Synthesis of porous hierarchical MgO and its superb adsorption properties.

The porous hierarchical MgO with superb adsorption properties has been synthesized by a facile and scaled-up method. The X-ray powder diffraction, electron microscopy, Fourier transformed infrared, and N2 adsorption-desorption were carried out to study the microstructure of the as-synthesized precursor and product. It has been demonstrated that the as-prepared MgO has a porous hierarchical structure and a high specific surface area (148 m(2) g(-1)). And the MgO sample exhibited super adsorption properties, with maximum adsorption capacity of 2409 mg g(-1) for Congo red, which is the highest reported value. Moreover, the adsorption process of Congo red on porous hierarchical MgO was systematically investigated, which was found to obey the pseudo-second-order rate equation and Langmuir adsorption model.

Altered glucose metabolism and preserved energy charge and neuronal structures in the brain of mouse intermittently exposed to hypoxia.

The key for an animal to survive prolonged hypoxia is to avoid rapid decline in ATP levels in vital organs such as the brain. This can be well achieved by a very few of hypoxia-tolerant animals such as freshwater turtles and newborn animals, since these animals can substantially suppress their metabolic levels by coordinated regulation of ATP-producing and ATP-demanding pathways. However, most animals, especially adult mammals, can only tolerate a short period of hypoxia since they are unable to maintain constant ATP levels and energy charge in vital organs during prolonged hypoxic exposure. Here, we described a special mouse model, in which a hypoxia intolerant adult mouse gradually built up an ability to survive prolonged hypoxia after intermittent hypoxic exposures. This increased ability was accompanied by reductions in body temperature and O(2) consumption as well as transient variations in blood pCO(2), pO(2) and pH. The glucose and energy metabolism in the brain of the mouse altered similarly to those reported in the brain of hypoxic turtles. Activities of phosphofructokinase and pyruvate kinase, the two rate-limiting enzymes controlling the rate of glycolysis decreased to baseline levels after a short period of increase. In contrast, the activity of complex I, the major enzyme complex controlling oxidative phosphorylation, was kept inhibited. These alterations in the ATP-producing pathway suggest the occurrence of reverse Pasteur effect, indicating that the animal had entered a hypometabolic state favoring maintenance of ATP level and energy charge in hypoxic conditions. In supporting this idea, the ATP levels and energy charge as well as neuronal structures in the brain were well preserved. This study provides evidence for a possibility that a hypoxic intolerant animal can build up an ability to survive prolonged hypoxia through regulation of its glucose and energy metabolism after an appropriate hypoxic training, which deserves further investigation.

Dilute acid pretreatment of black spruce using continuous steam explosion system.

The pretreatment of lignocellulosic materials prior to the enzymatic hydrolysis is essential to the sugar yield and bioethanol production. Dilute acid hydrolysis of black spruce softwood chip was performed in a continuous high temperature reactor followed with steam explosion and mechanical refining. The acid-soaked wood chips were pretreated under different feeding rates (60 and 92 kg/h), cooking screw rotation speeds (7.2 and 14.4 rpm), and steam pressures (12 and 15 bar). The enzymatic hydrolysis was carried out on the acid-insoluble fraction of pretreated material. At lower feeding rate, the pretreatment at low steam pressure and short retention time favored the recovery of hemicellulose. The pretreatment at high steam pressure and longer retention time recovered less hemicellulose but improved the enzymatic accessibility. As a result, the overall sugar yields became similar no matter what levels of the retention time or steam pressure. Comparing with lower feeding rate, higher feeding rate resulted in consistently higher glucose yield in both liquid fraction after pretreatment and that released after enzymatic hydrolysis.

Hypoxic preconditioning up-regulates glucose transport activity and glucose transporter (GLUT1 and GLUT3) gene expression after acute anoxic exposure in the cultured rat hippocampal neurons and astrocytes.

Hypoxic preconditioning has been shown to increase the hypoxic tolerance of brain neurons. However, the mechanism underlying the increased hypoxic tolerance has not been well elucidated. Since anaerobic glycolysis is the only pathway for a vertebrate cell to produce energy under anoxic conditions, which needs a large amount of glucose, we hypothesize that glucose transport, the rate-limiting step for glucose metabolism, plays a critical role in the hypoxic tolerance induced by hypoxic preconditioning. In this study, the effects of hypoxic preconditioning on glucose transport activity and the gene expression of two major forms of glucose transporters (GLUT1 and GLUT3) in the brain were investigated in cultured rat hippocampal neurons and astrocytes. The neuronal and astroglial cultures were preconditioned for 6 days by intermittently exposing the cells to sublethal hypoxic gas mixture (1% O2/10% CO2/89% N2) for 20 min each day. 24 h after the last hypoxic exposure, the cells were exposed to a lethal anoxic gas mixture (10% CO2/90% N2) for 6 h and the uptake rate of [3H] 2-deoxyglucose (2-DG) and the levels of GLUT1 and GLUT3 glucose transporter mRNAs in the cells were examined immediately after anoxic exposure. The neurons and astrocytes preconditioned with hypoxia showed higher 2-DG uptake rates than the non-preconditioned cells. Compatible with the change in 2-DG uptake, hypoxic preconditioning also increased GLUT1 mRNA levels in the astrocytes and GLUT1 and GLUT3 mRNA levels in the neurons. The neurons preconditioned by hypoxia displayed increased anoxic tolerance. However, when glucose uptake in the neurons was blocked by cytochalasin B, the anoxic tolerance was almost abolished. These results suggest that glucose transport is critical to neuronal survival during anoxic exposure and the increased glucose transport activity is probably one of the important mechanisms for the enhanced hypoxic tolerance induced by hypoxic preconditioning.