RO137529A2 - Biosensor for determining nickel ions - Google Patents

Abstract

The invention relates to a biosensor employed for quick and accurate in-situ determination of Ni ions in edible plant-based products, in order to prevent allergic symptoms in sensitive persons. According to the invention, the sensor consists of a potentiometric unit and a disposable electrode (1) made of a polymeric support material (2) with electrically insulating role, strip metal electrodes (3, 4 and 5) or electrodes modified with Ag nanoparticles over which an alginate 1% aqueous solution is deposited as fixation and immobilization agent (6) and a urease 0.1% solution as biologically active material (7) having the role of binding the Ni ion in the food sample (8) to be analyzed, the faradic current given by the potentiometric unit being correlated to the Ni ion concentration by a calibration curve established by means of a family of cyclic-voltammetric curves.

Description

BIOSENSOR FOR THE DETERMINATION OF NICKEL IONS

The biosensor according to the invention is intended for the rapid, in situ and precise determination of nickel ions in food products of vegetable origin.

The importance of determining the concentration of nickel ions in food raw materials and food is represented by their toxicity on the health of the population. It is estimated that about 8-10% of women and l-2% of men are sensitive to nickel.

Exposure to nickel up to 500 pg/day has been reported to worsen contact skin eczema in nickel-sensitized individuals. A total average daily intake was estimated at 0.ΙΟ.3 mg. In addition to these effects, higher concentrations of nickel can cause pulmonary fibrosis, cardiovascular and kidney disease, and lung and nasal cancer. Considering the mentioned effects, the accurate and precise determination of this element in food raw materials and foods becomes a major necessity.

Reference methods that measure total nickel content with detection limits at the nanogram (ppt) and microgram (ppb) level include flame atomic absorption spectrometry (FAAS), graphite furnace atomic absorption spectrometry (GFAAS ), inductively coupled plasma optical emission spectrometry (ICP-OES) or inductively coupled plasma mass spectrometry (ICP-MS), and for detection limits located at the milligram level, electrochemical methods of analysis are used including potentiometry, amperometry , polarography and conductometry, molecular spectrometry or volumetric methods.

The disadvantages of the spectrometric methods listed above consist in the fact that the means that serve them are bulky devices that do not allow the in situ analysis of nickel ions in food products of vegetable origin. Apart from these disadvantages, spectrometric analyzes require a high preparatory effort as well as specialized personnel for the analyzes and for the interpretation of the results.

In order to avoid frequently sending food samples of vegetable origin to specialized laboratories, to determine the concentration of nickel ions, there is a need for a high-performance, small-sized instrumental analysis tool that allows consumers to determine in a short time in situ and precisely the concentration of nickel ions.

Such a means of instrumental analysis can be a specialized nickel ion biosensor. following the acquisition and processing of the data obtained for a food sample of vegetable origin, the concentration of the nickel ion in that product appears on the biosensor display. As a way of working, only the use of a single drop of the liquid sample, obtained by squeezing or cutting for samples with concentrations between 0.l -10 mg/kg, is claimed, and for samples with higher concentrations, a dilution of them is also necessary, followed by reading the nickel ion concentration on the alphanumeric display.

There are numerous studies and researches on the detection of metal ions, but only some of them are aimed at the determination of nickel ions and very few are aimed at the determination of food products. Thus, in the document [Dl] “Mettakoonpitak, J., MillerLionberg, D., Reilly, T, Volckens, J., & Henry, C. S. (2017). Low-cost reusable sensor for cobalt and nickel depletion in aerosols using adsorptive cathodic square-wave stripping vollammetry. J. Electroanal. Chem, 805, 75-82”, a method is described, in which the concentration of nickel ions is determined with dimethylglyoxime (DMG), which is also the most used receptor for biosensors intended for the detection of nickel ions, by the adsorptive voltammetry technique with cathodic stripping with the linearity range between 5-175 pg/kg.

in document [D2| Ochab, M., G^ca, L, & Korolczuk, M. (2019). The new Micro-set for Adsorptive Stripping Voltammetric Simultaneous Determination of Nickel and Cobalt Traces in Aqueous Media. Electroanalysis, 31(9), 1769-1774", another method is described for the determination of nickel ions by another voltammetric technique and the use of nioxime, resulting in a linearity range of 0.11-0.58 pg/kg.

in document [D3| Yang, Y., Yuan, Z., Liu, XP, Liu, Q., Mao, CJ, Niu, HL....& Zhang, SY (2016). Electrochemical biosensor for Ni ²⁺ detection based on a DNAzyme-CdSe nanocomposite. Biosens, Bioelectron, 77, 13-18", a biosensor used to detect the concentration of nickel ions using a DNAzyme-CdSe nanocomposite bioreceptor and differential pulse anodic stripping voltammetry technique is described, achieving a wider linearity range 1.173 pg /kg - 11.73 mg/kg and a lower detection limit (6.67 nM).

in document [D4] “Verma, N, & Singh, M. (2006). A Bacillus sphaericus based biosensor for monitoring nickel ions in industrial effluents and foods. J Autom Methods Manag Chem., 2006”, the authors developed a sensor for nickel ions in food, but did not specify the sensitivity; reported only the detection range of Ni (11): 0.002-0.04 ppb with a response time of 1.5 minutes and a reliability of 91.5% and 90.6%. ...

in the document [D5| "Padilla. V., Serrano, N., & Diaz-Cruz, J. M. (2021). Determination of Trace Levels of Nickel (11) by Adsorptive Stripping Voltammetry Using a Disposable and Low-Cosi Carbon Screen-Printed Electrode. Chemosensors, 9(5), 94", describes a biosensor for the detection of nickel by differential pulse stripping voltammetry using dimethylglyoxime as the bioreceptor, a linearity range of 1.7 - 150 μg/l and a detection limit of 0 .5 pg/L.

The technical problem that the invention solves consists in making a biosensor with high sensitivity and precision, used for the in silico determination of nickel ions in food products of plant origin, so that toxic effects on the human body can be prevented.

for this purpose, a portable potentiometric structure is used, which includes a screen-printed electrode, consisting of three metal electrodes, of which the working electrode is modified with silver nanoparticles, on a non-electrically conductive polymeric support, over which an agent is deposited for fixation and immobilization (alginate) and a biologically active material (urease), with the role of binding the component (nickel), from food products of vegetable origin, for the analysis a quantity of the order of a single drop (50μΙ) is required.

The faradaic current measured by the potentiostat is an expression of the concentration of nickel ions in the analyzed food sample. As a result of the conversion, with the help of the internal software based on the calibration curve made in faradic current-concentration coordinates, the concentration of nickel ions appears on the biosensor display in units of milligrams per liter.

The advantage of using a biosensor according to the invention consists in the fact that it does not require specialized personnel, it is portable and can be used for in situ analyzes in order to determine the concentration of the nickel ion from small amounts of sample.

An embodiment is given next, in connection with Fig. 1, Fig. 2, Fig. 3, Fig. 4 and Tab. I, which represents:

Fig. I. General scheme of the biosensor intended for the determination of nickel ions in food products of vegetable origin

Fig. 2. Obtaining the screen-printed electrode and how to work with the biosensor

Fig. 3. Example of a family of cyclic voltammograms used to determine the concentration of nickel ions in food products of vegetable origin

Fig. 4. The calibration curve used to determine the concentration of nickel ions in food products of vegetable origin

Table I. Analytical performance characteristics of the biosensor used to determine the concentration of nickel ions in food products of vegetable origin _n

The biosensor according to the invention, Fig. 1, comprises a screen-printed electrode 1 for single use, with a working electrode modified with silver nanoparticles, planar, of reduced dimensions consisting of a polymeric support material 2, electrical insulator, some electrodes 3, 5 metal and 4 of nanoparticle powder of silver, over which a fixation and immobilization agent 6 is deposited (alginate) and a biologically active material 7 (urea) with the role of binding the targeted component (nickel ions) from food sample 8 of vegetable origin and an electronic unit 9 . For the analysis of the nickel ion from a food sample of vegetable origin 8, the disposable electrode 1 is inserted by sliding into the electronic unit 9 of the biosensor formed by a potentiostat, programmed for the specific working voltage of the nickel ion. The potentiostat is composed of a microprocessor for data acquisition and processing, an internal software for converting the faradic current into units of nickel ion concentration and an alphanumeric display d to show the concentration of nickel ions in food products of vegetable origin in units of mg/ kg.

The sequence of phases for obtaining the analytical structure of the biosensor described in Fig. 2, indicates how to use the biosensor to determine the concentration of nickel ions in food products of vegetable origin.

The steps to obtain a single-use screen-printed electrode involve in the first phase the deposition on the planar potentiometric electrochemical cell of the fixation and immobilization agent of 0.25 μΙ alginate 1% aqueous solution, followed by the deposition of the biologically active material of 0.25 μΙ aqueous solution of urea 0.1%, drying for 60 minutes at a temperature of 25 C and the operation of tight encapsulation.

The working mode of the biosensor according to the invention goes through the following successive stages:

-connecting the single-use electrode by sliding it into the corresponding slot of the electronic unit 9 of the biosensor, which automatically activates the microprocessor for data acquisition and processing.

- placing a drop (50 μΙ) of the sample on the working electrode and pressing the start button to carry out the voltammetric analysis.

- the reading on the alphanumeric display, of the electronic unit 9, of the concentration of the nickel ion in the food sample 8 of vegetable origin.

Once connected to the electrochemical cell 1, the potentiostat 9 is turned on, which measures the concentration of nickel ions present in the sample 8 of the analyzed food product. in order to establish the database for the internal software, several cyclovoltagrarns are performed (Fig. 3)

for different nickel ion concentrations using a nickel sulfate solution for this purpose. With the help of the maximum intensities of the redox peaks from the voltagrams, the calibration curve is made in faradic current-concentration coordinates, Fig.4, and the pairs of values of the points on the calibration curve are entered into the RAM memory of the microprocessor. further, any faradic current measurement performed for a food sample of vegetable origin is automatically converted based on the calibration curve in the memory into units of concentration of nickel ions per kg of food product which are displayed as such on the display of the biosensor.

The performance characteristics tested with this biosensor were analytical sensitivity and detection limit, Table l.

Claims (4)

I. The invention Biosensor for the determination of nickel ions in food products of vegetable origin, characterized by the fact that a biosensory system is used which is composed of a potentiometric unit and a screen-printed electrode (1) for single use, an agent (6) fixation and immobilization, a biologically active material (7), the correlation between the faradic current and the concentration of the nickel ion being made by a potentiometric method with the auger of a calibration curve which in turn is based on a family of cyclo-voltametric curves. 2. Screen-printed electrode (1) for single use, according to main claim no. 1, characterized in that the powder used for this purpose consists of silver nanoparticles; 3. Fixing and immobilizing agent (6), according to main claim no. 1, characterized in that the substance used for this purpose is a 1% aqueous solution of alginate; 4. The biologically active material (7) according to main claim no. 1, characterized in that the substance used for this purpose is a 0.1% urea aqueous solution;