Evaluation of glucose sensitive affinity binding assay entrapped in fluorescent dissolved‐core alginate microspheres

The feasibility of dissolved‐core alginate‐templated fluorescent microspheres as “smart tattoo” glucose biosensors was investigated in simulated interstitial fluid (SIF). The sensor works on the principle of competitive binding and fluorescence resonance energy transfer. The sensor consists of multilayer thin film coated alginate microspheres incorporating dye‐labeled glucose receptor and competing ligand within the partially dissolved alginate core. In this study, different approaches for the sensing and detection chemistry were studied, and the response of encapsulated reagents was compared with the solution‐phase counterparts. The glucose sensitivity of the encapsulated TRITC‐Con A/FITC‐dextran (500 kDa) assay in DI water was estimated to be 0.26%/mM glucose while that in SIF was observed to be 0.3%/mM glucose. The glucose sensitivity of TRITC‐apo‐GOx/FITC‐dextran (500 kDa) assay was estimated to be 0.33%/mM glucose in DI water and 0.5%/mM glucose in SIF and both demonstrated a response in the range of 0–50 mM glucose. Therefore, it is hypothesized that the calcium ion concentration outside the microsphere (in the SIF) does not interfere with the response sensitivity. The sensor response was observed to exhibit a maximum response time of 120 s. The system further exhibited a sensitivity of 0.94%/mM glucose with a response in range of 0–50 mM glucose, using near‐infrared dyes (Alexa Fluor‐647‐labeled dextran as donor and QSY‐21‐conjugated apo‐GOx as acceptor), thereby making the sensor more amenable to in vivo use, when implanted in scattering tissue. Biotechnol. Bioeng. 2009; 104: 1075–1085. © 2009 Wiley Periodicals, Inc.     

Novel micromachined silicon sensor for continuous glucose monitoring

The construction and the application properties of a micro-machined silicon sensor for continuous glucose monitoring are presented. The sensor uses the conventional enzymatic conversion of glucose with amperometric detection of H(2)O(2). The innovation is the precise diffusion control of the analyte through a porous silicon membrane into a silicon etched cavity containing the immobilised enzyme. A variation of the number and size of the membrane pores allows to adjust the linear range of the sensor to the respective requirement. The sensor was tested in vitro as well as in clinical studies, being supplied with interstitial fluid. The cavity sensor was designed for a linear range between 0.5 and 20 mM. A signal response time of below 30 s and a signal stability exceeding 1 week is shown. By using a double cavity sensor falsification of the glucose signal by interfering substances can be compensated. In clinical trials the sensor measured continuously in interstitial fluid for up to 18 h without any signal drift and with good correlation to blood glucose reference values.     

Graphene/Au-Enhanced Plastic Clad Silica Fiber Optic Surface Plasmon Resonance Sensor

Owing to its large surface-to-volume ratio and good biocompatibility, graphene has been identified as a highly promising candidate as the sensing layer for fiber optic sensors. In this paper, a graphene/Au-enhanced plastic clad silica (PCS) fiber optic surface plasmon resonance (SPR) sensor is presented. A sheet of graphene is employed as a sensing layer coated around the Au film on the PCS fiber surface. The PCS fiber is chosen to overcome the shortcomings of the structured microfibers and construct a more stable and reliable device. It is demonstrated that the introduction of graphene can enhance the intensity of the confined electric field surrounding the sensing layer, which results in a stronger light-matter interaction and thereby the improved sensitivity. The sensitivity of graphene-based fiber optic SPR sensor exhibits more than two times larger than that of the conventional gold film SPR fiber optic sensor. Furthermore, the dynamic response analyses reveal that the graphene/Au fiber optic SPR sensor exhibits a fast response (5 s response time) and excellent reusability (3.5% fluctuation) to the protein biomolecules. Such a graphene/Au fiber optic SPR sensor with high sensitivity and fast response shows a great promise for the future biochemical application.     

Glucose sensor with improved haemocompatibilty

A new biocompatible copolymer has been synthesised and used in an electrochemical enzyme-based glucose sensor. The copolymer incorporates three segments including a monomer with an electrically neutral phosphorylcholine head group that is able to reject protein adsorption and two segments that increase the affinity to polyurethane substrate. Peel and solution circulation tests showed that this material has high attachment to polyurethane. With the new copolymer as the outermost layer and the polyurethane as the diffusion-limiting membrane, the sensor showed extended linearity up to 50 mM glucose and stable output in bovine serum for 70 h. During in vivo tests, the sensor exhibited a steady current signal and a rapid transient response when the glucose concentration was raised. These results imply that the haemocompatibility of the glucose sensor coated with the new copolymer has been improved, which is crucial for a sensor used for clinical real-time monitoring. The material may also be suitable for application to other implantable devices.     

A reversible hydrogel membrane for controlling the delivery of macromolecules

Glucose-sensitive hydrogel membranes have been synthesized and characterized for their rate-of-delivery of macromolecules. The mechanism for changing this rate is based on variable displacement of the affinity interaction between dextran and concanavalin A (con A). Our main objective was to characterize the diffusion of model proteins (insulin, lysozyme, and BSA) through the membrane, in response to changes in environmental glucose concentrations. Membranes were constructed from crosslinked dextrans to which con A was coupled via a spacer arm. Changes in the porosity of the resulting hydrogel in the presence of glucose led to changes in the diffusion rate observed for a range of proteins. Gels of specified thickness were cast around to nylon gauze support (pore size, 0.1 mm) to improve mechanical strength. Diffusion of proteins through the gel membrane was determined using a twin-chamber diffusion cell with the concentrations being continuously monitored using a UV-spectrophotometer. Changes in the transport properties of the membranes in response to glucose were explored and it was found that, while 0.1M D-glucose caused a substantial, but saturateable, increase in the rates of diffusion of both insulin and lysozyme, controls using glycerol or L-glucose (0.1M) had no significant effect. Sequential addition and removal of external glucose in a stepwise manner showed that permeability changes were reversible. As expected, diffusion rates were inversely proportional to membrane thickness. A maximum increase in permeability was observed at pH 7.4 and at 37 degrees C. The results demonstrate that this hydrogel membrane functions as a smart material allowing control of solute delivery in response to specific changes in its external environment.     

Periodically interrupted amperometry. A way of improving analytical performance of membrane coated electrodes

Amperometry is a powerful voltammetric measuring method. Its application is specially advantageous when used in combination with a separation step or with some other sample treatment method providing selectivity. The selectivity is often achieved by coating the amperometric working electrode surface with a membrane of special character. Size exclusion membrane, immobilized enzyme containing reaction layer, protecting dialysis membrane, perm selective ion exchange film etc can be mentioned here. In conventional amperometry the measuring potential is continuously applied, therefore in case of membrane coated electrodes the electrode process depletes the diffusion layer. In this work the performance of a new periodically interrupted amperometric (PIA) measuring program has been investigated in case of glucose enzyme sensor. The measuring program allowing time for reloading the diffusion layer provided higher current and therefore improved sensitivity and lower limit of detection.     

Biocompatible glucose sensor prepared by modifying protein and vinylferrocene monomer composite membrane

This paper proposes a very simple procedure for preparing a biocompatible sensor based on a protein (bovine serum albumin, BSA), enzyme and vinylferrocene (VF) composite membrane modified electrode. The membrane was prepared simply by first casting vinylferrocene and then coating it with BSA and glucose oxidase immobilised with glutaraldehyde. The sensor response was independent of dissolved oxygen concentration from 3 to 10 ppm and showed good stability for serum sample measurement, unlike the commonly used BSA/enzyme modified electrode. The sensor response was almost unchanged over the measurement time (>10 h) whereas the responses of a BSA and glucose oxidase modified platinum electrode and an osmium-polyvinylpyridine wired horseradish peroxidase modified electrode (Ohara et al., 1993) fell to 68% of their initial value in a serum sample containing 10mM glucose.     

Cellular import of synthetic peptide using a cell-permeable sequence in plant protoplasts

In this paper, we describe a rapid method to incorporate biologically active synthetic peptide in plant protoplasts. The peptides used contain a hydrophobic membrane permeable sequence as a carrier for the import through the plasma membrane. The membrane permeable sequence corresponds to the h-region, the more hydrophobic domain found in the signal peptide of secreted proteins. To evaluate the feasibility of the method, we synthesized a cell-permeable peptide with an h-region of a plant signal peptide plus residues 410–419 of the human c-myc oncogene product. Detection was performed via fluorescence analysis using specific monoclonal anti-c-myc primary antibody and FITC-conjugated secondary antibody. No saturation of import was observed, suggesting that the mechanisms involved do not require energy. The half-life time of the internalized peptide was estimated and results indicate that peptide concentration into protoplasts was constant for 8 h following incorporation. This method is complementary to microinjection or to the use of membrane permeabilizing reagents to study in vivo protein–protein or DNA–protein interactions. Finally, this method was used to analyse a putative interaction between the conserved cytoplasmic tail of a transmembrane receptor (HaELP, Helianthus annuus EGF receptor like protein) and the cytoskeleton. No interaction was found between these components.     

Near-infrared fluorescence lifetime assay for serum glucose based on allophycocyanin-labeled concanavalin A

We describe an assay scheme for glucose based on fluorescence resonance energy transfer (FRET) between concanavalin A (con A), labeled with the near-infrared fluorescent protein allophycocyanin (APC) as donor, and dextran labeled with malachite green (MG) as acceptor. Glucose competitively displaces dextran-MG and leads to reduction in FRET, assessed by time-domain fluorescence lifetime measurements using time-correlated single-photon counting. The assay is operative in the glucose concentration range 2.5-30 mM, and therefore suitable for use in monitoring diabetes control. Albumin and serum inhibit FRET but the interference can be prevented by removal of high molecular weight substances by membrane filters. APC shows promise for incorporation in an implanted glucose sensor which can be interrogated from outside the body.     

Multi-day pre-clinical demonstration of glucose/galactose binding protein-based fiber optic sensor

We report here the first pre-clinical demonstration of continuous glucose tracking by fluorophore-labeled and genetically engineered glucose/galactose binding protein (GGBP). Acrylodan-labeled GGBP was immobilized in a hydrogel matrix at the tip of a small diameter optical fiber contained in a stainless steel needle. The fiber optic biosensors were inserted subcutaneously into Yucatan and Yorkshire swine, and the sensor response to changing glucose levels was monitored at intervals over a 7-day period. Sensor mean percent error on day 7 was 16.4±5.0% using a single daily reference blood glucose value to calibrate the sensor. The GGBP sensor's susceptibility to common interferents was tested in a well-plate system using human sera. No significant interference was observed from the tested interferents except for tetracycline at the drug's maximum plasma concentration. The robust performance of the GGBP-based fiber optic sensor in swine models and resistance to interferents indicates the potential of this technology for continuous glucose monitoring in humans.     

Nanodiscs allow the use of integral membrane proteins as analytes in surface plasmon resonance studies

Nanodiscs are small-sized and flat model membranes that provide a close to native environment for reconstitution of integral membrane proteins. Incorporation of membrane proteins into nanodiscs results in water-soluble proteolipid particles making the membrane proteins amenable to a multitude of bioanalytical techniques originally developed for soluble proteins. The transmembrane domain of the human CD4 receptor was fused to ubiquitin with a preceding N-terminal decahistidine tag. The resulting integral membrane protein was incorporated into nanodiscs. Binding of the nanodisc-inserted histidine-tagged protein to a monoclonal anti-pentahistidine antibody was quantified using surface plasmon resonance (SPR) experiments. For the first time, a membrane-inserted transmembrane protein was employed as analyte while the antibody served as ligand immobilized on the sensor chip surface. SPR experiments were conducted in single-cycle mode. We demonstrate that the nanodisc-incorporated membrane protein showed nearly identical affinity toward the antibody as did the soluble decahistidine-tagged ubiquitin studied in a comparative experiment. Advantages of the new experimental setup and potential applications are discussed.     

Glucose Level Measurement Using Photonic Crystal Fiber–based Plasmonic Sensor

In this study, we demonstrate the design of a photonic crystal fiber (PCF)-based plasmonic sensor to measure the glucose level of urine. The sensor is designed by placing a small segment of PCF between a lead-in and a lead-out single-mode fiber. We utilize the finite element method to simulate the proposed plasmonic sensor for the measurement of glucose level in urine. To offer external sensing, the cladding layer of the PCF was coated by a thin layer of gold where the gold-coated PCF was immersed in the urine sample. As a result, the urine can easily interact with the plasmonic layer of the sensor. In the outermost laser of the PCF, we considered a perfectly matched layer as a boundary condition. The simulation results confirm excellent wavelength and amplitude sensitivities where the maximum wavelength sensitivity was 2500 nm/RIU and amplitude sensitivity was 152 RIU^?1 with a sensing resolution of 4?×?10^?6. For optimization of the plasmonic sensor, we varied the physical parameters of the cladding air holes and the thickness of the gold layer during the simulation. We strongly believe that the proposed plasmonic sensor will play a significant role to pave the way for achieving a simple but effective PCF-based glucose sensor.

     

Diffusion delays and unstirred layer effects at monolayer cultures of Chinese hamster ovary cells

Cells grown in monolayer culture offer a convenient system for binding and other experiments under conditions that preserve the complexity of the living state. Kinetics experiments, however, may be distorted by the time course of drug penetration into even so simple a “tissue” as the monolayer. The impediments include unstirred layers both above and between the cells, the congregation of receptors within the confined space between cells, and nonspecific binding to membrane components. The contributions of these factors were investigated in cultures of Chinese hamster ovary (CHO) cells either nontransfected or stably transfected with μ opioid receptors. The dissociation of [³H]naloxone was four times faster under displacement than under infinite dilution conditions, clearly demonstrating the “retention effect” of receptors confined in space. Even the penetration of this ligand between nontransfected cells showed salient delays with respect to diffusion into a slab, indicating that nonspecific, low-affinity binding to membrane components was arresting its progress. The optical sectioning capabilities of confocal microscopy demonstrated that the kinetics of two fluorescent antagonists depended on the vertical plane, providing direct evidence for slowed diffusion down a single cell depth. Modeling shows that kinetic errors increase with receptor density, forward rate constant, and the thickness of the unstirred layer.     

Purification and characterization of an 82-kD membrane protein as a neurite outgrowth factor binding protein: possible involvement of NOF binding protein in axonal outgrowth in developing retina

Neurite outgrowth factor (NOF) is a glycoprotein isolated from an extract of gizzard that induces neurite outgrowth from cultured retinal or ciliary ganglionic (CG) neurons. We have reported that a glycoprotein of approximately 82 kD solubilized from gizzard muscles binds to NOF (ligand blotting) and inhibits the neurite promoting activity of NOF (inhibition assay). The 82-kD protein (NOF binding protein) was purified from gizzard muscle membranes as a doublet band on SDS-PAGE and a polyclonal antibody was raised against it. An NOF binding protein in developing retina exhibited the same physicochemical properties as that of the gizzard muscle. Quantitative decrease in NOF binding protein in embryonic retinas was observed after day 11 by the inhibition assay, ligand blotting, and immunoblotting, its decrease being parallel with reduction of NOF-induced neurite outgrowth of embryonic retinas. In an immunohistochemical study, the antibody stained only the optic fiber layers of the retinas of 8-d embryos, and this staining was no longer detectable in retinas of 18-d embryos. These results suggest that the 82-kD protein is a novel membrane protein that behaves as an NOF receptor and that the loss of neuritic response of the retinal neurons to NOF reflects a decrease in NOF receptor molecules.     

Immobilization of glucose oxidase on polymer membranes treated by low-temperature plasma

Low-temperature plasma was employed for activation of polymer membranes as a carrier for enzyme immobilization. Glucose oxidase was immobilized on polypropylene (PP), polyvinylidene fluoride (PVDF), or polytetrafluoroethylene (PTFE) membrane surfaces treated by nitrogen or ammonia gas plasma using glutaraldehyde as a linking agent. Enzyme activity was evaluated by the response of glucose sensor composed of the immobilized enzyme membrane and a dissolved oxygen electrode. The sensor response was found to depend on the kind of carrier membrane and to become maximum at suitable conditions of plasma treatment.     

Needle-type lactate biosensor

A needle-type lactate biosensor has been developed for continuous intravascular lactate monitoring. The sensor employs poly(1,3-phenylenediamine) as the inner layer on the platinum electrode in order to eliminate the interference from oxidizable physiological substances. Cross-linking with glutaraldehyde was used for enzyme immobilization. Dithiothreitol was used as the stabilizer of lactate oxidase. PVC (polyvinyl chloride) was chosen as the external diffusion control membrane. Sensor performance was evaluated in vitro and the sensor shows a sensitivity of 10-15 nA/mM, and a linear range from 1 mM to at least 15 mM lactate. Evaluation of the sensor response in blood plasma showed similar sensitivity and linear range as indicated by the calibration curves obtained in buffer solution. The sensor has a short response time of approximately 1 minute. The sensors were operated continuously for 7 days in phosphate buffer containing solution with a concentration at the physiological lactate level. No significant change in sensor sensitivity and its linear range has been observed. Sensors show a minimum change in its performance when stored in buffer at 4 degrees C for at least 9 months.     

Highly selective amperometric glucose microdevice derived from diffusion layer gap electrode

Although most of enzyme catalytic reactions are specific, the amperometric detection of the enzymatic reaction products is largely nonselective. How to improve the detection selectivity of the enzyme-based electrochemical biosensors has to be considered in the sensor fabrication procedures. Herein, a highly selective amperometric glucose biosensor based on the concept of diffusion layer gap electrode pair which we previously proposed was designed. In this biosensor, a gold tube coated with a conductive layer of glucose oxidase/Nafion/graphite was used to create an interference-free region in its diffusion layer by electrochemically oxidizing the interfering electroactive species at proper potentials. A Pt probe electrode was located in this diffusion layer of the tube electrode to selectively detect hydrogen peroxide generated from the enzyme catalytic oxidation of glucose in the presence of oxygen in the solution. In practical performance of the microdevice, parameters influencing the interference-removing efficiency, including the tip-tube opening distance, the tube electrode potential and the electrolyzing time had been investigated systematically. Results showed that glucose detection free from interferents could be achieved at the electrolyzing time of 30s, the tip-tube opening distance of 3mm and the tube electrode potential of 0.4V. The electrochemical response showed linear dependence on the concentration of glucose in the range of 1 x 10(-5) to 4 x 10(-3) M (the correlation coefficient: 0.9936, without interferents; 0.9995, with interferents). In addition, the effectiveness of this device was confirmed by numerical simulation using a model system of a solution containing interferents. The simulated results showed good agreement with the experimental data.     

The relationship of phosphatidylinositol turnover to receptors and calcium-ion channels in rat parotid acinar cells.

To help elucidate the possible role of phosphatidylinositol in the regulation of membrane permeability to Ca2+, the relationship in the rat parotid gland of phosphatidylinositol turnover to hormone receptor binding and to the hormone-mediated increase in K+ permeability (a Ca2+-dependent phenomenon) was investigated. The concentrations of adrenaline and substance P required to stimulate phosphatidylinositol turnover were found to be similar to those required for the Ca2+-mediated change in K+ permeability and for ligand binding. However, in the case of muscarinic (cholinergic) receptor stimulation, the phosphatidylinositol response was better correlated to the increase in membrane permeability to Ca2+, as determined by the change in K+ permeability, than to receptor occupation. Consistent with this relationship between the phosphatidylinositol response and Ca2+-channel activation were results obtained by simultaneous administration of maximal or submaximal concentrations of muscarinic and alpha-adrenergic agonists. The extent of 32P incorporation when stimulated by maximal concentrations of two agonists did not summate, but, rather, was intermediate between the response of either agonist alone. One interpretation for these observations is that the phosphatidylinositol response may not be related to receptor occupation or activation, but may be involved in the Ca2+-gating mechanism itself.     

Localized Surface Plasmon Resonance-Based Fiber Optic U-Shaped Biosensor for the Detection of Blood Glucose

In the present study, we report the first fiber optic glucose sensor utilizing localized surface plasmon resonance of metal nanoparticles. The fiber was bent in the form of a U-shaped probe for point detection and sensitivity enhancement. The probe was prepared by first attaching gold nanoparticles on the optical fiber core and then immobilizing glucose oxidase over it. The sensor operates in the intensity modulation scheme in which the absorbance is measured with respect to the changes in the glucose concentration. The presence of glucose in the vicinity of the sensing region changes the refractive index of the film due to the chemical reactions with glucose oxidase. The absorbance of the metal nanoparticle changes significantly due to local refractive index change. The fiber optic U-shaped probes of different bending radii were fabricated and it has been found that the probe with bending radius around 0.982?mm possesses the maximum sensitivity. The response of the sensor is fast and requires very small volume of sensing sample (??150???l) which makes it more suitable for commercialization and better than present commercial sensors, which require about 1.5?ml of blood for the detection of glucose.