催化反应热诱导激光光偏转法测定铁

报道催化反应热诱导激光光偏转分析法研究，将其应用于铁催化过氧化氢氧化二苯胺磺酸钠反应体系。探讨了催化反应的最佳条件及共存离子的影响。在铁浓度为９５×１０－４～９５×１０－６ｍｏｌ／Ｌ之间得到了良好线性关系。进行了赤铁矿中总铁量的测定，结果满意。     

依波西隆蓝与蛋白质作用的共振光散射光谱及其分析应用

微量蛋白质对依波西隆蓝的共振光散射产生增强作用，且增强程度与蛋白质浓度有良好的线性关系，由此建立了测定蛋白质的灵敏共振光散射分析方法。利用该方法测定合成样品和血清样品中的蛋白质，均获得了可靠的分析结果。     

化学反应热诱导激光光偏转分析法研究

探讨了化学反应热诱导激光光偏转分析法的基本原理及各种影响因素。用此法成功地进行了溶液酸碱中和反应、氧化还原反应、络合反应、沉淀反应以及胃动力新药吗丁啡片剂中有效药成分多潘立酮的分析测定,取得了满意结果。该法仪器装置简单,测定线性范围宽,应用范围广。     

激光光热光谱分析特性比较

本文详细比较了激光光热偏转,激光热透镜和激光光热折射光谱法的基本原理,光学构型和分析化学特性。并讨论了激光光热光谱法的分析现状和应用潜力。     

横向光热偏转技术检测双硫腙（H2Dz）固体试样光谱特性

用横向光热偏转技术测量双硫腙固体试样的光谱特性及Ｈ２Ｄｚ的浓度与横向光热偏转辐度之间的关系，检测限可达ｎｇ量级，为固体不透明材料的微量特性分析提供了一个简便的方法。     

激光功率和积分时间对表面增强拉曼光谱的影响EI北大核心CSCD

表面增强拉曼光谱(SERS)技术能够有效增强低浓度样品的拉曼光谱强度,然而由于SERS的结构、材质等工艺原因,SERS实际应用中往往由于未能正确选择激光功率与积分时间而导致测量效果显著下降。本文以浓度为2,0.08μg/mL的三聚氰胺溶液样品、Au@Ag NPs纳米柱结构固态SERS基底为例,使用自主搭建的便携式拉曼光谱仪,采集不同激光功率和积分时间下的SERS光谱,使用算法平滑光谱、计算光谱基线,得到样品SERS光谱强度和SERS光谱基线强度变化趋势。实验表明,激发光源功率和积分时间改变时,SERS光谱基线强度在不同光谱区域变化幅度不同,部分光谱区域基线强度的变化幅度远大于样品光谱强度,导致使用拉曼光谱仪进行光谱测量时极易造成光谱强度饱和,影响低浓度样品的测量。临时更换样品试剂或SERS基底又会增加成本,且操作繁琐。研究发现,通过控制激光功率和积分时间这2个简单可控的变量,可以在一定程度上抑制SERS光谱基线、提高样品光谱强度,从而避免因光谱强度易饱和而无法测得低浓度样品光谱信号的问题。     

小檗碱共振光散射法测定脱氧核糖核酸

研究了小檗碱与DNA作用的共振光散射光谱，在pH＝2.0-2.8的范围内，DNA的加入导致小檗碱共振光散射的增强，在308nm处，存在一共振光散射增强峰，其强度与DNA的浓度呈线性关系，据此建立了一种测定DNA的共振光散射法。该方法的线性范围为0－600μg/L，相关系数为0.9972，检出限为19.9μg/L。将该方法用于混合样品中DNA的测定。结果令人满意。     

气相色谱-红外光声检测器联机检测醚类化合物

激光诱导光声光谱是检测痕量气体的一种极为有用的技术。采用频率精确的CO_2激光光源对痕量气体如氯乙烯、乙烯、六氟化硫的检测浓度已达10~(-8)级,在环境监测上有着十分重要的意义。近年来,为了提高光声检测的选择性,扩大其应用范围,     

化学反应热诱导激光光束偏转分析法

文中综述了化学反应热诱导激光光束偏转分析法的基本原理、仪器装置、应用及发展前景。     

荧光猝灭法和动态光散射法研究尿素-水混合溶剂中牛血清 白蛋白的构象变化

利用荧光猝灭法和动态光散射法测定尿素-水混合溶剂中牛血清白蛋白(BSA)与荧光素的结合距离和BSA的流体动力学半径, 并通过分析BSA和荧光素在BSA-尿素-水和荧光素-尿素-水三元体系以及BSA-荧光素-尿素-水四元体系中荧光光谱的变化, 探讨尿素与蛋白质分子在水溶液中相互作用的机理及其对蛋白质构象的影响. 结果显示, BSA的3个结构域在尿素-水混合溶剂中具有不同的稳定性, 其中结构域III在尿素-水混合溶剂中是不稳定的, 而结构域I和结构域II分别在尿素浓度大于3.0和4.0 mol•L－1的混合溶剂中发生去折叠. 试验发现, BSA结构域II在低于去折叠浓度的尿素-水混合溶剂中形成更为紧密的构象, 这一现象可以归因于尿素与BSA结合引起的“蛋白质粘稠效应”     

Determination of Kinetic Parameters and Metal Ions in Urea-Urease System Based on the Biochemical Reaction Heat Induced Laser Beam Deflection

Reaction heat induced laser beam deflection is a new analytical method which came in tobeing in 1993', by probing the gradient of the refraction index which was induced byreaction heat with a laser probe beam, one can relate the laser beam deflection to theconcentration of the sample.In this paper, the method was used for the study of the kinetic process for ureaurease system. It is well known that urease catalyzes the hydrolysis of urea as follows fUreaseNHZCONHZ HZO~ CO2 2NH3 QThe pro…     

Fluorometric determination of urea in alcoholic beverages by using an acid urease column-FIA system

An acid urease column was applied to a fluorometric flow-injection analysis (FIA) system as a recognition element for determination of urea in rice wines.

The acid urease has specific properties of showing its catalytic activity in low pH range and tolerance to ethanol in comparison to those of a urease from jack-beans. The enzymes were covalently immobilized onto porous glass beads with controlled pore size and then, packed into a small polymer column. The flow-type of the biosensing system was assembled with a sample injection valve, the immobilized enzyme column, and a flow-through quartz cell attached to a fluorescent spectrophotometer. Citrate buffer (50 mM, pH 5.0) as the carrier solution was continuously pumped through the system. Sample solutions were introduced into the system via a rotary injection valve. A standard urea solution was measured through monitoring variations in fluorescent intensity attributable to fluorescent isoindole derivatives formed by coupling with ammonia molecules released in the enzymatic hydrolysis of urea and orthophthalaldehyde reagents. The fluorescent intensity was measured under the conditions of λ_ex = 415 nm and λ_em = 485 nm. A wide, linear relationship was obtained between the concentration of urea (1.0–100 μM) and the variation in fluorescent intensity. The monitoring did not suffer from ethanol and various amino acids contained in rice wines. Real samples pretreated with ion exchange resins for removal of endogenous ammonia were introduced into the FIA system and urea in the samples was determined. These results were compared with those obtained with use of an F-kit method. The proposed FIA system should present sensitive, selective and convenient analysis of urea in alcoholic beverages.     

Novel determination system for urea in alcoholic beverages by using an FIA system with an acid urease column.

A novel determination method for urea using an acid urease column-FIA system was developed, and the system was applied to the determination of urea in rice wine. This novel FIA system was characterized by CO2 detection due to the property of acid urease and by a microfluidic gas-diffusion device with the use of an ultra-thin hollow fiber membrane. A biosensing system fabricated in this study was assembled with a double-plunger pump, a sample-injection valve, an immobilized acid urease column as a recognition element for the assay of urea, a gas-diffusion unit, and a flow-type spectrophotometer. The gas-diffusion unit consisted of a double-tubing structure in which the outer tubing was made of PTFE (i.d. 1.0 mm; o.d. 1.5 mm) and the inner tubing was of porous PTFE (i.d. 0.19 mm; o.d. 0.25 mm). Standard urea solutions (20 microl) were measured through monitoring variations in the absorbance of a coloring agent solution resulting from a pH shift due to carbon dioxide molecules being enzymatically generated. A wide and linear relationship was obtained between the concentration of urea (16 microM - 1.0 mM) and the change in absorbance. This FIA system has great advantages that the system did not suffer from ammonia and ethanol in samples. This system, armed with a microfluidic gas-diffusion device, was applicable to the determination of various substrates of many kinds of decarboxylase, amino-acid oxidase, and amino-acid oxygenase, producing CO2 and NH3 molecules.     

Liquid crystal-based sensors for the detection of heavy metals using surface-immobilized urease

In this study, a new method for the detection of heavy metals in aqueous phase was developed using liquid crystals (LCs). When UV-treated nematic LC, 4-cyano-4'-pentyl biphenyl (5CB) that was confined in the urease-modified gold grid was immersed in a urea solution, an optical response from bright to dark was observed under a polarized microscope, indicating that a planar-to-homeotropic orientational transition of the LC occurred at the aqueous/LC interface. Since urease hydrolyzes urea to produce ammonia, which would be ionized into ammonium and hydroxide ions, the main product of the photochemically degraded 5CB, 4-cyano-4'-biphenylcarboxylic acid (CBA), was deprotonated and self-assembled at the interface, inducing the orientational transition in the LC. Due to the high sensitivity and rapid response of this system, detection of heavy metal ions was further exploited. The divalent copper ion, which could effectively inhibit the activity of urease, was used as a model heavy metal ion. The optical appearance of the LC did not change when urea was in contact with the copper nitrate hydrate-blocked urease. After the copper-inhibited urease was reactivated by EDTA, a bright-to-dark shift in the optical signal was regenerated, indicating an orientational transition of the LC. This type of LC-based sensor shows high spatial resolution due to its optical characteristics and therefore could potentially be used to accurately monitor the presence of enzyme inhibitors such as heavy metal ions in real-time.     

A Powder Based Polyaniline Carbon Paste Electrode for Urea Analysis

A new polyaniline carbon paste electrode prepared by mixing polyaniline (emeraldine), nafion, graphite powder and urease for urea analysis was exploited. The ratio of polyaniline, nafion, urease and graphite for the construction of the electrodes and the optimal conditions for urea determination were studied. The detection limit of this sensor for urea is 5 μM and the linearity from 5 μM to 7.5 mM is obtained in FIA. This sensor has a response time of 90s and shows good reproducibility and stability (RSD, 6.3%, n = 43). The blood samples from a patient during blood dialysis were taken and analyzed. The urea concentrations in blood obtained from this sensor are comparable with urea test kit method.     

Elaboration of Urease Adsorption on Silicalite for Biosensor Creation

A possibility of efficient urease adsorption on silicalite for the purpose of biosensor creation was investigated. The procedure of urease adsorption on silicalite is notable for such advantages as simple and fast performance and non‐use of toxic or auxiliary compounds. Optimal conditions for modifying transducer surfaces with silicalite and subsequent urease adsorption on these surfaces were selected. The working parameters of the created biosensor were optimized. The developed biosensor with adsorbed urease was characterized by good intra‐reproducibility (RSD – 4.5 %), improved inter‐reproducibility (RSD of urea determination is 9 %) and operational stability (less than 10 % loss of activity after 10 days). Besides, the developed method for enzyme adsorption on silicalite was compared with the traditional methods of urease immobilization in biosensorics. Working conditions of the produced biosensor (pH and ionic strength) were shown to be close to those of the biosensor based on urease immobilized in GA vapor. For these reasons, it was concluded that the method of enzyme adsorption on silicalite is well‐suited for biosensor standardization aimed at its further manufacture.     

Urea Biosensor Based on Electrochromic Properties of Prussian Blue

Prussian blue (PB) is an electrochromic material, which can be used as a signal transducer in the formation of optical urea biosensors. The previous researches in electrochromic properties of PB demonstrated the optical PB response to ammonium ions, which occurs when ammonium ions are interacting with PB layer at a constant 0.2 V vs Ag|AgCl|KCl_sat potential. In this work PB optical dependence on ammonium ions concentration was applied in the formation of electrochromic urea biosensor. Biosensor was formed by modifying the optically transparent indium tin oxide (ITO) coated glass electrode (glass/ITO) with Prussian blue layer and immobilizing urease (glass/ITO/PB‐urease). Calibration curve showed the linear dependency (R²=0.995) between the change of maximal absorbance (ΔA) and urea concentration in concentration range varying from 3 mM to 30 mM. The highest sensitivity (4 ΔA M^?1) of glass/ITO/PB‐urease biosensor is in the concentration range from 7 mM to 30 mM. It was determined that working principle of the glass/ITO/PB‐urease biosensor is not related to pH changes occurring during enzymatic hydrolysis of urea.     

Amperometric Urea Biosensor Using Aminated Glassy Carbon Electrode Covered with Urease Immobilized Carbon Sheet,Based on the Electrode Oxidation of Carbamic Acid

A large oxidation current can be observed when ammonium carbamate aqueous solution is electrolyzed using a glassy carbon electrode (GCE) at a potential exceeding 1.0 V vs. Ag/AgCl and amino groups are introduced at the surface of the GCE. Aminated GCE exhibits the electrocatalytic activity of the oxidation of ammonium carbamate that is produced from urea as an intermediate product of urease reaction, and a distinct oxidation current is observed when the aminated GCE is used to oxidize the urea in the urease solution. A novel amperometric determination method to detect urea has been developed. This method is based on the electrooxidation of carbamic acid produced during urease reactions. Urease is immobilized to polymaleimidostyrene (PMS) coated on the insulated amorphous carbon sheet set on the aminated GCE surface. A good linear relationship is observed between urea concentration and the electrolytic current of the urease‐immobilized electrode in the concentration range from 0.5 mM to 21.0 mM. The proposed urea biosensor has an effective merit in that the interference resulting from ammonia and pH change caused by the urease reaction can be eliminated, differing from conventional urea biosensors.     

Determination of urea with an ammonia gas-sensitive semiconductor device in combination with urease

An ammonia gas-sensitive Ir/Pd MOS capacitor is used for urea determinations with the aid of urease in two different systems. One combination utilizes a reaction column with immobilized urease in a flow-injection system. The lower limit of urea detection for 150-μl samples was 0.2 μM. Urea in whole blood and blood serum was determined after a 500-fold dilution, and 15 samples per hour could be assayed. The relative standard deviation was 4.6% (n=10). Recovery tests were satisfactory. Values obtained for urea in serum correlated well with those from a spectrophotometric method. The other combination is based on a small flow cell with free urease enclosed between a dialysis membrane and a gas-permeable membrane. Urea was determined in the concentration range 0.01–50 mM. The enzyme probe could be used for up to four days without changes of behaviour.