RU184680U1 - PROTECTED LABEL - Google Patents

Abstract

The utility model relates to the field of automatic identification and data collection, namely, devices for storing and transmitting identification data made in the form of standardized numerical (digital) or alphanumeric identifiers of national drug codes (NDC) and serial numbers (Serial Number - SN) accepted by the US Department of Health and Human Services Food and Drug Administration. The utility model can be widely used in automatic non-contact optoelectronic authentication and package identification in the pharmaceutical industry drug movement monitoring system, Blockchain technology. The technical result of the claimed utility model is to increase the security against forgery of the national drug code and serial number. the result is achieved due to the fact that the protected label contains a substrate, paper or other printed matter l, a printing ink with a metal transponder, printed on the national drug code and serial number, while the metal transponder, consisting of ferromagnetic, antiferromagnetic or ferrimagnetic powders, has the properties of nuclear magnetic resonance.

Description

The utility model relates to the field of automatic identification and data collection, namely, devices for storing and transmitting identification data made in the form of standardized numerical (digital) or alphanumeric identifiers of national drug codes (NDC) and serial numbers (Serial Number - SN) accepted by the US Department of Health and Human Services Food and Drug Administration. The utility model can be widely used for automatic non-contact optoelectronic authentication and package identification in the pharmaceutical industry drug movement monitoring system, Blockchain technology.

The term "metal transponder" in this utility model refers to a powder of ferromagnetic, antiferromagnetic or ferrimagnetic particles of micron or submicron sizes, possessing nuclear magnetic resonance properties due to electric / magnetic dipole or tunnel junctions between the Stark-Zeeman levels, which has at least two resonance frequencies.

A known matrix of binary code described in US patent No. 5288986 from 02.22.1994. The optically readable matrix described in US Pat. No. 5,288,986 dated 02.22.1994 has four intersecting sides of approximately equal length defining a perimeter, and includes a binary code formed of light and dark squares of equal sizes located around the perimeter. The matrix contains the first and second orientation squares located in opposite corners of the matrix.

Each of the orientation squares includes a contrasting circular area.

The disadvantage of optical readable matrix described in US patent No. 5288986 dated 02.22.1994: the ability to print fraudsters (third parties) in a printing house, which leads to an uncontrolled process of manufacturing and applying an optical readable matrix to the packaging of drugs and, as a result, does not provide protection against counterfeiting both optical readable matrix and drug packaging.

The known identification symbol described in US patent No. 4924078 from 05/08/1990 and No. 5,612 524 from 03/18/1997. The identification symbol includes a square array of data cells surrounded by a border of oriented and temporary data. A border may be surrounded by an external data field.

The disadvantage of the identification symbol described in US patent No. 4924078 from 05/08/1990 and No. 5 612 524 from 03/18/1997: low security against fakes.

Known is a fake-protected contactless smart card microcontroller described in the patent for utility model No. 51256 of September 16, 2005. A fake-protected contactless smart card microcontroller made on a substrate and containing memory, with its input-output connected to the information input-output of the microcontroller, the substrate has an input-output port consisting of N contacts, one end of which is connected to the second input the output of the microcontroller, and the second ends of some of the contacts of the I / O port are connected to the contacts of the antenna, designed for contactless energy reception and data transmission, respectively, from / to an external contactless radio frequency an accurate reader at a frequency of 13.56 MHz, and the second ends of the other contacts of the I / O port are designed to connect to an external data reader designed to read data from the said microcontroller, while the second end of each of the said contacts of the I / O port is made of a metal transponder selected from the following group: ferromagnetic metals and their alloys; antiferromagnetic metals and their alloys; ferrimagnetic metals and their alloys, the second external frequency reader configured to supply a read signal to at least one of the contacts of the input / output port, which is not connected to the contact of the aforementioned antenna or the contact of an external data reader, and to receive a response signal with a given frequency, which is formed by the metal transponder of this contact of the substrate.

The disadvantage of the microcontroller that is protected against counterfeiting contactless smart cards described in the patent No. 51256 of September 16, 2005 is that in some cases it is impossible to read data from the contactless smart cards of the microcontroller due to signal loss (shielding effect), low processing speed data and the lack of uniform standards for their encoding.

The national drug code of the United States is known (https://ndclist.com/what-is-ndc).

NDC consists of 11 digits, divided into 3 sections in the format 5 - 4 - 2. There may be other recording formats. The first five digits identify the label code representing the manufacturer of the drug, and are assigned by the US Food and Drug Administration (US FDA). The following four numbers identify a specific drug and are prescribed by the manufacturer. The last two digits determine the package size of the drug, and are also prescribed by the manufacturer.

NDC disadvantage: low security against fakes.

A U.S. identification mark is known which contains the U.S. national drug code (NDC) and serial number (SN) described in the literature: Security of Pharmaceuticals.Comparing, US and EU Standards, 09/2016 Mettler-Toledo GmbH. PI-VI-WP-EN-GEN-PCE-092016, page 13.

U.S. Identification Mark, contains a backing, paper, or other printed matter, the U.S. National Drug Code (NDC) in the form of 11 digits, divided into 3 sections in 5-4-2 format, and a serial number (SN) that has numeric (digital) or alphanumeric (including letters and / or numbers) characters, and contains no more than 20 letters and / or numbers.

This U.S. identification mark will be chosen as the prototype.

The disadvantage of the prototype: the impossibility of obtaining information about whether this identification mark is actually produced by a particular manufacturer; the impossibility of obtaining information about registered events in the past, the existence of which makes it impossible to handle this package with an identification mark. Another significant disadvantage of the prototype is the low security against fakes.

The technical result of the claimed utility model is to increase the security against forgery of the national code and serial number.

This result is achieved due to the fact that the protected label, made on a substrate, paper or other printed material, containing the image of the national drug code and serial number, designed to display the identification data of drugs and the manufacturer, characterized in that it further comprises a metal transponder, consisting of a powder with nuclear magnetic resonance properties, designed to verify the authenticity of the national code and serial number of drugs nuclear magnetic resonance scanner, while the above-mentioned metal transponder is added to the components of the printing ink and during printing, it is applied to the national code and to the serial number of the medicine, while the national code contains characters that include the label code, product code and packing code.

In a particular embodiment, the metal transponder consists of a ferromagnetic, antiferromagnetic or ferrimagnetic powder having the properties of nuclear magnetic resonance.

The claimed utility model is illustrated by the following drawings:

FIG. 1, which shows the overall structure of the claimed secure label (GP) 1;

FIG. 2, which shows the principle of operation of the claimed secure label 1.

As can be seen from FIG. 1, the claimed ZM 1, made on a substrate 2, paper or other printed material, contains an image of NDC 7 and SN 8.

The metal transponder 7 and 8, consisting of a ferromagnetic, antiferromagnetic or ferrimagnetic powder having nuclear magnetic resonance properties, is designed to verify the authenticity of NDC 7 and SN 8 on the surface of the substrate (packaging) of 2 drugs with a nuclear magnetic resonance scanner, while the metal transponder 7 and 8, added to the components of the printing ink and during printing, printed on national code 7 and serial number 8. NDC 7 contains numeric (digital) or alphanumeric (including letters and / or numbers) characters and includes: label code (labeler code) 3, product code (product code) 4 and packaging code (package code) 5. SN 8, contains numeric (alphanumeric) or alphanumeric (including letters and / or numbers) characters 6.

In a private version, protected label 1 displays: NDC 7 contains no more than 11 digits in the format 5 - 4 - 2: 5 digits - label code (labeler code) 3, 4 digits - product code (product code) 4 and 2 digits - code packages (package code) 5, and SN 8 contains no more than 20 letters and / or numbers 6, while NDC 7 and SN 8 meet the requirements of regulatory documents of the US Department of Health and Human Services Food and Drug Administration).

Consider the operation of the claimed secure label (GP) 1. In FIG. 2 shows the principle of operation of the claimed ZM 1.

The reader 6 includes a cellular modem, a microcontroller, a nuclear magnetic resonance scanner and an optical character recognition scanner or optical character recognition scanner (OCR Scanner) [not shown]. On the reader 6, the user, by pressing the "enable" icon, turns on the reader 6. Each reader 6 has a unique identifier ID1. The reader 6, having a cellular modem in its composition, transmits information data to the base station (not shown) in the cellular communication channel, and then to the cellular communication network 9.

To the cellular communication network 9, which consists of a switching system and a base station system (not shown in the drawing), an Internet network 10 is connected through a switching node in a cellular communication network (not shown in the drawing), to which users of the blockchain network 21 are connected, and a server 8. The servers of the blockchain technology 21, in essence, are a distributed database where the data storage of ZM 1 takes place.

When the reader 6 is turned on, through the cellular communication network 9, the identifier 11 (ID1) data of the reader 6 is sent to the server 8.

Server 8 has a public key generator (not shown) that generates keys. Server 8, having received ID1 identifier data 11 (ID1) from the reader 6, identifies it in the database (not shown).

If the identification data of identifier 11 (ID1) did not pass through the database of server 8, then the identification process stops.

After positive identification of reader 6 in the database, server 8 transmits data 12 of public key PK1 to reader 6. Having received data 12 of the PK1 public key, the reader 6 automatically turns on the nuclear magnetic resonance scanner (not shown in the drawing) and transmits data 13 of the PK2 key to ZM 1 containing the metal transponder in numbers NDC 7 and letters and / or numbers SN 8. Data key 13 PK2, in essence, are a unique part of nuclear magnetic resonance (NMR) for a particular type of metal transponder in NDC 7 and SN 8. Nuclear magnetic resonance (NMR) scanner [NMR scanner] contains an antenna, a receiver and a transmitter ( not shown) that operate in the frequency range o t 1 MHz to 1 GHz. NMR scanner through an antenna (not shown in the drawing) transmits data 13 of the PK2 key and energy to the metal transponder in numbers NDC 7 and letters and / or numbers SN 8. Thanks to the electric / magnetic dipole or tunnel junctions between the Stark-Zeeman levels in the metal -transponder in numbers NDC 7 and letters and / or numbers SN 8 there is nuclear magnetic resonance (NMR), which allows you to get a response 14 (unique frequency), it is this data identifier 14 (ID2) ZM 1.

An NMR scanner built into the reader 6 receives a unique frequency 14, or identifier data 14 — ID2, from ZM 1 with a metal transponder in NDC 7 digits and letters and / or SN 8 digits.

Let us consider a description of the physical effect for ZM 1 with a metal transponder in numbers NDC 7 and letters and / or numbers SN 8, containing, for example, ferrimagnetic powder MnFe ₂ O ₄ .

When irradiating 13 NMR with a scanner (not shown) ZM 1 with a metal transponder in numbers NDC 7 and letters and / or numbers SN 8 at a frequency of 536 MHz, in a layer of MnFe ₂ O ₄ ferrimagnetic powder, at the Stark-Zeeman levels nuclear magnetic resonance effect 14, which is unambiguously detected by an NMR scanner (not shown) of reader 6. For MnFe ₂ O ₄ spinel ferrite at a frequency fl = 536 MHz + 10.7 MHz = 546.7 MHz, where 10.7 MHz - the resonance frequency of the spinel ferrite MnFe ₂ O _4, and the 536 MHz - excitation frequency derived from 13 nuclear magnetic resonance scanner counting of Tell 6 via an antenna (not shown).

The metal transponder in numbers NDC 7 and letters and / or numbers SN 8.5 in protected label 1 may contain several layers (from one to N) of a ferrimagnetic powder in the region of NDC 7, for example, the first layer is MgFe ₂ O ₄ , the second layer NiFe ₂ O ₄ and the third layer is LiFe ₂ O ₄ . When printing a metal transponder with 5 different layers, a combination of layers will be formed in the NDC 7 area of security label 1:

- label code (labeler code), 5 digits containing the layer - MgFe ₂ O ₄ ,

- product code, 4 digits containing the layer - NiFe ₂ O ₄ ,

- package code (package code), 2 digits containing the layer - LiFe ₂ O ₄ . Thus, an attacker cannot be faked

a combination of layers in the NDC 7 region of protected label 1, since each value of the information data uniquely corresponds to unique frequencies of nuclear magnetic resonance 14, for example, the first layer — MgFe ₂ O ₄ has a frequency fl, the second layer — NiFe ₂ O ₄ has a frequency f2 and the third layer - LiFe ₂ O ₄ has a frequency fN, it becomes impossible to become, which increases the security of label 1 from counterfeiting.

Further, the reader 6 transmits the data 15 of the ID2 identifier of the secure label 1 to the server 8, which, in essence, is the unique NMR frequency of the metal transponder in numbers NDC 7 and letters and / or numbers SN8 3M1.

If in the database of the server 8 the identification of data 14 3 1 (ID2) has not passed, the identification process stops, the reader 6 sends a message "alarm" to the server 8, the message "alarm" appears on the display of the reader 6.

As soon as the authentication of ZM 1 is completed with a positive result on the server 8, the server 8 will transmit data 16 of the PK2 private key to the reader 6. Having received the data 16 of the PK2 private key, the reader 6 automatically turns on the OCR Scanner (not shown in the drawing).

OCR Scanner (not shown) of reader 6, reads 17 and recognizes NDC and SN applied to protected label 1.

Next, the reader 6 transmits to the server 8 the data 18 of the RKZ key of the secure label 1, which contains the data 16 of the private key PK2, plus SN 6 of the secure label 1, read and recognized by the OCR Scanner (not shown) from the NDC 7 and SN 8 area.

Thus, the key data 18 contains information: RKZ = PK2 + SN 6. After creating and distributing the keys PK1 and PK2, each protected label 1 in the blockchain system 21 will have its own key, which will contain PKK = PK2 + SN 6.

This RCH key will be used to create the encrypted hash code of the secure label 1 based on the SHA-1 (Secure Hash Algorithm 1) cryptographic hash algorithm.

Then, server 8 will encrypt this hash code using the RKZ private key of protected label 1 and save the serial number, manufacturer information and encrypted hash code in the memory of reader 6.

Reader 6 has the ability to display information data read from the NDC 7 and SN 8 areas of label 1 on the display (not shown in the drawing): labeler code 3, product code 4, package code 5 and SN 6. Information data 17 (NDC 7 + SN 8) received from secure label 1, reader 6 transmits in secure mode 19 to server 8. Server 8 encrypts information data 17 received from secure label 1, then transfers data to the Internet 10, and then to blockchain network 21. In the above scheme, each protected 1 has its own private key PK 3 = PK 2 + SN 6, and these keys are They differ from each other. If the private key RK 3 of the secure label 1 is known to the attacker, this will not have a big impact on the entire blockchain system 21, since the attacker cannot recognize the closure of the keys of other secure labels 1 by this key.

The metal transponder in numbers NDC 7 and letters and / or numbers SN 8 ЗМ 1 may consist of ferromagnetic, antiferromagnetic or ferrimagnetic powders, for example: MgFe ₂ O ₄ , NiFe ₂ O ₄ , LiFe ₂ O ₄ , CuFe ₂ O ₄ , ZnFe ₂ O _4, CoFe ₂ O _4; MnCO ₃ , MnFe ₂ O ₄ having NMR properties. The combination of only 8 of the above powders allows you to get 8! = 40'320 unique frequencies of nuclear magnetic resonance 14.

From the literature (A. Shamir, Identity-based Cryptosystems and Signature Schemes. Advances in Cryptology: Proceeding of Crypto 84, LNCS, 1984. - PP. 47-53), it is known that cryptographic scheme based on identification is one of the methods open-key cryptography that can be used by two participants to exchange messages and effectively verify signatures.

In the figure of FIG. 2 shows an architecture that allows data exchange from a secure tag 1, which is applied to packaging 7, reader 6, server 8, cellular communication network 9, Internet 10 and blockchain network 21.3a due to the presence of a metal transponder in NDC 7 and letters and / or numbers SN 8 ЗМ 1, the reader 6 can evaluate the print quality of letters and / or numbers, which is carried out by analyzing the NMR frequency 14. In the private version, the protected label 1 displays: NDC contains no more than 11 digits in the format 5 - 4 - 2: 5 digits - label code (labeler code), 4 digits - product code and 2 digits - package code (package code), and SN contains no more than 20 letters and / or numbers, while NDC and SN, meets the requirements of regulatory documents of the US Department of Health and Human Services.

Thus, by introducing a metal transponder into the protected label 1 in numbers NDC 7 and letters and / or numbers SN 8, the problem of the utility model is solved: increasing the security against forgery of the national drug code 7 and serial number 8.

The manufacturing technology of metal transponders makes it possible to obtain particles of micron or submicron sizes added at the stage of mixing the components during the production of printing ink using printing methods known from the literature.

A method for producing, for example, MgFe ₂ O ₄ -based metal transponders is described in the literature: H. Yasuoka, A. Hirai, NMR Determination of Metal Ion Distribution in Maganese Ferrite Preparad from Aqueous Solution, Journal of the Physical Society of Japan, Vol . 22, No. 1, January, 1967, PP. 174-180. Prototypes of the security label 1 were manufactured. Tests have shown that they meet the requirements of the NDC and SN accepted by the US Department of Health and Human Services.

Claims (2)

1. A secure label, made on a substrate, paper or other printed material, containing the image of the national drug code and serial number, designed to display the identification data of drugs and the manufacturer, characterized in that it further comprises a metal transponder consisting of a powder having the properties nuclear magnetic resonance, designed to verify the authenticity of the national code and serial number of drugs by a nuclear magnetic resonance scanner, with In this, the aforementioned metal transponder is added to the components of the printing ink and is printed on the national code and on the serial number symbols of the medicine, while the national code contains symbols including the label code, product code and packaging code. 2. A protected label according to claim 1, characterized in that the metal transponder consists of a ferromagnetic, antiferromagnetic or ferrimagnetic powder having the properties of nuclear magnetic resonance.

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