In vitro cytotoxicity evaluation of natural rubber latex film surface coated with PMMA nanoparticles

In order to increase surface roughness of the sulphur-prevulcanized natural rubber (SPNR) film and, hence, decrease the direct contact between the rubber and skin, the poly(methyl methacrylate) (PMMA) latex particles were deposited onto the SPNR film grafted with polyacrylamide (SPNR-g–PAAm). The surface coverage of PMMA particles on the SPNR-g–PAAm increased with increasing latex immersion time, particle size and concentration. Prior to the in vitro cytotoxicity evaluation on L-929 fibroblasts, the SPNR and SPNR-g–PAAm coated with PMMA particles were extracted by using the culture medium. Results showed that the cytotoxicity effect could be significantly reduced by coating PMMA particles onto the rubber film. At the extract concentrations of ≤12.5% for 24 h at 37 °C, no toxicity potential was detected. The study will be helpful for development of gloves designed for the hypersensitive person.     

Protein-free natural rubber

Some properties of protein-free natural rubber were investigated by measurements of both water uptake and stress versus strain. The protein-free natural rubber was prepared in latex stage by the novel procedure to remove all proteins from natural rubber with urea and a polar organic solvent in the presence of surfactant, which had been developed in our recent work. First, the condition for the removal of the proteins was investigated in terms of affinity of the polar organic solvents, concentration of the solvents, type of surfactant, and repeating times for washing latex with a centrifuge. Acetone and anionic surfactant were found to be effective for the removal of the proteins. Under an optimum condition, total nitrogen content and amount of extractable proteins of deproteinized natural rubber were 0.000 w/w% and 0.00 μg/ml, respectively. The removal of the proteins from natural rubber was confirmed through Fourier transform infrared (FT-IR) spectroscopy. Water uptake, hydration, and tensile strength of the rubbers were measured by water swelling method, FT-IR spectroscopy, and measurement of stress versus strain, respectively. The water uptake and the hydration were dependent upon the content of the proteins. The tensile strength of the rubbers, which were prepared to be as-cast films without crosslinking, decreased after removal of the all proteins.     

Development of a rubber elongation factor, surface-imprinted polymer-quartz crystal microbalance sensor, for quantitative determination of Hev b1 rubber latex allergens present in natural rubber latex products

Molecularly imprinted polymers (MIPs) for screening to detect rubber latex allergens (Hev b1) in natural rubber based products were designed as artificial recognition polymeric materials coated onto a quartz crystal microbalance (QCM). The polymers were prepared using a stamp imprinting procedure after mixing optimum amounts of methacrylic acid–vinylpyrrolidone–dihydroxyethylene bisacrylamide and Hev b1 latex allergen proteins, obtained from rubber gloves. QCM measurements showed that the resulting polymer layers after removal of the proteins used in their preparation could incorporate structures and features down to nanometer scale of protein templates into the imprinted polymer much better than a non-specific control polymer under controlled sensor conditions and an optimized polymerization process. This selective polymer but not the non-selective polymer clearly distinguished between the latex allergen Hev b1 and proteins such as lysozyme, ovalbumin and bovine serum albumin, with a selectivity factor of from 2 to 4, and the response of the rubber elongation factors by an astonishing factor of 12. The imprinted cavities recognized specific binding sites and could distinguish among related hevein latex allergenic proteins isolated from fresh natural rubber latex; Hev b1, Hev b2, and Hev b3 with a selectivity factor of from 4 to 6. The different QCM measurements obtained presumably reflected slightly different conformations and affinities to the MIP binding sites. The sensor layers selectively adsorbed Hev b1 within minutes in amounts ranging from 10 to 1500 μg L⁻¹ and with a detection limit of 1 μg L⁻¹. This work has demonstrated that this new sensor provides a fast and reliable response to natural rubber latex protein, even after being extracted from the matrix of rubber gloves.     

NATURAL RUBBER LATEX PRODUCTS: CONCERNS IN HEALTH CARE

ABSTRACT

In the last decade, there has been a tremendous increase in the reports on adverse allergic reactions from natural rubber latex products used in the health care field. One of the reasons for the widely reported latex allergy is attributed to the increased use of natural rubber latex products, mainly gloves, since the emergence of deadly diseases such as Acquired Immunodeficiency Syndrome (AIDS), hepatitis, etc. This review presents the latest reported clinical manifestations from contact with natural rubber latex products, at the same time exploring the reasons behind these allergies, which are mainly attributed to the protein and rubber additives present in these latex products. The wish for better safety and health has led to the rise of synthetic rubber as an alternative to natural rubber products, the only advantage being the absence of proteins in them, while the toxicity from the chemicals remains the same. The synthetic elastomers, along with other alternatives like radiation and peroxide prevulcanized latices, hydrophilic coatings, glove liners, etc., are also dealt with in detail. The review also discusses the diagnostic methods available for latex allergy, methods of protein determination, organizations dealing with latex allergy, FDA ruling on gloves, etc.     

丝胶接枝水性聚氨酯乳液对天然乳胶的改性研究

利用丝胶优良的生物相容性、抗氧化性等特点,结合水性聚氨酯优良的机械性能,合成了丝胶接枝水性聚氨酯乳液(1)。采用杂凝聚技术用1改善天然乳胶手套的机械性能和过敏性。结果表明,经1改性后的天然乳胶手套在断裂伸长率基本不变的情况下,断裂强度有了明显的提高;杂凝聚方法形成的核壳结构使丝胶包裹在手套的内表面,达到了改善过敏性的目的。     

Preparation of phenyl‐modified natural rubber in latex stage

Phenyl‐modified natural rubber was prepared in latex stage by bromination of deproteinized natural rubber followed by Suzuki‐Miyaura cross‐coupling reaction. First, the bromination of natural rubber was carried out using N‐bromosuccinimide in latex stage. The bromine atom content increased as amount of N‐bromosuccinimide increased. Second, the allylic bromine atom was replaced with a phenyl group using phenyl boronic acid in the presence of a palladium catalyst, according to the Suzuki‐Miyaura cross‐coupling reaction in latex stage. The resulting products were characterized by nuclear magnetic resonance (NMR) spectroscopy. Signal at 7.13 ppm was assigned to the phenyl group of the product, while signals at 3.98, 4.14, and 4.44 ppm were assigned to the remaining allylic brominated cis‐1,4‐isoprene units. The estimated phenyl group content and the conversion of the Suzuki‐Miyaura cross‐coupling reaction were 1.32 and 23.7 mol%, respectively. Glass transition temperature (T_g) of deproteinized natural rubber increased from ?62°C to ?46.7°C, when the phenyl group was introduced into the rubber.     

Preparation and characterization of protein‐free natural rubber

Protein‐free natural rubber was prepared by incubation of natural rubber latex with urea and polar organic solvent in the presence of surfactant. Effect of the polar organic solvent on the removal of the proteins was investigated with respect to chemical affinity and concentration of the solvents. Under a suitable condition, nitrogen content of the deproteinized natural rubber (DPNR) was 0.000 wt%, which was less than that of natural rubber deproteinized with proteolytic enzyme or urea in the presence of surfactant. The removal of all proteins from natural rubber was proved through FT‐IR spectroscopy. Changes in morphology of the DPNR were also investigated by transmission electron microscopy. Copyright © 2011 John Wiley & Sons, Ltd.     

胶乳法氯化天然橡胶的光、热氧稳定性能

胶乳法氯化天然橡胶CNR经紫外光老化、热氧老化实验、化学分析、紫外光谱分析和热分析,结果表明：产品较溶液法光稳定性稍差,加入0．4％(质量百分比)的紫外线吸收剂AUI(二苯甲酮类)、AUII(苯并三唑类)和极少量的抗氧剂,可显著提高抗热氧老化性能。最佳配方为0．2％／0．5％(质量百分比)AOI(酚类抗氧剂)与AOIH(亚磷酸酯类抗氧剂)并用,或加入0．2％(质量百分比)的AOI。     

Latex‐state NMR spectroscopy for quantitative analysis of epoxidized deproteinized natural rubber

Method of quantitative analysis through latex‐state ¹³C NMR spectroscopy was established for in situ determination of epoxy group content of epoxidized natural rubber in latex stage. The epoxidized natural rubber latex was prepared by epoxidation of deproteinized natural rubber with freshly prepared peracetic acid in latex stage. The resulting epoxidized deproteinized natural rubber (EDPNR) latex was characterized through latex‐state ¹³C NMR spectroscopy. Chemical shift values of signals of latex‐state ¹³C NMR spectrum for EDPNR were similar to those of solution‐state ¹³C NMR spectrum for EDPNR. Resolution of latex‐state ¹³C NMR spectrum was gradually improved as temperature for the nuclear magnetic resonance (NMR) measurement increased to 70°C. Signal‐to‐noise ratio of latex‐state ¹³C NMR measurement was similar to that of solution‐state ¹³C NMR measurement at temperature above 50°C. The epoxy group content determined through latex‐state NMR spectroscopy was proved to be the same as that determined through solution‐state NMR spectroscopy. Copyright © 2017 John Wiley & Sons, Ltd.     

Low temperature degradation and characterization of natural rubber

Low temperature degradation of natural rubber was performed with potassium persulfate (K₂S₂O₈, KPS) in the latex stage at 30 °C to accomplish a good processability of the rubber. Various grades of natural rubbers were used as a source rubber. Gel content, molecular weight and chemical structure of the rubbers were characterized by swelling method, size exclusion chromatography and ¹H NMR spectroscopy, respectively. The well characterized natural rubber was subjected to oxidative degradation with KPS at 30 °C. Mooney viscosity decreased when the latex was degraded with 1.0 phr of KPS and it was dependent upon the amount of KPS. Molecular weight and gel content of the degraded natural rubber were about one-half as low as those of the source rubber. Chemical structure of the rubber was analyzed through Fourier transform infrared and ¹H NMR spectroscopic methods. The degraded natural rubber was found to contain carbonyl and formyl groups as an evidence of the oxidative degradation. Tensile strength of a vulcanizate prepared from the degraded natural rubber was the same as that prepared from the source rubber, even though the gel content and the molecular weight of the degraded rubber were distinguished from those of the source rubber.     

Green biocomposites of chitosan dispersed in natural rubber matrices,and their urea controlled-release application

A green biocomposite comprising chitosan dispersed in partially cross-linked natural rubber matricesd was prepared. The starting materials and biocomposites were characterized by means of Fourier transform–infrared spectroscopy, thermogravimetric analysis, and scanning electron microscopy. Chitosan was found well dispersed in partially cross-linked natural rubber matrices indicating that natural rubber latex is successfully stabilized by sodium dodecyl sulfate. The swelling study of the biocomposites was carried out in several solvents. The biocomposites were used for the controlled-release of urea. The release behavior was found consistent, controlled, and prolonged over a period of 72 h. The Korsmeyer–Peppas model was applied to the experimental data and the possible release mechanism was found Fickian diffusion, which indicates that the polymer relaxation time is much greater than the characteristic solvent diffusion time.     

Contributions to the Characterization of Chlorinated Polyisoprene Surfaces

Summary: The present work is focused on the characterization of the surface properties and the mechanical properties of chlorinated polyisoprene films. Cross-linked polyisoprene films were treated with acidified hypochlorite solution and the influence of the chlorination time on the surface properties was determined by spectroscopic techniques including FT-IR spectroscopy and X-ray photoelectron spectroscopy (XPS). The surface morphology was investigated by scanning electron microscopy (SEM), optical microscopy and contact angle measurements. In addition, the effect of the chlorination time on the tensile strength and ageing stability of natural rubber latex gloves was investigated.     

Spectroscopic,thermal, and mechanical characterization of the polymeric fabrics used in extreme low-temperature protective garments

This paper presents the study of the chemical and physico-mechanical properties of the natural and synthetic fabrics used in extreme low-temperature (?20 °C) gloves. The essential properties, such as the weight of the gloves, cold insulation, and surface water repellency, were studied. In-depth analysis by ¹³C solid-state nuclear magnetic resonance spectroscopy (¹³C SSNMR), attenuated total reflectance fourier transform infrared spectroscopy (ATR-FTIR), and differential scanning calorimetry (DSC) techniques were undertaken to understand the chemical and thermal characteristics of the fabrics. The physico-mechanical properties, such as thickness, weight, softness, tear strength, abrasion resistance, blade cut resistance, and puncture resistance, of each fabric used in the gloves, were also studied. Finally, the physico-mechanical properties were correlated with the chemical nature of the fabrics and the garment's performance properties.The present study will guide in the selection of materials for designing low-temperature protective garments. The in-depth analysis presented in this work will also help the researchers in the chemical identification of natural and synthetic polymeric fabrics using solid-state NMR, ATR-FTIR, and DSC techniques.     

Mechanisms of antioxidant action: The reaction of hindered phenols with rubber in the presence of free radicals

Simple hindered phenols, containing ortho or para methyl groups, react with natural rubber latex in the presence of oxidizing free radicals (alkoxy or acyloxy), giving up to 20% yields of bound antioxidant. This reaction is most efficient when the concentration of the phenolic antioxidant in the rubber is less than 1%. As the concentration is increased, side reactions involving both the phenol (stilbenequinone formation) and the rubber (cross-linking) supervenes. The efficiency of the bound antioxidants is much higher than conventional antioxidants under aggressive conditions of air oven ageing and solvent or detergent extraction. This effect is due primarily to the non-removal of the bound antioxidants under these conditions whereas the conventional antioxidants are removed completely.     

Preparation and Characterization of Chitosan-Coated DBD Plasma-Treated Natural Rubber Latex Medical Surgical Gloves with Antibacterial Activities

The natural rubber latex (NRL) film taken from medical surgical gloves was surface-modified with a dielectric barrier discharge (DBD) plasma treatment under an air environment. The results showed that surface hydrophilicity of the NRL film increased after the plasma treatment due to the presence of oxygen-containing polar groups on the plasma-treated surface. An increase in plasma treatment time increased the surface roughness of the NRL film, and eventually decreased the mechanical properties. From the obtained results, the optimum plasma treatment time of 20?s was chosen. After immersion in a chitosan solution, the amount of chitosan deposited on the plasma-treated NRL film increased with increasing chitosan concentrations. The chitosan coating smoothed the surface of the plasma-treated NRL film and also improved the mechanical properties. The highest antibacterial activities of the chitosan-coated DBD plasma-treated NRL film against both Staphylococcus aureus and Escherichia coli were achieved when a 2?%(w/v) chitosan solution was used for the coating.     

Improving thermal and ozone stability of skim natural rubber by diimide reduction

The physical, chemical and thermal properties of diene-based polymers are improved by a chemical modification method such as hydrogenation. Skim natural rubber (SNR) which is mainly comprised of cis-1,4-polyisoprene was hydrogenated by diimide reduction in latex form, using hydrazine and hydrogen peroxide with copper sulfate as catalyst. The effect of various parameters on the level of hydrogenation calculated from proton nuclear magnetic resonance spectroscopy (¹H NMR) was investigated. The kinetic results indicated that the diimide hydrogenation of skim natural rubber latex (SNRL) exhibited a first order behavior with respect to the CC concentration. The apparent activation energy of the catalytic and non-catalytic hydrogenation of SNRL was calculated as 9.5 and 21.1 kJ/mol, respectively. From the TEM micrograph of hydrogenated SNRL particles, non-hydrogenated rubber core and hydrogenated rubber layer were observed according to a layer model. The results from thermal analysis confirmed that thermal stability of hydrogenated SNR was improved compared with the starting SNR. In addition, the thermal aging and ozone resistance of vulcanized hydrogenated SNR blends were also investigated.     

Nano-matrix structure formed by graft-copolymerization of styrene onto natural rubber

Nano-matrix structure was formed by graft-copolymerization of styrene onto urea-deproteinized natural rubber (U-DPNR) latex. The grafted U-DPNR was characterized by FT-IR spectroscopy, ¹H NMR spectroscopy and transmission electron microscopy. Conversion and grafting efficiency of styrene were more than 90% under the best condition of the graft-copolymerization. In transmission electron micrograph of film specimen stained by OsO₄, it was found that natural rubber particle of about 0.5 μm in diameter was dispersed in polystyrene matrix of about 15 nm in thickness. The conversion and grafting efficiency for the grafted U-DPNR were compared with those for a control sample prepared from enzymatic deproteinized natural rubber (E-DPNR) with styrene.     

Simple test kit based on colorimetry for quantification of magnesium content in natural rubber latex by miniaturized complexometric titration without using masking agent

A simple, low-cost and portable field test kit based on colorimetry with detection by naked eye was developed for determination of magnesium content in natural rubber latex (NRL). The miniaturized complexometric titration between Mg²⁺ and EDTA without any masking agent was a key reaction in this development, which was designed according to the concept of green chemistry by reduction of waste generation and chemical and time consumption. The system enabled quantification of magnesium content in NRL at low concentration with the detection limit being <50 mg L⁻¹, small sample volume uptake (0.18 g, sampling by a small spoon) and use of <1.5 mL reagent volume which was >70 times less than that applied in the conventional method. Moreover, with the presence of potential interference ions, greater selectivity towards magnesium was observed. Furthermore, the reagents used in our developed test kit were stable for >6 months at room temperature. The results obtained on real samples were in agreement with those obtained from the conventional complexometric titration (ISO 17403: 2014(E)) method. The proposed technique provides a low-cost, rapid, simple, selective and on-site analysis of magnesium content in NRL.     

Synthesis and application of cinnamate-functionalized rubber for the preparation of UV-curable films

A butyl rubber derivative that can be cured upon exposure to UV light in the absence of additional chemical additives was developed. This polymer was prepared by the reaction of hydroxyl-functionalized butyl rubber with cinnamoyl chloride to provide a cinnamate functionalized rubber. The cinnamate content was varied by starting with derivatives prepared from butyl rubber containing either 2 or 7 mol% isoprene. The kinetics of the cross-linking was studied by UV–visible spectroscopy and it was found to vary according to the film thickness. The changes in gel content and volume swelling ratio with irradiation time were dependent on the cinnamate content. Toxicity studies suggested that the cross-linked materials do not leach toxic molecules. The approach was also applied to obtain cross-linked films of butyl rubber-poly(ethylene oxide) graft copolymers, leading to surfaces that resisted the adhesion and growth of cells. Thus the approach is versatile and is of particular interest when non-leaching coatings of cross-linked butyl rubber are desired for biomedical or other applications.     

Estimation of dry rubber content in natural rubber latex by differential scanning calorimetry

Differential Scanning Calorimetry (DSC) is employed to study the changes in enthalpy of natural rubber latex samples when heated under a controlled temperature program. It is found that the mass normalized areas of the DSC curves between room temperature and 170 °C for different latex samples are inversely proportional to the dry rubber content (DRC) of the samples, measured following the weighing and drying method. The changes in total enthalpy of the samples in this temperature range are interpreted as due to the variations in the quantity of water present in the samples. The measurements have been repeated by diluting selected samples with known quantities of water, and it is found that the normalized areas of the DSC curves are directly proportional to the amount of water added to the latex. The method can be used to estimate the DRC of natural rubber latex accurately. Its advantages and limitations are discussed.