Effect of vibration on the structure and properties of polymer membranes

The structural memory effect in a wave field has been studied by IR spectroscopy using butadiene-styrene and acrylic latex blend films as polymer membrane models. Notable is the enhancement of interactions between phases in such systems, which can cause changes in their local and translational mobility. The response of disperse polymer systems and their composites to nonlinear vibrations means that their deformation properties are affected by vibration, by analogy with orientation phenomena in solid polymers (where the Rebinder effect can appear), and can be considered as a means for modifying polymers, including the manufacture of nanocomposites, polymer biocarriers, etc.     

Natural rubber latex protein reduction with an emphasis on enzyme treatment

Natural rubber latex (NRL), derived from the Hevea brasiliensis tree, is a material used to manufacture products in health care, including medical gloves. Proteins are a naturally occurring component of NRL. These proteins, which can be present on the surface of NRL gloves, have been related to hypersensitivity reactions in some humans who come into contact with them. These same proteins also help to maintain the latex colloidal stability during collection and transport prior to manufacture. Consequently, when measures are taken to remove or degrade these proteins, other problems can be introduced, such as destabilization of the latex and changes in its coagulation properties. Practical methods are available to reduce the extractable antigenic protein content of NRL products. We describe here methods of reducing proteins in commercial-grade NRL and finished products. NRL gloves manufactured with adequate leaching can produce products with lower levels of extractable antigenic proteins. Emphasis is given here to enzyme treatment of NRL, as this process is very effective in reducing antigenic proteins in NRL. While this technology adds marginally to the production cost of standard grades of NRL, it is still quite cost-effective when compared with postwashing NRL products or the use of synthetic latex. Moreover, enzyme-treated NRL maintains the excellent physical properties and performance of NRL.     

Influence of polymer addition on biogenic sulfuric acid attack of concrete

A simple and reproducible microbiological simulation procedure in combination with a chemical procedure was used to test concrete for its potential resistance towards biogenic sulfuric acid. Concerning fundamental aspects of the corrosion reaction, it was shown that particularly the penetration of H₂S inside the concrete crevices accelerated the corrosion process. The influence of different polymer types and silica fume additions on the resistance of the concrete samples was determined. The addition of the styrene acrylic ester polymer resulted in an increased resistance while the addition of the acrylic polymer or silica fume caused less resistant concrete. For the vinylcopolymer and the styrene butadiene polymer, no significant effect was observed on the resistance of the concrete samples. The results of the two different test methods confirmed the difference between corrosion due to purely chemical sulfuric acid and corrosion due to microbiologically produced sulfuric acid.     

Effect of vibration on the structure and properties of polymer membranes

The influence of vibration (nonlinear wave effects) on the properties of films based on mixtures of some butadiene-styrene and acrylic latex by infrared spectroscopy was investigated. An enhancement of interactions in heterogenous systems was found, which may cause changes in their local and translation mobility.     

Improved reactor performance and operability in the biotransformation of carveol to carvone using a solid-liquid two-phase partitioning bioreactor

In an effort to improve reactor performance and process operability, the microbial biotransformation of (-)-trans-carveol to (R)-(-)-carvone by hydrophobic Rhodococcus erythropolis DCL14 was carried out in a two phase partitioning bioreactor (TPPB) with solid polymer beads acting as the partitioning phase. Previous work had demonstrated that the substrate and product become inhibitory to the organism at elevated aqueous concentrations and the use of an immiscible second phase in the bioreactor was intended to provide a reservoir for substrates to be delivered to the aqueous phase based on the metabolic rate of the cells, while also acting as a sink to uptake the product as it is produced. The biotransformation was previously undertaken in a two liquid phase TPPB with 1-dodecene and with silicone oil as the immiscible second phase and, although improvement in the reactor performance was obtained relative to a single phase system, the hydrophobic nature of the organism caused the formation of severe emulsions leading to significant operational challenges. In the present work, eight types of polymer beads were screened for their suitability for use in a solid-liquid TPPB for this biotransformation. The use of selected solid polymer beads as the second phase completely prevented emulsion formation and therefore improved overall operability of the reactor. Three modes of solid-liquid TPPB operation were considered: the use of a single polymer bead type (styrene/butadiene copolymer) in the reactor, the use of a mixture of polymer beads in the reactor (styrene/butadiene copolymer plus Hytrel(R) 8206), and the use of one type of polymer beads in the reactor (styrene/butadiene copolymer), and another bead type (Hytrel(R) 8206) in an external column through which fermentation medium was recirculated. This last configuration achieved the best reactor performance with 7 times more substrate being added throughout the biotransformation relative to a single aqueous phase benchmark reactor and 2.7 times more substrate being added relative to the best two liquid TPPB case. Carvone was quantitatively recovered from the polymer beads via single stage extraction into methanol, allowing for bead re-use.     

柑橘用植物生长调节剂的登记与安全施用

为了加强植物生长调节剂在柑橘生产上的安全使用,对其登记信息现状的全面了解是非常有必要的.鉴于此,本文检索了目前在中国农药信息网上登记的产品,并对有效期内可用于柑橘生产的植物生长调节剂的种类、剂型与功效进行科学统计和分析,进一步提出安全施用建议及展望.结果表明,当前所登记的柑橘植物生长调节剂产品总共有75个,有效成分主要以单剂为主,产品有65个,占86.67%;剂型有12类,以可溶液剂和乳油为主,占46.7%;功效主要包含调节生长、增产、催熟、控梢、矮化、杀虫、促进生长、抗逆等作用.该结果为植物生长调节剂产业健康发展与柑橘的绿色生产提供参考.     

The Antibacterial Activity of a Series of Quaternaries Prepared from Hexamethylenetetramine and Halohydrocarbons

A series of quaternaries prepared from hexamethylenetetramine and halohydrocarbons are shown to possess antimicrobial activity which depends upon the slow release of formaldehyde over a wide pH range. The rate of release appears to depend upon the halohydrocarbon moiety to a large extent. Toxicological studies show that these products can be used safely as industrial preservatives for aqueous emulsions such as soluble oils and latex systems.     

Plant biostimulants: a review on the processing of macroalgae and use of extracts for crop management to reduce abiotic and biotic stresses

A biostimulant is an organic material that, when applied in small quantities, enhances plant growth and development such that the response cannot be attributed to the application of traditional plant nutrients. This review is aimed at highlighting developments in the processing of macroalgae for agricultural biostimulants (AB), summarising the biologically active components of brown macroalgae and examining the factors supporting the use of macroalgal AB for managing abiotic and biotic stresses in crop plants. The policy drivers supporting the use of macroalgal-derived ABs in agriculture are also emphasised. We examine the use of macroalgal ABs in crop production and evaluated the benefits of seed priming, foliar application, soil drenches and hydroponic treatments. The use of macroalgal ABs on crop plants can generate multiple benefits with reported effects including enhanced rooting, higher crop and fruit yields, freezing, drought and salt tolerance, enhanced photosynthetic activity and resistance to fungi, bacteria and virus. ABs can be applied as an alternative, or used in conjunction with synthetic crop protection products and plant growth regulators, and may have a role in maintaining crop production levels, health and quality in the future when many active ingredients will be lost to the industry due to changes in European Union regulations. Worldwide, macroalgae remain largely unexploited, we highlight some of the future research and development priorities.     

Emulsifying properties of a glycoprotein extract produced by a marine Flexibacter species strain TG382

We report, for the first time, on the production of an emulsifying polymer produced by a Flexibacter species (designated strain TG382). This polymer, E-382, was produced extracellularly during growth of the organism in a marine broth amended with glucose. After cold ethanol precipitation, extensive dialysis and lyophilization, a chemical analysis of the resultant dried polymer revealed it to be a glycoprotein composed of 10.9% protein, 23.3% carbohydrate and a 5.5% uronic acid content. At relatively low concentrations (0.02%, w/v), E-382 was found to form oil-in-water emulsions against hydrocarbon and food oils under neutral pH and acidic conditions. The most stable emulsions were formed against the oils sunflower, vegetable and ground nut under neutral pH conditions. Aqueous solutions of the polymer were viscous, and its reduced viscosity (η_red) was determined to be 0.54 m³/kg. Although proteins and uronic acids may possess surface-active properties, the viscosifying effect of this polymer, which is a typical feature of some commercial hydrocolloids, is more likely to confer its high emulsion-stabilizing qualities.     

Enzymatic decontamination of aqueous polymer emulsions containing acrylonitrile

Residual acrylonitrile monomer was quantitatively removed from aqueous polymer emulsions (latexes) of nitrilic rubbers by means of whole cells and cellular lysates of Brevibacterium imperiale and Corynebacterium nitrilophilus. A commercially-available immobilized nitrilase preparation allowed the conversion of acrylonitrile into acrylic acid and the recycle of the catalyst with retention of the reaction efficiency.     

The effects of parenteral lipid emulsions on cancer and normal human colon epithelial cells in vitro

Differences in lipid metabolism of tumor and normal tissues suggest a distinct response to available lipid compounds. In this study, the in vitro effects of five types of commercial parenteral lipid emulsions were investigated on human cell lines derived from normal fetal colon (FHC) or colon adenocarcinoma (HT-29). Changes of the cellular lipid fatty acid content, cell oxidative response, and the cell growth and death rates were evaluated after 48 h. No effects of any type of emulsions were detected on cell proliferation and viability. Compared to the controls, supplementation with lipid emulsions resulted in a multiple increase of linoleic and linolenic acids in total cell lipids, but the content of arachidonic, eicosapentaenoic, and docosahexaenoic acids decreased particularly in HT-29 cells. The concentration of emulsions which did not affected HT-29 cells increased the percentage of floating and subG0/G1 FHC cells probably due to their higher reactive oxygen species production and lipid peroxidation. Co-treatment of cells with antioxidant Trolox reduced the observed effects. Our results imply that lipid emulsions can differently affect the response of colon cells of distinct origin.     

Gene suppression in a tolerant tomato–vascular pathogen interaction

A plant can respond to the threat of a pathogen through resistance defenses or through tolerance. Resistance has been widely studied in many host pathogen systems but little is known about genetic changes which underlie a tolerant interaction. A recently developed model system for a tolerant tomato (Lycopersicon esculentum Mill) interaction with a fungal wilt pathogen, Verticillium dahliae Kleb, is examined with respect to changes in gene expression and compared to a susceptible infection. The results indicate that genetic changes can be dramatically different and some genes that are strongly elevated in the susceptible interaction are actually down-regulated in tolerance. Similar levels of fungal DNA and an up-regulation of many pathogenesis related genes indicate that in both types of interaction the presence of fungus is clearly recognized by the plant but other changes correlate with the absence of symptoms in the tolerant interaction. For example, a gene encoding a known 14-3-3 regulatory protein and a number of genes normally affected by this protein are down-regulated. Furthermore, genes which may contribute to foliar necrosis and cell death in the susceptible interaction also appear to be suppressed in the tolerant interaction, raising the possibility that the wilt symptoms, chlorosis and necrosis which are observed in the susceptible interaction, are actually programmed to further limit the growth of the fungal pathogen, and protect the general tomato population.     

The biological safety of condom material can be determined using an in vitro cell culture system.

Latex products have long been recognized as a cause of latex protein allergy. The increased usage of latex gloves, with the consequent increased occurrence of latex allergies appears to have escalated with increasing awareness of the transmission of HIV-AIDS and other infections. The use of condoms as a means to prevent the transmission of STD's (sexually transmitted diseases) and HIV-AIDS has been widely promoted. Although extensive testing is done to evaluate the physical quality of condoms, no information is available regarding the biological safety of condoms. This study was undertaken to determine the effects of short-term exposure to physiological levels of condom surface material on cell viability (MTT assay) and cell growth (crystal violet assay). A direct contact cell culture testing method (FDA test method F813-83 used to evaluate the cytotoxic potential of medical materials and devices) was used. The modified test method was found to be a sensitive test system for the evaluation of the biological safety of condoms. This study reveals the importance of evaluating the biological safety of all condoms that are commercially available, because of the potential health risk that may be associated with prolonged use of certain types of condoms.     

Hormones and cancer in humans

Hormones play a major role in the aetiology of several of the commonest cancers worldwide, including cancers of the endometrium, breast and ovary in women and cancer of the prostate in men. It is likely that the main mechanisms by which hormones affect cancer risk are by controlling the rate of cell division, the differentiation of cells and the number of susceptible cells. Hormones have very marked effects on cell division in the endometrium; oestrogens stimulate mitosis whereas progestins oppose this effect. The risk for endometrial cancer increases with late menopause, oestrogen replacement therapy and obesity, and decreases with parity and oral contraceptive use; thus risk increases in proportion to the duration of exposure to oestrogens unopposed by progestins, probably because unopposed oestrogens stimulate endometrial cell division. The effects of hormones on breast epithelial cell division in non-pregnant women are much less clear-cut than their effects on the endometrium, but both oestrogens and progestins appear to stimulate mitosis. Breast cancer risk increases with early menarche, late menopause and oestrogen replacement therapy, probably due to increased exposure of the breasts to oestrogen and/or progesterone. Early first pregnancy and multiparity reduce the risk for breast cancer, probably due to the hormonally-induced differentiation of breast cells and the corresponding reduction in the number of susceptible cells. Hormones do not have marked direct effects on the epithelial cells covering the ovaries, but hormones stimulate ovulation which is followed by cell division during repair of the epithelium. Risk for ovarian cancer increases with late menopause and decreases with parity and oral contraceptive use, suggesting that the lifetime number of ovulations may be a determinant of risk. For all three of these cancers risk changes within a few years of changes in exposure to sex hormones and some of the changes in risk persist for many years, indicating that hormones can affect both early and late stages of carcinogenesis. Understanding of the role of sex hormones in the aetiology of prostate cancer and of some rarer cancers is less complete.     

Challenges and Strategies in Thermal Processing of Amorphous Solid Dispersions: A Review

Thermal processing of amorphous solid dispersions continues to gain interest in the pharmaceutical industry, as evident by several recently approved commercial products. Still, a number of pharmaceutical polymer carriers exhibit thermal or viscoelastic limitations in thermal processing, especially at smaller scales. Additionally, active pharmaceutical ingredients with high melting points and/or that are thermally labile present their own specific challenges. This review will outline a number of formulation and process-driven strategies to enable thermal processing of challenging compositions. These include the use of traditional plasticizers and surfactants, temporary plasticizers utilizing sub- or supercritical carbon dioxide, designer polymers tailored for hot-melt extrusion processing, and KinetiSol® Dispersing technology. Recent case studies of each strategy will be described along with potential benefits and limitations.     

Application of whole cell rhodococcal biocatalysts in acrylic polymer manufacture

Rhodococci are ubiquitous in nature and their ability to metabolise a wide range of chemicals, many of which are toxic, has given rise to an increasing number of studies into their diverse use as biocatalysts. Indeed rhodococci have been shown to be especially good at degrading aromatic and aliphatic nitriles and amides and thus they are very useful for waste clean up where these toxic chemicals are present.The use of biocatalysts in the chemical industry has in the main been for the manufacture of high-value fine chemicals, such as pharmaceutical intermediates, though investigations into the use of nitrile hydratase, amidase and nitrilase to convert acrylonitrile into the higher value products acrylamide and acrylic acid have been carried out for a number of years. Acrylamide and acrylic acid are manufactured by chemical processes in vast tonnages annually and they are used to produce polymers for applications such as superabsorbents, dispersants and flocculants. Rhodococci are chosen for use as biocatalysts on an industrial scale for the production of acrylamide and acrylic acid due to their ease of growth to high biomass yields, high specific enzyme activities obtainable, their EFB class 1 status and robustness of the whole cells within chemical reaction systems.Several isolates belonging to the genus Rhodococcus have been shown in our studies to be among the best candidates for acrylic acid preparation from acrylonitrile due to their stability and tolerance to high concentrations of this reactive and disruptive substrate. A critical part of the selection procedure for the best candidates during the screening programme was high purity product with very low residual substrate concentrations, even in the presence of high product concentrations. Additionally the nitrile and amide substrate scavenging ability which enables rhodococci to survive very successfully in the environment leads to the formation of biocatalysts which are suitable for the removal of low concentrations of acrylonitrile and acrylamide in waste streams and for the removal of impurities in manufacturing processes.     

Polymer–Magnesium Aluminum Silicate Composite Dispersions for Improved Physical Stability of Acetaminophen Suspensions

The aims of this study were to characterize the morphology and size of flocculates and the zeta potential and rheological properties of polymer–magnesium aluminum silicate (MAS) composite dispersions and to investigate the physical properties of acetaminophen (ACT) suspensions prepared using the composite dispersions as a flocculating/suspending agent. The polymers used were sodium alginate (SA), sodium carboxymethylcellulose (SCMC), and methylcellulose (MC). The results showed that SA, SCMC, and MC could induce flocculation of MAS by a polymer-bridging mechanism, leading to the changes in the zeta potential of MAS and the flow properties of the polymer dispersions. The microscopic morphology and size of the flocculates was dependent on the molecular structure of the polymer, especially ether groups on the polymer side chain. The residual MAS from the flocculation could create a three-dimensional structure in the SA–MAS and SCMC–MAS dispersions, which brought about not only an enhancement of viscosity and thixotropic properties but also an improvement in the ACT flocculating efficiency of polymers. The use of polymer–MAS dispersions provided a higher degree of flocculation and a lower redispersibility value of ACT suspensions compared with the pure polymer dispersions. This led to a low tendency for caking of the suspensions. The SCMC–MAS dispersions provided the highest ACT flocculating efficiency, whereas the lowest ACT flocculating efficiency was found in the MC–MAS dispersions. Moreover, the added MAS did not affect ACT dissolution from the suspensions in an acidic medium. These findings suggest that the polymer–MAS dispersions show good potential for use as a flocculating/suspending agent for improving the rheological properties and physical stability of the suspensions.     

Allelopathy as a Tool in the Management of Biotic Resources in Agroecosystems

In modern agriculture, natural plant communities may be replaced by a single crop species. Weeds, some microorganisms, and viruses, as well as some herbivores are organisms that should be eliminated. Pesticides and fertilizers not only affect the pests and crops, but soil, non-pest species, water, food, and humans. In traditional agriculture weeds are components with an important ecological role in the maintenance of the system. Some weeds have been used as tools to control the growth of other weeds in traditional agroecosystems. Researchers on sustainable and organic agriculture get valuable information from traditional agriculture and currently are conducting research on plant breeding, soil fertility and tillage, crop protection, and cropping systems. Allelopathy and chemical ecology are directly involved in each of these fields and can play an important role in crop productivity, conservation of genetic diversity, and maintenance of ecosystems stability. Allelopathy has been shown to be related with problems of chemical interference between crops and weeds, crops and crops, toxicity of crops and weeds residues, and/or crops and weeds exudates. Problems of autotoxicity, orchard replanting, and forest regeneration are also referred as allelopathic. Allelopathy is strongly coupled with other stresses of the environment, including insects and disease, temperature extremes, nutrient and moisture variables, radiation, and herbicides. These stress conditions often enhance allelochemical production and increase the potential for allelopathic interference. Allelopathy offers potential for weed control through the production and release of allelochemicals from plants. Allelochemicals may impact the availability of nutrients through effects on the symbiotic microbes. Destruction and changes in the use of soils in the tropics have decreased biodiversity, bringing about the loss of valuable natural products. Many different types of useful products such as natural pesticides and drugs can arise from allelopathy studies. New methods must be generated for allelopathy as a part of the biotic resources management strategies.     

Protection of plants from frost using hydrophobic particle film and acrylic polymer

Frost damage to potatoes, grapevine and citrus plants was assessed following treatment with either an acrylic polymer (Antistress?) or with a hydrophobic particle film (CM‐96–018). In large freezing tests, the application of the hydrophobic particle film consistently led to less damage whilst the acrylic polymer led to the same amount or more damage when compared to control plants. Detailed examination of the freezing of leaves of all three species using infrared thermal imaging revealed that the hydrophobic particle film delayed the entry of ice from a frozen water droplet containing ice nucleating active bacteria and in some cases for the complete duration of the frost test. In contrast, the acrylic polymer was only able to influence the time of ice nucleation of the leaves of citrus plants. It was concluded that the hydrophobic particle film shows considerable promise as a frost protectant applied to susceptible crops just prior to a freezing event.     

Preparation of submicron unilamellar liposomes by freeze-drying double emulsions

A novel method is described for the preparation of sterile submicron unilamellar liposomes. The method is based on the lyophilization of double emulsions containing disaccharides as lyoprotectants in both the inner and outer aqueous phase. Using various phospholipids or mixtures of lipids as emulsifiers, the double emulsions can be prepared by a two-step emulsification, including hydrophilic agents in the inner aqueous phase or lipophilic agents in the oil phase. Then, the double emulsions are lyophilized after sterilization by passing them through a 0.22-μm pore filter. Rehydration of the lyophilized products results in liposomes with a relatively high encapsulation efficiency (for calcein, 87%; 5-fluorouracil, 19%; flurbiprofen, 93%) and a size below 200 nm measured by the dynamic light scattering technique (DLS) and the atomic force microscopy (AFM). The liposomes were found to be unilamellar from freeze-fracture electron micrographs and X-ray diffraction patterns. In addition, the liposomes can be reconstituted just before use by rehydration of the lyophilized products which are relatively stable. Thus, this reproducible and simple technique can be used to prepare sterilized, submicron unilamellar liposomes with a relatively high encapsulation efficiency, and excellent stability during long-term storage.