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Title:
PORTABLE DEVICE AND METHOD OF OPERATION THEREOF FOR ANALYZING SALT CONTENT IN FOOD
Document Type and Number:
WIPO Patent Application WO/2020/109993
Kind Code:
A1
Abstract:
Portable device and method of operation thereof for analyzing the salt content in food comprising: a container with a mixer-grinder propeller, an electrode, motor means for driving said propeller, a weight sensor of said container, an electronic data processor, and a lid for said container; wherein said lid comprises a water injector, a calibration solution injector, and a detachable coupling on the lid for the electrode, wherein said electronic data processor is configured to: detect the introduction of a food sample into said container by the weight gain measured by the sensor; driving the water injector to introduce water up to a predetermined volume of water and driving the motor means to grind the contents by said propeller; driving the motor means to stir the contents by said propeller and to measure the salt concentration.

Inventors:
DA SILVA GONÇALVES CARLA CRISTINA (PT)
RODRIGUES CARVALHO PENA MARIA JOÃO (PT)
MARCOS MOREIRA JOSÉ LUÍS (PT)
MAGALHÃES MENDES JOAQUIM GABRIEL (PT)
COSTA ALVES MARIA ARMINDA (PT)
DE CASTRO PINHO OLÍVIA MARIA (PT)
MAIA DA CRUZ MARTINS RODOLFO MANUEL (PT)
Application Number:
PCT/IB2019/060170
Publication Date:
June 04, 2020
Filing Date:
November 26, 2019
Export Citation:
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Assignee:
UNIV DO PORTO (PT)
EVOLEO TECH LDA (PT)
International Classes:
G01N33/02; A47J42/00; A47J43/04; A47J43/07
Domestic Patent References:
WO2015138961A12015-09-17
Foreign References:
EP3251567A12017-12-06
US10022008B12018-07-17
Attorney, Agent or Firm:
PATENTREE (PT)
Download PDF:
Claims:
C L A I M S

1. Portable device for analyzing the salt content in food, comprising:

a container with a mixer-grinder propeller, a detachable electrode, motor means for driving said propeller, a weight sensor of said container, an electronic data processor, and a lid for said container;

wherein said lid comprises a water injector and a calibration solution injector, wherein said electronic data processor is configured to:

detect the introduction of a food sample into said container by the weight gain measured by the weight sensor;

drive the water injector to introduce water into the container up to a predetermined volume of water and drive said motor means to grind the contents of the container by said propeller;

drive said motor means to stir the contents of the container by said propeller and to measure the salt concentration indicated by the electrode.

2. Portable device for analyzing the salt content in food according to the preceding claim, wherein the lid comprises a detachable coupling on the lid for coupling said electrode.

3. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said lid is coupled to said container by means of a hinged coupling.

4. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor for initializing the device for analyzing salt content is further configured to:

drive the calibration solution injector for introducing a predetermined salt concentration calibration solution into the container and driving said motor means to stir the contents of the container;

measure the salt concentration indicated by the electrode; calculate a calibration of said electrode as a function of the measured salt concentration and the predetermined salt concentration of the calibration solution.

5. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor is further configured to, upon driving said motor means for grinding the contents of the container, introduce a predetermined volume of water in the container:

previously drive the water injector to introduce a first part of the predetermined volume of water into the container before driving said motor means; and subsequently drive the water injector to introduce a second part of the predetermined volume of water into the container after driving said motor means.

6. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor is further configured to: drive said motor means to stir the contents of the container by said propeller and to subsequently measure the salt concentration indicated by the electrode.

7. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor is further configured to: when driving the calibration solution injector to introduce the calibration solution into the container, drive the water injector to introduce water into the container to dilute the calibration solution concentration up to a predetermined salt concentration of the calibration solution.

8. Portable device for analyzing the salt content in food according to any one of the preceding claims, comprising a screen and wherein said electronic data processor is further configured to:

query a database of reference products and, depending on the measured salt concentration, display a ranking;

IB or display a variable color indicator on the screen with the measured salt concentration.

9. Portable device for analyzing the salt content in food according to any one of the preceding claims, comprising a closure detector of said lid and wherein said electronic data processor is further configured:

not to drive the water injector to introduce water into the container until it detects that the lid is closed.

10. Portable device for analyzing the salt content in food according to any one of the preceding claims, comprising a closure detector of said lid and wherein said electronic data processor is further configured:

not to drive the calibration solution injector to introduce calibration solution into the container until it detects that the lid is closed.

11. Portable device for analyzing the salt content in food according to any one of the preceding claims, comprising a closure detector of said lid and wherein said electronic data processor is further configured:

not to drive said motor means until it detects that the lid is closed.

12. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor is further configured: not to drive the motor means for grinding until it detects that the electrode is not coupled to the lid.

13. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein said electronic data processor is further configured: not to drive the motor means for stirring until it detects that the electrode is coupled to the lid.

14. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein the predetermined volume of water is 200 mL

15. Portable device for analyzing the salt content in food according to any one of the preceding claims, wherein the water is deionized water.

16. Portable device for analyzing the salt content in food according to any one of the preceding claims, comprising a temperature sensor in said container or lid for gauging said salt concentration measurement by the electrode.

17. Method of operating a portable device for analyzing the salt content in food, comprising:

providing a device comprising a container with a mixer-grinder propeller, a detachable electrode, motor means for driving said propeller, a weight sensor of said container, an electronic data processor, and a lid for said container; wherein said lid comprises a water injector and a calibration solution injector;

detecting the introduction of a food sample into said container by the weight gain measured by the weight sensor;

driving the water injector to introduce water into the container up to a predetermined volume of water and drive said motor means to grind the contents of the container by said propeller;

driving said motor means to stir the contents of the container by said propeller and to measure the salt concentration indicated by the electrode.

18. Method of operating a portable device for analyzing the salt content in food according to claim 17, comprising, for initializing the device for analyzing the salt content:

driving the calibration solution injector for introducing a predetermined salt concentration calibration solution into the container and driving said motor means to stir the contents of the container; measuring the salt concentration indicated by the electrode;

calculating a calibration of said electrode as a function of the measured salt concentration and the predetermined salt concentration of the calibration solution.

19. Method of operating a portable device for analyzing the salt content in food according to claim 17 or 18, which, by driving said motor means to grind the contents of the container, comprises, for introducing a predetermined volume of water into the container:

previously driving the water injector to introduce a first part of the predetermined volume of water into the container before driving said motor means; and subsequently driving the water injector to introduce a second part of the predetermined volume of water into the container after driving said motor means.

20. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-19 comprising:

driving said motor means to stir the contents in the container by said propeller and subsequently measuring the salt concentration indicated by the electrode.

21. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-20 comprising:

when driving the calibration solution injector to introduce the calibration solution into the container, operating the water injector to introduce water into the container to dilute the calibration solution concentration up to a predetermined salt concentration of the calibration solution.

22. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-21, comprising:

querying a database of reference products and, depending on the measured salt concentration, displaying a ranking; or display a variable color indicator on a screen with the measured salt concentration.

23. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-22 comprising not driving the water injector to introduce water into the container until it detects that the lid is closed.

24. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-23 comprising not driving the calibration solution injector to introduce solution into the container until it detects that the lid is closed.

25. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-24 comprising not driving said motor means until it detects that the lid is closed.

26. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-25 comprising not driving the motor means for grinding until it detects that the electrode is not coupled to the lid.

27. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-26 comprising not driving the motor means for stirring until it detects that the electrode is coupled to the lid.

28. Method of operating a portable device for analyzing the salt content in food according to any one of claims 17-27 comprising accessing a database and storing the data of the measurement performed comprising the measured salt concentration.

Description:
D E S C R I P T I O N

PORTABLE DEVICE AND METHOD OF OPERATION THEREOF FOR ANALYZING SALT CONTENT IN FOOD

TECHNICAL FIELD

[0001] This description relates to a portable, preferably automatic, device and operating method thereof for analyzing the salt content in food.

BACKGROUND

[0002] Reducing salt intake has been a priority of public health interventions and recommendations from national and international health organizations. Reducing salt intake by decreasing salt supply through food processed by the food industry and catering meals is on the political agenda due to the high evidence of great public and economic benefit and cost-effectiveness of interventions. This portable device for the acquisition and processing of data concerning salt content in food makes it easy to quickly and easily analyze the salt content in food at the collection site, with no need for transport to a laboratory. In this way it is possible to correct the salt content of the food to be supplied to consumers if necessary.

[0003] This device is of high interest to catering agents, the food industry, nutritionists, doctors, veterinarians, food inspectors and the average consumer.

[0004] The World Health Organization (WHO) recommends that salt intake be less than 5 g/day in order to reduce the risks associated with its excessive intake. The last study with population representative data on salt intake in Portugal, conducted in 2012, revealed a consumption clearly above the recommended values, with an average intake of 10.7 g/day. Several published studies have found an association between high salt intake and the development of chronic diseases including cardiovascular diseases, the leading cause of death in Portugal and worldwide. Thus, reducing salt intake is a priority on the political agenda of developed and developing countries.

[0005] In view of the above, a method for dosing sodium in food matrices is extremely useful. The reference method currently used is atomic emission spectrophotometry, and the sample preparation process for analysis is time consuming. This method also has practical limitations, such as the impossibility of obtaining immediate results and not being portable, which makes its application in the audit and inspection routine difficult. Alternatively, the sodium ion-selective electrode potentiometric method can overcome the difficulty of automation and the speed of response required, while maintaining analytical uncertainty at an acceptable level.

[0006] There are some portable devices on the market that allow the assessment of the salt content in food. Some equipment is based on conductivity measurement, however this determination is not specific for sodium content, but is only indicated for food with large amount of salt such as brines, where the existence of sodium ions in larger quantity is assumed, not being recommended for use in other food matrices.

[0007] There are also portable devices that allow coupling of a selective sodium electrode. However, they do not allow automated analysis including the preparation of the food sample to be analyzed, requiring prior steps by the user and additional equipment (e.g. scale, volume meter, grinder and stirrer) and still relegating the calculation of the result to the user.

[0008] Direct potentiometric measurement with sodium selective electrodes requires that an Ionic Strength Adjustor Buffer (ISAB) solution be added to the sample to be analyzed, in order to maintain constant ionic strength on most electrodes on the market. This step increases the complexity and duration of the analysis. However, the present device uses a selective sodium electrode that incorporates an internal reference not requiring the addition of ISAB solution.

[0009] If a selective sodium electrode requiring the addition of ISAB solution is used, it is necessary to provide the reservoir with an additional ISAB solution container, another injection pump and provide for the same amount of ISAB solution to be added to all samples before measurement. [0010] Portable equipment for the assessment of sodium content in food is of maximum use in the area of food safety and quality. Also, the fact that in many countries, such as Portugal, legislation is in force regulating the salt content in bread, it is important that the assessment of salt content in bread is quick and easy so as to allow assessing and monitoring law compliance.

[0011] Given the importance of salt consumption reduction strategies, a Working Group led by the Directorate-General for Health was set up in 2015 in Portugal, which proposed new targets for reducing salt content in both food processed by food industries (4% reduction per year in various food categories) or in catering (reduction of salt content in soup and dish up to the reference value of 0.2g salt/lOOg food). Again, quickly and easily assessing salt content in food will allow to assess and monitor compliance with these targets.

[0012] These facts are described in order to illustrate the technical problems solved by the embodiments of the present document.

GENERAL DESCRIPTION

[0013] This disclosure comprises a portable multifunctional device that enables automatic preparation of solid and liquid food samples, determination of the salt content thereof through the direct sodium ion-selective electrode potentiometric method and nutritional information.

[0014] In particular, the system allows the determination of the salt and sodium content in food, expressed in g/lOOg (or mg/lOOg), the classification of salt content in associated classes, based on reference values and their association with colors (e.g. in the form of a traffic light) and still an indication of the percentage contribution of a given food to the total maximum intake recommended for adults.

[0015] Measurement of salt content with the portable device is preferably performed as follows: i) after selecting the food category on the touch screen, the device automatically starts calibration with measurement of a standard sodium chloride solution in the sample preparation unit; (ii) the electrode and the cup of the sample preparation unit are then washed, and the sample is introduced and grinding is performed together with deionized water; (iii) the equipment reads the sodium value and the temperature of the standard solution and the sample by calculating, based on Nernst's law, the salt and sodium concentration, which are displayed on the device screen, enabling it to be exported (interface with laptop, tablet, smartphone).

[0016] Expression of results is performed in such a way as to be readily and easily interpreted by the user, whereupon in addition to the salt and sodium content in g/lOOg (or mg/lOOg) and the contribution of the food according to the recommended maximum daily intake defined by the WHO, the device also preferably provides interpretative color information as a nutritional traffic light (red, yellow and green) indicating whether the salt content is adequate or excessive compared to the recommended maximum daily intake defined by the WHO.

[0017] This device is useful for quickly assessing salt content in food and in the environment of cooking the food, or where it is served, while providing relevant and unique nutritional information as it integrates the contribution of the various types of food in a meal, which is particularly important in the areas of nutrition, catering, veterinary medicine, medicine, and also in general health.

[0018] A possible embodiment of the portable automatic device for determining the salt content of solid and liquid food samples is characterized in that it has:

load cells (1) for determining the sample weight,

level sensor of the sample in the cup (2) for volume gauging,

salt sensor (3) by sodium ion-selective ion electrode,

temperature sensor (4),

motor for controlling the grinding and stirring process of the sample (6), a pump which allows adding water (7) and a pump for adding a calibration standard (8)

touch screen (10),

Wi-Fi connection (9).

[0019] One embodiment is characterized by using an electrode that combines two electrodes, a reference electrode and a sodium ion-selective electrode. [0020] One embodiment is characterized by performing salt content measurement by direct potentiometry using the Nernst equation as the theoretical quantification model.

[0021] One embodiment is characterized by performing salt content measurement of the food after automatic calibration of the device with only a standard solution with known sodium concentration.

[0022] One embodiment is characterized by the automation of the weighing process of the sample to be analyzed.

[0023] One embodiment is characterized by the automation of the grinding process of the sample to be analyzed.

[0024] One embodiment is characterized by the automation of the dilution process of the sample to be analyzed with deionized water.

[0025] One embodiment is characterized by the automation of the process of gauging the volume of the sample diluted with deionized water.

[0026] One embodiment is characterized by providing information regarding the salt content in solid and liquid food after 10% dilution with deionized water.

[0027] One embodiment is characterized by allowing the correction of the effect of temperature on the reading of the electrode potential difference.

[0028] One embodiment is characterized by using a control and processing unit with touch screen (10) for inputting and displaying information and interfacing with a laptop, tablet or smartphone for exporting results.

[0029] One embodiment is characterized in that the outer covering is resistant to falls and high temperature and humidity.

[0030] One embodiment is characterized by being light and easy to carry (less than 5 kg with respective accessories and solutions, in particular less than 2 kg).

[0031] One embodiment is characterized by presenting the data in the form of: salt and sodium content in g/lOOg (or mg/lOOg), classification of salt content according to the color traffic light by reference values and indication of the percentage contribution of that food to the maximum recommended total intake for adults and children. [0032] One embodiment is characterized by being able to synchronize with a database with information on the salt content levels of the commercially available food and also the analyzed food.

[0033] One embodiment is characterized by having the ability to make data available for aggregation in a central database, ensuring data protection and anonymity, for macro analysis of results, for example for geographic and demographic analysis.

[0034] A portable device for analyzing the salt content in food is described comprising: a container with a mixer-grinder propeller, an electrode, motor means for driving said propeller, a weight sensor of said container, an electronic data processor, and a lid for said container;

wherein said lid comprises a water injector, a calibration solution injector, and a detachable coupling on the lid for the electrode,

wherein said electronic data processor is configured to:

detect the introduction of a food sample into said container by the weight gain measured by the weight sensor;

drive the water injector to introduce water into the container up to a predetermined volume of water and drive said motor means so as to grind the contents of the container by said propeller;

drive said motor means to stir the contents of the container by said propeller and to measure the salt concentration indicated by the electrode.

[0035] In one embodiment, said lid is coupled to said container by means of a hinged coupling.

[0036] In one embodiment, said electronic data processor, in order to initialize the salt content analyzing device, is further configured to:

drive the calibration solution injector for introducing a predetermined salt concentration calibration solution into the container and drive said motor means to stir the contents of the container;

measure the salt concentration indicated by the electrode;

calculate a calibration of said electrode as a function of the measured salt concentration and the predetermined salt concentration of the calibration solution. [00B7] In one embodiment, said electronic data processor is further configured to, upon driving said motor means for grinding the contents of the container, introduce a predetermined volume of water in the container:

previously drive the water injector to introduce a first part of the predetermined volume of water into the container before driving said motor means; and subsequently drive the water injector to introduce a second part of the predetermined volume of water into the container after driving said motor means.

[0038] In one embodiment, said electronic data processor is further configured to drive said motor means to stir the contents of the container by said propeller and then measure the salt concentration indicated by the electrode.

[0039] In one embodiment, said electronic data processor is further configured to, upon driving the calibration solution injector to introduce the calibration solution into the container, drive the water injector to introduce water into the container to dilute the concentration of the calibration solution up to a predetermined salt concentration of the calibration solution.

[0040] In one embodiment, said electronic data processor is further configured to query a database of reference products and, depending on the measured salt concentration, display a ranking or variable color indicator with the measured salt concentration (see Department of Health, Food Standards Agency (2016). Llywodraeth Cymru Welsh Government, Food Standards Scotland, Inbhe Bidh Alba. Guide to creating a front of pack nutrition label for pre-packed products sold through retail outlets, Food Standards Agency).

[0041] In one embodiment, said electronic data processor is further configured not to drive the water injector to introduce water into the container until it detects that the lid is closed.

[0042] In one embodiment, said electronic data processor is further configured not to drive the calibration solution injector to introduce water into the container until it detects that the lid is closed.

[0043] In one embodiment, said electronic data processor is further configured not to drive said motor means until it detects that the lid is closed. [0044] In one embodiment, said electronic data processor is further configured not to drive the motor means for grinding until it detects that the electrode is not coupled to the lid.

[0045] In one embodiment, said electronic data processor is further configured not to drive the motor means for stirring until it detects that the electrode is coupled to the lid.

[0046] In one embodiment, the predetermined volume of water is approximately 200 mL.

[0047] In one embodiment, the water is deionized water.

[0048] One embodiment comprises a temperature sensor in said container or lid for gauging said salt concentration measurement by the electrode.

[0049] These facts are described in order to illustrate the solution or solutions to said technical problems.

BRIEF DESCRIPTION OF THE DRAWINGS

[0050] For an easier understanding, figures are herein attached, which represent preferred embodiments which are not intended to limit the object of the present description.

[0051] Figure 1 - Block diagram of an embodiment of the portable device.

[0052] Figure 2 - Representative scheme of the main components of an embodiment of the portable device in two alternative versions.

[0053] Figure 3 - Exemplary scheme of an embodiment of the salt content measurement procedure with an embodiment of the portable device.

DETAILED DESCRIPTION

[0054] The disclosure comprises a portable device that enables automatic preparation of solid and liquid food samples and determination of the salt content thereof through the direct potentiometric method. [0055] According to Figure 1, one embodiment of the device comprises a processing and control unit (5) which interconnects with sensors: load cells (1) for determining sample weight, level sensor of the sample in the cup (2) for volume gauging, salt sensor (3) and temperature sensor (4). The device controls the grinding and stirring process of the sample through a motor (6), for the preparation of the sample a pump is used which allows adding water (7) and also a pump for adding a standard (8) for calibration. The user can control the device via a touch screen (10) and can also communicate with a central server via a Wi-Fi connection (9).

[0056] Figure 2 shows a representative scheme of the main components of a preferred embodiment of the portable device. The device consists of a cup (11) having within a grinding and stirring system (12) which grinds the sample as well as the mixture during the test. This system is driven by a motor (13) which is mounted on the structure below the cup. The cup seats on a load cell system (23) which measures the weight of the assembly. At the front part there is a CPU (14) which controls the entire system, added to it is the screen (15) which interfaces with the user. At the rear part of the structure are the deionized water (17) and standard liquid (18) tanks which in turn are connected to the deionized water (18) and standard liquid (19) pumps. These pumps feed the deionized water and standard liquid injectors (24) into the cup. The injectors are mounted on the cup lid (21) which supports the sensor (22) and also seals to the outside of the cup. The lid has a pivoting and hinged movement created by the lid rotation mechanism (20).

[0057] The control and processing unit also allows controlling the injection pumps, the grinding and stirring motor and the recording of scale and level sensor data. This unit also calculates the salt and sodium content of the sample through the data obtained: temperature and potential difference of the calibration standard and weight, dilution, temperature and potential difference of the sample.

[0058] Salt content measurement with the portable device is performed according to the exemplary scheme shown in Figure 3: after selecting the food category on the touch screen (10), the device automatically starts calibration with injection of the standard solution into the sample preparation unit, with the sodium ion-selective electrode (13) inserted; stirring of the solution begins; after 3 minutes the device records the electrode potential difference measured in the solution as well as its temperature; the electrode and the sample preparation unit are removed and washed with deionized water.

[0059] In order to perform an analysis, the food to be assessed is added to the cup in the sufficient amount that is indicated by a light signal on the screen (assessed by the load cells, about 20 grams) (1); the sample weight is recorded; the device adds 100 mL of deionized water and grinds the sample; the device then completes the dilution with deionized water (up to 200 mL volume, as assessed by the level sensor); the electrode is reintroduced into the solution and stirring thereof is started; after 3 minutes the device records the potential difference of the measurement electrode inserted in the solution as well as its temperature; the control and processing unit calculates the salt and sodium concentration, which are displayed on the screen, its exporting being possible (interface with a laptop, tablet, smartphone).

[0060] The system allows the determination of salt and sodium content in food expressed in g/lOOg (or mg/lOOg) respectively, the classification of the salt content according to the color traffic light based on the reference values and also indication of the percentage of food contribution to the total maximum recommended intake for adults and children according to developed software.

[0061] The system will be interconnected to a database for the synchronization of information on salt content of different foods, allowing a comparison to be drawn between the measurements with other previous measurements.

[0062] The system allows the aggregation of information from the results of measurements made in a database, ensuring the protection and anonymity of the information in order to enable macro analysis, for example of geographic and demographic nature.

[0063] The term "comprises" or "comprising" when used herein is intended to indicate the presence of the features, elements, integers, steps and components mentioned, but does not preclude the presence or addition of one or more other features, elements, integers, steps and components, or groups thereof. [0064] The embodiments described are combinable with each other. The present invention is of course in no way restricted to the embodiments described herein and a person of ordinary skill in the art can foresee many possibilities of modifying it and replacing technical features with equivalents depending on the requirements of each situation as defined in the appended claims. The following claims define additional embodiments of the present description.