches that have been proposed and investigated are reviewed and critical limiting factors identified. The low energy content of solar irradiation dictates that photosynthetic processes operate at high conversion efficiencies and places severe restrictions on photobioreactor economics. Conversion efficiencies for direct biophotolysis are below 1% and indirect biophotolysis remains to be demonstrated. Dark fermentation of biomass or wastes presents an alternative route to biological hydrogen production that has been little studied. In this case the critical factor is the amount of hydrogen that can be produced per mole of substrate. Known pathways and experimental evidence indicates that at most 2–3 mol of hydrogen can be obtained from substrates such as glucose. Process economics require that means be sought to increase these yields.     

Single stage photofermentative hydrogen production from glucose: An attractive alternative to two stage photofermentation or co-culture approaches

Photosynthetic bacteria have been extensively investigated for biohydrogen production due to their high intrinsic substrate conversion efficiency. Many studies have examined different aspects of photo fermentative hydrogen production using various volatile organic fatty acids under nitrogen limited conditions, and in some cases nearly stoichiometric hydrogen yields have been obtained. In addition, there has been great interest in using photosynthetic bacteria to increase the yields of dark fermentation of glucose through either two stage or co-culture approaches. Although these processes can achieve yields of about 7 mol of H₂ per mole of glucose, there have many drawbacks. Thus, we have begun the systematic investigation of a simple one stage system for the conversion of glucose to hydrogen through photofermentation by Rhodobacter capsulatus. Yields of about 3 mol of H₂ per moles of glucose have been obtained, which represents a yield of 25% yield. Thus improvement is needed and can be sought through a variety of means, including. process optimization and gene inactivation. These approaches could allow the development of a single stage process for the complete stoichiometric conversion of glucose, or glucose containing wastes, to hydrogen with a minimal lag phase and relative insensitivity to inhibition by fixed nitrogen. This would present an attractive simple alternative to either two stage or co-culture fermentations for the complete conversion of carbohydrate substrates to hydrogen.     

Hibernation in ground squirrels induces state and species-specific tolerance to hypoxia and aglycemia: an in vitro study in hippocampal slices

This study investigated T-cell activation markers HLA-DR and CD69 in both naive (CD45RA+) and memory (CD45RA-) CD4+ as well as CD8+ T cells in peripheral blood of patients with autoimmune thyroiditis (AT, N = 28) or hyperthyroid untreated Graves' disease (GDH, N = 34) using three-color flow cytometry. It was demonstrated that patients with AT, but not those with GDH, expressed increased amounts of HLA-DR antigen compared to healthy subjects (HS, N = 26) on total CD4+ (AT: 14.1%; GDH: 11.3%; HS: 10.9%) and CD8+ cells (AT: 31.9%; GDH: 23.5%; HS: 19.4%) as well as on CD45RA- CD4+ cells (AT: 11.2%; GDH: 7.7%; HS: 7.9%). In GDH (+71%) and AT (+91%) only the proportion of HLA-DR+ CD45RA+ CD8+ cells was increased vs HS. Furthermore, euthyroid GD patients on methimazole (GDE, N = 22) displayed greater HLA-DR+ expression on total and CD45RA- cells within both CD4+ (+37 and 40%, respectively) and CD8+ cells (+47 and 93%, respectively) than GDH. In addition, total and CD45RA+ CD4+ and CD8+ cells were increased vs HS. In contrast, proportions of CD69 positive T cells were increased in AT and GDH on total CD4+ (+97 and 74%, respectively) and CD8+ (+95 and 68%, respectively) cells and all subsets thereof (except for CD45RA- cells in GDH), but normalized upon thyrostatic treatment. We conclude that patients with autoimmune thyroid disease harbor an almost twofold greater proportion vs HS of (a) HLA-DR+ CD45RA+ CD8+ T cells, and of (b) CD69 on total CD4+ and CD8+ cells, and an even more marked elevation on their CD45RA+ subset in AT and untreated GD. In addition, (c) thyrostatic treatment by methimazole in GD is accompanied by a further increase in circulating HLA-DR+ CD4+ and CD8+ cells and their CD45RA- subsets, but decreased CD69 expression. These data suggest association of HLA-DR expression with ongoing autoimmunity, while increased CD69 expression relates in part also to elevated thyroid hormone concentration in GDH.     

Morphological characterization,growth appraisal,and probing biofuels potential of newly isolated Scenedesmus sp. from desert Cholistan

Microalgae have an excellent potential for producing valuable natural products, including biofuels. Therefore, it is imperative to explore and document the existing microalgal flora and utilize their potentials to cope the increasing human needs. The present work aims at exploring and characterizing newly isolated microalgae from desert Cholistan, a habitat with myriad algal diversity. Light microscopy, scanning electron microscopy, and molecular phylogenetic approaches were used for species‐level identification. Characterization and growth optimization of Scendesmus sp. were analyzed under three different growth modes to determine the most favorable conditions for increasing biomass, growth rate, and lipid content. The results revealed that mixotrophic (MT) mode significantly increases photosynthetic activity, growth rate, and lipid content with glycerol as supplement carbon source. The investigated Scenedesmus dimorphous produced a maximum dry weight of 1.73 g L^?1, improved fatty acid methyl esters profile and yield lipid up to 40% of DCW (68 g L^?1) under MT mode, which is almost double to that of photoautotrophic cultivation. The glycerol availability in medium has been identified as the critical element for boosting growth and lipid content. Thus, it can reduce the cost of biofuel production.     

Immunologic tolerance to myelin basic protein decreases stroke size after transient focal cerebral ischemia

Immune mechanisms contribute to cerebral ischemic injury. Therapeutic immunosuppressive options are limited due to systemic side effects. We attempted to achieve immunosuppression in the brain through oral tolerance to myelin basic protein (MBP). Lewis rats were fed low-dose bovine MBP or ovalbumin (1 mg, five times) before 3 h of middle cerebral artery occlusion (MCAO). A third group of animals was sensitized to MBP but did not survive the post-stroke period. Infarct size at 24 and 96 h after ischemia was significantly less in tolerized animals. Tolerance to MBP was confirmed in vivo by a decrease in delayed-type hypersensitivity to MBP. Systemic immune responses, characterized in vitro by spleen cell proliferation to Con A, lipopolysaccharide, and MBP, again confirmed antigen-specific immunologic tolerance. Immunohistochemistry revealed transforming growth factor beta1 production by T cells in the brains of tolerized but not control animals. Systemic transforming growth factor beta1 levels were equivalent in both groups. Corticosterone levels 24 h after surgery were elevated in all sham-operated animals and ischemic control animals but not in ischemic tolerized animals. These results demonstrate that antigen-specific modulation of the immune response decreases infarct size after focal cerebral ischemia and that sensitization to the same antigen may actually worsen outcome.     

Fermentative hydrogen production: Principles, progress, and prognosis

Dark fermentative hydrogen production is an attractive route to the renewable production of hydrogen for a number of reasons. At least in its initial employment, it would use readily available waste streams as substrate. The required reactors would probably be relatively simple in design and based on technology that is already well known and widely used. The metabolic pathways involved are well understood and are reviewed here. A large amount of research has focused on factors affecting hydrogen yields during fermentation of various pure and waste substrates by either defined bacterial cultures or natural microbial flora and some of the pertinent highlights are discussed. Finally, known fermentation pathways can deliver at most 4H₂/glucose, at best a 33% yield. Four different strategies to extract more hydrogen or energy have been proposed and are currently being investigated. The current progress in this direction is presented.     

Near stoichiometric reforming of biodiesel derived crude glycerol to hydrogen by photofermentation

Biodiesel manufacture produces crude glycerol as a major byproduct. At the scale estimated for future biodiesel production, extensive quantities of crude glycerol fraction will be generated, creating a large waste stream with potentially significant environmental impacts. The magnitude of projected future crude glycerol supplies suggests that its conversion to a biofuel is the only viable route to producing a product that does not cause market saturation. Previously it was shown that crude glycerol could be converted to hydrogen, a possible future clean energy carrier, by photofermentation using Rhodopseudomonas palustris through photofermentation. Here, the effects of nitrogen source and different concentrations of crude glycerol on this process were assessed. At 20 mM glycerol, 4 mM glutamate, 6.1 mol hydrogen/mole of crude glycerol were obtained under optimal conditions, a yield of 87% of the theoretical, and significantly higher than what was achieved previously.