METHOD AND DEVICE FOR THE RAPID QUANTIFICATION OF AFLATOXIN M1 (AFM1) IN MILK

Abstract

The present invention relates to a rapid method for the direct quantification of Aflatoxin M1 (AFM1) in a sample of milk. The invention also relates to a device and the use thereof in implementing said method.

Claims

1. A method for the quantification of Aflatoxin M1 (AFM1) in milk, comprising the steps of: a) providing a sample of milk; b) irradiating the sample of milk of step a) with a first electromagnetic radiation comprising at least one wavelength in the range from 340 to 400 nm; c) detecting a second electromagnetic radiation, emitted by the sample of milk of step b), in the range from 410 to 860 nm; d) selecting at least 9 wavelengths comprised in said range from 410 to 860 nm of the second electromagnetic radiation detected in step c); and e) quantifying the Aflatoxin M1 (AFM1) in said sample of milk, on the basis of the intensity of the radiation emitted at said at least 9 wavelengths selected in step d), wherein said at least 9 wavelengths are selected from the group consisting of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm; and wherein said at least 9 wavelengths are used to quantify Aflatoxin M1 (AFM1), by means of equation (I):
AFM1 (ppt)=0.0092×(F1)2+1.0694×(F1)+31.635   (I) wherein AFM1 (ppt) is the concentration of Aflatoxin M1 in said sample of milk in ng kg−1, and F1 is a parameter calculated by means of equation (II):
F1=2.533×Is410 nm+−0.132×Is435 nm+5.527×Is560 nm+1.911×Is585 nm+7.225×Is645 nm+−1.082×Is705 nm+−8.849×Is760 nm+−11.337×Is810 nm+1.874×Is860 nm  (II), and wherein Is410 nm, Is435 nm, Is560 nm, Is585 nm, Is645 nm, Is705 nm, Is760 nm, Is810 nm, Is860 nm are the standardized fluorescence intensity values, respectively at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm, wherein said standardized fluorescence intensity values are respectively obtained according to the following equations (III1-III9):
Is410 nm=(I410 nm−52.737)/2.468  (III1)
Is435 nm=(I435 nm−52.503)/2.141  (III2)
Is560 nm=(I560 nm−24.267)/0.928  (III3)
Is585 nm=(I585 nm−14.800)/0.563  (III4)
Is645 nm=(I645 nm−13.437)/0.523  (III5)
Is705 nm=(I705 nm−18.540)/0.759  (III6)
Is760 nm=(I760 nm−20.033)/2.972  (III7)
Is810 nm=(I810 nm−24.233)/4.183  (III8)
Is860 nm=(I860 nm−12.387)/1.574  (III9) wherein I410 nm, I435 nm, I560 nm, I585 nm, I645 nm, I705 nm, I760 nm, I810 nm, I860 nm are respectively the values of fluorescence intensity detected in phase c), respectively at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and

2. The method according to claim 1, wherein said sample of milk is a sample of raw milk.

3.-4. (canceled)

5. The method according to claim 1, wherein at least one step from a) to e) occurs at a temperature in the range from 4 to 37° C.

6. (canceled)

7. The method according to claim 1, wherein step a) comprises injecting the sample of milk into a container suitable for containing said sample of milk.

8. The method according to claim 1, wherein said step a) comprises a step a′) of: irradiating with a third electromagnetic radiation comprising at least one wavelength in the range from 200 to 280 nm.

9. The method according to claim 8, wherein in step a′) of irradiating, the third electromagnetic radiation comprises at least one wavelength of 254 nm.

10. The method according to claim 8, wherein step a′) of irradiating has a duration of at least 1 minute.

11. (canceled)

12. The method according to claim 1, wherein in step b) of irradiating, the first electromagnetic radiation comprises at least one wavelength in the range from 340 to 400 nm.

13. (canceled)

14. The method according to claim 1, wherein step b) of irradiating has a duration of at least 1 minute.

15. (canceled)

16. The method according to claim 1, wherein said step a) comprises a step a″) of: adding trifluoroacetic acid, or at least a source of bromine selected from the group consisting of alkali bromine salts, and PBPB (pyridinium bromide-perbromide), or iodine, or mixtures thereof.

17. The method according to claim 1, wherein the step c) of detecting has a duration of at least 5 seconds.

18.-19. (canceled)

20. A device (100) for analyzing at least one sample of milk, comprising: at least one main source (24) apt to irradiate the sample with a first electromagnetic radiation comprising at least one wavelength in the range from 340 to 400 nm, at least one spectral sensor (26) apt to detect a second electromagnetic radiation, emitted by the sample, in the range from 410 to 860 nm; a container (1) apt to containing the sample of milk, having one or more electromechanical actuators (22, 23) apt to opening or closing one or more ducts (11, 12) of a container (1); and an electronic control unit (30) apt to perform, by means of the device (100), manually and/or automatically, the method according to claim 1.

21. The device (100) according to claim 20, further comprising an auxiliary source (21) apt to irradiate the sample with a third electromagnetic radiation comprising at least one wavelength in the range from 200 to 280 nm.

22. The device (100) according to claim 20, wherein said container (1) comprises an auxiliary chamber (7) provided with at least one inlet duct (2) for introducing a sample of milk and at least a first window (5) apt to allow the irradiation of the sample in the auxiliary chamber (7) with an electromagnetic radiation emitted by a source (21) placed outside the container (1), wherein the auxiliary chamber (7) is connected via at least one internal duct (11) to a main chamber (8) provided with at least a second window (9) apt to allow the irradiation of the sample in the main chamber (8) with an electromagnetic radiation emitted by a source (24) placed outside the container (1), wherein the main chamber (8) is connected to an outlet duct (12) for discharging the sample of milk.

23. The device (100) according to claim 22, wherein the first window (5) and the second window (9) are derived in a first flat frame (3) and/or in a second flat frame (4), wherein the frames (3, 4) are joined together in a separable way.

24. The device (100) according to claim 22, wherein one or both frames (3, 4) comprise several windows (5, 6, 9, 10).

25. The device (100) according to claim 24, wherein the surface of a window (6, 10) of at least one frame (3, 4), which faces towards a window (5, 9) of the other frame (3, 4), is reflective.

26. (canceled)

27. The device (100) according to claim 20, wherein the internal duct (11) and/or the outlet duct (12) are equipped with at least one valve (13, 14).

28. (canceled)

29. The device (100) according to claim 20, wherein the auxiliary chamber (7), the internal duct (11), the main chamber (8) and the outlet duct (12) are aligned along a common axis (A).

30. The device (100) according to claim 20, wherein said container (1) is housed in a housing of the device in a removable way.

31. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] Further advantages and features of the method, container and device according to the present description will be apparent to those skilled in the art from the following detailed and non-limiting description of some of their embodiments with reference to the appended drawings wherein:

[0031] FIG. 1 shows a histogram showing the 9 fluorescence intensities of the sample of milk according to Example 1;

[0032] FIG. 2 shows a histogram showing the 9 fluorescence intensities of the sample of milk according to Example 2;

[0033] FIG. 3 shows a histogram showing the 9 fluorescence intensities of the sample of milk according to Example 3;

[0034] FIG. 4 shows a first axonometric view of the container;

[0035] FIG. 5 shows a vertical section of the container of FIG. 4;

[0036] FIG. 6 shows a second axonometric view of the container of FIG. 4;

[0037] FIG. 7 shows a first schematic axonometric view of the device;

[0038] FIG. 8 shows a second schematic axonometric view of the device of FIG. 7;

[0039] FIG. 9 shows a front view of the first electromagnetic radiation source holder and the device detector of FIG. 7; and

[0040] FIG. 10 shows a block diagram of the device in FIG. 7.

DETAILED DESCRIPTION OF THE INVENTION

[0041] The present invention relates to a method for the quantification of Aflatoxin M1 (AFM1) in milk, comprising the steps of a) providing a sample of milk; b) irradiating the sample of milk of step a) with a first electromagnetic radiation comprising at least one wavelength in the range from 340 to 400 nm; c) detecting a second electromagnetic radiation, emitted by the sample of milk of step b), in the range from 410 to 860 nm; d) selecting at least 9 wavelengths comprised in said range from 410 to 860 nm of the second electromagnetic radiation detected in step c); and e) quantifying the Aflatoxin M1 (AFM1) in said sample of milk, on the basis of the intensity of the radiation emitted at said at least 9 wavelengths selected in step d), wherein said at least 9 wavelengths are selected from the group consisting of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm; and wherein said at least 9 wavelengths are used to quantify Aflatoxin M1 (AFM1), by means of equation (1):

AFM1 (ppt)=0.0092×(F1).sup.2+1.0694×(F1)+31.635  (I)

[0042] wherein AFM1 (ppt) is the concentration of Aflatoxin M1 in said sample of milk in ng kg.sup.−1,

[0043] and F1 is a parameter calculated by means of equation (II):

F1=2.533×Is.sub.410nm+−0.132×Is.sub.435nm+5.527×Is.sub.560nm+1.911×Is.sub.585nm+7.225×Is.sub.645nm+−1.082×Is.sub.705nm+−8.849×Is.sub.760nm+−11.337×Is.sub.810nm+1.874×Is.sub.860nm   (II),

[0044] and

[0045] wherein Is.sub.410nm, Is.sub.435nm, Is.sub.560nm, Is.sub.585nm, Is.sub.645nm, Is.sub.705nm, Is.sub.760nm, Is.sub.810nm, Is.sub.860nm are the standardized fluorescence intensity values, respectively at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm, wherein said standardized fluorescence intensity values are respectively obtained according to the following equations (III1-III9):

Is.sub.410nm=(I.sub.410nm−52.737)/2.468  (III1)

Is.sub.435nm=(I.sub.435nm−52.503)/2.141  (III2)

Is.sub.560nm=(I.sub.560nm−24.267)/0.928  (III3)

Is.sub.585nm=(I.sub.585nm−14.800)/0.563  (III4)

Is.sub.645nm=(I.sub.645nm−13.437)/0.523  (III5)

Is.sub.705nm=(I.sub.705nm−18.540)/0.759  (III6)

Is.sub.760nm=(I.sub.760nm−20.033)/2.972  (III7)

Is.sub.810nm=(I.sub.810nm−24.233)/4.183  (III8)

Is.sub.860nm=(I.sub.1860nm−12.387)/1.574  (III9)

[0046] wherein I.sub.410nm, I.sub.435nm, I.sub.560nm, I.sub.585nm, I.sub.645nm, I.sub.705nm, I.sub.760nm, I.sub.810nm, I.sub.860nm are respectively the values of fluorescence intensity detected in phase c), respectively at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm.

[0047] Without being bound to any theory, and as will be apparent from the following and the examples, the inventors believe that by identifying at least 9 specific wavelengths comprised in a range from 410 to 860 nm of the method of the invention, emitted by a sample of milk after irradiation with an electromagnetic radiation comprised in the range from 340 to 400 nm, and on the basis of the intensity of the radiation emitted at said at least 9 specific wavelengths, there is an advantageous possibility of directly and quickly identifying Aflatoxin M1 (AFM1) in a sample of milk, allowing a better and easier identification and quantification of said sample of milk.

[0048] In view of this, the present invention provides a simple method, convenient in terms of the cost and time required to perform the analysis, which allows direct, rapid, accurate, and precise quantification of Aflatoxin M1 (AFM1) in a sample of milk.

[0049] In the present invention with the following terms: [0050] “photo-derivatization” it is meant a modification reaction of Aflatoxin M1 (AFM1) obtained by irradiation with an electromagnetic radiation comprising the wavelength of 254 nm, to give an Aflatoxin M1 named AFM2a of formula (i):

##STR00001##

[0051] Photo-derivatization allows to increase the intensity of the radiation emitted (fluorescence) by the sample after irradiation (excitation) with an electromagnetic radiation having at least one wavelength comprised in the range from 340 to 400 nm; [0052] “chemical derivatization” it is meant a modification reaction of the Aflatoxin M1 (AFM1) molecule with the addition of groups of atoms, obtained chemically/electrochemically, in order to increase the intensity of the emitted radiation (fluorescence) after irradiation (excitation) with an electromagnetic radiation having at least one wavelength comprised in the range of 340 to 400 nm. This process can be achieved either by hydration of the double bond of the bis-furan unit of Aflatoxin M1 (AFM1) through trifluoroacetic acid, or by saturation of the cis-furan double bond of Aflatoxin M1 (AFM1) with bromination, i.e. formation of new carbon-bromine bonds in the presence of bromine or PBPB (pyridinium bromide perbromide), or by iodination, i.e. formation of carbon-iodine bonds in the presence of iodine.

[0053] The method according to the present invention, through the identification at least 9 specific wavelengths comprised in a range from 410 to 860 nm, allows a direct and fast identification and quantification of Aflatoxin M1 (AFM1) in a sample of milk. Said at least 9 wavelengths are selected from the group consisting of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm, and in step e), said at least 9 wavelengths are used to quantify Aflatoxin M1 (AFM1), by means of equation (I):

AFM1 (ppt)=0.0092×(F1).sup.2+1.0694×(F1)+31.635  (I)

[0054] wherein AFM1 (ppt) is the concentration of Aflatoxin M1 in said sample of milk in ng kg.sup.−1,

[0055] and F1 is a parameter calculated by means of equation (II):

F1=2.533×Is.sub.410nm+−0.132×Is.sub.435nm+5.527×Is.sub.560nm+1.911×Is.sub.585nm+7.225×Is.sub.645nm+−1.082×Is.sub.705nm+−8.849×Is.sub.760nm+−11.337×Is.sub.810nm+1.874×Is.sub.860nm   (II),

[0056] and

[0057] in cui Is.sub.410nm, Is.sub.435nm, Is.sub.560nm, Is.sub.585nm, Is.sub.645nm, Is.sub.705nm, Is.sub.760nm, Is.sub.810nm, Is.sub.860nm are the standardized fluorescence intensity values at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm, respectively, wherein said standardised fluorescence intensity values are respectively obtained according to the following equations (III1-III9):

Is.sub.410nm=(I.sub.410nm−52.737)/2.468  (III1)

Is.sub.435nm=(I.sub.435nm−52.503)/2.141  (III2)

Is.sub.560nm=(I.sub.560nm−24.267)/0.928  (III3)

Is.sub.585nm=(I.sub.585nm−14.800)/0.563  (III4)

Is.sub.645nm=(I.sub.645nm−13.437)/0.523  (III5)

Is.sub.705nm=(I.sub.705nm−18.540)/0.759  (III6)

Is.sub.760nm=(I.sub.760nm−20.033)/2.972  (III7)

Is.sub.810nm=(I.sub.810nm−24.233)/4.183  (III8)

Is.sub.860nm=(I.sub.1860nm−12.387)/1.574  (III9)

[0058] wherein I.sub.410nm, I.sub.435nm, I.sub.560nm, I.sub.585nm, I.sub.645nm, I.sub.705nm, I.sub.760nm, I.sub.810nm, I.sub.860nm are respectively the values of fluorescence intensity detected in phase c), respectively at 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm.

[0059] Advantageously, in the method according to the present invention said sample of milk is a sample of raw milk.

[0060] Even more advantageously, said sample of raw milk is selected from the group consisting of pre-harvest raw milk, bulk milk, whey, and mixtures thereof.

[0061] Preferably, the raw milk is selected from the group consisting of raw bovine milk, sheep milk, goat milk, buffalo milk, and mixtures thereof.

[0062] In a preferred and advantageous aspect of the invention, at least one step from a) to e) of the method according to the present invention takes place at a temperature comprised in a range from 4 to 37° C. More preferably, all steps from a) to e) of the method according to the present invention take place at a temperature comprised in a range from 4 to 37° C.

[0063] In a particularly preferred embodiment of the method according to the invention, the steps from a) to e) take place at a temperature comprised in a range from 15 to 30° C., even more preferably from 22 to 27° C.

[0064] Preferably, step a) of the method according to the invention comprises injecting a sample of milk into a container apt to contain said sample of milk.

[0065] In a further preferred and advantageous aspect of the invention, step a) of the method of the invention comprises a step a′) of irradiating with a third electromagnetic radiation comprising at least one wavelength in the range from 200 to 280 nm.

[0066] Even more preferably, in step a′) of irradiating, the third electromagnetic radiation comprises at least a wavelength of 254 nm.

[0067] Still preferably, said step a′) of irradiating has a duration of at least 1 minute, more preferably it has a duration in the range from 1 to 2 minutes.

[0068] In this step a′) said third electromagnetic radiation, having at least a wavelength of 254 nm, allows to photo-derivatize Aflatoxin M1 (AFM1) in the sample so as to obtain Aflatoxin M1 named AFM2a of formula (i):

##STR00002##

[0069] Subsequently, in step b) of the method according to the invention, the sample of milk of step a) is irradiated with a first electromagnetic radiation comprising at least a wavelength in the range from 340 to 400 nm.

[0070] Preferably, said first radiation comprises at least a wavelength of 365 nm.

[0071] Advantageously, in step b) of the method according to the invention, the irradiation has a duration of at least 1 minute, more preferably it has a duration in the range from 1 to 2 minutes.

[0072] In a further preferred and advantageous aspect, step a) of the method of the invention comprises a step a″) of adding trifluoroacetic acid, at least a source of bromine selected from the group consisting of alkali bromine salts, and PBPB (pyridinium bromide-perbromide), or iodine, or mixtures thereof.

[0073] In this step a″) said addition allows for a chemical derivatization which enables to increase the intensity of the emitted radiation (fluorescence) when subjected to irradiation with the first electromagnetic radiation of step b) of the method according to the present invention.

[0074] Advantageously, after irradiation with a first electromagnetic radiation of step b) of the method of the invention, there is a step c) of detecting a second electromagnetic radiation, emitted by the sample of milk of step b), having a wavelength comprised in the range from 410 to 860 nm.

[0075] Preferably, said step c) of detecting said second electromagnetic radiation has a duration of at least 5 seconds, more preferably has a duration in the range from 5 to 10 seconds.

[0076] Advantageously, a detector is used to detect the radiation emitted in step c). Still advantageously said detector is a spectral sensor.

[0077] Referring to FIGS. 4 to 6, it can be seen that the container 1 according to the present description, is provided with at least one inlet duct 2 into which a sample of milk to be analysed can be injected by means of an external apparatus (not shown). The container 1 preferably comprises at least two flat frames 3, 4, in particular having a substantially rectangular shape, each of which is provided with at least one window. A window 5 of the first frame 3 is closed by a transparent slab, while a window 6 of the second frame 4 is closed by a reflective slab from the inside towards the first frame 3, in order to equalize the irradiation of the sample of milk with possible third electromagnetic radiations, and to avoid the dispersion thereof. The window 6 of the second frame 4 is arranged at a distance comprised between 1 and 10 mm in front of the window 5 of the first frame 3. The space between the windows 5, 6 and surrounded by the frames 3, 4 forms an auxiliary chamber 7, in particular having a volume of at least 0.5 mL, preferably 50 mL. The window 5 of the first frame 3 allows the exposure of the content of the auxiliary chamber 7 to an electromagnetic radiation, in particular said third electromagnetic radiation to modify the AFM1 aflatoxin molecule (derivatization), making it more fluorescent in blue wavelengths following subsequent irradiation with said first electromagnetic radiation.

[0078] The frames 3, 4 are joined together in a separable way, for example by means of screws, interlocking or at least one hinge arranged on an adjacent side thereof, so as to allow internal cleaning and reuse of the container 1. A thin layer of elastomeric material acting as a seal is applied on the internal side of at least one frame 3 and/or 4 to prevent liquid leakage during use.

[0079] At least one main chamber 8 is arranged between the frames 3, 4 below the auxiliary chamber 7. For example, the main chamber 8 has a substantially discoidal shape and is bordered by a transparent window 9 which is derived in the second frame 4.

[0080] The volume of the main chamber 8 is preferably smaller, in particular about 5 mL, than the volume of the auxiliary chamber 7, since the main chamber 8 serves to break down the just derivatized sample into sub-samples on which to perform fluorescence measurements, induced by irradiation with the first electromagnetic radiation, for greater statistical robustness of the data obtained.

[0081] The main chamber 8 is also bordered by a reflective window 10 which is derived in the first frame 3 and is apt to reflect towards the inside of the main chamber 8 the first electromagnetic radiation, so as to improve the uniformity of the irradiation and maximize the fluorescence of Aflatoxin AFM1 towards the detector.

[0082] At least one internal duct 11 connects the auxiliary chamber 7 to the main chamber 8. The base of the auxiliary chamber 7 is slightly inclined towards the internal duct 11 to facilitate the flow of the sample from the auxiliary chamber 7 to the internal duct 11.

[0083] At least one outlet duct 12 connects the main chamber 8 with the outside of the container 1.

[0084] The internal duct 11 and/or the outlet duct 12 are preferably straight and/or made of an elastomeric material, for example a soft silicone material, with a flattened cross-section.

[0085] The internal duct 11 and/or the outlet duct 12 are equipped with at least one valve, for example a piston 13, 14 which is movable in the frame 3 or 4, in particular in the first frame 3, to crush the external surface of the internal duct 11 and/or the outlet duct 12 and thus prevent the passage of at least a portion of the sample from the auxiliary chamber 7 to the main chamber 8 and/or from the main chamber 8 towards the outside of the container 1.

[0086] The auxiliary chamber 7, the internal duct 11, the main chamber 8 and the outlet duct 12 are preferably aligned along a common axis A, in particular an axis of symmetry of the container 1.

[0087] Referring also to FIGS. 7 and 8, it can be seen that the device 100 according to the present description comprises a casing 20 (shown with dashed lines) and a housing (not shown) apt to removably house at least one container 1 of the type described above, with its common axis A arranged in a substantially vertical manner.

[0088] The device 100 may further comprise at least one auxiliary source 21 of a third electromagnetic radiation which is arranged alongside the housing for the container 1 to irradiate the content of the auxiliary chamber 7 of the container 1, in particular through the window 5 of the first frame 3. The auxiliary source 21 is preferably provided with a diffuser to equalize the irradiation of the auxiliary chamber 7. The electromagnetic radiations emitted by the auxiliary source 21, after passing through the auxiliary chamber 7, are reflected by the window 6 inwardly.

[0089] The third electromagnetic radiations emitted by the auxiliary source 21 have at least one wavelength in the range from 200 to 280 nm, in particular 254 nm. The device 100 further comprises one or more electromechanical actuators 22, 23 which are arranged alongside the housing for the container 1 to open or close the internal duct 11 or the outlet duct 12. The actuators 22, 23 preferably comprise a servomotor apt to rotate a cam that can press a piston 13, 14 of the container 1.

[0090] The rotation of the actuator cam 22 or 23 presses the piston 13 or 14 against the duct 11 or 12, closing its internal lumen and interrupting the passage of the sample. A further rotation of the cam releases the piston 13 or 14 so that the duct 11 or 12 opens due to its elasticity.

[0091] Referring also to FIG. 9, it can be seen that the device further comprises at least one main source 24 of first electromagnetic radiations which is arranged alongside the housing for the container 1 to irradiate the content of the main chamber 8 of the container 1, in particular through the transparent window 9 of the second frame 4.

[0092] In particular, three main sources 24 are arranged like a triangle on a support 25, for example a printed circuit board, which is arranged alongside the housing for the container 1.

[0093] The first electromagnetic radiation emitted by the main sources 24 comprises at least one wavelength in the range of 340 to 400 nm, in particular 365 nm, so as to be able to excite the fluorescence at 435 nm wavelength of Aflatoxin M1 (AFM1), previously derivatized by the auxiliary source 21.

[0094] The first electromagnetic radiations emitted by the main sources 24, after passing through the main chamber 8, are reflected by the window 10 inwardly.

[0095] The device 100 also comprises at least one spectral sensor 26, in particular a spectral sensor with at least 9 detection wavelengths comprising three integrated circuits arranged like a triangle, such as for example the AMS AG model AS7265x spectral sensor with 18 channels.

[0096] The operations of filling the chambers 7, 8, of activating the sources 21, 24 and/or of detecting and controlling the spectral sensor 26 are preferably managed by an electronic control unit 30 provided with a program, in particular executable by a microcontroller, also of a known type, to perform said operations and/or to record on at least one memory 31 the data collected and/or to transfer said data to an external unit, for example a PC, for their subsequent processing and/or display. The control unit 30 is powered by a power source 32, such as a power supply and/or a battery, and may comprise output means 33 and/or input means 34, for example embedded in a touch screen. Thanks to the program of the control unit 30, the device 100 can carry out all the steps of the method described above, manually and/or automatically.

[0097] The spectral sensor 26 can simultaneously detect in the main chamber 8 the emission intensity (fluorescence) at 18 wavelengths from a sample of milk, and/or continuously in the range of 410 to 860 nm.

[0098] In use, the initially empty container 1 is placed in the housing of the device 100. The control unit 30, after verifying the correct insertion and positioning of the container 1 in the device 100, for example by means of mechanical sensors 35 arranged in the housing of the container 1, closes the internal duct 11 and the outlet duct 12 by operating the actuators 22, 23.

[0099] The auxiliary chamber 7 of the container 1 is then filled with a sample of milk through the inlet duct 2, whereupon the control unit 30 activates the auxiliary source 21 to irradiate this sample for a predetermined duration, for example 1-2 minutes, which may be adjustable via the input means 34 and the control unit 30.

[0100] After this time has elapsed, the auxiliary source 21 is turned off and the control unit 30 opens the internal duct 11 by means of the actuator 22, so as to fill, by gravity, the main chamber 8 of the container with a first portion of the sample present in the auxiliary chamber 7. During this step, the outlet duct 12 remains closed.

[0101] Once the main chamber 8 contains such first portion of the sample (sub-sample), the control unit 30 activates the main sources 24 with a predetermined intensity.

[0102] The fluorescence intensity of the sample of milk irradiated by the main sources 24 is detected by the spectral sensor 26 and recorded in the memory 31 of the control unit 30. Having performed such sub-sample analysis, the control unit 30 closes the internal duct 11 and opens the outlet duct 12 to discharge this sub-sample to the outside of the device 100.

[0103] The control unit 30 may perform such analysis of various portions of the sample for one or more times, for example 10 times, after which the container 1 may be removed from the device 100, opened and washed with water and detergent.

[0104] The invention will be further detailed with the following experimental part, which sets forth examples and tests of the method of the invention.

EXPERIMENTAL PART

Example 1

[0105] Determination of the Amount of Aflatoxin M1 (AFM1) in a Sample of Milk According to the Method of the Invention

[0106] A sample was prepared, starting from 50 mL of milk, collected from dairy cattle farms in Veneto, free of Aflatoxin M1 (AFM1), adding to said 50 mL of milk, an amount of 22.5 μL of an aqueous solution having a concentration of 200000 ppt of AFM1, obtaining a sample with a known concentration of Aflatoxin M1 (AFM1) equal to 90 ppt of AFM1.

[0107] The aforesaid sample of milk was subjected to photo-derivatization for 2 minutes with an electromagnetic radiation, generated by a mercury vapour lamp, having a wavelength comprised between 200 and 280 nm and a peak at 254 nm.

[0108] The sample of milk was then irradiated for 2 minutes at a temperature of 25° C. with an electromagnetic radiation, generated by a Wood's light lamp, having a wavelength in the range from 340 to 400 nm and a peak at 365 nm.

[0109] By using the device according to the present description, while keeping the excitation source (Wood's light) active, fluorescence intensity values were acquired at the wavelengths of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm.

[0110] FIG. 1 shows the histogram with the 9 fluorescence intensities of the sample of milk tested.

[0111] Table 1 reports the acquired fluorescence intensity and standardized fluorescence intensity values calculated according to equations (III1-III9).

TABLE-US-00001 TABLE 1 Standardized Wavelength Fluorescence intensity fluorescence (nm) (AMS arbitrary units) intensity 410 56.1 1.363 435 60.2 3.595 560 25.7 1.544 585 15.6 1.420 645 14.16 1.383 705 19.62 1.424 760 16.4 −1.223 810 19.5 −1.132 860 11.1 −0.818

[0112] Said standardized fluorescence intensity values were then used to calculate the F1 parameter according to equation (II):

F1=(2.533×1.363)+(−0.132×3.595)+(5.527×1.544)+(1.911×1.420)+

(7.225×1.383)+(−1.082×1.424)+(−8.849×−1.223)+(−11.337×−1.132)+(1.874×−0.818)=44.797.

[0113] Subsequently, the concentration of Aflatoxin M1 (AFM1) in the sample of milk was calculated using equation (I).

AFM1 (ppt)=0.0092×(44.797).sup.2+1.0694×(44.797)+31.635=98.003 ppt.

[0114] It is evident that the method according to the invention is able to quantify the concentration of Aflatoxin M1 (AFM1) in a sample of milk by obtaining a value extremely close to the actual value of 90 ppt.

Example 2

[0115] Determination of the Amount of Aflatoxin M1 (AFM1) in a Sample of Milk According to the Method of the Invention with Comparison with Known HPLC Method (Mortimer et al., 1987)

[0116] A 50 mL sample of milk collected from dairy cattle farms in Veneto was provided. Said sample of milk was subjected to analysis according to the known method (Mortimer et al., 1987) coupled with HPLC and a concentration of 52 ppt of Aflatoxin M1 (AFM1) was measured.

[0117] The aforesaid sample of milk was subjected to photo-derivatization for 2 minutes with an electromagnetic radiation generated by a mercury vapour lamp, having a wavelength comprised between 200 and 280 nm and a peak at 254 nm.

[0118] Said sample of milk was then irradiated for 2 minutes at a temperature of 25° C. with an electromagnetic radiation, generated by a Wood's light lamp, having a wavelength in the range from 340 to 400 nm and a peak at 365 nm.

[0119] By using the device according to the present description, while keeping the excitation source (Wood's light) active, fluorescence intensity values were acquired at the wavelengths of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm.

[0120] FIG. 2 shows the histogram with the 9 fluorescence intensities of the sample of milk tested.

[0121] Table 2 reports the acquired fluorescence intensity and standardized fluorescence intensity values calculated according to equations (III1-III9).

TABLE-US-00002 TABLE 2 Standardized Wavelength Fluorescence intensity fluorescence (nm) (AMS arbitrary units) intensity 410 55.35 1.059 435 58.22 2.670 560 23.37 −0.966 585 15.17 0.657 645 14.76 2.531 705 19.27 0.962 760 19.68 −0.119 810 24.6 0.088 860 15.17 1.768

[0122] Said standardized fluorescence intensity values were then used to calculate the F1 parameter according to equation (II):

F1=(2.533×1.059)+(−0.132×2.670)+(5.527×−0.966)+(1.911×0.657)+(7.225×2.531)+(−1.082×0.962)+(−8.849×−0.119)+(−11.337×−0.088)+(1.874×1.768)=18.862.

[0123] Subsequently, the concentration of AFM1 in the sample of milk was calculated using equation (I).

AFM1 (ppt)=0.0092×(18.862).sup.2+1.0694×(18.862)+31.635=55.079 ppt.

[0124] The concentration values of Aflatoxin M1 (AFM1), obtained by means of the method of the invention, were compared to those obtained by means of the known method (Mortimer et al., 1987) coupled with HPLC.

[0125] It is evident that the method according to the invention is able to quantify the concentration of Aflatoxin M1 (AFM1) in a sample of milk obtaining a value extremely close to the value obtained according to the known method (Mortimer et al., 1987) coupled with HPLC.

Example 3

[0126] Determination of the Amount of Aflatoxin M1 (AFM1) in a Sample of Milk According to the Method of the Invention with Comparison with Known HPLC Method (Mortimer et al., 1987)

[0127] A 50 mL sample of milk collected from dairy cattle farms in Veneto was provided. Said sample of milk was subjected to analysis according to the known method (Mortimer et al., 1987) coupled with HPLC and a concentration of 8 ppt of Aflatoxin M1 (AFM1) was measured.

[0128] The aforesaid sample of milk was subjected to photo-derivatization for 2 minutes with an electromagnetic radiation generated by a mercury vapour lamp, having a wavelength comprised between 200 and 280 nm and a peak at 254 nm.

[0129] The sample of milk was then irradiated for 2 minutes at a temperature of 25° C. with an electromagnetic radiation, generated by a Wood's light lamp, having a wavelength in the range from 340 to 400 nm and a peak at 365 nm.

[0130] By using the device according to the present description, while keeping the excitation source (Wood's light) active, fluorescence intensity values were acquired at the wavelengths of 410 nm, 435 nm, 560 nm, 585 nm, 645 nm, 705 nm, 760 nm, 810 nm, and 860 nm.

[0131] FIG. 3 shows the histogram with the 9 fluorescence intensities of the sample of milk tested.

[0132] Table 3 reports the acquired fluorescence intensity and standardized fluorescence intensity values calculated according to equations (III1-III9).

TABLE-US-00003 TABLE 3 Standardized Wavelength Fluorescence intensity fluorescence (nm) (AMS arbitrary units) intensity 410 55.35 1.059 435 58.22 2.67 560 23.37 −0.966 585 15.17 0.657 645 14.76 2.531 705 19.27 0.962 760 27.88 2.641 810 32.8 2.048 860 15.17 1.768

[0133] Subsequently, the parameter F1 was calculated using equation (II):

F1=(2.533×1.059)+(−0.132×2.67)+(5.527×−0.966)+(1.911×0.657)+(7.225×2.531)+(−1.082×0.962)+(−8.849×2.641)+(−11.337×2.048)+(1.874×1.768)=−27.782.

[0134] Subsequently, the concentration of AFM1 in the sample of milk was calculated using equation (I).

AFM1 (ppt)=0.0092×(−27.782).sup.2+1.0694×(−27.782)+31.635=9.026 ppt.

[0135] The concentration values of Aflatoxin M1 (AFM1), obtained by means of the method of the invention, were compared to those obtained by means of the known method (Mortimer et al., 1987) coupled with HPLC.

[0136] It is evident that the method according to the invention is able to quantify the concentration of Aflatoxin M1 (AFM1) in a sample of milk obtaining a value extremely close to the value obtained according to the known method (Mortimer et al., 1987) coupled with HPLC.

[0137] Any variants or additions may be made by the persons skilled in the art to the embodiments described and illustrated herein while remaining within the scope of the following claims. In particular, further embodiments may comprise the technical characteristics of any of the following claims with the addition of one or more technical characteristics described in the text or illustrated in the drawings, taken singularly or in any combination thereof.