Enzyme-modified electrodes for peroxide, choline, and acetylcholine

Towards timely Alzheimer diagnosis: A self-powered amperometric biosensor for the neurotransmitter acetylcholine

Serious brain disorders, such as the Alzheimer's Disease (AD), are associated with a marked drop in the levels of important neurotransmitters, such as acetylcholine (ACh). Real time monitoring of such biomarkers can therefore play a critical role in enhancing AD therapies by allowing timely diagnosis, verifications of treatment effectiveness, and developments of new medicines. In this study, we present the first acetylcholine/oxygen hybrid enzymatic fuel cell for the self-powered on site detection of ACh in plasma, which is based on the combination of an enzymatic anode with a Pt cathode. Firstly, an effective acetylcholinesterase immobilized electrode was developed and its electrochemical performance evaluated. Highly porous gold was used as the electrode material, and the enzyme was immobilized via a one step rapid and simple procedure that does not require the use of harsh chemicals or any electrode/enzyme pre-treatments. The resulting enzymatic electrode was subsequently used as the anode of a miniature flow-through membrane-less fuel cell and showed excellent response to varying concentrations of ACh. The peak power generated by the fuel cell was 4nW at a voltage of 260mV and with a current density of 9μAcm^-2. The limit of detection of the fuel cell sensor was 10μM, with an average response time as short as 3min. These exciting results open new horizons for point-of-care Alzheimer diagnosis and provide an attractive potential alternative to established methods that require laborious and time-consuming sample treatments and expensive instruments.

Decomposition and solubility of H2O2: implications in exhaled breath condensate

Hydrogen peroxide (H2O2) is one of the metabolic end products present in exhaled breath. High levels of H2O2 found in breath condensate are an indicator of airway inflammation and could be used for monitoring the condition of patients with chronic obstructive pulmonary disease. However, sampling conditions such as breath temperature, condensing temperature, flow rate and collection time can affect the intrinsic properties of H2O2-its solubility, volatility, and decomposition rate. Sudden decreases to H2O2 concentration may be due to the sampling conditions instead of the patient's health status. The decomposition rate and Henry's law constant for saturated H2O2 vapor (RH > 95%) within 22-42 °C, which correlates to room temperature and range of human breath temperatures, are needed for better understanding and standardization of breath collection. In this study, we determined the effects of initial H2O2 concentration, temperature, and sampling time on the decomposition rate by comparing electrochemical measurements of H2O2 in simulated breath samples. The experimental results showed the decomposition rate of H2O2 increased as the breath temperature and sampling time increased and the solubility of H2O2 increased with increasing flow rate and condensing temperature during sampling. Prediction models for H2O2 sensing in exhaled breath sample were developed that could be used in the standardization of exhaled breath condensate collection. These experimental findings need to be further verified with human/animal breath samples.

Natural and synthetic affinity agents as microdialysis sampling mass transport enhancers: current progress and future perspectives

Microdialysis sampling is a diffusion-based separation method that allows analytes to freely diffuse across a hollow fiber semi-permeable dialysis membrane. This sampling technique has been widely used for in vivo chemical collection. The inclusion of affinity-based trapping agents into the microdialysis perfusion fluid serves to improve the relative recovery via the binding reaction of low molecular weight hydrophobic analytes and larger analytes such as peptides and proteins. Here, we briefly review our past studies using different compounds (native cyclodextrins and antibodies) to improve microdialysis sampling recovery. A brief compilation of our studies using antibody-immobilized beads as a means to improve cytokine collection during microdialysis sampling is also described. We present new work focused on the use of antibody-immobilized bead microdialysis sampling enhancement for various endocrine hormones (amylin, GLP-1, glucagon, insulin, and leptin). The antibody-bead enhancement approach allowed for recovery enhancements that ranged between 3 and 20-fold for these peptides. Using the enhanced recovery approach, endocrine peptides at pM concentrations can be quantified. Finally, our initial work focused on developing non-antibody based enhancement agents using bovine serum albumin-heparin conjugates covalently bound to polystyrene microspheres is presented for the cytokine, tumor necrosis factor-alpha (TNF-alpha). Unlike antibodies, heparin provides the advantage of being reusable as an enhancement agent and served to improve the relative recovery of TNF-alpha by three-fold.

Amperometric microsensors for monitoring choline in the extracellular fluid of brain

Selective amperometric enzyme microsensors for monitoring low micromolar concentrations of choline in extracellular fluid of rat brain have been developed. Preparation of the choline microsensors involved the modification of carbon fiber microcylinder electrodes (10 microns diameter, 300-400 microns long) with a cross-linked redox-active gel containing horseradish peroxidase and choline oxidase. Rejection of the noise recorded from the choline microsensors implanted in living brain tissue improved the in vivo detection capabilities of the sensors. The microsensors and a differential detection scheme were used to estimate the basal concentration of choline in striatal tissue at 6.6 +/- 2.9 microM and to measure changes in choline concentrations of 6.1 +/- 2.7 microM in vivo. The microsensors were also used to monitor choline produced following the injections of acetylcholine in vivo. Coinjections of neostigmine and acetylcholine significantly lowered the choline response recorded with the microsensors, confirming that the response following the injections of acetylcholine alone was due to the activity of endogenous acetylcholinesterase. Comparison of the maximal rate of decrease in choline concentration following the injections of 1 mM choline and 1 mM acetylcholine was used to estimate the rate of acetylcholine clearance from extracellular fluid through cholinesterase activity at approx. 2.5 microM/min.