The Fibrinogen Concentration in Blood of Dairy Cows and its Influence on the Interpretation of the Glutaraldehyde and Formol-Gel Test Reactions

It has earlier been shown that the formol-gel test on serum and glutaraldehyde test on whole blood are simple and rapid methods for evaluation or the immunoglobulin status in the cow. Both tests function as coagulation tests in which aldehyde groups oross-link basic blood globulins at their NH2-groups, forming polymerisates. The glutaraldehyde has in whole blood the capacity to polymerize not only immunoglobulins but also fibrinogen. This investigation was made in order to study whether the fibrinogen level may influence the result of the glutaraldehyde test, so revealing any differences between the results of that and the formol-gel test carried out on serum. In 92 cows with a variety of clinical disorders (most of them with inflammatory processes) the total protein, albumin, total globulin concentration and albumin/globulin ratio in serum and fibrinogen concentration in plasma were recorded. The material was grouped according to glutaraldehyde and formol-gel test reactions. It is shown that increases in the fibrinogen level have an effect on the results of the glutaraldehyde test. A positive glutaraldehyde test in more acute processes is ascribed to a heavy rise of plasma fibrinogen in its capacity of acute-phase protein. A positive glutaraldehyde test in chronic diseases may be viewed as a result of interaction between high immunoglobulin concentrations and elevated fibrinogen concentration. In conclusion the fibrinogen and immunoglobulin status of blood is important to assess in many diseases of cattle. The semiquantitative tests described for field use can separately, or especially in parallel use, provide valuable information about the character and development of a disease and may be regarded as good substitutes for the sedimentation rate (SR), which is not demonstrable in cattle. kw|Keywords|k]bovine fibrinogen; k]bovine serum proteins; k]formol-gel reaction; k]glutaraldehyde test; k]acute and chronic inflammations     

低浓度戊二醛对红细胞膜力学特性的影响

采用显微动态图像分析技术无扰、实时、在位地研究了低于0．005％浓度的戊二醛对年轻、老龄红细胞膜变形能力的作用．实验结果表明随着戊二醛浓度的增加,年轻、老龄红细胞膜的弯曲弹性模量明显变大,而老龄红细胞增加幅度更大;且随着戊二醛固定时间的延长,年轻、老龄红细胞膜变形能力的差距越来越大．说明作为免疫分析中常用固定剂的戊二醛对年轻、老龄红细胞细胞骨架的影响差异较大。研究结果可为适当选取在免疫分析测定中,以及以年轻红细胞作为药物载体时需采用的戊二醛浓度提供依据。     

The structure of glutaraldehyde in aqueous solution determined by ultraviolet absorption and light scattering.

The structure of glutaraldehyde (GA) in aqueous solutions has been the subject of much debate. Since there were fundamental problems in the experiments in the preceding studies, in this article, the structure of GA was investigated with uv absorption and light scattering to avoid those problems. It was discovered that 70% glutaraldehyde solution contains a large quantity of polymeric species with cyclic hemiacetal structure. On dilution, the polymerized glutaraldehyde slowly converted to monomers. In dilute solution, glutaraldehyde is almost monomeric at pH 3-8, the major portion taking the cyclic hemiacetal structure. The structure of GA in 20% solution is similar to that in more dilute solution. alpha, beta-Unsaturated structure does not exist in aqueous solution regardless of the concentration of glutaraldehyde.     

Colorimetric micromethods for glutaraldehyde determination by means of phenol and sulfuric acid or phenol and perchloric acid

Aqueous micromolar solutions of glutaraldehyde produce a yellow color when treated with 20% phenol in ethanol followed by concentrated sulfuric acid or with phenol in 70% perchloric acid. The absorbance at 482 or 479 nm, respectively, is linearly related to the glutaraldehyde concentration. Of the two methods developed, the sulfuric acid-phenol assay gives a higher sensitivity and the perchloric acid-phenol assay allows the determination of glutaraldehyde in the presence of sugars and proteins.     

Stabilization of configurational states and enzyme activities in subcellular fractions after fixation with extremely low concentrations of glutaraldehyde

Synopsis The activities of various enzymes in some subcellular organelle fractions were examined after fixation in glutaraldehyde of various concentrations. A high speed centrifuge was used to shorten the fixation time.At the lowest concentration (0.01%) glutaraldehyde stabilized instable configurational states of mitochondria as revealed by electron microscopy. In addition, at this concentration, at least 70% of the original monamine oxidase, ATPase and cytochrome oxidase activities were preserved. The activity of acid phosphatase, on the other hand, was enhanced in a lysosomal fraction when fixed with the aldehyde at higher concentrations, e.g. 0.1% and 1.0%. It is possible that the aldehyde at higher concentrations has the same effects on the lysosomal membrane as freeze-thawing. Glucose-6-phosphatase activity was well-preserved in a microsomal fraction fixed with 0.01% glutaraldehyde but was decreased drastically when the concentration of the aldehyde was greater than 0.05%.     

蒜氨酸酶的固定化及其酶学性质研究

为了提高蒜氨酸酶的稳定性并实现酶的反复利用,研究了影响蒜氨酸酶固定化的因素及固定化蒜氨酸酶的酶学性质。蒜氨酸酶的固定化以壳聚糖微球为载体,戊二醛为交联剂,固定化的最适条件为：戊二醛浓度4%,给酶量20.2U,交联时间2h。固定化蒜氨酸酶的最适pH值7.0,最适温度35℃,米氏常数Km 7.9 mmol/L,操作稳定性比较好,连续使用10次后酶活力损失低于10%。     

Pronase treatment increases the staining intensity of GABA-immunoreactive structures in the paravertebral sympathetic ganglia

A novel tissue preparation technique for improving gamma-aminobutyric acid (GABA) immunocytochemistry has been developed. The influence of the glutaraldehyde concentration in the fixative and the effect of pronase treatment on the GABA immunostaining were tested. This method includes fixation with a high concentration of glutaraldehyde, gelatin embedding and treatment of the sections with pronase. In sympathetic (paravertebral) ganglia and their connectives, the most intense and specific immunoreaction was obtained with the following procedure: immersion fixation in 5% glutaraldehyde, infiltration and embedding in 15% gelatin, secondary fixation of the samples with 4% formaldehyde, floating frozen sections and digestion with 0.1% pronase for 15-20 min. With this technique, the GABA-containing structures (cells and nerve fibers with varicosities forming basket-like networks around some principal neurons) were selectively labeled. The data presented suggest that (1) a high concentration (5%) of glutaraldehyde in the primary fixative is necessary to preserve a large proportion of the GABA content; (2) this glutaraldehyde fixation partly masks the GABA immunoreactivity; and (3) this masking may be overcome by a proteolytic treatment preceding the immunostaining. This method has been extensively tested for the light microscopic visualization of GABA-containing tissue components in the sympathetic ganglion chain, but it may probably also be used for the immunocytochemical detection of other small molecules in other parts of the nervous system.     

Transport capacity, alkaline phosphatase activity and protein content of glutaraldehyde-treated cell forms of Escherichia coli.

Studies on the comparative transport capacity of various cell forms of Escherichia coli suggest that glutaraldehyde acts only in the outer regions of the cell envelope and to such an extent that transport of alpha-aminoisobutyric acid is reduced by 50%. Alkaline phosphatase activity in whole cells was severely impaired in the presence of alkaline glutaraldehyde and in NaCl-washed cells both acid and alkaline glutaraldehyde (0.01%) caused approximately 80-90% reduction in enzyme activity in 10 min. Protein content was reduced by only 10-15% with this concentration of glutaraldehyde, and cell volume decreased by the same extent. These results are discussed in terms of the mode of action of the disinfectant.     

The Use of Tannic Acid-Glutaraldehyde in the Study of Elastic and Elastic-Related Fibers

Fixation with tannic acid—glutaraldehyde permits distinction of oxytalan, elaunin and elastic fibers in the electron microscope. The results obtained using tannic acid at concentrations of 1.0%, 0.5% and 0.25% in 3% glutaraldehyde were compared. The 0.25% concentration is recommended for studying fine details of connective fibrils and for regular staining of elastin.     

Glutaraldehyde pretreatment blocks temperature-induced high-affinity [3H]tryptamine binding

The effect of glutaraldehyde (and Azure A) on temperature-sensitive high-affinity [3H]tryptamine binding was investigated in rat brain synaptic plasma membranes. In the 0.01-0.1% concentration range, the glutaraldehyde pretreatment preferentially inhibited only the above-mentioned portion of the binding, whereas the posttreatment of this reagent had no effect. On the other hand, in cases of pretreatment or posttreatment, a concentration of glutaraldehyde as high as 0.1% was inactive on the basal [3H]ligand binding capacity of the membranes (i.e., temperature-independent binding). Furthermore, it was revealed that the Scatchard plot of [3H]tryptamine binding in membranes pretreated with glutaraldehyde (0.05%) conformed to a straight line, as did a similar plot of temperature-independent binding. And, it was interesting to find that the binding parameters (KD and Bmax values) of both samples corresponded closely to each other. On the contrary, in all concentrations, Azure A affected nonspecifically both the temperature-dependent and the independent [3H]tryptamine binding to the same degree, regardless of whether or not there was pretreatment or posttreatment. All these observations clearly demonstrate that an appropriate concentration (0.01-0.1%) of glutaraldehyde pretreatment specifically blocks the temperature-induced allosteric modifications of high-affinity [3H]tryptamine binding sites.     

α-Amylase immobilization on gelatin: Optimization of process variables

α-Amylase was extracted and purified from soybean seeds to apparent homogeneity by affinity precipitation. The homogeneous enzyme preparation was immobilized on gelatin matrix using glutaraldehyde as an organic hardener. Response surface methodology (RSM) and 3-level-3-factor Box–Behnken design was employed to evaluate the effects of immobilization parameters, such as gelatin concentration, glutaraldehyde concentration and hardening time on the activity of immobilized α-amylase. The results showed that 20% gelatin (w/v), 10% glutaraldehyde (v/v) and 1 h hardening time yielded an optimum immobilization of 82.5%.     

氨基化硅胶载体固定化纤维素酶的研究

用硅胶作载体,戊二醛作交联剂,制备了固定化的纤维素酶。对制备固定化纤维素酶的偶联剂浓度、pH、给酶量3个影响因素进行了研究,通过正交试验优化得出最佳的固定化条件:交联剂戊二醛浓度为1%,固定化pH值为5,固载量为每克载体100mg纤维素酶。     

Optimization of immobilization conditions for acid proteinase from Aspergillus awamori

To optimize the immobilization conditions for acid proteinase from Aspergillus awamori by covalent binding through glutaraldehyde, experiments were carried out using the Box-Wilson method. The optimization process was assessed on the basis of absolute activity A, coefficient of activity retention gamma and their product A gamma. The following conditions can be recommended: glutaraldehyde concentration 50--60 mg/g, enzyme concentration not less than 40 mg/g, time of glutaraldehyde treatment 2--2.5 hrs, immobilization time 2 hrs, pH about 4.0, and temperature 35--40 degrees C. Under these conditions A=220--230 U/g, gamma = 23--24% Agamma = 5,000--6,000.     

L-DOPA production from tyrosinase immobilized on nylon 6,6

The production of L-DOPA immobilized on chemically modified nylon 6,6 membranes was studied in a batch reactor. Tyrosinase was immobilized on nylon using glutaraldehyde as a crosslinking agent. The effects of membrane pore size and glutaraldehyde concentration upon enzyme uptake and L-DOPA production were investigated. Enzyme uptake was unaffected by glutaraldehyde concentration; approximately 70% uptake was observed when 25% w/v (group 1), 5% (group 2), and 3% (group 3) glutaraldehyde were used, indicating that glutaraldehyde was in excess. Similarly, uptake was the same for membranes with 0.20 and 10 mum pore sizes.Membranes produced using different levels of glutaraldehyde exhibited dramatically different capacities for L-DOPA production, despite the fact that enzyme uptake was equivalent. Membranes from groups 2 and 3 (5% and 3% glutaraldehyde) produced L-DOPA at a rate of 1.70 mg L(-1) h(-1) over 170 h in a 500-mL batch reactor. However, no free L-DOPA was detected when group 1 membranes were used. Experimental evidence suggests that L-DOPA was produced, but remained bound to these membranes via excess glutaraldehyde left over from the immobilization process. Membrane pore size also effected L-DOPA production; less production was observed when 10-mum membranes were used, despite equivalent enzyme uptake. The observed difference in production may be due to differences in the pore density on the two types of membranes which could affect the access of the substrate to the immobilized enzyme.The results of these studies indicate that tyrosinase can be effectively immobilized on nylon 6,6. L-DOPA production was optimal when 0.20-mum-pore-size membranes were activated with 3-5% glutaraldehyde. Stability studies indicated a 20% reduction in activity over 14 days when the immobilized enzyme was used under turnover conditions. (c) 1996 John Wiley & Sons, Inc.     

Ultrasonic Synergistic Effects in Liquid-Phase Chemical Sterilization

New methods of sterilization employing a chemical with moderate heat and ultrasonic energy have been devised. Inactivation of high-density bacterial spore suspensions is achieved by treatment with low concentration aqueous acid glutaraldehyde solutions at temperatures above or about 54 C. Low (20 kHz) or high (250 kHz) frequency ultrasonic energy is synergistic with glutaraldehyde. Rapid inactivation may also be achieved by using ultrasonic energy and aqueous alkalinized glutaraldehyde solutions at low (25 C) or moderate (55 C) temperatures. If compared to present room temperature techniques, "surface sterilization" time for contaminated objects can be reduced from hours to minutes.     

Application of response surface methodology to optimization of glutaraldehyde activation of a support for enzyme immobilization

Summary We have studied the influence of several parameters (glutaraldehyde concentration, pH and contact time) on the activation of an amine silica with glutaraldehyde. In order to take interactions between parameters into consideration, we have used the Response Surface Methodology which allows us to obtain an equation (not a single estimation). The optimal conditions for glutaraldehyde activation of amine Spherosil beads were as follow: the porous silica was activated for 1 h at 25°C with an 8% (V/V) solution of glutaraldehyde at pH 6.4 these conditions were the same with RNA or CMP used as substrates.     

Uptake of l-[14C]-alanine by glutaraldehyde-treated and untreated spores of Bacillus subtilis

The effect of glutaraldehyde on the uptake of L-alanine, and subsequent germination, in spores of Bacillus subtilis NCTC 8236 was examined. Germination was induced by single amino acids, D-glucose and phosphate buffer at 37 degrees C. L-alanine was the best germinant of all amino acids tested. Pretreatment of spores with low concentrations of acid and alkaline glutaraldehyde inhibited subsequent germination, complete inhibition being observed at concentrations of 0.1% (w/v). This concentration also prevented the loss of heat resistance of spores placed in germination medium and exposed to 75 degrees C. Radioactive studies indicated that maximum uptake of L-alanine occurred after ca 30 min at 37 degrees C. Only 1.2% of available L-alanine was taken up during germination. Pretreatment of spores with glutaraldehyde did not interfere with L-alanine uptake at aldehyde concentrations up to 0.5% (w/v). However, this was significantly reduced at a glutaraldehyde concentration of 1.0% (w/v). Minimal differences were observed between acid and alkaline forms of the aldehyde. The results are discussed in terms of the mode of action of glutaraldehyde.     

Pronase treatment increases the staining intensity of GABA-immunoreactive structures in the paravertebral sympathetic ganglia

Summary A novel tissue preparation technique for improving gamma-aminobutyric acid (GABA) immunocytochemistry has been developed. The influence of the glutaraldehyde concentration in the fixative and the effect of pronase treatment on the GABA immunostaining were tested. This method includes fixation with a high concentration of glutaraldehyde, gelatin embedding and treatment of the sections with pronase. In sympathetic (paravertebral) ganglia and their connectives, the most intense and specific immunoreaction was obtained with the following procedure: immersion fixation in 5% glutaraldehyde, infiltration and embedding in 15% gelatin, secondary fixation of the samples with 4% formaldehyde, floating frozen sections and digestion with 0.1% pronase for 15–20 min. With this technique, the GABA-containing structures (cells and nerve fibers with varicosities forming basket-like networks around some principal neurons) were selectively labeled. The data presented suggest that (1) a high concentration (5%) of glutaraldehyde in the primary fixative is necessary to preserve a large proportion of the GABA content; (2) this glutaraldehyde fixation partly masks the GABA immunoreactivity; and (3) this masking may be overcome by a proteolytic treatment preceding the immunostaining. This method has been extensively tested for the light microscopic visualization of GABA-containing tissue components in the sympathetic ganglion chain, but it may probably also be used for the immunocytochemical detection of other small molecules in other parts of the nervous system.     

Author index volume 65

Spores of Bacillus subtilis 168 were apparently fully inactivated by exposure to 2% (w/v) glutaraldehyde for 20 h but a few spores could be revived by further treatment with 10-100 mM NaOH. A similar effect was found with spores from a range of Bacillus species. A minimum concentration of 5% (w/v) glutaraldehyde was required to prevent the alkali-induced reactivation. The implications of these results for the use of glutaraldehyde as a sporicidal agent are discussed.     

Intracellular distinction between peroxidase and catalase in exocrine cells of rat lacrimal gland: a biochemical and cytochemical study.

The lacrimal gland (Glandula orbitalis externa) of rat contains both peroxidase and catalase and was used as a model for biochemical and cytochemical distinction between peroxidase and catalase. Both enzymes were isolated by ammonium sulfate precipitation from tissue homogenates, and the effects of fixation with glutaraldehyde and various conditions of incubation were investigated colorimetrically using DAB as hydrogen donor. The lacrimal gland peroxidase is strongly inhibited by glutaraldehyde treatment. In contrast, for catalase the fixation with glutaraldehyde is the prerequistie for demonstration of its peroxidatic activity. The maximal peroxidatic activity was obtained after treatment of catalase with 3% glutaraldehyde, higher concentrations being inhibitory. For lacrimal gland peroxidase, the maximal rate of oxidation of DAB is at pH 6.5, whereas for catalase it is at pH 10.5. The optimal concentration of H2O2 for lacrimal gland peroxidase is at 10(-3)M and for peroxidatic activity of catalase at 10(-1)M. These optimal conditions obtained biochemically were applied to tissue sections of rat lacrimal gland. After the fixation of tissue with a low concentration of glutaraldehyde and incubation in the DAB medium at neutral pH containing 10(-3)M H2O2 (Peroxidase medium), the reaction product was localized in the cisternae of the rough endoplasmic reticulum, in elements of the Golgi apparatus, and in secretory granules. After the fixation of tissue with 3% glutaraldehyde and incubation in the DAB-medium containing 10(-1)M H2O2 and at pH 10.5 (catalase medium), the staining in the endoplasmic reticulum, the Golgi-apparatus and in secretory granules was completely inhibited and reaction product was localized exclusively in small (0.2-0.5 mu) particles similar to small peroxisomes described in various other cell-types.