Relationship between the hydrophobic and hydrophilic molecular parameters of some synthetic nucleosides, determined by means of adsorptive and reversed-phase thin-layer chromatography

The adsorption capacity, the specific adsorptive surface, the lipophilicity and the specific hydrophobic surface of 59 natural and synthetic nucleoside derivatives were determined by means of adsorptive chromatography and reversed-phase thin-layer chromatography for the future application of these molecular parameters in quantitative structure-activity relationship studies. Stepwise regression analysis and principal component analysis proved that each of the physico-chemical parameters has a different information content, and their application in the design of new bioactive derivatives is therefore justified.     

石墨烯及其衍生物氧化石墨烯作为新型药物载体材料在肿瘤治疗领域的应用研究

石墨烯及其衍生物氧化石墨烯因具有水溶性好、比表面积大、载药量高以及易于修饰等优势,近年来在生物医药领域尤其在肿瘤治 疗领域的应用研究发展迅速。综述石墨烯及氧化石墨烯作为新型药物载体材料所具有的特性和生物安全性、表面修饰方式以及在肿瘤靶向 递药系统中的应用,为其在生物医药领域的应用研究提供新方法和新思路。     

Effect of salt concentration and pH on the hydrophobicity parameters of surfactants studied by TLC and spectral mapping technique

The lipophilicity and specific hydrophobic area of 56 surfactants having different hydrophobic moiety and different length of ethylene oxide chain were determined by reversed-phase thin-layer chromatography and the strength and selectivity of the effect of sodium chloride and pH on the hydrophobicity parameters was elucidated using spectral mapping technique followed by two-dimensional nonlinear mapping. In each instance significant linear correlations were found between the lipophilicity and specific hydrophobic surface area of surfactants suggesting that from a chromatographic point of view they behave as a homologous series of solutes. It was established that the strength of the effect of both salt concentration and pH is relatively low and the selectivity of their influence on the hydrophobicity parameters is markedly different.     

Production of lyophilized culture ofLactobacillus acidophilus with preserving cell viability

Optimal lyophilization process was developed for manufacturing the dried product ofLactobacillus acidophilus with high cell viability. Three major factors, freezing rate, specific surface area of samples, and stabilizer type and their synergy were shown to play a crucial role in the development of an effective lyophilization process. Finally we found an optimal combination among three process parameters mentioned above: an exceptionally high cell survival percentage of 90% was achieved using the 8.28 cm⁻¹ specific surface area of samples, slow freezing rate, and a stabilizer composition of 4% skim milk+1% glycerol +0.1% calcium chloride.     

Relation between morphologic reactive rearrangement of neuronal elements and their specific surface

A great vuendorability of thin terminal neural processes as compared to thick fibers or neural cell bodies has been proved. This phenomenon does not depend on whether this very structure is pre- or postsynaptic. It is not connected with distance of the structures from the nucleus-containing area, and is, evidently, stipulated by their geometrical parameters, in particular, by their specific surface (dispersivity). By means of mathematical models it is demonstrated that geometry of the terminal fibrillae contributes to most rapid diffusion through neurolemma and saturation of their neuroplasm with toxic agents. Thus, indissoluble connection between the structure and some functional processes in the neuron at its reactive rearrangement is demonstrated.     

Biomonitoring of urban habitat quality by anatomical and chemical leaf characteristics

This study focused on the potential of specific leaf area, stomatal density and stomatal pore surface as easy-to-measure plant parameters in low cost biomonitoring of urban habitat quality with a high spatial resolution. The study area (81.5 km²) was the city of Gent, Belgium. In the study area 148 sampling locations were identified within 4 land use classes. Specific leaf area, stomatal density, stomatal pore surface, minimal stomatal resistance, chlorophyll a and b, C and N content, δ¹³C and δ¹⁵N in the leaf samples of a common herbaceous plant Taraxacum officinalis were measured. The stomatal pore surface and minimal stomatal resistance of T. officinalis varied significantly between land use classes. In the harbor and industry land use class and the urban land use class a 27% and 21% lower mean stomatal pore surface at the abaxial leaf surface, and a 29% and 27% lower mean stomatal pore surface at the adaxial leaf surface was observed compared to that in the pasture land use class. The minimal stomatal resistance at the abaxial leaf surface was significantly higher in the urban land use class and harbor and industry land use class by 28% and 29%, respectively compared to that in the pasture land use class. In addition, urbanized and industrial land use classes as the harbour and industry and the urban land use classes showed significantly lower δ¹³C values compared to pasture land use class. The specific leaf area, stomatal parameters and δ¹³C data were geostatistically analyzed to understand their spatial variation. The spatial distributions of stomatal pore surface and minimal stomatal resistance varied considerably across the study area, indicating a different habitat quality from the harbour area in the north, over the city centre in the middle and the industrial areas in the south, compared to off city areas. Spatial patterns of δ¹³C showed depleted δ¹³C levels in city areas indicating the diluted δ¹³C in the urban atmosphere by fuel combustion. We concluded that stomatal characteristics seem to be the most promising parameter for estimating urban habitat quality.     

Comparison of leaf morphology among submersed species of Myriophyllum (Haloragaceae) from different habitats and geographical distributions

An image analysis system was used to calculate the surface area and volume of the submerged leaves of seven species of Myriophyllum. We separated the species into two categories based on their distribution and habitat differences and compared their surface area, volume, dry mass, specific leaf area, and surface to volume ratios. The geographic location and habitat of the species explained the greatest percentage of total variance for these variables when compared by analysis of variance. A leaf shape analysis was performed by regressing surface area with volume for each species. Interspecific comparisons of leaf shape were made using analysis of covariance. Fundamental interspecific differences in submerged leaf shape, associated with differences in their geographic distributions and habitats, are explained as adaptations for different nutrient uptake regimes.     

Adsorption of cellulase on cellulose: Effect of physicochemical properties of cellulose on adsorption and rate of hydrolysis

In the cellulase-cellulose reaction system, the adsorption of cellulase on the solid cellulose substrate was found to be one of the important parameters that govern the enzymatic hydrolysis rate of cellulose. The adsorption of cellulase usually parallels the rate of hydrolysis of cellulose. The affinity for cellulase varies depending on the structural properties of cellulose. Adsorption parameters such as the half-saturation constant, the maximum adsorption constant, and the distribution coefficient for both the cellulase and cellulsoe have been experimentally determined for several substrates. These adsorption parameters vary with the source of cellulose and the pretreatment methods and are correlated with the crystallinity and the specific surface area of cellulose substrates. The changing pattern of adsorption profile of cellulase during the hydrolysis reaction has also been elucidated. For practical utilization of cellulosic materials, the cellulose structural properties and their effects on cellulase adsorption, and the rate of hydrolysis must be taken into consideration.     

Surface kinetic test method for determining rate of kill by an antimicrobial solid.

An antimicrobial-surface kinetic test which maximizes probability of cell-to-surface contact has been developed. The measurement of rate of kill by a nonleaching antimicrobial surface is based on the number of surviving bacterial cells at specific times of exposure to various amounts of total treated surface area of test substrate. This method gives information for direct comparison of rate of kill for a variety of antimicrobial surfaces in terms of rate of kill per square centimeter of surface area. Data obtained by this method can also give valuable dose response application information as an indication of the exponential efficiency of concentration in terms of treated surface area.     

Surface kinetic test method for determining rate of kill by an antimicrobial solid.

An antimicrobial-surface kinetic test which maximizes probability of cell-to-surface contact has been developed. The measurement of rate of kill by a nonleaching antimicrobial surface is based on the number of surviving bacterial cells at specific times of exposure to various amounts of total treated surface area of test substrate. This method gives information for direct comparison of rate of kill for a variety of antimicrobial surfaces in terms of rate of kill per square centimeter of surface area. Data obtained by this method can also give valuable dose response application information as an indication of the exponential efficiency of concentration in terms of treated surface area.     

Evaluation of Sample Recovery Efficiency for Bacteriophage P22 on Fomites

Fomites are known to play a role in the transmission of pathogens. Quantitative analysis of the parameters that affect sample recovery efficiency (SRE) at the limit of detection of viruses on fomites will aid in improving quantitative microbial risk assessment (QMRA) and infection control. The variability in SRE as a function of fomite type, fomite surface area, sampling time, application media, relative humidity (rH), and wetting agent was evaluated. To quantify the SRE, bacteriophage P22 was applied onto fomites at average surface densities of 0.4 ± 0.2 and 4 ± 2 PFU/cm². Surface areas of 100 and 1,000 cm² of nonporous fomites found in indoor environments (acrylic, galvanized steel, and laminate) were evaluated with premoistened antistatic wipes. The parameters with the most effects on the SRE were sampling time, fomite surface area, wetting agent, and rH. At time zero (the initial application of bacteriophage P22), the SRE for the 1,000-cm² fomite surface area was, on average, 40% lower than that for the 100-cm² fomite surface area. For both fomite surface areas, the application medium Trypticase soy broth (TSB) and/or the laminate fomite predominantly resulted in a higher SRE. After the applied samples dried on the fomites (20 min), the average SRE was less than 3%. A TSB wetting agent applied on the fomite improved the SRE for all samples at 20 min. In addition, an rH greater than 28% generally resulted in a higher SRE than an rH less than 28%. The parameters impacting SRE at the limit of detection have the potential to enhance sampling strategies and data collection for QMRA models.     

The effect of sulfur supply on the root characteristics of subterranean clover and annual ryegrass

Summary The root characteristics and sulfur absorption of Trikkala sub-clover and Wimmera ryegrass were compared in a pot experiment in which plants were grown at two levels of sulfur supply (0 and 64 mgS/pot) for a period of 40 days after emergence.Ryegrass roots had a greater weight and root weight ratio, but a lower sulfur content than sub-clover roots at both levels of sulfur supply. Ryegrass roots were longer, had a greater length per unit weight, longer root hairs, and hence a larger volume and surface area than sub-clover roots. However, when the sulfur content in the whole plant was related to the root parameters, sub-clover absorbed a far greater amount of sulfur, irrespective of whether the content was expressed on the basis of the weight, length, volume or surface area of the roots.Sulfur application had relatively little effect on the morphology of roots of either species. However, whilst sulfur application increased the weight of both shoots and roots, it decreased the root weight ratio for sub-clover but not for ryegrass. Increasing sulfur supply reduced the total length of sub-clover roots but tended to increase the length of ryegrass roots. For both species, the length per unit weight of roots decreased, and the average root diameter increased, with increasing sulfur supply. Sulfur application decreased the volume and surface area of sub-clover roots, but increased these parameters in ryegrass roots.     

喀斯特峰丛洼地不同植被恢复阶段细根生物量、形态特征及其影响因素

以喀斯特峰丛洼地不同植被恢复阶段的草丛、灌丛、次生林和原生林为研究对象,采用土芯法,分0~10、10~20、20~30 cm等3层获取群落活细根(直径≤2 mm),分析其生物量、形态特征及其与土壤性状的关系.结果表明:各恢复阶段细根生物量为194.63~255.19g·m^-2,集中分布在0~10 cm表层土壤中,占0~30 cm土层总生物量60%以上,不同恢复阶段群落生物量的差异不显著;细根比根长和比表面积在不同恢复阶段差异显著,随着植被由草丛向原生林正向恢复而逐渐降低;超过66%的根长和64%的根面积分布在0~10 cm表层土壤中,多数细根根长和根面积均在0~0.5 mm和0.5~1 mm径级,这两级根长和根面积占其总量的87%和72%以上.冗余分析表明,喀斯特峰丛洼地植物群落细根特征与土壤性状之间存在着不同的相关性,其中土壤有机碳、速效钾和全氮对细根特征影响较大.这是植物长期适应生境条件形成的有效策略.     

A Model for the Biofiltration of Butyl Acetate and Xylene Mixtures by a Trickle‐Bed Air Biofilter

A mathematical model that incorporates the rates of the mass transfer process and the biofilm reaction is presented to predict the performance of a trickle‐bed air biofilter (TBAB) for treating butyl acetate and xylene mixtures. A thorough understanding of the factors that influence these rates is necessary before the practical application of a TBAB for treating many kinds of pure and mixed volatile organic compounds (VOC) in the air stream. The model presented consists of a set of mass balance equations for butyl acetate, xylene and oxygen in the bulk gas phase and within the biofilm. The butyl acetate and xylene concentration profiles of the gas phase predicted by the model were in good agreement with the measured data documented in a previous study. The most relevant parameters were evaluated in a sensitivity analysis to determine their respective effects on the model performance. Four parameters were identified to strongly influence the model performance, the surface area of the biofilm per volume unit of the packing material (A_S), the empty‐bed residence time (EBRT), the maximum specific growth rate of the microorganism (μ_m), and the microbial yield coefficient (Y). The practical application of the model to derive the performance equation is also presented and discussed. This equation makes it possible to simultaneously obtain a relatively high VOC removal efficiency and to minimize the capital cost.     

A comparative study of the effect of refining on physical and electrokinetic properties of various cellulosic fibres

The aim of this work was to study the influence of refining on various pulp properties such as freeness, specific surface area, specific volume, surface charge, total charge and elastic modulus. The results indicated that specific surface area of the pulps increased with increased refining, and at the same freeness level the pine pulp exhibited higher surface charge, surface area, and specific volume than the eucalyptus pulps. Also, the eucalypt pulps were much easier to beat than the pine pulps. The total fibre charge, as determined by conductometric titrations, was not affected by refining. However, the surface charge, as determined by titrations with poly-DADMAC, increased with refining. Increasing the specific surface area by refining resulted in a higher fibre surface charge and better fibre-fibre bonding. The change of the fibre surface charge during refining could be monitored using the FTIR characteristic bands within 1700-1300cm(-1).     

A model for treating toluene and acetone mixtures by a trickle-bed air biofilter

A mathematical model that incorporates mass transfer process and biofilm reactions is presented to predict the performance of a trickle-bed air biofilter (TBAB) for treating toluene (T) and acetone (ACE) mixtures. The model consists of a set of mass balance equations for T, ACE and oxygen in the bulk gas phase and within the biofilm. The gas phase T and ACE concentrations predicted by the model were in good agreement with the measured data available in a previous study. The important parameters were evaluated in the sensitivity analysis to determine their respective effects on the model performance. Four parameters were identified as strongly influencing the model performance, the surface area of the biofilm per unit volume of packing material (A _S), the empty-bed residence time (EBRT), the maximum specific growth rate of microorganism ( _m), and the microbial yield coefficient (Y). A practical application of the model to derive the performance equation of TBAB is also given.     

Decoupled drought responses of fine-root versus leaf acquisitive traits among six Prunus hybrids

要预测干旱对森林和果树种植的影响，就需要更好地了解干旱胁迫对叶片和细根的资源获取性状(比叶面积SLA、比根面积SRA以及比根长SRL)的影响。本研究试图验证以下科学假设：在重度干旱胁迫下，叶片与细根的资源获取性状具有协同效应，使得植物能够采取整合的资源节约策略。我们收集了不同干旱敏感性的六种李属砧木的幼树，通过在温室中对它们进行干旱试验来验证我们的科学假设。这些幼树被分为两组进行水分处理试验，即对照处理组(浇水量为100%田间持水量)与重度干旱处理组(每种砧木的浇水量为该砧木对照组植物每日蒸散量的33%)。在处理开始后的第30天和第60天，分别对两组处理下的六种砧木的植物叶片与细根进行取样。结果表明，在重度干旱胁迫下，没有任何一种植物同时显著降低了SLA和SRA(或SRL)。六种李属砧木植物的细根性状表现出两种主要的干旱响应组合：(1)根组织密度(RTD)增大，同时平均根径减小，而SRL没有显著变化；(2) RTD增大，同时SRL减小，而平均根径没有显著变化。六种砧木植物性状的干旱响应展现出两个相互垂直的变化梯度，这两个梯度均以从对照处理组到干旱处理组植物的资源节约性变化为特征，其中一个梯度展现了叶片气体交换，SRA，SRL以及RTD的干旱响应之间的密切相关关系，而另一个梯度以SLA的降低为特征。这些发现突出了(1)根系性状干旱响应的多维性；(2)重度干旱胁迫下，叶片经济性状与叶片水力性状之间的解耦联关系；(3)重度干旱胁迫下，叶片水力性状与根系水力性状之间的协同变化关系。这项研究有助于在种内尺度上确认根系干旱响应多维性的起源，并重点突出了不同植物如何通过不同的叶片与细根性状的干旱响应组合而得以在重度干旱胁迫下存活。     

山东银莲花叶片形态结构对异质生境和海拔变化的响应

山东银莲花为一分布极其狭域的稀有物种,对海拔600 m以上的针阔混交林和山顶灌丛两种异质的生境都具有较高的适应性。为探索其适应策略,选择两种异质生境中的5个海拔梯度样带,采用常规石蜡切片法和显微观察技术,对叶片进行观察、分析和测量,通过比较叶片外部形态特征参数和内部解剖结构的差异,推测其叶片适应海拔和异质生境的响应策略。结果表明:为适应阴暗、潮湿的针阔混交林和干旱、强光照的山顶灌丛两种不同环境,山东银莲花分别表现出不同的适应策略。针阔混交林下,叶片的背腹表皮毛密度、比叶面积和气孔相对开度较山顶灌丛的大,而气孔密度、叶片厚度、栅栏组织和海绵组织的厚度较山顶灌丛的小;山顶灌丛植株叶片栅栏组织细胞排列较林下更加整齐紧密。两种生境中叶片腹面表皮毛的长度、气孔相对开度都随海拔的升高而减小,且差异明显;而叶片厚度、比叶面积、气孔指数等对600 m以上海拔变化未表现出明显的规律性。本研究将为山东银莲花的保护和利用提供理论基础及依据,为其他植物的相关研究提供参考。     

Determination of hydrophobicity of non-homologous series of anticancer drugs by reversed-phase high-performance liquid chromatography

The hydrophobiciy and specific hydrophobic surface area of 21 commercial anticancer drugs were determined by reversed-phase high-performance liquid chromatography on an octadecyl-silica column using methanol-water mixtures as eluents. Linear correlations were calculated between the log k′ values and the methanol concentration of the eluent, the intercept and slope were considered as the best estimation of the hydrophobicity and specific hydrophobic surface area. The relationship between retention characteristics and physicochemical parameters of drugs was evaluated by multivariate mathematical statistical methods, such as principal component analysis followed by two-dimensional non-linear mapping, varimax rotation and by cluster analysis. Anticancer drugs can be well separated by reversed-phase HPLC. Various multivariate mathematical statistical calculations indicate that the retention of the investigated drugs is mainly governed by hydrophobic and steric parameters. The results suggest that the use of principal component analysis followed by two-dimensional non-linear mapping is superior to cluster analysis for the evaluation of large retention data matrices.