Detection of traces of formaldehyde in pure air by gas chromatography and helium ionization detection

The sensitive helium ionization detector (HID) was used for the direct determination of ppm to ppb levels of formaldehyde in air. Two methods to generate formaldehyde in an air stream were evaluated. The first method utilized a paraformaldehyde permeation tube and the second utilized a motor driven syringe and a dilute solution of formaldehyde. The two methods were evaluated using gas chromatography with HID and spectrophotometry. The paraformaldehyde permeation tube generates only about 60% of the theoretical value, while the motor driven syringe was accurate for levels below 2 ppm; however, at a concentration of 13 ppm or above, oligomers or other chemical forms of CH2O are formed to decrease the concentration of gaseous CH2O produced.     

没食子酸-过氧化氢-甲醛体系中Co(Ⅱ)和Mn(Ⅱ)的化学发光同时测定

在较大量硫脲存在下,没食子酸-过氧化氢-甲醛体系中化学发光的动力学性质发生了变化,出现多峰现象,藉此实现了Co(Ⅱ)和Mn(Ⅱ)的化学发光同时测定。该法灵敏度高,选择性好,Co(Ⅱ)的测定范围是3×10^-5～2ppm,Mn(Ⅱ)是0.03～10ppm。     

新型三唑类抗真菌活性化合物毛细管电泳手性拆分及手性识别机理分子模拟研究

研究了7种新型三唑类抗真菌活性化合物的毛细管电泳法手性分离,利用计算机辅助分子模拟技术研究拆分机理。考察了8种中性环糊精手性添加剂,只有2,6-二甲基-β-环糊精对7种活性化合物都有手性识别能力。在30mmol/L NaH2PO4缓冲液中含2,6-二甲基-β-环糊精30mmol/L,用H3PO4调至pH 2.2,温度20℃,电压20kV,在此条件下7种活性化合物都能达到手性分离,其中4种活性化合物能达到基线分离(Rs>1.5)。应用计算机辅助分子模拟软件Discovery Studio 2.5/Sybyl/Gold模拟2,6-二甲基-β-环糊精与7种活性化合物主客体包结过程,并计算相互结合能,探讨手性识别机理,发现拆分结果与结合能的差异有关,结合能差异越大拆分结果越好。     

Analysis of repaglinide enantiomers in pharmaceutical formulations by capillary electrophoresis using 2,6-di-o-methyl-β-cyclodextrin as a chiral selector

This study used the general applicability of 2,6-didi-o-methyl-β-cyclodextrin (DM-β-CD) as the chiral selector in capillary electrophoresis for fast and efficient chiral separation of repaglinide enantiomers. A systematic study of the parameters affecting separation was performed with UV detection at 243 nm. The optimum conditions were determined to be 1.25% (w/v) DM-β-CD in 20 mM sodium phosphate (pH 2.5) as the running buffer and separation voltage at 20 kV. DM-β-CD had the best enantiomer resolution properties under the tested conditions, whereas other β-cyclodextrins showed inferior performances or no performance. The proposed method had a linear calibration curve in the concentration range of 12.5-400 μg/mL. The limit of detection was 100 ng/mL. The intra-day and inter-day precisions were 2.8 and 3.2%, respectively. Recoveries of 97.9-100.9% were obtained. The proposed method was fast and convenient, and was determined to be efficient for separating enantiomers and applicable for analyzing repaglinide enantiomers in quality control of pharmaceutical production.     

The role of water release from the cyclodextrin cavity in the complexation of benzoyl chlorides by dimethyl-β-cyclodextrin

The influence of temperature on the solvolysis of substituted benzoyl chlorides in the presence of dimethyl-β-cyclodextrin (DM-β-CD) was studied. Based on the influence of the DM-β-CD concentration on chemical reactivity in this process, the cyclodextrin has a catalytic effect on the solvolysis of 4-nitrobenzoyl chloride (4-NO₂) but an inhibitory effect on that of 4-methoxy-(4-MeO), 3-chloro-(3-Cl) and 3-trifluoromethyl-(3-CF₃) benzoyl chlorides. These disparate effects are related to a difference in reaction mechanism; thus, DM-β-CD catalyses associative solvolysis and inhibits dissociative solvolysis. Examining the influence of temperature on the solvolytic process allowed the stoichiometry of the host-guest complexes formed to be established. The formation constants for the complexes of meta-substituted benzoyl chlorides increased with increasing temperature. On the other hand, the equilibrium formation constants for the 1:1 host-guest complexes of para-substituted benzoyl chlorides exhibited the opposite trend. The equilibrium formation constant for 2:1 host-guest complexes for the para-substituted benzoyl chlorides increased with increasing temperature. These differences are ascribed to the release of water from the DM-β-CD cavity during the formation of the host-guest complex.     

Photolysis of formaldehyde: Relative quantum yields of H2 and CO in the wavelength range 270–360 nm

The ratio of H₂ and CO production from the photolysis of ppm concentrations of formaldehyde was measured at several wavelengths for two experimental conditions: in nitrogen with 80 ppm propene added, and in a 20:80 mixture of oxygne and nitrogen. The relative quantum yields for H atom generation are derived and compared with results of other authors.     

Low-Level Quantitation of Formaldehyde in Drug Substance by HPLC–UV

Formaldehyde has been highlighted as potential genotoxic impurity (GTI). Trace-level quantification of GTIs in drug substances requires sensitive, precise and accurate analytical methodologies for their estimation in drug substances and control. Analysis and estimation of formaldehyde is very challenging due to its properties namely volatility, high polarity, low molecular weight and over and above the absence of chromophore. This article presents a validated HPLC–UV method which is sensitive to quantification of formaldehyde in active pharmaceutical ingredient. As formaldehyde does not possess chromophore, the developed HPLC method involves derivatization with 2,4-dinitrophenylhydrazine. Using this method, the detection and quantitation limits achieved are 0.5 and 1.5 ppm, respectively. The calibration curve of formaldehyde was linear over the concentration range of 1.5–20 ppm. The method was found to be sensitive, precise and accurate and the proposed method has been successfully applied to estimate formaldehyde content in scale-up batches of bulk drug.

     

A rapid, simple method for determining formaldehyde in drinking water using colorimetric-solid phase extraction

Formaldehyde has been detected in drinking water supplies across the globe and on board NASA spacecraft. A rapid, simple, microgravity-compatible technique for measuring this contaminant in water supplies using colorimetric-solid phase extraction (C-SPE) is described. This method involves collecting a water sample into a syringe by passage through a cartridge that contains sodium hydroxide, to adjust pH, and Purpald, which is a well-established colorimetric reagent for aldehydes. After completing the reaction in the syringe by agitating for 2 min on a shaker at 400 rpm, the 1.0-mL alkaline sample is passed through an extraction disk that retains the purple product. The amount of concentrated product is then measured on-disk using diffuse reflectance spectroscopy, and compared to a calibration plot generated from Kubelka-Munk transformations of the reflectance data at 700 nm to determine the formaldehyde concentration. This method is capable of determining formaldehyde concentrations from 0.08 to 20 ppm with a total work-up time of less than 3 min using only 1-mL samples.     

The determination of aldehydes in the exhaust gases of LPG fuelled engines

Summary The exhaust gas of a LPG fuelled engine is drawn through two bubblers in series in an ice bath, and filled with saturated 2,4-dinitrophenylhydrazine in 2M HCl. After heating the derivatives are extracted with toluene-cyclohexane and 1l samples injected on-column on a OV1 capillary column. Using an FID the lower limit of detection is 15–18 pg for formaldehyde (about 8–10 ppbv for a 16l exhaust sample). Taking the blank into account, the limit is about 40 ppbv.The exhaust gases of a LPG-fuelled engine contain formaldehyde, acetaldehyde, propionaldehyde, acrolein and acetone. Carbonyl compounds of more than 3 C-atoms were not found in detectable amounts. The engine was rund under stoichiometric, lean and rich air/fuel conditions. Under rich conditions the concentrations of the aldehydes were: formaldehyde 2.8 ppm, acetaldehyde 1.3 ppm, propionaldehyde 0.06 ppm, acrolein 0.03 ppm, acetone 0.17 ppm; under stoichiometric conditions: 4.5, 1.6, 0.10, 0.03 and 0.18 ppm respectively; under lean conditions 17.0, 2.9, 0.13, 0.07 and 0.27 ppm respectively. These figures demonstrate the necessity of measuring aldehydes in exhaust gases of LPG-fuelled engines.     

Quantitative Analysis of Formaldehyde Using UV‐VIS Spectrophotometer Pattern Recognition and Artificial Neural Networks

Abstract

This study is focused on the quantitative analysis of formaldehyde in aqueous solution using a Fluoral‐P reagent and describes the characterization of the reaction, including the effect of reagent concentrations, pH, response time, dynamic range, reproducibility, photostability, and selectivity by using an ultraviolet‐visible (UV‐VIS) spectrophotometer. The relative standard deviation value was 1.79 to 2.12%. The dynamic range of the complex gives a linear stimulation of 0.00 to 3.60 ppm for the concentration of formaldehyde. The reproducibility of this study is high, with 1.79 and 2.12% for 20 and 40 ppm of formaldehyde, respectively. The interference from acetaldehyde (formaldehyde: acetaldehyde=1:100) was lower than 2.10%. In addition, the application of artificial neural networks to quantitative analysis for formaldehyde has also been done in this study to optimize the dynamic range of formaldehyde involved in the formation of Fluoral‐P–formaldehyde complex. A three‐layer feed‐forward network and the back propagation algorithm‐operated training process were used in this study. For quantitative analysis of formaldehyde, artificial neural networks, networking with 23 hidden neurons and 40,000 cycle numbers with 0.001% learning rate, produce the best training results, with sum‐squared error value 0.5847.     

The solvolysis of benzoyl halides as a chemical probe determining the polarity of the cavity of dimethyl-β-cyclodextrin

The solvolysis of benzoyl halides (BzX) in the presence of dimethyl-β-cyclodextrin (DM-β-CD) was studied. Methylation or hydroxyalkylation of the hydroxyl groups in β-cyclodextrin increases their solubility and the highest possible concentration of DM-β-CD that can be dissolved in water is 0.2 M. The ability to use more readily soluble CDs may allow one to determine the stoichiometry of their complexes and the properties of water held in their cavity with increased precision. Based on the experimental results, this cyclodextrin forms host-guest complexes of variable stoichiometry where two reaction pathways are considered: in water and in the internal cavity of the cyclodextrin. We determined the rate constants for the halides in their reaction inside the internal cavity. This allowed the influence of the substituent and leaving group on the reactions in the bulk water and the internal cavity of DM-β-CD to be compared. Depending on whether the solvolysis reaction is preferentially associative or dissociative, the presence of the cyclodextrin has a catalytic or inhibitory effect, respectively.     

High-performance liquid chromatographic determination of dopamine sulfoconjugates in urine after L-dopa administration

A procedure was developed for the separation and determination of dopamine-3-O-sulfate (DM-3-S) and dopamine-4-O-sulfate (DM-4-S) in the urine of subjects administered L-DOPA. The method consists of sample preparation using cation- and anion-exchange resins followed by determination of the sulfates by high-performance liquid chromatography. The addition recoveries were 96 +/- 2.9% (S.D.) for DM-3-S and 93 +/- 3.0% (S.D.) for DM-4-S. Twenty samples could be measured per day. When every 2-h urine specimen from normal subjects was analyzed after L-DOPA administration (0.5 g), the maximum excretion of each sulfate was observed in the second 2-h specimen. For the first 6 h 7.5 +/- 1.5% (S.D.) of the administered L-DOPA was excreted as DM-O-sulfates. During this time, the ratio of DM-4-S to the DM-O-sulfates was 11.7 +/- 0.58% (S.D.).     

Interaction of Natural and Modified β-Cyclodextrins with a Biological Membrane Model of Dipalmitoylphosphatidylcholine

Lipid vesicles made up of dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) were used as a biological membrane model to investigate the interaction between natural and modified β-cyclodextrins and these membrane bilayers. Differential scanning calorimetry was used to study the thermotropic behavior of the DPPC vesicles and any change caused by the presence of cyclodextrins. The presence of dimethyl-β-cyclodextrin (DM-β-CyD) triggered a reduction in the enthalpy values related to the main transition peak from gel state to liquid crystal phase of DPPC aqueous dispersions, as a function of the DM-β-CyD molar fraction: the larger the amount of DM-β-CyD, the greater the reduction in ΔHvalues. This effect was probably due to the ability of DM-β-CyD to extract and to complex the DPPC molecules forming the phospholipid vesicles. The presence of β-cyclodextrin (β-CyD) or hydroxypropyl-β-cyclodextrin (HP-β-CyD) caused no particular alteration in the thermotropic parameters of DPPC vesicles, whereas trimethyl-β-cyclodextrin (TM-β-CyD) at molar fractions higher than 0.12 caused broadening of the transition peak due to a possible interaction with the hydrophobic part of the bilayers. Experiments on DPPC–cholesterol (10 mol%) vesicles showed the capability of β-CyD and TM-β-CyD to extract cholesterol from the ordered bilayer structures, triggering an alteration in the lipid constituents of the membranes. HP-β-CyD caused no variation in the thermotropic parameters of the DPPC–cholesterol (10 mol%) vesicles. The findings show that HP-β-CyD seems the most suitable molecular drug carrier forin vivoadministration.     

Bemerkung zur Formaldehydbestimmung unter Verwendung von komplex gebundenem Schwefeldioxid

Zusammenfassung Arbeitsweisen zur Bestimmung von HCHO-Spuren werden angegeben. Die Bestimmungsgrenze ist 0,0128 ppm, die Standardabweichung für Konzentrationen von 0,0128 bis 0,20 ist 0,00513, für Konzentrationen von 0,40 bis 2,0 beträgt sie 0,0139 ppm HCHO.

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Summary Procedures are given for determining traces of formaldehyde. The determination limit is 0.0128 ppm, the standard deviation is 0.00513 for concentrations from 0.0128 to 0.20, and 0.0139 ppm formaldehyde for concentrations from 0.40 to 2.0.

     

Spectrophotometric determination of formaldehyde in air

A spectrophotometric method for the determination of formaldehyde in air is described, based on the colour reaction of formaldehyde, p-aminoazobenzene and sulphur dioxide in hydrochloric acid medium. Beer's law is obeyed at 505 nm in the range 2-12 mug of formaldehyde per 25ml of final solution (0.08-0.48 ppm). Optimum conditions for colour development, and possible interferences, have been studied.     

Cable-Like Core–Shell Mesoporous SnO2 Nanofibers by Single-Nozzle Electrospinning Phase Separation for Formaldehyde Sensing

In this study, we have developed a simple and efficient single-nozzle electrospinning strategy involving the phase separation of polystyrene and poly(vinylpyrrolidone) to construct cable-like core–shell mesoporous SnO₂ nanofibers. Compared with traditional multi-axial electrospinning approaches to the synthesis of core–shell nanofibers, the single-nozzle electrospinning process requires no complex multi-axial electrospinning setups or post-treatments, just drying and annealing after electrospinning. The obtained SnO₂ nanofibers show promise as a sensing material for formaldehyde at low concentrations, the detection limit being about 1 ppm. Furthermore, the nanofibers exhibited good cycling stability and selectivity, with response and recovery times toward 10 ppm formaldehyde being approximately 18 and 196 s, respectively, at an operating temperature of 195 °C.     

Badge-type diffusive sampler using 3-methyl-2-benzothiazolinone hydrazone for measuring formaldehyde in indoor air.

The evaluation of a badge-type diffusive sampler for measuring formaldehyde using 3-methyl-2-benzothiazolinone hydrazone (MBTH) was investigated. On average, the formaldehyde concentration in blanks was reduced by approximately 31% by cleaning procedures. The cleaning techniques did not significantly differ in effectiveness. The maximum sampling rate was 22.4 +/- 3.5 mL min(-1) at MBTH concentrations of 0.05%. The formaldehyde concentration in blanks did not appreciably increase over a period of about 1 month at room temperature, and was 0.36 +/- 0.03 microg, with a relative standard deviation of 8%. The diffusive sampler had good precision and accuracy for measuring formaldehyde in indoor environments. For a 24-h exposure time, the limits of detection and quantification calculated with the field blanks were 9.7 and 13.8 ppb, respectively. The minimum exposure times were calculated based on the measured and calculated limits of quantification, the sampling rate, and the atmospheric formaldehyde concentration. The capacity of the diffusive sampler with 0.5% MBTH was 3 ppm h(-1), approximately 1.5-times the capacity when the MBTH concentrations were 0.05%.     

A sensitive microwave cavity spectrometer: Direct detection of formaldehyde in automobile exhaust

A newly constructed sensitive microwave cavity spectrometer of the Stark-dc-voltage sweep type has revealed that formaldehyde in concentrations as small as 0.2 ppm can be directly detected by using the 7₂₅ ← 7₂₆ rotational line. The cavity resonator is operated in the rectangular TE_1,0,20 mode. A sample of automobile-engine exhaust showed a strong spectrum indicating a concentration of 24 ppm of formaldehyde.     

Bioremediation Potential of Formaldehyde by the Marine Microalga <Emphasis Type="Italic">Nannochloropsis oculata</Emphasis> ST-3 Strain

The present work is intended to investigate biodegradation of formaldehyde by the marine microalga Nannochloropsis oculata ST-3 strain. Formaldehyde concentration in the medium decreased with the growth of the ST-3 strain. It is observed that the degradation of formaldehyde concentration depends on the increased cell number of the ST-3 strain. The ST-3 strain which was adapted to formaldehyde stepwise was able to tolerate to 19.9 ppm formaldehyde and degrade 99.3% of it in the medium for 22 days. Tolerance and degradation ability of formaldehyde by the ST-3 strain was improved by stepwise increasing of the formaldehyde concentration. Transformation of [¹³C]formaldehyde in the medium with the passage of incubation was monitored by using a nuclear magnetic resonance (NMR) spectrometer. Formaldehyde was transformed into formate, and these two substances degraded in the medium with the passage of incubation as clearly shown by the NMR spectrum.     

Determination of free formaldehyde in nail varnish by HPLC

Summary Free formaldehyde in cosmetic samples can be determined by HPLC and post-column derivatisation as a lutidine derivative. Applying this method to nail varnishes results in poor reproducibility. It is demonstrated that most of the formaldehyde determined is generated by hydrolysis of the resin in aqueous solution during sample clean-up, extraction and determination procedures. The hydrolysis is slowest in acidic solution at low temperature. The formaldehyde concentration is thus a function of the method of determination. Kinetic evaluation of its formation by hydrolysis shows that the initial concentration of free formaldehyde in the resin is below 100 ppm.