Dual-mode thin film bulk acoustic wave resonators for parallel sensing of temperature and mass loading

Thin film bulk acoustic wave resonator (FBAR) devices supporting simultaneously multiple resonance modes have been designed for gravimetric sensing. The mechanism for dual-mode generation within a single device has been discussed, and theoretical calculations based on finite element analysis allowed the fabrication of FBARs whose resonance modes have opposite reactions to temperature changes; one of the modes exhibiting a positive frequency shift for a rise of temperature whilst the other mode exhibits a negative shift. Both modes exhibit negative frequency shift for a mass load and hence by monitoring simultaneously both modes it is possible to distinguish whether a change in the resonance frequency is due to a mass load or temperature variation (or a combination of both), avoiding false positive/negative responses in gravimetric sensing without the need of additional reference devices or complex electronics.     

Convenient and highly effective fluorescence sensing for Hg2+ in aqueous solution and thin film

A quinolinocyclodextrin, that is, MQAS-β-cyclodextrin (MQAS = N-(2-methyl-8-amino- quinolyl)-p-aminobenzene sulfonamide) was synthesized. Further experiments showed that it could form very stable stoichiometric 2:1 complex with Zn²⁺ in water. Significantly, the resultant quinolinocyclodextrin/Zn²⁺ complex showed the specific fluorescence response to Hg²⁺ over other metal ions, which could be readily distinguished in either aqueous solution or the PVA-based thin film. This finding would enable Zn·3₂ complex as a convenient and highly efficient fluorescence sensor for the detection of Hg²⁺.     

Carbon nanotube/gold nanoparticles/polyethylenimine-functionalized ionic liquid thin film composites for glucose biosensing

A novel glucose biosensor based on immobilization of glucose oxidase (GOD) in thin films of polyethylenimine-functionalized ionic liquid (PFIL), containing a mixture of carbon nanotubes (CNT) and gold nanoparticles (AuNPs) and deposited on glassy carbon electrodes, was developed. Direct electrochemistry of glucose oxidase in the film was observed, with linear glucose response up to 12mM. The PFIL-stabilized gold nanoparticles had a diameter of 2.4+/-0.8nm and exhibited favorable stability (stored even over one month with invisible change in UV-vis spectroscopic measurements). In addition, CNT were also well dispersed in the PFIL matrix, then, the resulting CNT/AuNPs/PFIL composites film showed high electrocatalytic activity toward reduction of hydrogen peroxide and oxygen. Here, PFIL, due to its high ionic conductivity, good solubility to CNT, and stability to nanoparticles, played an important role in constructing stable CNT/AuNPs/PFIL/GOD composites. And good biocompatibility of PFIL also offered a friendly environment for the immobilization of biomolecules.     

Enzymic thin film coatings for bioactive materials

Bioactive materials have been explored for a broad range of applications including biocatalysts, biosensors, antifouling membranes and other functional and smart materials. We report herein a unique method for preparation of bioactive materials through a spin coating process. Specifically, we investigated the preparation of protease Subtilisin Carlsberg-coated plastic films and examined their activities for hydrolysis of chicken egg albumin (CEA). The process generated enzymic coatings with a typical loading of 13 microg/cm2, retaining 46% of the enzyme activity for hydrolysis of CEA in aqueous solutions. Interestingly, the surface-coated protease thin film not only catalyzed the hydrolysis of CEA in aqueous solutions, but also showed good activity for solid-state CEA that was coated on top of the enzyme thin film.     

Molecularly imprinted hydroxyapatite thin film for bilirubin recognition

A novel piezoelectric sensor has been developed for bilirubin (BR) detection, based on the modification of molecularly imprinted hydroxyapatite (HAP) film onto a quartz crystal by molecular imprinting and surface sol-gel technique. The performance of the developed BR biosensor was evaluated and the results indicated that a sensitive BR biosensor could be fabricated. The obtained BR biosensor presents high-selectivity monitoring of BR, better reproducibility, shorter response time (37 min), wider linear range (0.05-80μM) and lower detection limit (0.01μM). The analytical application of the BR biosensor confirms the feasibility of BR detection in serum sample.     

A sputtered thin film of nanostructured Ni/Pt/Ti on Al2O3 substrate for ethanol sensing

A novel thin film ethanol sensor using sputtered Ni/Pt/Ti on an Al2O3 substrate as the working electrode in an alkaline solution was developed. Atomic force microscopy (AFM) and scanning electron microscopy (SEM) were used to characterize the nanostructure of nickel films. Sputtering deposition conditions for maximum catalytic efficiency, electrode selectivity, and reproducibility were discussed. The results showed that ethanol oxidation was more efficient on the sputtered Ni/Pt/Ti on an Al2O3 substrate electrode than that on the conventional nickel electrode. The optimal operating conditions to generate the sputtered Ni/Pt/Ti on the Al2O3 substrate electrode were: 45 min of Ni sputtering deposition time, and 50 W of Ni sputtering power. The results also indicated that the response time of the prepared ethanol sensor is 27 s and the best sensitivity is 3.08 microA microM(-1) cm(-2).     

A thin film nitinol heart valve

In order to create a less thrombogenic heart valve with improved longevity, a prosthetic heart valve was developed using thin film nitinol (NiTi). A "butterfly" valve was constructed using a single, elliptical piece of thin film NiTi and a scaffold made from Teflon tubing and NiTi wire. Flow tests and pressure readings across the valve were performed in vitro in a pulsatile flow loop. Bio-corrosion experiments were conducted on untreated and passivated thin film nitinol. To determine the material's in vivo biocompatibility, thin film nitinol was implanted in pigs using stents covered with thin film NiTi. Flow rates and pressure tracings across the valve were comparable to those through a commercially available 19 mm Perimount Edwards tissue valve. No signs of corrosion were present on thin film nitinol samples after immersion in Hank's solution for one month. Finally, organ and tissue samples explanted from four pigs at 2, 3, 4, and 6 weeks after thin film NiTi implantation appeared without disease, and the thin film nitinol itself was without thrombus formation. Although long term testing is still necessary, thin film NiTi may be very well suited for use in artificial heart valves.     

Composite thin film and electrospun biomaterials for urologic tissue reconstruction

A replacement material for autologous grafts for urinary tract reconstruction would dramatically reduce the complications of surgery for these procedures. However, acellular materials have not proven to work sufficiently well, and cell‐seeded materials are technically challenging and time consuming to generate. An important function of the urinary tract is to prevent urine leakage into the surrounding tissue—a function usually performed by the urothelium. We hypothesize that by providing an impermeable barrier in the acellular graft material, urine leakage would be minimized, as the urothelium forms in vivo. However, since urothelial cells require access to nutrients from the supporting vasculature, the impermeable barrier must degrade over time. Here we present the development of a novel biomaterial composed of the common degradable polymers, poly(ε‐caprolactone) and poly(L ‐lactic acid) and generated by electrospinning directly onto spin‐coated thin films. The composite scaffolds with thin films on the luminal surface were compared to their electrospun counterparts and commercially available small intestinal submucosa by surface analysis using scanning electron microscopy and by analysis of permeability to small molecules. In addition, the materials were examined for their ability to support urothelial cell adhesion, proliferation, and multilayered urothelium formation. We provide evidence that these unique composite scaffolds provide significant benefit over commonly used acellular materials in vitro and suggest that they be further examined in vivo. Biotechnol. Bioeng. 2011; 108:207–215. © 2010 Wiley Periodicals, Inc.     

Plasmonic metasurface for light absorption enhancement in GaAs thin film

Plasmonics - Using the plasmonic metasurface, we have designed a highly efficient solar ray absorber by tailoring the thickness of the metallic arrays. The geometric-dependent local surface plasmon...     

Extra thin alginate film: an efficient technique for protoplast culture

Summary. This paper reports an efficient protoplast culture technique, the “extra thin alginate film” technique. The development of this improved method of protoplast culture was an outcome of an assessment of the efficiency and shortcomings of various protoplast culture techniques. The efficiency of this technique was evaluated with two model plant systems, viz., Nicotiana tabacum and Lotus corniculatus, and a comparison was made with the “thin alginate layer” technique, another efficient protoplast culture system. Results indicate that the culture technique with extra thin alginate film is as efficient as the technique with thin alginate layer, with many additional advantages. The present innovation overcomes most of the limitations of protoplast culture techniques described so far and can now be applied to a wide variety of crops to check its general applicability. Correspondence and reprints: Department of Botanical and Environmental Sciences, Guru Nanak Dev University, Amritsar 143 005, India.     

Fundamental aspects of antimony thin film electrodes for pH measurement.

This report concerns the investigation of the sensitivity, temperature dependence, accuracy, and the standard electrode potential EO of an antimony thin film pH electrode which was prepared with electron beam evaporation techniques. The air-formed oxide film on antimony thin film electrodes has been proved by both the cathodic reduction method and electron spectroscopy for chemical analysis (ESCA). The antimony thin film electrode responded rapidly to pH changes and its sensitivity was slightly changed depending on the buffer composition. The accuracy of this electrode was compared with that of the glass electrode. Temperature had some influence on the function of this electrode. The standard electrode potential of this electrode was discussed together with that of other forms of antimony electrodes. The structure and thickness of the surface oxide on antimony thin film electrodes was confirmed by cathodic reduction and ESCA. It was clear that the surface oxide governs the electrode reactions. Possible applications of the antimony thin film electrode are discussed stating some limitations in the use.     

Addressing single molecules of a thin magnetic film

Electron spin noise-scanning tunneling microscopy (ESN-STM) represents the most promising technique for single spin centres addressing on surfaces. After a brief introduction on the results previously obtained by using this technique for the detection of both isolated molecules and small aggregates of BDPA, DPPH and TTM free radicals, we discuss here our improved results in the single-molecule addressing of thio-functionalized nitronyl nitroxide radicals (NNRs) chemically bound to gold. ESN-STM spectra of NNRs self-assembled monolayers (SAMs) on Au(1 1 1) surfaces are reported together with the crystal structure of the studied radical NN–Ph–CH₂SMe, considered up to now as the best aromatic NNR for the obtainment of thin magnetic films.     

Potential of phenothiazine as a thin film dosimeter for UVA exposures.

The research reported in this paper on the changes in absorbance and the calibration of a proposed UVA (320-400 nm) dosimeter have established the phenothiazine-mylar combination as a potential UVA dosimeter for population studies of UVA exposures. The change in optical absorbance at 370 nm was employed to quantify the UVA exposures. This change starts to saturate at a change in absorbance of approximately 0.3. This relates to solar UVA exposures at a sub-tropical site on a horizontal plane of approximately three to four hours. The shape of this calibration curve varies with the season. This can be overcome in the same manner as for polysulfone where the dosimeter is calibrated for the conditions that it will be employed to measure the UVA exposures.     

DNA hybridization sensor based on pentacene thin film transistor

A DNA hybridization sensor using pentacene thin film transistors (TFTs) is an excellent candidate for disposable sensor applications due to their low-cost fabrication process and fast detection. We fabricated pentacene TFTs on glass substrate for the sensing of DNA hybridization. The ss-DNA (polyA/polyT) or ds-DNA (polyA/polyT hybrid) were immobilized directly on the surface of the pentacene, producing a dramatic change in the electrical properties of the devices. The electrical characteristics of devices were studied as a function of DNA immobilization, single-stranded vs. double-stranded DNA, DNA length and concentration. The TFT device was further tested for detection of λ-phage genomic DNA using probe hybridization. Based on these results, we propose that a "label-free" detection technique for DNA hybridization is possible through direct measurement of electrical properties of DNA-immobilized pentacene TFTs.     

Label-free DNA sensor based on organic thin film transistors

Organic thin film transistors (OTFTs) are excellent candidates for the application on disposable sensors due to their potentially low-cost fabrication process. A novel DNA sensor based on OTFTs with semiconducting polymer poly(3-hexylthiophene) has been fabricated by solution process. Both single- and double-strand DNA molecules are immobilized on the surface of the Au source/drain electrodes of different OTFT devices, producing a dramatic change in the performance of the devices, which is attributed to the increase of the contact resistances at the source/drain electrodes. Single-strand DNA and double-strand DNA are differentiated successfully in the experiments indicating that this is a promising technique for sensing DNA hybridization without labelling.     

Micropatterned thin film honeycomb materials from regiospecifically modified cellulose

Thin film honeycomb materials were prepared from regioselectively modified celluloses. The method uses water condensation at the surface of a cellulosic solution as an ordered template to form honeycomb structures. Pore size and distribution is controlled by several factors, one of which is the hydrophilicity of the cellulosic used. The amphiphilic nature of the celluloses was modified with varying lengths of ethylene glycol side chains using 2,6-thexyldimethylsilyl cellulose. It was found that the side chains do affect the honeycomb formation, with longer ethylene glycol chains leading to increased pore uniformity but having little influence on the pore size.