Tribo-electrochemical technique for studying tribocorrosion behavior of biomaterials

Tribocorrosion is the term which describes the synergy between tribological and electrochemical processes. An apparatus was designed and built to study the tribocorrosion behavior of biomaterials. Electrochemical set-up with three electrodes is used for controlling the potential of the surface of a conducting material subjected to classical wear testing. Using this equipment, it is possible to carry out friction and wear tests in electrolytic solution under well-defined electrochemical conditions determined by the applied electrode potential. In this paper, this apparatus was described and the tests of deposited TiN on pure Ti for corrosion and tribocorrosion behavior under simulated body fluid were conducted. The presence of TiN layer on the surface of Ti has increased the open circuit potential. The charge transfer resistance (R(ct)) determined using electrochemical impedance spectroscopy (EIS) was higher for the nitrided surfaces than for the Ti substrates. However after wear test, R(ct) was significantly reduced because the protective layer was damaged.     

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。     

Enzyme immunosensors based on electropolymerized polytyramine modified electrodes

Highly sensitive amperometric enzyme immunosensors for human immunoglobulin G (IgG) were prepared on the basis of electrogenerated polytyramine (PTy, tyramine = p-(2-aminoethyl)-phenol) modified electrodes. Properties of PTy films changed depending on electrolysis conditions. On the basis of the found properties of the films, an effective IgG sensor was prepared: a PTy film was formed first from an acid solution on a Pt electrode, and the surface was further covered with a PTy film from an alkaline methanol solution to give a PTy doubly coated electrode on which anti-IgG was then immobilized. This electrode provided a large surface area with little non-specific adsorption of proteins. By means of the competitive enzyme immunoassay technique using glucose oxidase (GOD) labeled IgG conjugates, IgG was determined in the concentration range of c. 10 pg/ml-1 mg/ml from the oxidation current of H2O2 generated by the enzyme (GOD) reaction using the above IgG sensor. Also, an anti-IgG immobilized electrode, prepared by using a Pt electrode singly covered with a PTy film from an alkaline methanol solution, acted as an effective IgG sensor with a detection limit for IgG of c. 100 pg/ml.     

Reduction of electrode polarization capacitance in low-frequency impedance spectroscopy by using mesh electrodes

Dielectric measurements of biological samples are obscured by electrode polarization, which at low frequencies dominates over the actual sample response. Reduction of this artifact is especially necessary in studying interactions of electric field with biological systems in the α-dispersion range. We developed a method to reduce the influence of electrode polarization by employing mesh instead of solid electrodes as sensing probes, thereby reducing the area of the double layer. The design decreases the electrode-electrolyte contact area by almost 40% while keeping the bulk sample capacitance the same. Interrogation electric fields away from the electrode surface and sensitivity are unaffected. Electrodes were microfabricated (600μm×50μm, spacing of 100μm) with and without mesh holes 7.5μm×7.5μm in size. Simulations of electric field performed using Comsol Multiphysics showed non-uniformity of the electric field within less than 1.5μm from the electrode surface, which encompasses the double layer region, but at greater distance the solid and mesh electrodes gave the same results. Mesh electrodes reduced capacitance measurements for water and KCl solutions of different concentrations at low frequencies (<10kHz), while higher frequency capacitance remained the same for both electrode types, confirming our hypothesis that this design leaves the electric field mainly unaffected. Impedance measurements at low frequencies for water and mice heart mitochondrial suspension were lower for mesh than for solid electrodes. Comsol simulations confirmed these results by showing that mesh electrodes have a greater charge density than solid electrodes, which affects conductance. These electrodes are being used for mitochondrial membrane potential studies.     

Polyvinylferrocenium modified Pt electrode for the design of amperometric choline and acetylcholine enzyme electrodes

A simple method of enzyme immobilization was investigated, which is useful for development of enzyme electrodes based on polyvinylferrocenium perchlorate coated Pt electrode surface. Enzymes were incorporated into the polymer matrix via ion exchange process by immersing polyvinylferrocenium perchlorate coated Pt electrode in enzyme solution for several times. Choline and acetylcholine enzyme electrodes were developed by co-immobilizing choline oxidase and acetylcholinesterase in polyvinylferrocenium perchlorate matrix coated on a Pt electrode surface. The amperometric responses of the enzyme electrodes were measured at +0.70 V versus SCE, which was due to the electrooxidation of enzymatically produced H2O2. The effects of the thickness of the polymeric film, pH, temperature, substrate and enzyme concentrations on the response of the enzyme electrode were investigated. The optimum pH was found to be pH 7.4 at 25 degrees C. The steady-state current of these enzyme electrodes were reproducible within +/-5.0% of the relative error. Response time was found to be 30-50s and upper limit of the linear working portions was found to be 1.2mM choline and acetylcholine concentrations in which produced detectable currents were 1.0 x 10(-6)M substrate concentrations. The apparent Michaelis-Menten constant and the activation energy of this immobilized enzyme system were found to be 1.74 mM acetylcholine and 14.9 kJ mol(-1), respectively. The effects of interferents and stability of the enzyme electrodes were also investigated.     

Titanium nitride cardiac pacemaker electrodes

The sensing and pacing performance of pacemaker electrodes is characterized by the electrochemical properties of the electrodes/tissue layer; the usually smooth metallic electrode surface results in a high pass filter characteristic. Consequently, the detected intracardiac signals, which control the implantable systems, are not optimally matched to the spectral contents of the depolarisation signal. To avoid interference caused by noise (EMI, muscle potentials, etc.) a shift of the frequency of the band pass towards the lower frequency spectrum is required. As previously reported, the electrochemical properties of sintered and surface-treated electrodes prove the predicted improvement of sensing performance if titanium-nitride coated electrodes are used. Our results demonstrate their superiority above all the other electrodes presently known. The advantages can be referred to the micro-crystalline surface structure achieved by sputter-deposited electrode coatings and the kinetics of the ionic exchange. Furthermore, the acute thresholds achieved with the TiN-systems were significantly better than those of the smooth metallic surface. These results were also confirmed for chronic implants and are attributable to the known biocompatibility of titanium and its alloys.     

Highly sensitive and selective uric acid biosensor based on RF sputtered NiO thin film

Present study highlights the importance of RF sputtered NiO thin film deposited on platinum coated glass substrate (NiO/Pt/Ti/glass) as a potential matrix for the realization of highly sensitive and selective uric acid biosensor. Uricase has been immobilized successfully onto the surface of NiO matrix by physical adsorption technique. The prepared bioelectrode (uricase/NiO/Pt/Ti/glass) is utilized for sensing uric acid using the cyclic voltammetry and UV visible spectroscopy techniques. The bioelectrode is found to exhibit highly efficient sensing response characteristics with high sensitivity of 1278.48 μA/mM; good linearity of 0.05-1.0 mM, and very low Michaelis-Menten constant (k(m)) of 0.17 mM indicating high affinity of uricase towards the analyte. The enhanced response is due to the development of NiO matrix with good electron transport property and nanoporous morphology for effective loading of enzyme with preferred orientation.     

An autonomous CMOS hysteretic sensor for the detection of desorption-free DNA hybridization

This paper describes a sensor for label-free, fully electrical detection of DNA hybridization based on capacitive changes in the electrode-electrolyte interface. The sensor measures capacitive changes in real time according to a charging-discharging principle that is limited by the hysteresis window. In addition, a novel autonomous searching technique, which exclusively monitors desorption-free hybridized electrodes among electrode arrays, enhances the performance of the sensor compared with conventional capacitive measurement. The sensor system achieves a detection range of 80 dB. The integrated circuit sensor is fabricated with a 0.35 μm CMOS process. The proposed sensor offers rapid, robust and inexpensive measurement of capacitance with highly integrated detection circuitry. It also facilitates quantitative evaluations of molecular densities on a chip with distinctive impedance variations by monitoring desorption-free hybridized electrodes. Our electrical biosensor has great potential for use with bio analytical tools and point-of-care diagnosis.     

A biocompatible titanium nitride nanorods derived nanostructured electrode for biosensing and bioelectrochemical energy conversion

In this study, a facile method is proposed to fabricate biocompatible TiN nanorod arrays through solvent-thermal synthesis and subsequent nitridation in ammonia atmosphere. The TiN nanorod arrays are potential excellent nanostructured electrodes owing to their good electronic conductivity and large surface area. These nanostructured electrodes not only deliver superior electrocatalytic activity (the limit of detection, LOD is 0.5 μM) and highly selective sensing towards H(2)O(2), but also exhibit excellent biocompatibility with horseradish peroxidase (HRP) in a highly sensitive enzymatic biosensor for H(2)O(2) (the LOD can reach to 0.05 μM). Furthermore, a novel biocatalytic cathode based Li air fuel cell (bio-Li-air fuel cell) is explored based on the combination of TiN nanorod arrays and laccase (LAC) for electrochemical energy conversion. These results demonstrate that TiN nanorod arrays can be served as excellent nanostructured electrodes for multifunctional bioelectrochemical applications.     

Exceptionally Enhanced Electrode Activity of (Pr,Ce)O2−δ‐Based Cathodes for Thin‐Film Solid Oxide Fuel Cells

It is shown that an electrochemically‐driven oxide overcoating substantially improves the performance of metal electrodes in high‐temperature electrochemical applications. As a case study, Pt thin films are overcoated with (Pr,Ce)O_2?δ (PCO) by means of a cathodic electrochemical deposition process that produces nanostructured oxide layers with a high specific surface area and uniform metal coverage and then the coated films are examined as an O₂‐electrode for thin‐film‐based solid oxide fuel cells. The combination of excellent conductivity, reactivity, and durability of PCO dramatically improves the oxygen reduction reaction rate while maintaining the nanoscale architecture of PCO layers and thus the performance of the PCO‐coated Pt thin‐film electrodes at high temperatures. As a result, with an oxide coating step lasting only 5 min, the electrode resistance is successfully reduced by more than 1000 times at 500 °C in air. These observations provide a new direction for the design of high‐performance electrodes for high‐temperature electrochemical cells.     

Exploratory studies of some drug charge transfer interactions

Conductivity and capacitance titrations yield minima for the chlorpromazine hydrochloride-heparin interaction, confirming clinical suspicions of its occurrence. The effective dosage of heparin thus is reduced if administered in conjunction with chlorpromazine. The interaction is interpreted as charge transfer complex formation, occurring as an (electrode) surface reaction. It is suggested that the charge transfer complexing capability of heparin preparations, as evidenced by conductance and/or capacitance changes, evaluated against a well defined donor such as chlorpromazine hydrochloride, may be adapted as a more precise method of measuring heparin activity than coagulation time determinations. Phenytoin and chlorpromazine likewise yield conductance and capacitance minima; voltammetry indicates new peaks at +250mV and −300mV vers.SCE supporting the suggestions that an uncharged 1∶1 complex is being formed, again in a type of surface reaction. Phenytoin and lignocain form a precipitate at 0.002 equimolar; in conductance and capacitance titrations phenytoin behaves as a weak electron donor against iodine though as a weak acceptor against lignocain. Lignocain and chlorpromazine conductance and capacitance titrations using gold electrodes fail to show any evidence for their previously reported interaction on Pt/Pt electrodes. Voltammetry on Pt/Pt electrodes indicates 2 new peaks at zero and at −750mV vers.SCE. It is thought that these two compounds interact only on catalytically highly active surfaces, where they form a weak surface charge transfer complex. Adrenalin, in conductance and capacitance titrations, behaves amphoteric, i.e. as an electron acceptor against the strong donor chlorpromazine and as a donor against the strong acceptor tetramethyl-p-phenylenediamine. Voltammograms of the above listed interactions are interpreted as of the ECE type exhibiting mainly irreversible behaviour.     

Mesh‐Shaped Nanopatterning of Pt Counter Electrodes for Dye‐Sensitized Solar Cells with Enhanced Light Harvesting

A facile process to produce large‐area platinum (Pt) counter electrode platforms with well‐arrayed, mesh‐shaped nanopatterns using commercially available TiO₂ paste and poly(dimethyl siloxane) (PDMS) nanostamps is presented. The process involves mesh‐shaped (200 nm × 200 nm) nanopatterning of a TiO₂ scaffold onto a fluorine‐doped tin oxide (FTO) substrate, followed by Pt sputtering. The structure and morphology of the counter electrodes are characterized by a field emission scanning electron microscope (FE‐SEM) and an atomic force microscope (AFM). Solid‐state dye‐sensitized solar cells (ssDSSCs) fabricated with these mesh‐shaped Pt counter electrodes showed an efficiency of 7.0%. This is one of the highest efficiencies observed for N719 dye and is much higher than that of devices with non‐patterned, thermally deposited electrodes (5.4%) or non‐patterned, sputtering deposited electrodes (5.7%). This improvement is attributed to enhanced light harvesting and a greater surface area and has been confirmed by incident photon‐to current efficiency (IPCE), electrochemical impedance spectroscopy (EIS), and cyclic voltammetry (CV) measurements.     

纳米结构Ti/TiN涂层对NiTi合金生物相容性的影响

目的：评价纳米结构Ti/TiN涂层对镍钛形状记忆合金（含镍50.6at%）生物相容性的影响,为生物医用纳米结构Ti/TiN涂层表面改性的NiTi合金材料生物安全性提供依据。方法：不影响基体的形状记忆性或超弹性效应的前提下,采用真空过滤电弧离子镀技术,在NiTi合金表面沉积一层纳米结构Ti/TiN涂层,分别对表面改性前和改性后的NiTi合金样品进行体外细胞毒性实验、溶血实验和血小板粘附实验,探索纳米结构Ti/TiN涂层对NiTi合金生物相容性的影响。结果：表面具有纳米结构Ti/TiN涂层的NiTi合金无细胞毒性,H9C2（2-1）细胞相容性优于涂层前,细胞形态典型,粘附数量明显大于涂层前。纳米结构Ti/TiN涂层有改善NiTi合金的血液相容性作用,其溶血率从2.1%降至涂层改性后的1.2%,同时,血小板黏附量和聚集程度小于处理前的NiTi合金。结论：纳米Ti/TiN涂层能够显著改善NiTi合金的生物相容性。     

Electrocatalytic reduction of protons and oxygen at glassy carbon electrodes coated with a cobalt(II)/platinum(II) porphyrin

The electrocatalytic reduction of protons in 1.0 M perchloric acid at glassy carbon electrodes anodically modified with a Co(II)/Pt(II) porphyrin show shifts of 400 mV versus Ag/AgCl when compared to the same electrodes which have not been anodically modified. Anodic cycling of glassy carbon electrodes coated with the Co(II)/Pt(II) porphyrin in this study form stable electroactive films capable of improving both electroreduction of protons to hydrogen and oxygen to both peroxide and water. Electrooxidation of glassy carbon electrodes coated with the free base porphyrin show no improvement in catalytic ability for the reduction of protons in acidic solution or the reduction of molecular oxygen in basic solution. Glassy carbon electrodes coated with the Co(II)/Pt(II) porphyrin indicate, by rotating disk electrochemistry, that the electrocatalysis of oxygen is a two electron process leading to the formation of hydrogen peroxide. Koutecky-Levich plots of the data obtained from the reduction of oxygen at electrode surfaces coated with the Co(II)/Pt(II) porphyrin after oxidation of the surface indicate that 25% of the oxygen is reduced by four electrons directly to water while 75% of the oxygen is reduced by two electrons to hydrogen peroxide.     

Fast and easy preparation of an amperometric glucose biosensor

Summary Electrochemical polymerization of pyrrole in aqueous KCl solution containing glucose oxidase produces adherent films at platinum electrode surface. Such coated electrodes are prepared in 20 min and can determine glucose in the range 0 to 100mm. The useful lifetime of the electrode is 85 assays. Its stability is at least 75 days under storage in PBS at 4°C.     

Glucose oxidase-polypyrrole electrodes synthesized in p-toluenesulfonic acid and sodium p-toluenesulfonate

Amperometric glucose biosensors have been developed based on entrapment on platinum (Pt) electrode using cyclic voltammetry technique in glucose oxidase (GOD) and pyrrole containing p-toluenesulfonic acid (pTSA) or sodium p-toluenesulfonate (NapTS) as supporting electrolyte solutions. Both of electrolyte solutions were suitable media for the formation and deposition of polypyrrole-GOD (PPy-GOD) layers on Pt substrate. Pt/PPy-GOD electrodes brought about in different morphological properties as well as different electrochemical and biochemical response. The highest responses obtained in pTSA and NapTS electrolytes were observed at pH of 4.5 and 7.0 for Pt/PPy-GOD electrodes, respectively. While linearity was observed between 0.0-1.0 mM glucose substrate for both electrodes, I(max) value of Pt/PPy-GOD(NapTS) electrode was approximately twice as high as that of Pt/PPy-GOD(pTSA) electrode as 25.4 and 14.2 microA, respectively. Five commercial drinks were tested with enzyme electrodes and compared with results obtained spectrophotometrically using glucose kit. Results revealed that Pt/PPy-GOD(NapTS) electrode exhibited better biosensor response.     

Bipolar resistivity profiling of 3D tissue culture

We describe a new low-cost technique for continuous monitoring of the thickness of biofilms and tissue cultures, and we demonstrate the advantage of using electrodes of different dimensions to probe different depths of a sample. We have used electric impedance spectroscopy to monitor keratinocyte stem cells (YF29) growing on an array of Ti/Pt coplanar microelectrodes. The thickness of the sample was reconstructed by fitting the measurements to theoretical curves. We have developed an algorithm for the rapid calculation of the resistance through a multilayered sample. This algorithm is based on conformal mapping and the serial partial capacitance technique. The validity of the technique was tested by measuring the sedimentation rate of an alumina powder. Sample thicknesses between 10 and 80 microm could be measured with a resolution of a few microns using the device.     

大肠杆菌的直流电场刺激过程

以钛网电极和铂网电极对培养瓶中大肠杆菌生长过程进行加电刺激,研究其在直流电场作用下的生长情况,并结合循环伏安扫描、恒电流、十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)及测定菌体ATP酶活力等技术对大肠杆菌的直流电场刺激过程进行研究。结果表明,在0-0.2275mA/cm2范围内,随着电流密度的增加,直流电场对大肠杆菌生长量的增长促进作用逐渐增加,而0.0455mA/cm2的电场则是获得最大活菌量的最适电流密度;通过对析氢活性不同的铂网电极与钛网电极通加相同电流密度的电场,发现铂电极培养体系菌体生长优于钛电极培养体系菌体的生长。经验证发现引起这种变化的原因主要是水的阴极电解产物吸附氢和氢气比例的不同引起的;同时发现在0.091mA/cm2电流密度下,直流电场能有效提高ATP酶的活力,在8h时通电菌样酶活为不通电菌样酶活的3.2倍;通过对0.0455mA/cm2直流电场刺激后的菌体蛋白进行SDS-PAGE分析发现加电菌体在分子量25kD与35kD左右多肽表达量明显高于不加电菌体的多肽表达量,而在分子量为66.2kD左右时多肽表达量低于不加电菌体多肽表达量。     

Glucose oxidase-polypyrrole electrodes synthesized in <Emphasis Type="Italic">p</Emphasis>-toluenesulfonic acid and sodium <Emphasis Type="Italic">p</Emphasis>-toluenesulfonate

Amperometric glucose biosensors have been developed based on entrapment on platinum (Pt) electrode using cyclic voltammetry technique in glucose oxidase (GOD) and pyrrole containing p-toluenesulfonic acid (pTSA) or sodium p-toluenesulfonate (NapTS) as supporting electrolyte solutions. Both of electrolyte solutions were suitable media for the formation and deposition of polypyrrole-GOD (PPy-GOD) layers on Pt substrate. Pt/PPy-GOD electrodes brought about in different morphological properties as well as different electrochemical and biochemical response. The highest responses obtained in pTSA and NapTS electrolytes were observed at pH of 4.5 and 7.0 for Pt/PPy-GOD electrodes, respectively. While linearity was observed between 0.0–1.0 mM glucose substrate for both electrodes, I _max value of Pt/PPy-GOD_NapTS electrode was approximately twice as high as that of Pt/PPy-GOD_pTSA electrode as 25.4 and 14.2 μA, respectively. Five commercial drinks were tested with enzyme electrodes and compared with results obtained spectropho-tometrically using glucose kit. Results revealed that Pt/PPy-GOD_NapTS electrode exhibited better biosensor response.     

Amperometric glucose biosensor based on gold-deposited polyvinylferrocene film on Pt electrode

The preparations and performances of the novel amperometric biosensors for glucose based on immobilized glucose oxidase (GOD) on modified Pt electrodes are described. Two types of modified electrodes for the enzyme immobilization were used in this study, polyvinylferrocene (PVF) coated Pt electrode and gold deposited PVF coated Pt electrode. A simple method for the immobilization of GOD enzyme on the modified electrodes was described. The enzyme electrodes developed in this study were called as PVF-GOD enzyme electrode and PVF-Au-GOD enzyme electrode, respectively. The amperometric responses of the enzyme electrodes were measured at constant potential, which was due to the electrooxidation of enzymatically produced H2O2. The electrocatalytic effects of the polymer, PVF, and the gold particles towards the electrooxidation of the enzymatically generated H2O2 offers sensitive and selective monitoring of glucose. The biosensor based on PVF-Au-GOD electrode has 6.6 times larger maximum current, 3.8 times higher sensitivity and 1.6 times larger linear working portion than those of the biosensor based on PVF-GOD electrode. The effects of the applied potential, the thickness of the polymeric film, the amount of the immobilized enzyme, pH, the amount of the deposited Au, temperature and substrate concentration on the responses of the biosensors were investigated. The optimum pH was found to be pH 7.4 at 25 degrees C. Finally the effects of interferents, stability of the biosensors and applicability to serum analysis of the biosensor were also investigated.