酷想大晒台

哎呀呀,这个世界乱套了!大人变成了小孩,小孩变成了大人。现在,终于轮到各位小酷想家来当家做主了,快来看看他们都有什么出色的表现吧!看到爸妈变成了小孩,我立马学着他们的样子,下达了第一道命令:写作业去!我想他们一定会哭的,因为老师留的作业实在是太多了。新浪YOYO     

生物信息学中途径研究进展

叙述了生物信息学中途径的研究背景;综述了近几年来相关途径及生物化学数据库及其特点;介绍了有关的途径分析方法.同时对于途径研究应用作了展望.     

浅谈天津市行道树的应用现状与选用分析

行道树是城市园林绿化的骨干树种,美化了城市景观,促进了城市生态环境的改善。对天津市现有行道树的选择与应用进行了分析,找出了天津市行道树栽植和管理方面存在的主要问题,提出了改变天津市行道树种应用现状的对策。     

中国生物材料专利保护及其现状分析

本文叙述了我国生物材料专利制度的变迁,耐我国生物材料的专利保护范围进行了论述,对生物材料的保藏问题进行了说明;对我国生物材料保护制度进了论述,并对我国生物材料领域的专利现状进行了分析,就如何加强我国生物材料的专利保护提出几点建议。     

乌龙茶品质研究进展

综述了近年来乌龙茶品质的研究进展，介绍了乌龙茶的感官品质特征，阐述了乌龙茶的理化品质特征和相关药理作用，分析了影响乌龙茶品质的主要因素，概述了乌龙茶品质研究技术，提出乌龙茶品质下一步的研究重点方向。     

美国孟山都公司找到玉米产量翻番的新途径

2008年9月,美国孟山都（Monsanto）公司宣布已经查清了与玉米增收相关的遗传信息,找到了粮食增产的新途径。 孟山都公司从其产量最高的雌株玉米中挑选了1株,绘制出了其遗传基因的蓝图。这次研究对于将来向农户提供优质玉米种子至关重要,它采用了高通量DNA测序法．并利用了最近刚完成的玉米基因组计划所获得的数据。     

应用改进的通用荧光PCR引物进行多重STR分型

通过设计通用荧光PCR引物并结合DNA测序系统建立了小鼠的多重STR分型方案.实验针对小鼠基因组设计了两对不同的通用引物序列,标记了FAM荧光的通用序列和"加尾"的位点特异性引物共同用于小鼠的多重PCR的STR基因分型.本研究优化了通用引物和特异性引物间的比例,优化了多重STR-PCR的反应条件,并最终利用该技术方案实现了五重STR分型.实验验证了该方案在多重STR分型中的可行性.与传统的荧光检测PCR产物方案相比,应用通用方案完成多重PCR反应大大节省了实验时间与经费.     

大仓鼠( Cricetulus triton )的某些生态研究

１９８５年４月用标志重捕法观察了大仓鼠的活动范围；野外直接观察了鼠的活动及危害；室内直接观察了昼夜活动节律；在笼养状况下，观察了大仓鼠捕食黑线仓鼠和小白鼠的行为；室内观察了大仓鼠选食种子的行为。     

促进微生物实验技术创新水平的改革初探

为了加强对本科生综合素质和能力的培养 ,激发学生的学习兴趣 ,我们对微生物实验课的教学内容进行了一系列改革 ,优化了实验项目 ,节约实验成本 ,并且引入科研成果转化实验 ,同时改进了实验方法和手段 ,实验结果更为准确。这些措施蕴含了较高的理论水平 ,增加了教学信息量 ,明显提高了教学效果 ,为培养高素质人才奠定了基础。     

中华猕猴桃良种选育研究

本文扼要叙述了中华猕猴桃原产地的生态条件,分析了引入栽培园中所遇到的突出问题,提出了中华猕猴桃从高海拔山区引入低海拔丘陵平原应解决的关键技术,初步总结了在武汉风土条件下的栽培经验,简述了优株选育途径和效果,介绍了武植3号等优良品系的主要经济性状。     

在污染环境下带时滞和脉冲输入两种营养液和一种微生物模型性质的研究

提出并研究污染环境下带时滞和脉冲输入的恒化器模型,利用脉冲方程比较定理得到微生物灭绝周期解全局吸引和系统持续生存的充分条件,最后给出一个简单讨论.     

The effect of pulsed microwaves on passive electrical properties and interspike intervals of snail neurons

The effects of pulsed microwaves (2.45 GHz, 10 μs, 100 pps, SAR: 81.5 kW/kg peak, 81.5 W/kg average) on membrane input resistance and action potential (AP) interval statistics were studied in spontaneously active ganglion neurons of land snails (Helix aspersa), at strictly constant temperature (20.8±.07°C worst case). Statistical comparison with sham-irradiated neurons revealed a significant increase in the mean input resistance of neurons exposed to pulsed microwaves (P ? .05 ). Pulsed microwaves had no visible effect on mean AP firing rate; this observation was confirmed by analysis of interspike intervals (ISIs). Using an integrator model for spontaneously active neurons, we found the net input current to be more variable in neurons exposed to pulsed microwaves. The mean input current was not affected. The standard deviation of ISIs and the autocorrelation of the input current were marginally affected, but these changes were not consistent across neurons. Although the observed effects were less obvious than those reported in other studies, they represent evidence of a direct interaction between neurons and pulsed microwaves, in the absence of macroscopic temperature changes. The data do not suggest a single, specific mechanism for such interaction. © 1993 Wiley-Liss, Inc.     

Automated computation of relative flow resistance using a pulsed Doppler flowmeter

Use of a pulsed Doppler flowmeter to assess changes in blood flow resistance often requires a laborious series of calculations, and full characterization of resistance changes frequently necessitates replotting of calculated data. To facilitate the interpretation of pulsed Doppler flowmetry data, a simple, inexpensive device was constructed that computes the signal ratio of mean arterial pressure (MAP) to directional pulsed Doppler outputs. With this device, relative flow resistance can be recorded and quantitatively assessed at a glance in three vascular beds in real time. This computer-like device was designed around the Burr-Brown DIV100HP integrated circuit. C741G OpAmps provide input buffering, zeroing, and ranging adjustments enabling the user to accurately follow resistance over a very broad range of changes without exceeding the device's operating limits. A LM339 quad comparator monitors the input of each DIV100 and indicates when operating limits are exceeded via a channel-specific LED indicator and an audible alarm. No significant attenuation of the input signals occurs over the range of direct current to 50 kHz, and the output is without significant phase shift. Comparisons with calculated changes in resistance derived from the MAP and pulsed Doppler flowmetry in unanesthetized, unrestrained rats confirmed that resistance changes can be measured with precision and accuracy.     

Analysis and modeling of suspended solids from high-frequency monitoring in a stormwater treatment wetland

Tools for modeling pulsed flows and constituent fluxes in wetlands, although well developed in theory, have not been well tested in practice. High-frequency monitoring of suspended solids and flows in a stormwater treatment wetland enabled application and analysis of these tools. A dynamic flow- and volume-weighted time variable, analogous to the retention time in steady-flow systems, is one important tool tested in this study. Cross-correlations with time lags demonstrated that the dynamic time variable was a better predictive variable of pulsed events than was the standard, static time variable. Although plug-flow models are typically used for steady-flow wetlands, residence time distribution (RTD) models are indispensable for describing pulsed flows and constituent fluxes in wetlands. This study demonstrated that RTD modeling with reaction kinetics of suspended solids during storm events produces a better explanation of outflow data than possible with steady, plug-flow models. Using only input and output data, an RTD model explained sedimentation rates with less unexplained variance than the standard, plug-flow model. The results of this study underscore the importance and utility of RTD modeling for complex flows.     

Interpretation of mixed sediment profiles by means of a sediment-mixing model and radioactive fallout

Chernobyl fallout provided a pulsed release to the environment and an opportunity to study sediment mixing processes in lakes. The paper presents the application of a mathematical modelling technique using a radionuclide as tracer. The model simulates the radionuclide profiles in sediments and computes the concentrations by solving numerically a one-dimensional mass-balance equation. The mixing-advection-decay model has been designed to include time-variable input capabilities and a depth-dependent mixing coefficient.     

Thermoelastic excitation of acoustic waves in biological models exposed to high-peak-power pulsed electromagnetic radiation of extremely high frequency

We experimentally demonstrated for the first time that high-peak-power pulsed electromagnetic radiation of extremely high frequency (35.27 GHz; pulse widths, 100 and 600 ns; peak power, 20 kW) is capable of thermoelastic excitation of acoustic waves in model water-containing objects and muscle tissue of animals. The amplitude and duration of excited acoustic pulses are within the limits of accuracy of theoretical estimates and are a complex nonlinear function of electromagnetic energy input. The propagation velocities of acoustic pulses in water-gelatin models and isolated muscle tissue of animals are close to reference data. The excitation of acoustic waves in biological systems exposed to high-peak-power pulsed microwaves is an important phenomenon that makes an essential contribution to understanding the mechanisms of biological effects in these electromagnetic fields.     

Thermoelastic excitation of acoustic waves in biological models under the effect of the high peak-power pulsed electromagnetic radiation of extremely high frequency

The capability of high peak-power pulsed electromagnetic radiation of extremely high frequency (35,27 GHz, pulse widths of 100 and 600 ns, peak power of 20 kW) to excite acoustic waves in model water-containing objects and muscular tissue of animals has been experimentally shown for the first time. The amplitude and duration of excited acoustic pulses are within the limits of accuracy of theoretical assessments and have a complex nonlinear dependence on the energy input of electromagnetic radiation supplied. The velocity of propagation of acoustic pulses in water-containing models and isolated muscular tissue of animals was close to the reference data. The excitation of acoustic waves in biological systems under the action of high peak-power pulsed electromagnetic radiation of extremely high frequency is the important phenomenon, which essentially contributes to the understanding of the mechanisms of biological effects of these electromagnetic fields.     

Low and high nucleic acid content bacteria play discrepant roles in response to various carbon supply modes

Planktonic bacteria can be grouped into ‘high nucleic acid content (HNA) bacteria’ and ‘low nucleic acid content (LNA) bacteria.’ Nutrient input modes vary in environments, causing nutrient availability heterogeneity. We incubated them with equal amounts of total glucose added in a continuous/pulsed mode. The pulse-treated LNA bacteria exhibited twice the cell abundance and four times the viability of the continuous-treated LNA, while HNA did not show an adaptation to pulsed treatment. In structural equation modelling, LNA bacteria had higher path coefficients than HNA, between growth and carbon-saving metabolic pathways, intracellular ATP and the inorganic energy storage polymer, polyphosphate, indicating their low-cost growth, and flexible energy storage and utilisation. After incubation, the pulse-treated LNA bacteria contained more proteins and polysaccharides (0.00064, 0.0012 ng cell⁻¹) than the continuous-treated LNA (0.00014, 0.00014 ng cell⁻¹), conferring endurance and rapid response to pulses. Compared to LNA, HNA keystone taxa had stronger correlations with the primary glucose metabolism step, glycolysis, and occupied leading positions to explain the random forest model. They are essential to introduce glucose into the element cycling of the whole community under both treatments. Our work outlines a systematic bacterial response to carbon input.     

The effect of temporal variation in soil carbon inputs on interspecific plant competition

Aims Release of carbon from plant roots initiates a chain of reactions involving the soil microbial community and microbial predators, eventually leading to nutrient enrichment, a process known as the 'microbial loop'. However, root exudation has also been shown to stimulate nutrient immobilization, thereby reducing plant growth. Both mechanisms depend on carbon exudation, but generate two opposite soil nutrient dynamics. We suggest here that this difference might arise from temporal variation in soil carbon inputs.Methods We examined how continuous and pulsed carbon inputs affect the performance of wheat (Triticum aestivum), a fast-growing annual, while competing with sage (Salvia officinalis), a slow-growing perennial. We manipulated the temporal mode of soil carbon inputs under different soil organic matter (SOM) and nitrogen availabilities. Carbon treatment included the following two carbon input modes: (i) Continuous: a daily release of minute amounts of glucose, and (ii) Pulsed: once every 3 days, a short release of high amounts of glucose. The two carbon input modes differed only in the temporal dynamic of glucose, but not in total amount of glucose added. We predicted that pulsed carbon inputs should result in nutrient enrichment, creating favorable conditions for the wheat plants.Important findings Carbon addition caused a reduction in the sage total biomass, while increasing the total wheat biomass. In SOM-poor soil without nitrogen and in SOM-rich soil with nitrogen, wheat root allocation was higher under continuous than under pulsed carbon input. Such an allocation shift is a common response of plants to reduced nutrient availability. We thus suggest that the continuous carbon supply stimulated the proliferation of soil microorganisms, which in turn competed with the plants over available soil nutrients. The fact that bacterial abundance was at its peak under this carbon input mode support this assertion. Multivariate analyses indicated that besides the above described changes in plant biomasses and bacterial abundances, carbon supply led to an accumulation of organic matter, reduction in NO 3 levels and increased levels of NH 4 in the soil. The overall difference between the two carbon input modes resulted primarily from the lower total wheat biomass, and lower levels of NO 3 and soil PH characterizing pots submitted to carbon pulses, compared to those subjected to continuous carbon supply. Carbon supply, in general, and carbon input mode, in particular, can lead to belowground chain reactions cascading up to affect plant performance.     

Temporal and spatial patterns of organic carbon are linked to egg deposition by beach spawning horseshoe crabs (<Emphasis Type="Italic">Limulus polyphemus</Emphasis>)

The spring spawning by the American horseshoe crab (Limulus polyphemus L.) results in temporally and spatially discrete inputs of eggs onto sandy beaches in Delaware Bay, USA. We tested the hypothesis that seasonal patterns of sediment organic carbon on Delaware Bay beaches is linked to this pulsed input of horseshoe crab eggs. At a location with minimal horseshoe crab spawning activity (Higbee Beach), there was little seasonal variation in sediment organic carbon, no distinction between organic carbon levels as a function of shoreline position or sediment depth, and no significant correlation between the abundance of crab eggs and percent organic carbon. Conversely, at a prime horseshoe crab spawning habitat (North Beach), organic carbon levels were seasonally pulsed and were correlated with egg abundance. Moreover, the strongest evidence of seasonality was seen at the middle foreshore location at the 15–20 cm depth, consistent with the highest input of horseshoe crab eggs. Although some of the organic carbon contributed by horseshoe crab eggs in May–June leaves the beach in the form of hatched larvae later in the year, there is a net input of organic carbon to the system in the form of unfertilized and/or dead eggs, egg membranes, and embryonic molts. We suggest that the inputs of eggs from horseshoe crabs and other beach spawning animals, such as grunion and capelin, make significant contributions to the energy budget of sandy beaches.