Cataluminescence‐based sensors: principle,instrument and application

The cataluminescence (CTL)‐based sensor is a new promising type of chemical transducer, and has attracted much attention of researchers for its potential versatile applications in public safety, emission control and environmental protection. In this review, we briefly introduce the development history of CTL‐based sensors and summarize existing explanations of the CTL reaction mechanism as well as three research strategies for mechanism the CTL mechanism. In the following, all the function units of a typical CTL‐based sensor system are described and the investigation of the sensor materials. CTL‐based sensor arrays, are discussed in detail. We classify the recent novel hyphenated techniques based on CTL coupled to other analysis techniques into the preconcentration‐CTL hyphenated technique, nebulization‐CTL hyphenated technique, plasma‐assisted CTL technique and tandem CTL technique according to the type of analysis combined with CTL and provide a detailed account of novel hyphenated techniques. Owing to the appearance of these novel techniques, the application range of CTL has been expanded as well as the sensitivity and selectivity of CTL system has been greatly improved. Finally, the applications of CTL‐based sensor and sensor arrays in the last several years are classified and summarized. Copyright © 2014 John Wiley & Sons, Ltd.     

Genetically encoded sensors for measuring histamine release both in vitro and in vivo

1. Download : Download high-res image (185KB)
2. Download : Download full-size image

     

Nanostructured material-based optical and electrochemical detection of amoxicillin antibiotic

The penicillin derivative amoxicillin (AMX) plays an important role in treating various types of infections caused by bacteria. However, excessive use of AMX may have negative health effects. Therefore, it is of utmost importance to detect and quantify the AMX in pharmaceutical drugs, biological fluids, and environmental samples with high sensitivity. Therefore, this review article provides valuable and up-to-date information on nanostructured material-based optical and electrochemical sensors to detect AMX in various biological and chemical samples. The role of using different nanostructured materials on the performance of important optical sensors such as colorimetric sensors, fluorescence sensors, surface-enhanced Raman scattering sensors, chemiluminescence/electroluminescence sensors, optical immunosensors, optical fibre-based sensors, and several important electrochemical sensors based on different electrode types have been discussed. Moreover, nanocomposites, polymer, and MXenes-based electrochemical sensors have also been discussed, in which such materials are being used to further enhance the sensitivity of these sensors. Furthermore, nanocomposite-based photo-electrochemical sensors and the market availability of biosensors including AMX have also been discussed briefly. Finally, the conclusion, challenges, and future perspectives of the above-mentioned sensing techniques for AMX detection are presented.     

电化学阻抗谱在生物传感器研究中的应用进展

电化学阻抗谱(EIS)是近年快速发展起来的一种电化学分析方法。它具有良好的界面表征作用,特别适合于分析电极表面生物敏感膜的制备、生物学反应的动力学机制,已逐渐成为生物传感器研究的有效辅助方法。简要概述了EIS技术的原理,及其在各种生物传感器中的应用进展。     

Toward real-time continuous brain glucose and oxygen monitoring with a smart catheter

Oxygen and glucose biosensors have been designed, fabricated, characterized and optimized for real-time continuous monitoring on a new smart catheter for use in patients with traumatic brain injury (TBI). Oxygen sensors with three-electrode configuration were designed to achieve zero net oxygen consumption. Glucose sensors were based on the use of platinum nanoparticle-enhanced electrodes that were modified with polycation and glucose oxidase immobilized by chitosan matrix. An iridium oxide electrode was developed to work as a biocompatible reference electrode with enhanced durability and stability in the biological solutions. A study of the effect of temperature on oxygen sensor performance, and both temperature and oxygen effects on glucose sensor performance were accomplished to enhance their operative stability and provide useful information for in vivo applications. A new methodology for automatic correction of the temperature and oxygen dependence of biosensor outputs is demonstrated through programmed LabView™ software. In vitro experiments in both physiological and pathophysiological ranges (oxygen: 0–60 mmHg; glucose: 0.1–10 mM; temperature: 25–40 °C) with clinical samples of cerebrospinal fluid obtained from TBI patients have demonstrated stable measurements with enhanced accuracy, indicating the feasibility of the sensors for a real-time continuous in vivo monitoring.     

Characterisation of operation conditions and online monitoring of physiological culture parameters in shaken 24-well microtiter plates

A new online monitoring technique to measure the physiological parameters, dissolved oxygen (DO) and pH of microbial cultures in continuously shaken 24-well microtiter plates (MTP) is introduced. The new technology is based on immobilised fluorophores at the bottom of standard 24-well MTPs. The sensor MTP is installed in a sensor dish reader, which can be fixed on an orbital shaker. This approach allows real online measurements of physiological parameters during continuous shaking of cultures without interrupting mixing and mass transfer like currently available technologies do. The oxygen transfer conditions at one constant shaking frequency (250 1/min) and diameter (25 mm) was examined with the chemical sulphite oxidation method. Varied filling volumes (600–1,200 μL) of Escherichia coli cultures demonstrated the importance of sufficient oxygen transfer to the culture. Cultures with higher filling volumes were subjected to an oxygen limitation, which influenced the cell metabolism and prolongated the cultivation time. The effects could be clearly monitored by online DO and pH measurements. A further study of different media in an E. coli fermentation elucidated the different growth behaviour in response to the medium composition. The MTP fermentations correlated very well with parallel fermentations in shake flasks. The new technique gives valuable new insights into biological processes at a very small scale, thus enabling parallel experimentation and shorter development times in bioprocessing.     

Structural characterization and bioimaging of Zn2+ using meta-benziporphodimethene analogue

‘Prevention is better than cure, especially when something has no cure.’ Cancer, in most patients is detected at the stage beyond which it becomes noncurative. Therefore, the early detection of cancer cells can play a crucial role in enhancing the chances of a patient's survival. In this light, we present a nonfluorescent receptor used for the detection of Zn²⁺ ion in MDA-MB-231 carcinoma cells that exhibits fluorescence turn-on behaviour upon binding with the metal ion. In this work, the synthesis of 11,16-bis(2,6-difluorobenzene)-6,6,21,21-tetramethyl-meta-benziporpho-6,21-dimethene and its Zn²⁺ chloride complex have been reported. The compounds were fully characterized using UV–visible, nuclear magnetic resonance (NMR), infrared (IR) and mass spectrometry. Furthermore, the X-ray polymorphs of a meta-benziporphodimethene analogue were added. The study of its bioimaging applications in MDA-MB-231 breast cancer cells for the detection of Zn²⁺ ions is reported.     

Dynamic concentration challenges for biosensor characterization

A method and apparatus are described for characterization of the steady state and dynamic response of biosensors. The apparatus produces a steady stream of homogeneously mixed analyte whose concentration can be fixed at discrete values or varied continously. The device is ideally suited for continously operated biosensors, but is also effective for biosensors that operate in discrete sampling modes. The system permits simultaneous testing of several sensors and determination of the accuracy, precision and repeatability of sensor response. The characteristics of this testing apparatus were validated with ferrocyanide and glucose as indicators. As an example of use of the apparatus, concentration ramps were created and used to complement conventional step changes for characterizing an implantable glucose sensor. The ramp rate can be adjusted easily by scaling the apparatus to simulate the rate of concentration change anticipated during actual monitoring situations.     

The FG loop of a heme-based gas sensor enzyme, Ec DOS, functions in heme binding, autoxidation and catalysis

Ec DOS is a heme-based gas sensor enzyme that catalyzes conversion from cyclic-di-GMP to linear-di-GMP in response to gas molecules, such as oxygen, CO and NO. Ec DOS contains an N-terminal heme-binding PAS domain and C-terminal phosphodiesterase domain. Based on crystal structures of the isolated heme-binding domain, it is suggested that the FG loop is involved in intra-molecular signal transduction to the catalytic domain. We generated nine full-length proteins mutated at ionic and non-ionic polar residues between positions 83 and 96 corresponding to the F-helix and FG loop, and examined the heme binding properties, autoxidation rates, and catalytic activities of mutant proteins. N84A and R85A mutant proteins displayed lower heme binding affinities, consistent with the finding that Asn84 interacts with propionate of protoporphyrin IX, and Arg85 with Asp40 on the heme proximal side. Autoxidation rates (0.058-0.54 min⁻¹) of R91A, S96A and K89A/R91A/E93A mutant proteins were significantly higher than that (0.0053 min⁻¹) of wild-type protein, suggesting that these residues in the FG loop form heme distal architecture conferring stability to the Fe(II)-O₂ complex. Catalytic activities of N84A and R85A mutant proteins with low heme affinity were significantly higher than those of wild-type protein in the absence of gas molecules. Accordingly, we propose that loss of heme binding enhances basal catalysis without the gas molecule, consistent with previous reports on heme inhibition of Ec DOS catalysis.     

Development of a new kind of dual modulated QCM biosensor

To distinguish the mass loading effect from the total frequency change is a problem in the application of a quartz crystal microbalance (QCM) biosensor in the liquid phase. Based on the characteristic damping theory, this paper proposes a new method of dual modulation to solve this problem. Usingg polyethyleneimine to immobilize anti-SE (staphylococcin enterotoxin) antibody (C₂ type), a dual modulated QCM SE biosensor was developed and the experiment proved that it has little cross-reaction with B-type SE. The measuring curve of the sensor was also determined through experiment.     

微生物传感器及其在氨基酸分析中的应用

介绍了微生物传感器的发展状况、制作方法,综述了微生物传感器在氨基酸分析中的应用,引文献４２篇。     

核酸生物传感器及其研究进展

核酸生物传感器在涉及分子生物学的研究领域具有重要意义.为适应分子生物学及其相关学科的发展需要,其研究正成为90年代生物传感技术研究热点.文章对核酸生物传感器的工作原理、分类、研究现状以及发展趋势作了较详细的介绍.     

A sugar-aza-crown ether-based fluorescent sensor for Cu and Hg ions

A sugar-aza-crown ether (SAC)-based fluorescent sensor 4 was prepared. It contains a pyrene as the fluorophore and its fluoroionophoric properties toward transition metal ions were investigated. Chemosensor 4 exhibits highly selective recognition toward Cu²⁺ and Hg²⁺ ions among a series of tested metal ions in methanol solution. The association constants for 4*Cu²⁺ and 4*Hg²⁺ in methanol solution were calculated to be 7.4 × 10¹ M⁻¹ and 4.4 × 10³ M⁻¹, respectively. Chemosensor 4 formed complexes with the Cu²⁺ or Hg²⁺ ion at a 1:1 ligand-to-metal ratio with a detection limit of 1.3 × 10⁻⁴ M Cu²⁺ and 1.26 × 10⁻⁵ M Hg²⁺, respectively.     

厚叶景天组织传感器的研究

利用厚叶景天的叶和茎组织作为生物催化材料,分别同二氧化碳气敏电极和氨气敏电极组合,研制了L－精氨酸传感器及,L－赖氨酸传感器。两种传感器的线性范围分别为1.0×10^-4 1.O×10^-3mol/L和8．0×10^-5—3.0×10^-3mol/L．检测下限分别为3．2×10^-5mol／L和2.2×10^-5mol/L,响应斜率分别为42.2mV／dec和41．4mv／dec。考察了两种传感器的回收率．结果表明,L－精氨酸传感器和L－赖氨酸传感器的回收率平均值分别为98．6％和101.6％,标准偏差分别为4.6％和4.0％。     

Noninvasive measurement of dissolved oxygen in shake flasks

Shake flasks are ubiquitous in cell culture and fermentation. However, conventional devices for measuring oxygen concentrations are impractical in these systems. Thus, there is no definitive information on the oxygen supply of growing cells. Here we report the noninvasive, nonintrusive monitoring of dissolved oxygen (DO) in shake flasks using a low-cost optical sensor. The oxygen-sensitive element is a thin, luminescent patch affixed to the inside bottom of the flask. The sensitivity and accuracy of this device is maximal up to 60% DO, within the range that is critical to cell culture applications. By measuring actual oxygen levels every 1 or 5 min throughout the course of yeast and E. coli fermentations, we found that a modest increase in shaker speed and a decrease in culture volume slowed the onset of oxygen limitation and reduced its duration. This is the first time that in situ oxygen limitation is reported in shake flasks. The same data is unattainable with a Clark type electrode because the presence of the intrusive probe itself changes the actual conditions. Available fiber optic oxygen sensors require cumbersome external connections and recalibration when autoclaved.     

Diaphragm‐based optical fiber sensor for pulse wave monitoring and cardiovascular diseases diagnosis

Arterial pulse wave has been considered as a vital sign in assessment of cardiovascular diseases. Noninvasive pulse sensor with compact structure, immunity to electro‐magnetic interference and high sensitivity is the research focus in recent years. While, optical fiber biosensor is a competitive option to meet these needs. Here, a diaphragm‐based optical fiber pulse sensor was proposed to achieve high‐precision radial pulse wave monitoring. A wearable device was developed, composed of a sports wristband and an aluminum diaphragm‐based optical fiber sensor tip of only 1 cm in diameter, which was highly sensitive to the weak acoustic signal. In particular, coherent phase detection was adopted to improve detection signal‐to‐noise ratio, so as to recover the high‐fidelity pulse waveforms. A clinical experiment was carried out to detect and morphological analyze the pulse waveforms of four subjects, the results of which preliminarily demonstrated the feasibility of pulse diagnosis method. The proposed pulse fiber sensor provides a comfortable way for pulse diagnosis, which is promising in early cardiovascular diseases indicating.     

Changes in pericytic expression of NG2 and PDGFRB and vascular permeability in the sensory circumventricular organs of adult mouse by osmotic stimulation

The blood–brain barrier (BBB) is a barrier that prevents free access of blood‐derived substances to the brain through the tight junctions and maintains a specialized brain environment. Circumventricular organs (CVOs) lack the typical BBB. The fenestrated vasculature of the sensory CVOs, including the organum vasculosum of the lamina terminalis (OVLT), subfornical organ (SFO) and area postrema (AP), allows parenchyma cells to sense a variety of blood‐derived information, including osmotic ones. In the present study, we utilized immunohistochemistry to examine changes in the expression of NG2 and platelet‐derived growth factor receptor beta (PDGFRB) in the OVLT, SFO and AP of adult mice during chronic osmotic stimulation. The expression of NG2 and PDGFRB was remarkably prominent in pericytes, although these angiogenesis‐associated proteins are highly expressed at pericytes of developing immature vasculature. The chronic salt loading prominently increased the expression of NG2 in the OVLT and SFO and that of PDGFRB in the OVLT, SFO and AP. The vascular permeability of low‐molecular‐mass tracer fluorescein isothiocyanate was increased significantly by chronic salt loading in the OVLT and SFO but not AP. In conclusion, the present study demonstrates changes in pericyte expression of NG2 and PDGFRB and vascular permeability in the sensory CVOs by chronic osmotic stimulation, indicating active participation of the vascular system in osmotic homeostasis. Copyright © 2013 John Wiley & Sons, Ltd.