Crystalline Behavior of Chitosan Organic Acid Salts

The crystal structures of chitosan acid salts were studied by X-ray diffraction measurements on a fiber diagram and a new procedure to obtain an anhydrous polymorph of chitosan was found. The salts prepared by immersing a chitosan into a mixture of acid solution and isopropanol were classified into two types (Types I and II) depending on their conformation. Molecular conformation of the Type I salt retains the extended 2-fold helical structure of the original chitosan, but that of Type II salt is a twisted 2-fold helix. All the Type II salts changed to the anhydrous “Annealed” polymorph of chitosan when soaking in 75% aqueous isopropanol, but when the Type I salts were immersed in the solution, they returned to the hydrated “Tendon” polymorph which is that of the original chitosan. The strange transformation observed in Type II salt may be related to the stability of the molecular conformation of chitosan in the salt.     

Effect of Counterions on Physicochemical Properties of Prazosin Salts

This study evaluated the effect of counterions on the physicochemical properties of prazosin salts. Salt forms of prazosin, namely, mesylate, besylate, tosylate, camsylate, oxalate, and maleate, were prepared and compared with the marketed anhydrous and polyhydrate forms of prazosin hydrochloride. Physicochemical characterization was performed in the order of crystallinity, hygroscopicity, solubility, and stability to select the optimal salt(s). Permeability study in Caco-2 cell lines and in vivo bioavailability study in rat model were investigated to ascertain their biopharmaceutical advantage. All salt forms were crystalline, nonhygroscopic (except the anhydrous hydrochloride salt), and had solubility in the range of 0.2 to 1.6 mg/ml. All salts were physically and chemically stable at 40°C/75% relative humidity, but degraded in UV-visible light, except the anhydrous hydrochloride salt. Prazosin mesylate was selected as the optimal salt, as it possessed higher solubility, permeability, and bioavailability, compared to the commercial hydrochloride salts. Hydrochloride salt is reported to have poor bioavailability that is partially attributed to its low solubility and extensive common-ion effect in the gastric region. Factors like hydrophilicity of the counterion, hydration state of the salt, and melting point of the salt contribute to the physicochemical properties of the salts. This study has implications in the selection of an optimal salt form for prazosin, which is suitable for further development.     

Counterion Effect on the Energy Gap in Doped trans-Poly-acetylene (t-PA)

Doped t-PA is a well known benchmark model for studying the effect of a variety of atomic impurities on the energy gap variations in organic solids. This system is used here to study the effect of cationic and anionic impurities on the energy gap, leading to the observed phase transitions from insulator to metallic conductor behaviour displayed by this system. The model used is based on a cluster-like approach to the doped t-PA system, and the analysis is performed by focusing on the electrostatic and non-electrostatic contributions to the energy gap variations upon doping with different Lewis acids and bases at both low and high charge transfer regimes. The variations of the energy gap naturally appear to be associated with the fluctuation of the electrostatic potential induced by the host–:guest charge transfer.     

Counterion effects on transfection activity of cationic lipid emulsion

Cationic lipid emulsion systems consisting of 1,2-dioleoyl-sn-glycero-3-trimethyl-ammonium-propane (DOTAP) and plasmid DNA with various counterions in the lipid headgroups were prepared. The transfection activity of the cationic lipid emulsion systems was then investigatedin vitro andin vivo. The complex formation of plasmid DNA and lipid emulsion was affected by the counterions through charged headgroup repulsion and also by the salt concentration in the media. As such, the transfection activity of the DOTAP emulsion system can be controlled by changing the counterions.     

Counterion charge density determines the position and plasticity of RNA folding transition states

The self-assembly of RNA structure depends on the interactions of counterions with the RNA and with each other. Comparison of various polyamines showed that the tertiary structure of the Tetrahymena ribozyme is more stable when the counterions are small and highly charged. By monitoring the folding kinetics of the ribozyme as a function of polyamine concentration, we now find that the charge density of the counterions determines the positions of the folding transition states. The transition state ensemble (TSE) between U and N moves away from the native state as the counterion valence and charge density increase, as predicted by the Hammond postulate. The TSE is broader and less structured when the RNA is refolded in polyamines rather than Mg2+. That the charge density of the counterions determines the plasticity of the TSE demonstrates the importance of interactions among condensed counterions for the self-assembly of RNA structures. We propose that the major barrier to RNA folding is dominated by entropy changes when counterion charge density is low and enthalpy differences when it is high.     

Enhanced Photodegradation of PNP on Soil Surface under UV Irradiation with TiO2

Photodegradation of p-nitrophenol (PNP) on soil surface was investigated to explore the photochemical remediation of soil polluted by nitrophenols. Soil samples spiked with PNP were irradiated by UV light with and without the addition of TiO ₂ . The addition of 0.5–2 wt% TiO ₂ enhanced PNP photodegradation with approximately 1.36 times increase in apparent rate of PNP disappearance. Soil moisture, humic acid and soil pH were important factors influencing the rate of PNP photodegradation. Increase in soil moisture improved the degradation significantly, whereas humic acid reduced the degradation rate. Changes in soil pH resulted in different degradation rates, and higher degradation efficiencies were observed under alkaline condition.     

无机盐诱导鱼腥藻 595 (Anabaena sp.595)的细胞学效应

鱼腥藻595(Anabaena sp．595)在0．05mol／L钾、钠、铵的盐酸盐、硝酸盐、硫酸盐和磷酸盐的诱导下,2d后即出现显著的细胞学效应：细胞体积增大,明显液泡化;少数细胞发生横向和不均等分裂;藻丝片段化,异形胞分化率相对提高。其中,铵盐培养的藻丝细胞内出现特异的浓缩颗粒状区域。钙盐、镁盐也诱导类似细胞学变化,但作用较弱。在含0．1mol／L NaO的培养基中长期培养,细胞出现周期性分化行为,开始细胞膨大并液泡化,以后色素质重新充满细胞,液泡消失,然后细胞分裂至正常细胞大小,成为接近正常的藻丝,但接着又膨大液泡化,如此进入新的周期过程。     

The Effect of Different Salts of Sodium and Potassium on the Accumulation of Glycinebetaine in Atriplex Prostrata

Atriplex prostrata was grown for one month in nutrient solutions with NaCl, KCl, Na₂SO₄, and K₂SO₄ (at osmotic potentials of 0, –0.75, –1.00, and –1.50 MPa). Plants treated with K₂SO₄ had less glycinebetaine at –1.0 and –1.50 MPa than those treated with Na⁺ salts, probably due to the inhibitory effects of K⁺ on glycinebetaine accumulation.     

Effect of Behavior Selection on the Morphofunctional State of Pineal Gland in Norway Rats

Functional state of pineal gland in female Norway rats selected for tame and aggressive behavior was analyzed using stereometric technique. Activity of epiphysis in tame rats (the study was performed in November, during diestrus stage) was evaluated higher than in aggressive rats. Data obtained are discussed in comparison with results of selection for behavior of silver foxes.     

Effect of Oxytocin on the Emotional State and Behavior of Rats under Stress Conditions

Oxytocin, a hormone exerting controlling effects on lactation, sexual and maternal behavior, and cyclic organization of sleep and wakefulness, is capable of significantly modulating reactions of the organism to the action of stressogenic stimuli. We studied the effects of injections of synthetic oxytocin on the behavioral phenomena and emotional state of rats during realization of a proconflict test induced by “punishments” (nociceptive electrical stimuli) in the process of drinking after water deprivation. Intraperitoneal injections of oxytocin in a 4.0 μg dose resulted in shortening of the delays of coming of rats to a water dish and also in an increase in the number of drinks of water punished by electrical stimulation, as compared with the corresponding indices in control animals. After oxytocin injections, the intensity of research activity of rats in the open field, in general, increased. After realization of the proconflict test, locomotor and orientational/research activities in animals preliminarily injected with oxytocin were much more intense than those in control rats (in the latter ones, these activities were sharply suppressed). Injections of oxytocin also led to certain normalization of the emotional state; after the proconflict test, negative shifts in this state in control rats were obvious. Therefore, oxytocin appreciably increases the resistivity of the organism against stress.     

Stress Effects of Mixed Salts with Various Salinities on the Seedlings of Aneurolepidium chinense

Seedlings of Aneurolepidium chinense (Trin.) Kitag. were subjected to stress with 30 kinds of 50 to 350 mmol/L of salt mixture which were composed of NaC1, NaHCO3, Na2SO4, and Na2CO3 in various proportion. The results showed that all the responded strains, such as changes in the relative growth rate (RGR), K+ and Na+ contents, content of proline accumulation, and leave electrolyte leakage rate, were aggravated with the increasing salt concentrations and the proportion of the basic salts. The strain reaction from high pH caused by the basic salt was closely related to salinity. The high pH reaction was weaker when the salinity was lower and became progressively stronger intensely with the increasing salinity. The results indicated that there were actually two stresses, the salt and the alkaline stress in the mixed salt stress. It was reasonable to consider the total salt concentration as the strength value of salt stress and the buffer capacity as the strength value of alkaline stress. When the alkaline stress was weak, the strain effect was mainly associated with the total salt concentration, but the buffer capacity became the dominant factor effecting strain with the increasing alkaline stress.     

Effect of Nitrogen Form and Counterion on Establishment of the Rhizobium trifolii-Trifolium repens Symbiosis

The effect of level of different counterion forms of or or both, on establishment of the Rhizobium trifolii-Trifolium repens symbiosis was evaluatedin plants cultured under bacteriologically controlled conditions. Ammonium had little effect on nodule formation, and even after exhaustion there was little compensatory nodule formation. Plant growth, nodule mass and acetylene reductionactivity all declined with increasing levels of . Except for , different counterion forms had little effect on plant growth, nodule numberand mass, and acetylene reduction activity. Ammonium markedlydecreased pH, the extent being dependent upon level and counterion present. Nitrate inhibited nodulation while levels remained in excessof plant uptake. Compensatory nodulation followed exhaustionof or at lower or levels. Nodule mass and acetylene reduction activity decreased, but plant growth increased withincreasing or levels. Nitrate raised the pH of the nutrient solution by one unit orless. Different or counterion forms had little effect on the symbiosis or plant growth. Ammonium nitrate severely inhibited nodulation but on exhaustionmarked compensatory nodulation occurred. The patterns of nodulemass, acetylene reduction activity and plant growth with increasingNH₄NO₃ levels were similar to or alone. Plants provided with NH₄NO₃ or no nitrogenwere similar in only slightly decreasing pH. Key words: Ammonium, Nitrate, Ammonium nitrate, Nitrogen fixation, Rhizobium trifolii, Trifolium repens, Symbiosis establishment, Nodulation     

Photodegradation of Dialkyl 1,3-Dithiolan-2-ylidenemalonates and Some Other Pesticides on Solid Particles

On irradiation with UV light the fungicide isoprothiolane (diisopropyl 1,3-dithiolan-2-ylidenemalonate) decomposed rapidly on the silica gel surface. The degradation pathways involved dithiolane ring cleavage, ester hydrolysis, decarboxylation, heterocycles formation such as dithietane and trithiolane, and sulfur liberation. The photoproducts confirmed were oxalic acid, dithiolanylidenemalonic acid, dithiolanylideneacetic acid, 2,4-bis[bis(isopropoxycar-bonyl)methylene]-1, 3-dithietane, 3, 5-bis[bis(isopropoxy-carbonyl)methylene]-1,2,4-trithiolane and sulfur. The methyl and ethyl homologs of isoprothiolane similarly gave the corresponding photoproducts. The surface area where isoprothiolane was placed appeared to be related closely with the photolysis rate. Isoprothiolane decomposed much more rapidly on sand than on a glass plate. This surface effect was greatly depressed under nitrogen atmosphere. Similar phenomena were observed with some other pesticides, with particularly those containing sulfur atoms in the molecule.     

Effect of Acetylation of Ovalbumin on Its Adsorption Behavior at Solid/Liquid Interface

This paper reports the effect of modification of lysine residues on the adsorption of ovalbumin at alumina/water interface. It has been shown that the pH dependence of the adsorption changes on acetylation of lysine. Thus at pH 7.6 acetylated ovalbumin does not show any affinity for alumina surface although unmodified protein does. It seems that although electrostatic interactions are operative, surface unfolding of proteins and surface hydrophobicity of protein also control the adsorption of ovalbumin onto alumina.     

Conformational Behavior of Chitosan in the Acetate Salt: An X-Ray Study

A well-defined X-ray fiber pattern of chitosan acetate was obtained by immersing a tendon chitosan, prepared from a crab tendon chitin by a solid-state N-deacetylation, in an aqueous acetic acid-isopropanol solution at 110°C. This pattern was very similar to that of chitosan salts with some inorganic acids, such as HF, HCl, and H₂SO₄, in which chitosan chains form an 8/5 helix, indicating that chitosan acetate also take up this conformation. This information may give an influential clue to the chitosan conformation in the aqueous acetic acid solution, the most popular solvent for chitosan. However, after one month of storage of the chitosan acetate, the fiber pattern, the density and its IR spectrum changed to those of the anhydrous polymorph of chitosan, suggesting that the acetic acid was removed accompanied with water molecules from the crystal during storage and that the polymorph can be obtained not only by annealing chitosan, but also through the chitosan acetate.     

Role of Constitutive Behavior and Tumor-Host Mechanical Interactions in the State of Stress and Growth of Solid Tumors

Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells inhibits their proliferation rate, induces apoptosis and enhances their invasive and metastatic potential. Additionally, compression of intratumor blood vessels reduces the supply of oxygen, nutrients and drugs, affecting tumor progression and treatment. Despite the great importance of the mechanical microenvironment to the pathology of cancer, there are limited studies for the constitutive modeling and the mechanical properties of tumors and on how these parameters affect tumor growth. Also, the contribution of the host tissue to the growth and state of stress of the tumor remains unclear. To this end, we performed unconfined compression experiments in two tumor types and found that the experimental stress-strain response is better fitted to an exponential constitutive equation compared to the widely used neo-Hookean and Blatz-Ko models. Subsequently, we incorporated the constitutive equations along with the corresponding values of the mechanical properties - calculated by the fit - to a biomechanical model of tumor growth. Interestingly, we found that the evolution of stress and the growth rate of the tumor are independent from the selection of the constitutive equation, but depend strongly on the mechanical interactions with the surrounding host tissue. Particularly, model predictions - in agreement with experimental studies - suggest that the stiffness of solid tumors should exceed a critical value compared with that of the surrounding tissue in order to be able to displace the tissue and grow in size. With the use of the model, we estimated this critical value to be on the order of 1.5. Our results suggest that the direct effect of solid stress on tumor growth involves not only the inhibitory effect of stress on cancer cell proliferation and the induction of apoptosis, but also the resistance of the surrounding tissue to tumor expansion.     

大鼠侧脑室注射神经降压素对血压的作用

雄性Ｓｐｒａｇｕｅ－Ｄａｗｌｅｙ大鼠,用乌拉坦腹腔麻醉,在侧脑室注射神经降压素（ＮＴ）（１０,２０μｇ）可引起血压升高或降低,心率减慢,预先ｉｃｖ ａ１受体阻断剂哌唑嗪,可阻断ＮＴ的中枢升压反应,预先ｉｃｖ Ｍ受体阻断剂硫酸阿托品,可阻断ＮＴ的中枢降压反应,预先ｉｃｖ Ｈ１受体阻断剂扑尔敏或Ｈ２受体阻断剂甲氰咪胍,对ＮＴ的中枢心血管效应均无明显影响。实验结果表明：脑中ＮＴ升高可使血压升高或降低;在     

固态发酵的参数周期变化及对微生物发酵的影响

研究了压力脉动固态发酵反应器内环境参数的周期性变化以及这些周期性的环境刺激对于固态培养的斜卧青霉发酵的影响。研究结果显示:在这种反应器中,在空气压力脉动的带动下,反应器内的温度和空气湿度也会发生较大幅度的周期性变化,变化的周期和空气压力脉动的周期相同,变化的幅度随着压力脉动的幅度增大而增加;在外界周期刺激的条件下,较未加外界周期刺激斜卧青霉的生物量增加了104% ,二氧化碳的产生总量增加了229%和纤维素酶的产量增加了320 % ,数据显示外界周期刺激不仅增加了菌体的生物量同时增加了其代谢活性。     

Effects of Water on Enzyme Performance with an Emphasis on the Reactions in Supercritical Fluids

ABSTRACT

Enzymes require a certain level of water in their structures in order to maintain their natural conformation, allowing them to deliver their full functionality. Furthermore, as a modifier of the solvent, up to a certain level, water can modify the solvent properties such as polarity/polarizability as well as the solubility of the reactants and the products. In addition, depending on the type of the reaction, water can be a substrate (e.g., in hydrolysis) or a product (e.g., in esterolysis) of the enzymatic reaction, influencing the enzyme turnover in different ways. It is found that regardless of the type of reaction, the functionality of enzyme itself is maximum at an optimum level of water, beyond which the enzyme performance is declined due to the loss in enzyme stability. Furthermore, mass transfer limitations caused by pathway blockage and/or by reduced solubilities of the reactants and/or products can also affect the enzyme performance at higher water levels. Controlling water content of ingoing CO₂ and substrates as well as precise management of enzyme support and salt hydrates are important strategies to adjust water level in reaction media, especially in supercritical environments.