FIELD OF THE INVENTION

[0001] The present invention is directed to the marking of commercial bulk products, so as to allow for the verification of the genuine nature and the absence of dilution of said products. Methods are disclosed for in-product marking, preferably invisible, as well as corresponding authentication procedures that permit determinations in the field as well as off-the-field for even more precise laboratory verification of adulteration levels of marked products.

BACKGROUND OF THE INVENTION

[0002] In a global economy, which facilitates the trans -boundary movement of commercial goods, there is an increasing need, from the side of tax authorities and brand owners, for methods allowing to control the genuine nature of merchandise.

[0003] In the particular case of bulk products, such as distilled alcoholic beverages, perfumes, medical preparations, fuel and the like, most counterfeiting is actually performed by replacement or adulteration of the original contents, while recycling original packaging. Bulk products or bulk materials, in general, are divided solid or liquid materials which are handled by volume or by weight.

[0004] Material-based security solutions (overt and covert), incorporated into inks and applied through various printing processes, efficiently allow to distinguish genuine packaging from counterfeit one. However, a genuine packaging alone is no warranty by itself for that the product content is genuine too.

[0005] Product adulteration, i.e. the 'dilution' of a genuine product with a low-grade counterfeits is hereby of particular concern. For example, a distilled alcoholic beverage, for which the taxes have been paid, might be subsequently diluted to a certain extent with an alcoholic 'back-yard' -product, manufactured out of tax. Such adulteration causes important losses to the state and can also have consequences to public health, in case where the 'back-yard' alcohol of poor quality contains larger amounts of methanol and/or other toxic contaminants.

[0006] In the medical field, the dilution of drugs is particularly troublesome because dilution can lead to ineffectiveness of the drug. Moreover, dilution can lead to the lack of use of a therapeutic dose leading to the lack of preventive and/or therapeutic activity of the diluted material. For example, it will be extremely useful to authenticate and/or quantify drugs not only for humans for also for other animals, such as, chickens, pigs and calves.

[0007] The in-product marking and the authentication of bulk products is the object of numerous disclosures of the prior art: U.S. Pat. No. 5,156,653 discloses the marking of petroleum products with latent dyes (added at the level of parts per million), which can be subsequently revealed through a coloring reaction. U.S. Pat. No. 5,980,593 discloses the use of latent fluorescent markers, U.S. Pat. No. 5,498,808 the use of fluorescein esters, all for the same purpose. The use of NIR absorbing or emitting colorless dyes as markers has furthermore been disclosed in U.S. Pat. No. 5,525,516, U.S. Pat. No. 5,998,21 1, U.S. Pat. No. 5,804,447, U.S. Pat. No. 5,723,338 and U.S. Pat. No. 5,843,783. The disclosures of these patents are incorporated by reference herein in their entireties.

[0008] Moreover, methods and colorants suited for incorporation into products for human application, such as alcoholic beverages, perfumes and medical preparations, are known as see, for example, U.S. Patent Nos. 8,071 ,386 and 8,268,623. The disclosures of these patents are incorporated by reference herein in their entireties

[0009] U.S. Pat. No. 5,942,444 and U.S. Pat. No. 5,776,713, which are incorporated by reference herein in their entireties, disclose biologic marking agents, to be detected with a specific, monoclonal antibody. The technology suffers, however, from certain limitations, too: a) The preparation of monoclonal antibodies to specific marker molecules is costly and time-consuming, inhibiting a fast 'change of code' to a new marker and detection system; b) the amount of marker which must be present (e.g. 20 ppm in "Eau de

Cologne" or in Whiskey) can be observed with the help of modern analytical tools such as GC-MS and HPLC, and this the easier as both methods recommend that no similar chemicals should be present in the product aside the marker, i.e. that there may be no "forest to hide the tree"; c) the proposed detection system is only of qualitative nature, able to detect the presence of a counterfeit or adulteration, without, however, the capability of quantifying the degree of adulteration.

[0010] US 2002/0048822 Al , which are incorporated by reference herein which are incorporated by reference herein, discloses the marking of a product with a marker molecule which can be electrochemically reduced or oxidized. Presence and amount of the marker is electrochemically determined with the help of amperometric or coulometric electrodes. The proposed preferred authentication method is liquid chromatography (HPLC) separation coupled to an electrochemical detector, which is however not suitable as a field-portable auditing instrument. The method recommends as well that the product should be free of other electroactive compounds, i.e. that there may be no "forest to hide the tree".

[0011] U.S. Pat. No. 5,981,283 and U.S. Pat. No. 5,474,937 which are incorporated by reference herein in their entireties, disclose the marking of liquids by non-radioactive isotopic compounds. The marker is of similar nature as the product to be marked and can thus be perfectly hidden. Only sub-ppm amounts of markers are furthermore required, i.e. typically parts per billion (ppb). The authentication is performed by modem analytical tools, comprising a gas-chromatography (GC) or electro-spray mass-spectroscopy (MS) separation step, followed by a classical fragmentation-mass-spectroscopy (MS) analysis step. However, even this approach suffers from limitations: a) The deliberate addition of isotopically marked compounds into food or beverage products is increasingly less tolerated by regulatory authorities; b) the cost of isotopic marking compounds is rather high, although the choice of such compounds is almost limitless; c) the authentication, by GC-MS or MS-MS, of ppb amounts of markers is time-consuming and requires expensive laboratory equipment and highly skilled operating personnel, which makes it unsuitable for rapid field audits.

[0012] Despite the fact that solutions already exist, it remains that there is a need for techniques compatible with almost real-time analysis in a critical environment (e.g., farm for mass production of chickens using veterinary products). Moreover, there is need to be able to generate a quick and reliable response with the aid of basic or simple devices. Thus, there is a need to for markings which provide even further advantageous results over the prior art.

SUMMARY OF THE INVENTION

[0013] The marking method and marking for identifying the authenticity and/or the genuine nature of the present invention applies to bulk materials, that means liquids or divided solids which are handled on a per volume or on a per weight base. The method is particularly suited for bulk materials which are destined to human, animal and/or poultry application, such as food and drink, pharmaceutical preparations or cosmetic products.

[0014] There is provided a method for marking a material, comprising including a blend of components having different fluorescent characteristics in the material, the blend of components not being already associated with the material and at least one of the components of the blend of components having a fluorescence that varies in spectral position and/or intensity according to variation of pH, the blend of components being included in the material in an amount effective to be qualitatively and/or quantitatively determined.

[0015] There is also provided a method for determining whether a material is genuine by determining presence of a blend of components which vary in spectral position and/or intensity according to variation of pH, the blend of components having been added to the material as a marker, the components in the blend of components not being already associated with the material prior to being added as a marker, comprising:

a) preparing an aliquot of a solvent containing a sample of the material at a first pH;

b) measuring spectral position of the fluorescence of the aliquot of a) at one or more excitation wavelengths;

c) adjusting the pH of the aliquot of b) to a second pH wherein at least one component of the blend of components has at least one of a different spectral position and/or intensity at the second pH than the first pH;

d) measuring spectral position of the fluorescence of the aliquot formed in c) at one or more excitation wavelengths; and

e) comparing spectral position of the fluorescence between the fluorescence measured in b) and the fluorescence measured in d) with known spectral positions of at least two components of the blend of components at the pH's used in a) and c) to thereby determine whether the at least two components of the blend of components is present in determining whether the material is genuine.

[0016] The method can further comprise:

f) dissolving in the aliquot of a) or c) different known concentrations, preferably at least three known concentrations, of a fluorescence quenching agent, preferably one or more halogen salts, the fluorescence quenching agent causing a progressive decrease in fluorescent intensity with increasing concentration of the fluorescence quenching agent of at least one component of the blend of components; g) measuring for each known concentration of the fluorescence quenching again a corresponding fluorescence intensity;

h) determining a curve of variation of fluorescence intensity with concentration of the fluorescence quenching agent; and

i) comparing the curve of h) with a known (calibration) curve of concentration of the fluorescence quenching agent versus fluorescence of at least two of the components of the blend of components. [0017] There is also provided a method for authenticating if a material has been subject to diversion or adulteration by determining the concentration of a two or more components of a blend of components that has been added to the material as a marker, the components in the blend of components not being already associated with the material prior to being added as a marker, at least one of the two or more components of a blend of components having a fluorescence which varies in intensity according to variation of pH, comprising:

a) measuring fluorescence intensity of an aliquot of a solvent in the absence of the components at an excitation wavelength as a noise base measure ( BM).

b) preparing an aliquot of the solvent containing a sample including a known amount of the material at a first pH;

c) measuring fluorescence intensity of the aliquot of b) one or more excitation wavelengths;

d) adjusting the pH of the aliquot of b) to a second pH wherein at least one component of the blend of components has a different intensity than at the first pH; e) measuring fluorescence intensity of the aliquot formed in d) at one or more excitation wavelengths;

f) comparing a difference in fluorescence intensity between the fluorescence

measured in c) and the fluorescence measured in e) for at least two components of the blend of components with a known difference in fluorescence intensity of the components at the pH's used in a) and c) to thereby determine the presence or concentration of at least two components of the blend of components to permit a determination of diversion or adulteration of the material.

[0018] The method can further comprise:

g) dissolving in the aliquot of b) or d) different known concentrations, preferably at least three known concentrations, of a fluorescence quenching agent, preferably one or more halogen salts, the fluorescence quenching agent causing a progressive decrease in fluorescent intensity with increasing concentration of the fluorescence quenching agent of at least one component of the blend of components; h) measuring for each known concentration of the fluorescence quenching agent a corresponding fluorescence intensity;

i) determining a curve of variation of fluorescence intensity with concentration of the fluorescence quenching agent; and

j) comparing the curve of i) with a known (calibration) curve of concentration of the fluorescence quenching agent versus fluorescence to thereby confirm identity and/or concentration.

[0019] The at least two different components can each comprise an alkaloid so that at least two different alkaloids can be present in the material.

[0020] The at least two different alkaloids can include at least one alkaloid having a pyridine moiety which is protonated, in a non-protonated state or in a form of a salt and at least one second alkaloid have a beta-carboline moiety which is protonated, in a non- protonated state or in a form of a salt.

[0021] The at least two alkaloids can be present in a concentration at a subppm level to a ppm level, based on the total composition including the material and the at least two different alkaloids.

[0022] The at least two different alkaloids can be present in a total concentration of the at least two different alkaloids of 0.1 ppm to 100 ppm, based on the total weight of the composition.

[0023] The variation of pH can be a pH variation of 2 to 6, or a pH variation of 2 to 4.5.

[0024] One of the two different alkaloids can comprise at least one of quinine and a quinine salt, and another of the at least two different alkaloids can comprise at least one of a harmala compound and a salt of a harmala compound and/or lucigenin.

[0025] The at least two different alkaloids can be selected from quinine, and salts of quinine (e.g., quinine sulfate, quinine hydrochloride), lucigenin, harmine, harmane, harmaline, harmalol, tetrahydroharmine or tetrahydroharmane, harmalan, harmilinic acid, harmanamide, acetylnorharmine or acetylnorharmane. [0026] Each of the at least two different alkaloids can have a fluorescence that varies in spectral position and/or intensity according to variation of pH. Also, only one of the at least two different alkaloids can have a fluorescence that varies in spectral position and/or intensity according to variation of pH.

[0027] At least one of the at least two different alkaloids can have a fluorescence that is quenched in the presence of a salt.

[0028] Moreover, the at least two different alkaloids can have a fluorescence that is quenched in the presence of a salt.

[0029] The degree of quenching can be different for at least two of the at least two different alkaloids.

[0030] The first pH can be a pH of from 5 to 8, and the second pH can be a pH of 3.5 or below.

[0031] The excitation wavelength can be from 300 nm to 410 nm, or 340nm to 365nm.

[0032] The blend of components can comprise a blend of alkaloids. The blend of alkaloids can include at least one alkaloid having a pyridine moiety which is protonated, in a non-protonated state or in a form of a salt and at least one alkaloid having a beta- carboline moiety which is protonated, in a non-protonated state or in a form of a salt.

[0033] One of the alkaloids of the blend can comprise at least one of quinine and a quinine salt, and another of the alkaloids can comprise at least one of a harmala compound and a salt of a harmala compound and/or lucigenin.

[0034] The blend of alkaloids can be selected from quinine , and salts of quinine (e.g., quinine sulfate , quinine hydrochloride), lucigenin, harmine, harmane, harmaline, harmalol, tetrahydroharmine or tetrahydroharmane, harmalan, harmilinic acid, harmanamide, acetylnorharmine or acetylnorharmane.

[0035] Only one of the alkaloids can be chosen to change spectral position and/or intensity, or at least two of the alkaloids can change spectral position and/or intensity. [0036] More than one halogen salt can be added to the sample, and effects of the more than one halogen salt with respect to at least two components of the blend of components can be determined.

[0037] The material can be combined with the solvent to obtain an aliquot of about 0.0001 to 3weight %, based upon the weight of the total weight of the aliquot.

[0038] The material can be a liquid, a solid, a gel, a colloid or a semi-liquid.

[0039] The alkaloid can be inert and non-deleterious to the material.

[0040] The material can be combined with the solvent to extract at least a portion of the alkaloid from the material.

[0041] The pH can be adjusted by adding an acid that does not cause a decay in fluorescence.

[0042] The solvent can be water.

[0043] The halogen salt can be selected from halogen chloride or halogen bromine, and can be added at a concentration between 10 - ^" 3 to 10 - ^" 1 M.

[0044] There is also provided a marked material which comprises an alkaloid blend which is present in a concentration of 0.00001 to 0.3% by weight, based on the total weight of the composition, preferably 0.0003 to 0.01% by weight, more preferably 0.0001 to 0.001% by weight.

[0045] The material can be selected from alcohol, medicinal and/or veterinary preparation, perfume, liquid, cosmetic liquid formulation, and fuel. The material can be a liquid, a solid or a gel, a colloid or a semi-liquid and contain water and/or organic solvent.

[0046] There is also provided a material including a chemical key, the chemical key comprising a blend of at least two different alkaloids having different fluorescent characteristics, the at least two different alkaloids not being already associated with the material and one or more of the alkaloids, preferably two or more, having a fluorescence that varies in spectral position and/or intensity according to variation of pH or fluorescence quenching agent (e.g., halogen salts), the blend of alkaloids being included in the material in an amount effective to be qualitatively and/or quantitatively

determined.

[0047] There is also provided use of an alkaloid in a material composition, such as a liquid, for determining whether or not a material, such as a liquid material, has been subject to diversion or adulteration wherein the concentration of the alkaloid blend is between 0.00001 to 0.3% by weight, based on the total weight of the composition, preferably 0.0003 to 0.01% , more preferably 0.0001 to 0.001% by weight.

BRIEF DESCRIPTION OF THE DRAWINGS

[0048] The present invention is further described in the detailed description which follows, in reference to the noted plurality of drawings by way of non-limiting examples of exemplary embodiments of the present invention, in which like reference numerals represent similar parts throughout the several views of the drawings, and wherein:

Fig. 1 is a graph of fluorescence quenching by bromine ions with respect to Harmane, Harmaline, Harmane and Harmalol;

Fig. 2 is a graph of Harmine emission spectrum with 364 nm.

Fig. 3 is a graph of Harmine and Lucigenine quenching with bromine ions;

Fig. 4 is a graph of Harmine and Lucigenine quenching with chloride ions; and

Fig. 5 is a graph of emission and excitation spectrum of Harmine and Lucigenine.

DETAILED DESCRIPTION

[0049] The particulars shown herein are by way of example and for purposes of illustrative discussion of the embodiments of the present invention only and are presented in the cause of providing what is believed to be the most useful and readily understood description of the principles and conceptual aspects of the present invention. In this regard, no attempt is made to show structural details of the present invention in more detail than is necessary for the fundamental understanding of the present invention, the description is taken with the drawings making apparent to those skilled in the art how the forms of the present invention, including embodiments of flakes and films, may be embodied in practice.

[0050] Unless otherwise stated, a reference to a compound or component includes the compound or component by itself, as well as in combination with other compounds or components, such as mixtures of compounds.

[0051] As used herein, the singular forms "a," "an," and "the" include the plural reference unless the context clearly dictates otherwise. For example, reference to "a component" or "a fluorescence quenching agent would also mean that mixtures of one or more components or one or more fluorescence quenching agents can be present unless specifically excluded.

[0052] Except where otherwise indicated, all numbers expressing quantities of ingredients, reaction conditions, and so forth used in the specification and claims are to be understood as being modified in all instances by the term "about." Accordingly, unless indicated to the contrary, the numerical parameters set forth in the specification and claims are approximations that may vary depending upon the desired properties sought to be obtained by the present invention. At the very least, and not to be considered as an attempt to limit the application of the doctrine of equivalents to the scope of the claims, each numerical parameter should be construed in light of the number of significant digits and ordinary rounding conventions.

[0053] Additionally, the recitation of numerical ranges within this specification is considered to be a disclosure of all numerical values and ranges within that range. For example, if a range is from about 1 to about 50, it is deemed to include, for example, 1, 7, 34, 46.1 , 23.7, or any other value or range within the range. [0054] The various embodiments disclosed herein can be used separately and in various combinations unless specifically stated to the contrary.

[0055] The markings herein can be soluble in and can chemically withstand a largely aqueous environment, such as provided by products for human and/or animal and/or poultry application. The present invention also provides for stable preparations even when packaged in transparent recipients, such as glass bottles, etc, in which such products are often commercialized. Moreover, the present invention is sufficiently nontoxic, especially when used in low concentrations that are detectable, so that the addition of markers to a food, drug or perfumery products can be compliant with public health and the prescriptions of regulatory bodies such as the FDA and/or the ATF bureau.

[0056] The present invention provides for in-product marking methods and techniques for various products, without limitation, such as branded or taxed bulk goods which are suited for human and/or animal and/or poultry application.

[0057] In particular, there is provided herein a marking method and markings for identifying the authenticity and the genuine nature of various products, such as alcoholic beverages, perfumes, and medical preparations, such as pharmaceuticals, wherein the markings can be easily incorporated (by mixing or by dissolution) into bulk products, are robust against aqueous environment and light, do not alter the properties (e.g.,. taste and smell) of the marked products, do not have any negative impact on the health of the consumer, and allow for a qualitative and/or quantitative determination of the level of adulteration.

[0058] It is a further object of the present invention to provide a method of identifying and assessing a correspondingly marked product, which is particularly suited for the screening in the field, and which can be backed by even more precise laboratory analyses.

[0059] The method includes the incorporation into a material of at least two

components having different fluorescent characteristics. The components can be included as a predetermined blend into the material to thereby provide a desired combination of the at least two components. Thus, different components and/or the concentration of components can be varied to provide a desired marking of the material. For example, one or more of the components can have a fluorescence intensity and/or spectral position that varies with changing pH. Moreover, one or more of the components can have a fluorescence that varies by interaction with a fluorescence quenching agent that can be used when performing an analysis. Thus, for example, one of the components can have a fluorescence that varies with a change a pH while another component can have a fluorescence that does not vary with pH or varies with pH.

Moreover, one of the two components, which can be the same or a different component than the component that changes fluorescence with pH, can have a fluorescence that changes in the presence of a fluorescence quenching agent.

[0060] Preferably, the components are non-toxic to mammals, including dogs, cats, sheep, calves, pigs, cows, humans , or poultry, such as, chickens. The non-toxic nature can be achieved by the component being non-toxic in any amount. Also, the non-toxic nature can be achieved by the component being present and being detectable at low concentrations. Therefore, the components can be included in the material at a concentration that is considered to be non-toxic, even if at a higher concentration of one or more of the components may be toxic.

[0061] Through the choosing of blends of components, chemical keys can be devised that permit identification of materials to which the blends have been added. Thus, for example, a blend of components can be added to the material having known fluorescence characteristics of the components therein at one pH as well as at a second pH and/or in the presence of a pH quenching agent. By having a corresponding unique blend of components, a unique chemical key is provided. The addition of the unique blend of components leads to a specific blend having specific fluorescence characteristics for the components, such as alkaloids, contained therein. The known fluorescence

characteristics of the components and how these fluorescence characteristics vary are associated with a specific profile to thereby obtain a chemical key. The determination of the specific profile (including how the fluorescence of one or more of the components varies under one or more conditions, such as pH variation or the presence of one or more quenching agents can be used to attest that a product is genuine, because the product contains a specific blend of components, such as a specific blend of alkaloids, as the chemical key.

[0062] The chemical key can be included in a database so that the detected key can be compared to keys included in the database to match with the known key in the database. The chemical key could also be known by any party or individual with a need to track or monitor and/or to check for authenticity of a product. For example, a producer and/or a retailer can provide or be provided with the key.

[0063] Accordingly, a material can be marked by including at least two components having different fluorescent characteristics as a blend of components in the material. The components are not already associated with the material. One or more of the components has a fluorescence that varies in spectral position and/or intensity according to variation of pH. The components are included in the material so that their fluorescence can be qualitatively and/or quantitatively determined. Preferably, the components are non-toxic or are included in the material at a non-toxic concentration .

[0064] Preferably, each of the components comprises an alkaloid so that at least two different alkaloids are present in the material.

[0065] One of the at least two alkaloids can include an alkaloid having a pyridine moiety which is protonated, in a non-protonated state or in a form of a salt. Such an alkaloid can include quinine or salts thereof, such as quinine hydrochloride and quinine sulfate. The structure of quinine is illustrated, as follows:

[0066] Quinine has fluorescence properties that vary with pH. Moreover, the fluorescence of quinine can be quenched by and is dependent upon the concentration of halogens, such as chloride ion and bromide ion. In this regard, quenching by using a fluorescence quenching agent refers to any process which decreases or modifies the fluorescence intensity and/or position of a component, e.g., quinine, of which

fluorescence intensity is being determined. The fluorescence quenching agent causes quenching not directly by a change in pH, but can have different quenching effects at different pH. For example, the fluorescence quenching agent can have varying quenching effects at different pH. The quenching can be a quenching that provides a decrease in fluorescence of the component and can also include quenching to such a degree wherein the component no longer has a detectable fluorescence or a modification of the position of the fluorescence peak (or integrated fluorescence intensity) of the compounds used in the blend of alkaloids. .

[0067] Such an alkaloid can also include lucigenin (10-Methyl-9-(10-methylacridin-10- ium-9-yl)acridin-10-ium dinitrate), as shown in the structure below:

[0068] Lucigenin has fluorescence properties that vary with basic pH (e.g., greater than 7 to about 10). Moreover, the fluorescence of lucigenin can be quenched by and is dependent upon the concentration of halogens, such as chlorine and bromine.

[0069] One of the at least two alkaloids can include harmala alkaloids having a beta- carboline moiety which is protonated, in a non-protonated state or a salt thereof. Such alkaloids can include, for example, β-carboline (9H-pyrido[3,4-&]indole, harmine, harmane, harmaline, harmalol, tetrahydroharmine or tetrahydroharmane, harmalan, harmilinic acid, harmanamide and acetylnorharmine or acetylnorharmane or lucigenin has fluorescence properties that vary with pH, but less than quinine and changes at strong basic pH, such as at basic pH, preferably 8 to 12. Moreover, the fluorescence of harmane can be quenched by and is dependent upon the concentration of bromine ion and iodine ion, but not of chlorine ion. Thus, for example, one of the alkaloids can comprise at least one of quinine and a quinine salt, and another of the alkaloids can comprise at least one of a harmala compound and a salt of a harmala compound and/or lucigenin. The at least two different alkaloids can be selected from quinine and salts of quinine (e.g., quinine sulfate, quinine hydrochloride), lucigenin, harmine, harmane, harmaline, harmalol, tetrahydroharmine, tetrahydroharmane, harmalan, harmilinic acid,

harmanamide and acetylnorharmine or acetylnorharmane.

[0070] The authentication procedure can include a blend of the components, such as a blend of two or more of quinine, harmine, harmane and lucignen in order to obtain a complex spectrum where the fluorescence of one component or more than one component is modified by pH variation. For example, only the portion of the spectrum originated by the quinine can vary in intensity and spectral position, changing at the same time the overall shape. The pH variation affecting only one family of the molecules and not the other family of molecules in the blend will be proof that a predetermined blend, i.e., a desired key, is present by having the predetermined blend of two or more components and the expected pH variation.

[0071] Still further, as a further validation of the predetermined blend being present, and hence the genuineness of the authenticated material, a further test can be made to determine the blend of the components included in the material. In this regard, an aliquot of a fluorescence quenching agent, such as a halogen in the form of a halogen salt, including, for example, chlorine, bromine and iodine salts, such as NaCl, KBr, Nal, can be added to the sample being analyzed. The fluorescence quenching agent can induce quenching of the fluorescence of one or more of the components (fiuorophores), which is dependent upon the specific component and the related fluorescence quenching agent. For example, a specific concentration of the fluorescence quenching agent, e.g., halogen, can reflect the exact composition of the blend or a modification of the curve of a curve of fluorescence vs. pH can indicate the presence of particular compounds in the blend. The Stern- Volmer plot quenching curve Io/I[q] as a function of the molar quencher concentration (where Io is an alkaloid fluoresce intensity in absence of quenchers and I[q] is the fluoresce intensity at a given quencher concentration represented by [q]) will be characteristic of the alkaloid blend for a given halogen quencher. The fluorescence quenching agent can be added at a concentration that provides sufficient decrease in fluorescence to be determined, such as between 10 ^~3 to 10 ^_1 M.

[0072] The fluorescence quenching agent can quench all of the components of the blend at different quenching rates depending on the given component, e.g., alkaloid, or just one or more of them. For example, quinine or lucignen fluorescence can be quenched by chloride ions, but chloride ions will have insignificant impact on the fluorescence of harmanes. In contrast, bromide ions or iodide ions will act as a quencher on all alkaloids although at different quenching rates. Accordingly, such variations in the actions of the fluorescence quenching agents depending upon the specific components in the blend can be used along with variations in pH sensitivity based upon the specific components to assist in generating keys that uniquely identify the associated marking as well as the associated marking including the specific blend.

[0073] The authentication procedure can include procedures to make a qualitative or quantitative analysis of the sample. For example, the fluorescence baseline on an equivalent unmarked product can be acquired. The fluorescence signal (intensity) from a marked product can be acquired either at different excitation wavelength (in order to excite separately the different marker components) or at one optimized excitation wavelength but with a spectrally filtered detection (in order to discriminate between the different fluorescence components of the markers blend). For this purpose, the detector can be equipped with optical filters or dispersive gratings. Halogen salts (I, CI, Br) can be added in sequence at increasing quantities and measuring at each step the fluorescence intensity. The curve of the obtained quenching curve can be measured to authenticate the marker. [0074] In an alternative, when the product marking is done with more than one component, there can be added in sequence two halogen salts at increasing quantities measuring at each step the fluorescence intensity. The fluorescence intensity can be measured either with a wavelength selective detection (by means of filters or gratings) or by exciting selectively each alkaloid if the two alkaloids have different excitation wavelengths. The resultant quenching curve of the alkaloid blend obtained can be used to authenticate the marked product. In the alternative, separate quenching curves for a blend of alkaloids can be arrived at with using at least two different halogen quenchers to further assist in the obtaining of the chemical keys.

[0075] Thus, for example, each of the at least two different alkaloids can have a fluorescence that varies in spectral position and/or intensity according to variation of pH. Also, only one of the at least two different alkaloids can have a fluorescence that varies in spectral position and/or intensity according to variation of pH. Moreover, at least one of the alkaloids can have a fluorescence that is quenched in the presence of a fluorescence quenching agent, such as a halogen salt, or more than one of the at least two different alkaloids has a fluorescence that is quenched in the presence of a fluorescence quenching agent, such as a halogen salt.

[0076] Still further, the degree of quenching can be different for at least two of the at least two different alkaloids.

[0077] There is also provided herein a method for determining whether a material is genuine by determining presence of a blend of components which vary in spectral position and/or intensity according to variation of pH, the blend of components having been added to the material as a marker, the components in the blend of components not being already associated with the material prior to being added as a marker, comprising: a) preparing an aliquot of a solvent containing a sample of the material at a first pH; b) measuring spectral position of the fluorescence of the aliquot of a) at one or more excitation wavelengths; c) adjusting the pH of the aliquot of b) to a second pH wherein at least one component of the blend of components has at least one of a different spectral position and/or intensity at the second pH than the first pH;

d) measuring spectral position of the fluorescence of the aliquot formed in c) at one or more excitation wavelengths; and

e) comparing a spectral position of the fluorescence between the fluorescence

measured in b) and the fluorescence measured in d) with known spectral positions of at least two components of the blend of components at the pH's used in a) and c) to thereby determine whether the at least two components of the blend of components is present in determining whether the material is genuine.

[0078] To further define the chemical key with such a method, there can be provided: f) dissolving in the aliquot of a) or c) different known concentrations, preferably at least three known concentrations, of a fluorescence quenching agent, preferably one or more halogen salts, the fluorescence quenching agent causing a progressive decrease in fluorescent intensity with increasing concentration of the fluorescence quenching agent of at least one component of the blend of components;

g) measuring for each known concentration of the fluorescence quenching agent a corresponding fluorescence intensity;

h) determining a curve of variation of fluorescence intensity with concentration of the fluorescence quenching agent; and

i) comparing the curve of h) with a known (calibration) curve of concentration of the fluorescence quenching agent versus fluorescence of at least two of the components of the blend of components.

[0079] The methods disclosed herein also permit authenticating if a material has been subject to diversion or adulteration by determining the concentration of a two or more components of a blend of components that has been added to the material as a marker, the components in the blend of components not being already associated with the material prior to being added as a marker, at least one of the two or more components of a blend of components having a fluorescence which varies in intensity according to variation of pH, comprising: a) measuring fluorescence intensity of an aliquot of a solvent in the absence of the components at an excitation wavelength as a noise base measure ( BM).

b) preparing an aliquot of the solvent containing a sample including a known amount of the material at a first pH;

c) measuring fluorescence intensity of the aliquot of b) at one or more excitation wavelengths;

d) adjusting the pH of the aliquot of b) to a second pH wherein at least one component of the blend of components has a different intensity than at the first pH; e) measuring fluorescence intensity of the aliquot formed in d) at one or more excitation wavelengths;

f) comparing a difference in fluorescence intensity between the fluorescence

measured in c) and the fluorescence measured in e) for at least two components of the blend of components with a known difference in fluorescence intensity of the components at the pH's used in a) and c) to thereby determine the presence or concentration of at least two components of the blend of components to permit a determination of diversion or adulteration of the material.

[0080] To further define the chemical key with such a method, there can be provided: g) dissolving in the aliquot of b) or d) different known concentrations preferably at least three known concentrations, of a fluorescence quenching agent, preferably one or more halogen salts, the fluorescence quenching agent causing a progressive decrease in fluorescent intensity with increasing concentration of the fluorescence quenching agent of at least one component of the blend of components;

h) measuring for each known concentration of the fluorescence quenching agent a corresponding fluorescence intensity;

i) determining a curve of variation of fluorescence intensity with concentration of the fluorescence quenching agent; and

j) comparing the curve of i) with a known (calibration) curve of concentration of the fluorescence quenching agent versus fluorescence to thereby confirm identity and/or concentration. [0081] In the methods disclosed herein, the pH can be varied to any degree wherein there is a determinable shift in position and/or intensity of the fluorescence, exemplary useful ranges include a pH of from 5 to 8 for the first pH and a pH of 3.5 or below for the second pH.

[0082] Similarly, the excitation wavelength can be varied depending upon the fluorescence characteristics of the components. Without limitation, useful emission wavelengths include excitation wavelengths of from 300 nm to 410 nm, or from 340nm to 365nm. Excitation wavelengths can be used that provide appropriate fluorescence and can be varied by specific components of the blend of components and how the fluorescence varies by pH and fluorescence quenching agent. Thus, one or more excitation wavelengths can be used, such as one or more excitation wavelengths at different pH. Moreover, for example, the one or more excitation wavelengths can be different at different pH.

[0083] The device for measuring the fluorescence can be a device that measures the spectrum, and can even be a device that can merely measure the peak (integrated fluorescence intensity). The device used can therefore be varied for laboratory and field use and can be varied depending upon the sensitivity of the desired test and the ensuring of the accuracy of the key.

[0084] The curve that results when using the fluorescence quenching agent can be linear or non-linear depending upon the fluorescence quenching agents and the components used in the blend of components.

[0085] There can also be included in the blend of components ingredients that have detectable parameters, such as a magnetic parameters; luminescent parameters; physical parameters, such a size and/or shape; optical parameters, such as absorption and/or reflectance characteristics that can be used as part of the chemical key. Thus, for example, the inclusion of certain size particles that are not normally included in the material to be marked can be used to even add a further level of detection. [0086] The material to be marked can be a liquid such as a distilled alcoholic beverage or an Eau de Cologne, perfume , or a solid such as a pharmaceutical or veterinary preparation or a cosmetic product or a petroleum product e.g. the fuel. The marker is preferably incorporated into the bulk material by adding the components to the bulk material, such as by adding the components separately the bulk material or adding a composition containing the components. However, the incorporation can be achieved by any manner of combining the material to be marked and the blend of components. For example, the components can be added to the bulk material by adding one or more of the components individually to the bulk material and one or more compositions containing one or more components. Still further, one or more compositions, each composition containing one or more of the components, can be added to the bulk material. As discussed above, the material can be a liquid, a solid, a gel, a colloid or a semi-liquid.

[0087] As noted above, the components are preferably non-toxic, Thus, the addition or incorporation of such components and the resulting concentration preferably complies with various and numerous legal requirements in force for food, drugs, cosmetics. The amount of the marking composition and especially the individual concentrations of the components incorporated in the marked material or product can be easily kept at nontoxic levels in case the marked material or product is intended for human or animal use.

[0088] The components can be present in a concentration at a subppm level to a ppm level, based on the total composition including the material and the at least two different alkaloids. The at least two different alkaloids are present in a total concentration of the at least two different alkaloids of 0.1 ppm to 100 ppm, based on the total weight of the composition.

[0089] The method of marking a material, preferably a liquid comprises a) choosing a desired blend of components as a chemical key for the material to be marked; and b) combining the blend of components with the material to form a marked composition. The concentration of each component in the blend of components is preferably below a toxic concentration. Moreover, the total concentration of all of the components of the blend of components is preferably below a toxic concentration, especially when the material is intended for use in a form for contact and/or consumption by an animal, such as a food or pharmaceutical product.

[0090] When the material is in liquid form, the material can be an aqueous or a nonaqueous liquid.

[0091] Moreover, the analysis of the material can include extraction of the components from the material, such as by extraction of the components from the sample into an aqueous liquid, such as water, alcohol, organic solvent or mixtures thereof (if forensic analysis is required).

[0092] The concentration of the components in the marking composition and/or identification of the components and the baselines with respect to pure solvents can be maintained in a database. Moreover, the reference values may also be added directly to the product label as a code which will be readable for authentication purposes. Thus, reference values can be provided to authorized personal by the manufacturer of the product who has marked the product. The reference values can also be already available in form of a code for example applied on the container of the marked material. Beside these ways there are still other ways known to the skilled person to provide reference data.

[0093] The marking methods according to the present invention are particularly suited for marking bulk products destined to human or animal application or use, in particular products selected from the group of products comprising alcoholic beverages, perfumes, cosmetic products, and pharmaceutical or veterinary preparations or petroleum products.

[0094] The variation of pH for changing the fluorescence characteristics of the components in the blend of components is a pH variation of 2 to 6, and can be a pH variation of 2 to 4.5. The pH can be adjusted by adding an acid that does not cause a decay in fluorescence, such as hydrosulfuric acid or hydrochloric acid or phosphoric acid.

[0095] The components are preferably inert and non-deleterious to the material. [0096] The sample for performing the test can be prepared in any manner wherein the components can be determined in the sample. For example, the material can be combined with a solvent to extract at least a portion of the alkaloid from the material. The material can be combined with the solvent to obtain an aliquot of about 0.0001 to 3 weight %, based upon the weight of the total weight of the aliquot. The solvent can be aqueous or non-aqueous or organic or mixtures thereof, and preferably is water.

[0097] There is also provided a marked material which comprises an alkaloid blend which is present in a concentration of 0.00001 to 0.3% by weight, based on the total weight of the composition, preferably 0.0003 to 0.01% by weight, more preferably 0.0001 to 0.001% by weight. The marked material can be selected from alcohol, medicinal and/or veterinary preparation, perfume, liquid, cosmetic liquid formulation, and fuel.

[0098] Moreover, there is use of an alkaloid in a liquid material composition for determining whether or not a liquid material has been subject to diversion or adulteration wherein the concentration of the alkaloid blend is between 0.00001 to 0.3% by weight, based on the total weight of the composition, preferably 0.0003 to 0.01 %, more preferably 0.0001 to 0.001% by weight.

[0099] The invention is now described in more detail with the help of examples.

Example

Macro lide antibiotic solution is a drug that can be used for the treatment of respiratory infections in animals, such as in chicken and turkey flocks.

Examples:

Marking and use of the product Macrolide antibiotic solution can be marked with a blend of components, such as alkaloids, such as a blend of quinine hydrochloride and harmine or harmane to provide a total weight of the blend of, for example, 0.1 to 0.3% by weight.

An aliquot of Macrolide antibiotic solution can be diluted in potable water for livestock/nursery animals (especially chickens, but also pigs and calves), with variable dilution depending on the animals involved (up to 0.03 wt% of Macrolide antibiotic/water corresponding to concentrations of about 1 ppm or less of quinine in the water)

Process for authenticating and quantifying Macrolide antibiotic solution

1. Measuring the base noise of a non-medicated water aliquot with the fluorescence detection device having an excitation of 365 nm.

2. Measuring the intensity of a medicated water aliquot, unaltered (and therefore at a PH 5.5 - 8, depending on the type of water used).

3. Measuring the fluorescence of the medicated water sample acidified at a pH <3 using an acid (generally inorganic, such as HCI or H ₂ SO ₄ or H ₃ PO ₄ ). The acid pH induces an increase in fluorescence intensity and a spectral displacement towards the red (from the purple to the blue).

4. Depending on the fluorescence intensity ratios, it is possible, not only to identify the marked Macrolide antibiotic in the water, but also to quantify it with precision that is dependent upon its concentration.

First alternative authentication

• Proceed with stepped-acidification of the medicated water aliquot by measuring the fluorescence intensity at each step to confirm that the pH dependence on fluorescence intensity corresponds to that of quinine (authentication of quinine as a marker).

Second alternative authentication • After item 4 above, proceed with a stepped dissolving of the halogen salt (for example, CI, Br, I) in the medicated water aliquot, which will have a dynamic quenching effect (collision between the molecules) on the quinine fluorescence.

• Proceed with the differential measurement of the fluorescence intensity of the aliquot as a function of the added salt concentration. The variation in

fluorescence intensity will have a curve that is going to be specific to the fluorophore (quinine) and to the type of quencher (salt) used. The measurement of this curve makes it possible to authenticate the presence of the marker.

It is noted that the foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention. While the present invention has been described with reference to an exemplary embodiment, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitation. Changes may be made, within the purview of the appended claims, as presently stated and as amended, without departing from the scope and spirit of the present invention in its aspects. Although the present invention has been described herein with reference to particular means, materials and embodiments, the present invention is not intended to be limited to the particulars disclosed herein; rather, the present invention extends to all functionally equivalent structures, methods and uses, such as are within the scope of the appended claims.