A study of conventional formaldehyde fumigation methods

The currently recommended methods for the formaldehyde fumigation of rooms have been studied with the aid of an instrument designed to monitor the temperature, humidity and formaldehyde concentration. The results show that although the procedures are generally effective as measured by microbiological methods the conditions within the areas treated are not those expected from calculations based on the room volume and the amount of formaldehyde used. The measured formaldehyde levels in particular are much lower than predicted and indicate that formaldehyde vapour may be effective at lower concentrations than previously supposed.     

Comparison of standard methods and gas chromatography method in determination of formaldehyde emission from MDF bonded with formaldehyde-based resins

Formaldehyde emissions from MDF bonded with urea-formaldehyde resin (UF), melamine-formaldehyde resin (MF) and the co-polycondensation resin of urea-melamine-formaldehyde (UMF) and melamine-formaldehyde, measured by the Japanese standard method of determining formaldehyde emission with a desiccator (JIS A 5908) and the DIN EN 120 (European Committee For Standardization, 1991) method using the perforator value, were used as the typical standard methods. While the UF resin showed a desiccator value of 7.05 ppm and a perforator value of 12.1 mg/100 g panel, the MF resin exhibited a desiccator value of 0.6 ppm and a perforator value of 2.88 mg/100 g panel. According to the Japanese industrial standard and the European standard, the formaldehyde emission level of the MDF panels made with UF resin in this study was E(2) grade. The formaldehyde emission level was dramatically reduced by the addition of MF resin. This is because the addition of formaldehyde to melamine occurs more easily and completely than its addition to urea, even though the condensation reaction of melamine with formaldehyde is similar to that between urea and formaldehyde. These two methods, the desiccator method and the perforator method, produced proportionally equivalent results. Gas chromatography, a more sensitive and advanced method, was also used. The samples used for gas chromatography were gathered during the experiment involving the perforator method. The formaldehyde emission levels obtained from gas chromatography were similar to those obtained from the perforator method. The formaldehyde contents measured by gas chromatography were directly proportional to the perforator values.     

Histomorphometric comparison after fixation with formaldehyde or glyoxal

Abstract

Formaldehyde has long been the fixative of choice for histological examination of tissue. The use of alternatives to formaldehyde has grown, however, owing to the serious hazards associated with its use. Companies have striven to maintain the morphological characteristics of formaldehyde-fixed tissue when developing alternatives. Glyoxal-based fixatives now are among the most popular formaldehyde alternatives. Although there are many studies that compare staining quality and immunoreactivity, there have been no studies that quantify possible structural differences. Histomorphometric analysis commonly is used to evaluate diseased tissue. We compared fixation with formaldehyde and glyoxal with regard to the histomorphological properties of plantar foot tissue using a combination of stereological methods and quantitative morphology. We measured skin thickness, interdigitation index, elastic septa thickness, and adipocyte area and diameter. No significant differences were observed between formaldehyde and glyoxal fixation for any feature measured. The glyoxal-based fixative used therefore is a suitable fixative for structural evaluation of plantar soft tissue. Measurements obtained from the glyoxal-fixed tissue can be combined with data obtained from formalin-fixed for analysis.     

The reactions between formaldehyde,glutaraldehyde and osmium tetroxide,and their fixation effects on bovine serum albumin and on tissue blocks

Summary The reactions between osmium tetroxide and glutaraldehyde and formaldehyde were investigated. It was found that they react together to form intermediate products which then break down to form osmium black. Glutaraldehyde reacts much more rapidly with osmium tetroxide than formaldehyde. The rates of the reactions are increased by increasing the glutaraldehyde concentration or adding bovine serum albumin to the reaction mixture. The reaction rates increase with temperature. The mixtures of fixatives were also tried on tissues and the results paralleled the model experiments. The crosslinking of bovine serum albumin by osmium tetroxide, formaldehyde and glutaraldehyde singly and in mixtures was quantitatively assessed by viscosimetry, gel filtration and disc electrophoresis coupled with densitometry. The crosslinking of bovine serum albumin by pairs of fixatives was less than that produced by the most effective of the pair. After 5 min reaction osmium tetroxide was the most effective crosslinking agent according to viscosimetric experiments, but after one hour's reaction with bovine serum albumin, glutaraldehyde was revealed as the most effective crosslinking agent by gel filtration and electrophoresis.     

Submicrodeterminations of thiols, disulphides and thiol esters in serum by using o-hydroxymercuribenzoic acid and dithiofluorescein

1. Methods are described for selective estimation of thiols, disulphides and thiol esters in standard solutions and in serum. The methods are based on the reaction with the excess of o-hydroxymercuribenzoic acid (HMB) in alkaline solution with subsequent addition of dithiofluorescein in excess and determination of the extinction at 588mmu. The sensitivity of the methods amounts to 1.5x10(-9)g.equiv. in 5ml. of final solution. Of results obtained on standard solutions 80% have the errors within the range +/-4%. 2. It has been found that serum contains an unidentified substance (substance X) producing green complexes with dithiofluorescein which undergo decomposition on addition of formaldehyde. The correction for substance X must be estimated in a separate sample and taken into account. The concentration of substance X can be calculated from extinctions measured at 588mmu and 635mmu in the presence of dithiofluorescein in excess. 3. The selective determination of thiols and disulphides is based on different reaction rates with formaldehyde. The complexes between HMB and cysteine can be selectively decomposed by formaldehyde, and free glutathione can be selectively removed by formaldehyde in the presence of protein thiols. 4. Thiols are determined in the presence of triethylamine, thiols plus disulphides in the presence of triethylamine and sulphite, and thiols plus thiol esters in the presence of dimethylamine, with subsequent addition of ammonium sulphate.     

Behaviour of DNA-RNase A complex in the presence of formaldehyde]

A formaldehyde-produced fixation of defects caused by a despiralizing action of a protein was studied in the case of DNA-RNAase A complex. The concentration of the defects fixed was measured by kinetic formaldehyde method (KF-method). It was shown that following processes take place in the complex in the presence of formaldehyde: (a) fixation of defects; (b) unwinding of DNA; (c) inactivation of the protein. The rates of all these processes depend on the concentration of formaldehyde, phi. At formaldehyde concentrations above some critical value phic the protein is inactivated before the defects are fixed. At phi less than phic the protein inactivation proceeds more slowly than the fixation of defects; at sufficiently low formaldehyde concentration no inactivation of protein occurs practically during the fixation time (20 min). The number of new defects formed during the time of fixation is linear with the formaldehyde concentration in the region where no inactivation of the protein occurs. Therefore the initial concentration of defects can be determined through an extrapolation to zero concentration of formaldehyde. On the basis of the data obtained a method is proposed for the evaluation of the number of defects in DNA caused by the despiralizing action of proteins. A model is proposed describing the behaviour of the complexes of DNA with despiralizing proteins in the presence of formaldehyde.     

Comparison of the secondary metabolites in two scales of cephalosporin C (CPC) fermentation and two different post-treatment processes

Cephalosporin C (CPC) is the precursor of a class of antibiotics that were more effective than traditional penicillins. CPC production is performed mainly through fermentation by Acremonium chrysogenum, whose secondary metabolism was sensitive to the environmental changes. In the present work, secondary metabolites were measured by ion-pair reversed-phase liquid chromatography tandemed with hybrid quadrupole time-of-flight mass spectrometry, and the disparity of them from two scales of CPC fermentations (pilot and industrial) and also two different post-treatment processes (oxalic acid and formaldehyde added and control) were investigated. When fermentation size was enlarged from pilot scale (50 l) to industrial scale (156,000 l), the remarkable disparities of concentrations and changing trends of the secondary metabolites in A. chrysogenum were observed, which indicated that the productivity of CPC biosynthesis was higher in the large scale of fermentation. Three environmental factors were measured, and the potential reasons that might cause the differences were analyzed. In the post-treatment process after industrial fermentation, the changes of these secondary metabolites in the tank where oxalic acid and formaldehyde were added were much less than the control tank where none was added. This indicated that the quality of the final product was more stable after the oxalic acid and formaldehyde were added in the post-treatment process. These findings provided new insight into industrial CPC production.     

The effects of mercaptoethanol-formaldehyde on tissue fixation and protein retention

Summary The study compared the effects of mercaptoethanol-formaldehyde and formaldehyde alone, on tissue fixation and protein retention in human and mouse tissues. Shrinkage of tissues and the penetration rate of the fixatives were assessed. The cross-linking ability of the fixatives was determined by viscometry, sodium dodecyl sulphate-polyacrylamide gel electrophoresis, and spectrophotometry, using bovine serum albumin and human haemoglobin. Tissues fixed in buffered 0.0025% mercaptoethanol-4% formaldehyde showed good nuclear and cytoplasmic detail, better than those fixed in buffered 4% formaldehyde. There was no significant difference in shrinkage. A mixture of 0.0025% mercaptoethanol-4% formaldehyde penetrated faster into adult liver than 4% formaldehyde. The mean penetration rate (±SE) or coefficient of diffusibility of 0.0025% mercaptoethanol-4% formaldehyde into adult liver was 1.32±0.01 and that of 4% formaldehyde was 1.12±0.06 (p<0.04). Both fixatives diffused more rapidly into mouse liver than into human liver. The cross-linking ability of mercaptoethanol-formaldehyde depends on the concentration of the fixative and the time of fixation. Bovine serum albumin (15%) and 0.1% mercaptoethanol alone formed a gel, whilst electrophoresis showed monomers in the supernatant. Mercaptoethanol (0.1%) also rapidly decreased the absorption at 420 nm, suggesting denaturation. It seems that mercaptoethanol increases the number of thiol groups available to form cross-links with formaldehyde. This study demonstrated that mercaptoethanol-formaldehyde fixed and cross-linked tissues better than formaldehyde at 3 h and 4 h, but not at 1 h and 2 h. The most effective concentration of mercaptoethanol for tissue fixation in 4% formaldehyde is 0.0025%.     

The titration of tetanus antitoxin V. Effect of formalization method for the fixation of sheep erythrocytes on the indirect haemagglutination test

Two methods of fixation of sheep erythrocytes with formaldehyde for the titration of tetanus antitoxin by the indirect haemagglutination (IHA) test have been compared. The cells fixed with 3% formaldehyde at 4-8 degrees C for 24 h (formaldehyde (I) fixed cells) were less sensitive than the cells fixed with 3% formaldehyde at 4-8 degrees C for 24 h and subsequently treated with 40% formaldehyde at 4-8 degrees C for a further 24 h (formaldehyde (II) fixed cells). The correlation between the toxin neutralization (TN) and IHA titres using formaldehyde (I) fixed cells was better than that obtained with formaldehyde (II) fixed cells. There was no statistically significant difference between TN and IHA titres after treatment of the sera with 2-Mercaptoethanol using formaldehyde (I) fixed cells. Formaldehyde (I) fixed cells can be used for two months with adequate sensitivity to detect the minimum protective level of tetanus antitoxin in the sera.     

分光光度法测定地骨皮中牛磺酸含量

用分光光度法测定地骨皮中是否含有牛磺酸。在一定条件下,牛磺酸与乙酰丙酮和甲醛反应生成带色的配合物,建立了测定牛磺酸含量的分光光度法。结果表明,地骨皮中含有牛磺酸,已测定样品1中牛磺酸的质量分数为3.124 mg.g-1,样品2中牛磺酸的质量分数为6.203 mg.g-1,且样品2中的牛磺酸质量分数极显著高于样品1(p<0.01)。研究结果表明,地骨皮中含有牛磺酸,而且分光光度法成本低,干扰少,是测定地骨皮中牛磺酸质量分数的较好方法。     

Development of highly selective and stable potentiometric sensors for formaldehyde determination

Two types of biosensors selective to formaldehyde have been developed on the basis of pH-sensitive field effect transistor as a transducer. Highly or partially purified alcohol oxidase (AOX) and the permeabilised cells of methylotrophic yeast Hansenula polymorpha (as a source of AOX) have been used as sensitive elements. The response time in steady-state measurement mode is in the range of 10-60 s for the enzyme-based sensors and 60-120 s for the cell-based sensor. When measured in kinetic mode the response time of all biosensors developed was less than 5 s. The linear dynamic range of the sensor output signals corresponds to 5-200 mM formaldehyde for highly and partially purified alcohol oxidase, and 5-50 mM formaldehyde for the cells. The operational stability of the biosensors is not less than 7 h, and the relative standard deviation of intra-sensor response is approximately 2 and 5% for the enzyme- and cell-based sensors, respectively. When stored at 4 degrees C, the enzyme and cell sensor responses have been found stable for more than 60 and 30 days, respectively. Both types of biosensors demonstrate a high selectivity to formaldehyde with no potentiometric response to primary alcohols, including methanol, or glycerol and glucose. The possible reasons of such unexpected high selectivity of AOX-based FET-sensors to formaldehyde are discussed. The influence of the biomembrane composition and the effect of different buffers on the sensor response to formaldehyde are also discussed.     

New Formaldehyde Base Disinfectants

Preparations of formaldehyde in various organic liquids-ethylene glycol, glycerol, and propylene glycol-serve as effective disinfectants towards microbial vegetative cells and spores. This disinfection is a temperature-dependent process and is manifest when these formaldehyde base disinfectants are dissolved in water. The irritating vapors associated with formaldehyde disinfection are not present in either of these new formaldehyde base disinfectants or in aqueous solutions of them.     

2308、M28、S1330、16M四株布鲁氏菌灭活参数研究

【目的】比较不同灭活方法对布鲁氏菌灭活的效果,确定灭活参数,为制备布鲁氏菌灭活抗原提供参考。【方法】将4株布鲁氏菌参考强毒株2308(牛种)、M28(羊种)、S1330(猪种)以及16M(羊种)分别经大豆酶消化蛋白胨(TSA)培养基培养繁殖后,用生理盐水制成(4-8)×1010 CFU/m L的菌悬液,分成等份于80 oC灭活不同时间,另将同样浓度的菌悬液分别用不同浓度甲醛于37 oC灭活不同时间,通过灭活检验,确定灭活效果。取经甲醛和热灭活的16M抗原,分别以1×1010 CFU/只剂量皮下注射1.5-2.0 kg家兔2只,免疫6周内,每周采血用虎红平板凝集试验(RBT)和试管凝集试验(SAT)测定抗体效价。【结果】80 oC、5 min可灭活2308、S1330和16M三种菌株,80 oC、10 min可灭活全部4种菌株。0.2%甲醛灭活7 d,4种试验菌株均不能被彻底灭活;0.4%甲醛在12 h内只能灭活16M,72 h可灭活M28;0.4%甲醛灭活2308和S1330两次试验结果差异较大。0.6%甲醛可在72 h内灭活4种试验菌。不同方法灭活的16M抗原免疫家兔后,其血清抗体虎红平板凝集和试管凝集效价消长趋势基本一致,甲醛灭活的抗原免疫原性略高于热灭活抗原。【结论】80 oC热灭活和0.6%甲醛灭活均可用于对布鲁氏菌的灭活,且不影响布鲁氏菌的免疫原性。     

A novel sensitive high-performance liquid chromatography/electrochemical procedure for measuring formaldehyde produced from oxidative deamination of methylamine and in biological samples

Formaldehyde is a well-known environmental toxic hazard. It is also a product of oxidative deamination of methylamine catalyzed by semicarbazide-sensitive amine oxidase (SSAO). Increased SSAO-mediated deamination has been implicated in some pathophysiological conditions, such as diabetic complications. The measurement of formaldehyde in the enzymatic reactions and in vivo production using conventional methods was not straightforward due to limitations of selectivity and sensitivity. A novel high-performance liquid chromatography (HPLC)/electrochemical procedure for the measurement of formaldehyde has been developed. The measurement is based on the formation of adducts between formaldehyde and dopamine. These adducts can be selectively purified and concentrated using a batch method of alumina absorption, separated by HPLC, and electrochemically quantified. The method is highly selective and substantially more sensitive, i.e., detection of picomole levels of formaldehyde, than the conventional methods. The procedure not only facilitates the assessment of SSAO activity in vitro but also is useful for assessing formaldehyde in tissues and biological fluids.     

Inhibition of hyphal development and kill of Candida albicans blastospores by noxythiolin in vitro

The cidal activity of the antimicrobial agent, noxythiolin, was investigated against a laboratory strain and a fresh isolate of Candida albicans. The order of resistance to noxythiolin was hyphal form (isolate) greater than or equal to 25 degrees C-grown blastospores (isolate) greater than 37 degrees C-grown blastospores (isolate) greater than laboratory strain blastospores. Noxythiolin activity was superior to that of 'equivalent' formaldehyde concentrations. Mycelial transformation in C. albicans was examined by light and scanning electron microscopy and measured in terms of percentage germination and hyphal extension. Noxythiolin, 2.5%, in contact for 30 min prevented germination of the blastospore population whereas the decomposition products, formaldehyde and N-methylthiourea, showed no appreciable effect in the expected concentrations. The implications of these results are discussed in relation to the observed clinical efficacy of noxythiolin.     

Formation of DNA adducts by formaldehyde-activated mitoxantrone.

Recent studies with the anthracycline Adriamycin have demonstrated its activation by formaldehyde and subsequent binding to DNA in vitro. Since formaldehyde levels are known to be higher in cells of myeloid origin and the structurally related drug mitoxantrone is most effective against cancers of myeloid origin, this indicates a possible role of formaldehyde in the activation of mitoxantrone. In vitro studies revealed that the activation of mitoxantrone by formaldehyde leads to the formation of drug-DNA adducts. These adducts stabilised DNA such that they functioned as virtual interstrand crosslinks. The interstrand crosslinks were formed in the presence of mitoxantrone and formaldehyde in a time- and concentration-dependent manner. In the absence of formaldehyde no crosslinks were formed, indicating a key role in drug activation and DNA binding. The adducts (virtual crosslinks) were relatively unstable with 50% crosslinks remaining after 10 min at 60 degrees C in 45% formamide. Like Adriamycin, the mitoxantrone-formaldehyde-DNA crosslinks are heat labile and do not display the stability associated with covalent interstrand crosslinks.     

Inhibition of the oxidation of acetaldehyde and formaldehyde by hepatocytes and mitochondria by crotonaldehyde

Crotonaldehyde was oxidized by disrupted rat liver mitochondrial fractions or by intact mitochondria at rates that were only 10 to 15% that of acetaldehyde. Although a poor substrate for oxidation, crotonaldehyde is an effective inhibitor of the oxidation of acetaldehyde by mitochondrial aldehyde dehydrogenase, by intact mitochondria, and by isolated hepatocytes. Inhibition by crotonaldehyde was competitive with respect to acetaldehyde, and the Ki for crotonaldehyde was about 5 to 20 microM. Crotonaldehyde had no effect on the oxidation of glutamate or succinate. Very low levels of acetaldehyde were detected during the metabolism of ethanol. Crotonaldehyde increased the accumulation of acetaldehyde more than 10-fold, indicating that crotonaldehyde, besides inhibiting the oxidation of added acetaldehyde, also inhibited the oxidation of acetaldehyde generated by the metabolism of ethanol. Formaldehyde was a substrate for the low-Km mitochondrial aldehyde dehydrogenase, as well as for a cytosolic, glutathione-dependent formaldehyde dehydrogenase. Crotonaldehyde was a potent inhibitor of mitochondrial oxidation of formaldehyde, but had no effect on the activity of formaldehyde dehydrogenase. In hepatocytes, crotonaldehyde produced about 30 to 40% inhibition of formaldehyde oxidation, which was similar to the inhibition produced by cyanamide. This suggested that part of the formaldehyde oxidation occurred via the mitochondrial aldehyde dehydrogenase, and part via formaldehyde dehydrogenase. The fact that inhibition by crotonaldehyde is competitive may be of value since other commonly used inhibitors of aldehyde dehydrogenase are irreversible inhibitors of the enzyme.     

Inhibition of CO2 production from aminopyrine or methanol by cyanamide or crotonaldehyde and the role of mitochondrial aldehyde dehydrogenase in formaldehyde oxidation

Previous results have shown that cyanamide or crotonaldehyde are effective inhibitors of the oxidation of formaldehyde by the low-Km mitochondrial aldehyde dehydrogenase, but do not affect the activity of the glutathione-dependent formaldehyde dehydrogenase. These compounds were used to evaluate the enzyme pathways responsible for the oxidation of formaldehyde generated during the metabolism of aminopyrine or methanol by isolated hepatocytes. Both cyanamide and crotonaldehyde inhibited the production of 14CO2 from 14C-labeled aminopyrine by 30-40%. These agents caused an accumulation of formaldehyde which was identical to the loss in CO2 production, indicating that the inhibition of CO2 production reflected an inhibition of formaldehyde oxidation. The oxidation of methanol was stimulated by the addition of glyoxylic acid, which increases the rate of H2O2 generation. Crotonaldehyde inhibited CO2 production from methanol, but caused a corresponding increase in formaldehyde accumulation. The partial sensitivity of CO2 production to inhibition by cyanamide or crotonaldehyde suggests that both the mitochondrial aldehyde dehydrogenase and formaldehyde dehydrogenase contribute towards the metabolism of formaldehyde which is generated from mixed-function oxidase activity or from methanol, just as both enzyme systems contribute towards the metabolism of exogenously added formaldehyde.     

Improvement in the persistence of microbial asparaginase and glutaminase in the circulation of the rat by chemical modifications

Three enzymes used in cancer chemotherapy (asparaginases from Escherichia coli and Erwinia carotovora and glutaminase from Achromobacter) were each reacted with four amino specific reagents (ethyl acetimidate, O-methylisourea, succinic anhydride, and formaldehyde/sodium borohydride). The half-lives of the modified enzymes measured in the blood of rats showed that guanidation, acetimidation and reductive alkylation were more likely to increase the persistence of the native enzymes than succinylation. However, the improvement in the persistence of any one enzyme after any one modification could not be predicted from the results with the others. It was concluded that changes in persistence caused by each modification were due to the different effects on the tertiary structure of each native enzyme. The advantages of chemical modification for increasing the persistence of enzymes over other methods such as encapsulation or aggregation are discussed.     

In vitro studies of aldehyde effects related to human respiratory carcinogenesis

Aldehydes are ubiquitous compounds which are generated from many both endogenous and exogenous sources. Primarily because certain aldehydes are respiratory toxicants and carcinogens in laboratory animals, and also because they are present in both tobacco smoke and automotive emissions, cultured human bronchial cells have been used to study the ability of aldehydes, i.e., acrolein and formaldehyde, to cause pathobiological effects associated with carcinogenesis. Comparative studies indicate that each aldehyde distinctly affects several molecular and cellular variables including colony-forming efficiency, clonal growth rate, membrane integrity, formation of cross-linked envelopes, levels of cytosolic free calcium, low-molecular-weight thiol status, DNA structure, i.e., formation of DNA single-strand breaks and DNA-protein cross-links, and various DNA repair mechanisms. In relation to the toxicity exerted by these agents, acrolein induces differentiation more readily than formaldehyde whereas formaldehyde causes much higher levels of genetic damage than acrolein. However, for all biological endpoints measured, acrolein on a molar basis is always more potent than formaldehyde. Taken together, a variety of effects that relate to cell death, accelerated epithelial terminal differentiation and genotoxicity are associated with aldehyde exposure, which in human airways may have a role in the pathogenesis of various diseases. In the development of cancer, the possible contribution of aldehydes from both intra- and extra-cellular sources may partly depend on the ability of target cells to detoxify and counteract those aldehyde-related effects believed to critically relate to multi-stage carcinogenesis.