KR101495875B1 - Composition for New Latent Fingerprint Detector Comprising Food Dyes - Google Patents

Abstract

The present invention relates to a composition for a novel latent fingerprint insufflator, which displays remarkably improved insufflation efficiency in limited various conditions and circumstances that existing latent fingerprint insufflators show low insufflation efficiency, and which is harmless to a human body to be safely used. More specifically, the composition comprises one or more selected from food dyes described in Table 1.

Description

Composition for New Latent Fingerprint Detector Comprising Food Dyes [0002]

The present invention relates to a novel latent fingerprinting agent which can be used safely and harmlessly to the human body, in which the existing potential fingerprinting agents exhibit superior detection efficiency in various limited conditions and environments that exhibit low detection efficiency.

The potential fingerprints that were collected in various forms of micro evidences collected during the initial investigation stage of the crime investigation site were composed of water (98.5%) and polar organic matter (0.5%) and nonpolar organic matter (1%) , Which is the subject of the first priority evidence collection, along with biological samples for DNA (DNA) analysis. The development of potential fingerprints can be classified as follows: 1) the nature of the presenting agent to be used and the physical and chemical characteristics thereof, 2) the amount of the fugitive fingerprint ingredients, 3) the composition of the material with potential fingerprints, and 4) ), The color of the material from which the potential fingerprint is circulated, 5) the presence and absence of porosity on the surface of the material, and the degree to which it is large and small severely affects the resolution of the potential fingerprint very sensitively . Therefore, although it is important to prove the potential fingerprint as an objective evidence of scientific investigation, it is difficult to obtain the result of the high resolution to the extent that the feature points can be read in various types of potential fingerprints through the identification work.

There are three methods of developing potential fingerprints: optical methods, physical methods, and chemical methods. 1) The optical method is a method using a light source (LASER, UV or ALS; Alternative Light Source) and 2) physical methods are a solid powder (black powder, fluorescent powder, magnetic powder, Nano) powder and thermoplastic powder). 3) The chemical method is a method of using a reaction with a chemical reagent, such as a Ninhydrin method, a cyanoacrylate (CA) fumigation method, an iodine method, an AgNO 3 solution method, a Sudan Black method, a vacuum deposition method, 28 solution method, Amido Black method, 1,8-Diazafluoren-9-one method, Basic Yellow 40 solution method, Rhodamine 6G solution method, Safranin O solution method, Zinc chloride solution method, Crystal Violet solution method, Liqui- Arodrox solution method, TapeeGlo solution method and so on. These test methods have various characteristics and advantages and disadvantages (Non-Patent Document 1).

When the potential fingerprint sensor is a solid (powder) phase formulation, a chemical reaction is difficult to occur due to the absence of a liquid medium (Non-Patent Document 2). Instead, the Coulomb attraction due to the electronic affinity between the different ionic materials and the hydrophobic Van der Waals attraction between the non-polar and nonpolar materials, The hydrogen bonds between the materials (Non-Patent Document 3) and the like physically adsorb the powder particles on the surface of the potential fingerprint, resulting in the fingerprint being developed, resulting in a weak fingerprint development compared with a chemical reaction.

The chemical method uses a color reaction which is a result of a chemical reaction between a fingerprint component and a detection agent. Thus, there is a lot of room for improvement in detection resolution, and the reagents and solvents used are harmful to the human body. In addition, since the sample is dissolved in a solvent and used, for example, when the written contents are present in the sample or the potential fingerprint is oiled on a solvent-sensitive material such as a thermal paper, A problem may arise.

In particular, in order to solve the difficulties in the area of potential fingerprint detection among the micro-evidence in the context of scientific investigation, it is necessary that 1) the potential fingerprint sensor should maintain good detection efficiency and be non-toxic, 2) the potential of the potential fingerprint on the surface of the porous material is good And 3) the efficacy of potential fingerprints circulating on human skin should be high. Also, it is necessary to maintain 4) prolonged exposure to the potential fingerprints exposed for a long period of time, 5) not only should the potential fingerprints circulated in the underwater evidence immersed in water be good, 6) It should be readable at a noticeable level. In addition, in order to obtain a clear image of the potential fingerprint even if a separate light source is not used, it is also necessary to develop various colors of the present invention so that the potential fingerprint can be appropriately selected and used according to the chromaticity of the background.

Edible dyes are not toxic and their use is restricted by law. Currently, there are 16 edible dyes available in Korea, including 9 edible dyes and 7 aluminum lake dyes, and different edible dyes may be used in different countries depending on their dietary and cultural differences . 12 types of food dyes in basic form, not aluminum lakes, 15 kinds in Japan, 15 kinds in EU, 9 kinds in USA, and 14 kinds of food dyes in Codex (International Food Standards Committee) Some are also allowed in the form of aluminum racks. These pigments have various functional groups such as a sulfonic acid group, a carbonyl group, a methoxy group, a hydroxyl group, an imide group, an amino group, and an aryl group in the dye molecule, and thus polar substances having relative charge including metal ions in the potential fingerprint, And it is expected that it will be effective for the potential fingerprinting. In addition, these pigments are already secured and are composed of various colors, so that the potential effect of the potential fingerprints can be improved if they are selectively used by using the complementary color relationship according to the color of the oiled evidence. In this paper, we compare the potential use of potential fingerprint emitters with those of conventional potential fingerprint emitters and find ways to overcome the limitations of conventional potential fingerprint emitters.

Robert S. Ramotowski (2013), Lee and Gaensslen ' s Advances in Fingerprint Technology. 3rd Edition., CRC Press, Taylor & Francis Group. New York. GS Sodhi, and J Kaur (2001), Powder Method for Detecting Latent Fingerprints; A Review. Forensic Sci. Int. 120; 172-176. T Steiner (2002), Review; The Hydrogen Bond in the Solid State. Angew Chem. Int. Ed. 41; 48-76.

In order to solve the problems of the related art as described above, the present invention provides a latent fingerprint sensor that can detect a variety of potentials such as a porous surface material having a very low efficacy, a sensible article exposed for a long period of time, It is an object of the present invention to provide a composition capable of developing a potential fingerprint at high resolution in an environment and a condition.

In addition, since the present invention can be used in a wide variety of colors of the composition so as to have excellent visibility according to the color of the background where the potential fingerprint is made of various colors, it is possible to obtain a clear Another object of the present invention is to provide a composition for developing a potential fingerprint capable of obtaining an image.

It is still another object of the present invention to provide a composition for developing a potential fingerprint that can be safely used by a detecting agent because the stability against the human body is secured.

In order to achieve the above-mentioned object, the present invention provides a latent fingerprint image forming composition comprising at least one selected from the food colors listed in Table 1.

The edible dyes are approved for use in Korea, Japan, the United States (FDA) and the European Union (EU). Examples 1 to 9 are azo dyes, 10 to 11 are carbonyl dyes, 12 to 15 are triarylmethane dyes to be. The edible dyes include various functional groups such as a sulfonic acid group (-SO ₃ ^- Na ⁺ ), a hydroxyl group, an imide group, a phenyl group, a methoxy group and a dimethylamino group in addition to chromophore groups such as an azo group, a carbonyl group and a triarylmethane group, It is believed that the potential fingerprints are generated by the interaction of negative and cationic polar materials with relative charge including metal ions and hydrophobic lipid molecules. That is, the negative (-) ions in the polarity (-SO ₃ ^- Na ⁺ ) part of the dye molecule are inorganic matters in the fingerprint component and the amount (+) of various metals (Na ⁺ , K ⁺ , Ca ⁺⁺ and Mg ⁺⁺ ) ) Ions and electrostatic Coulomb attraction and the other functional groups (C = O and NH) are the hydrogen bonds between the amino acids (Serine, Glycine and Ornithine etc.), carbohydrate (H-bond). In addition, the non-polar hydrocarbons (phenyl, napthyl and bis-indolyden) are part of the intermolecular interactions induced by hydrophobic interactions with hydrocarbons such as lipid-based fats, glycerin, der Waals) Physical adsorption is possible depending on manpower.

Since the edible dye is highly scattered, it is preferable to apply the rolling method, and potential fingerprints can be obtained in a similar degree to nonporous glass in porous paper, which was almost impossible with conventional black powder.

In addition, the edible dye in the composition of the present invention may be one of the compounds listed in Table 2, in the form of an aluminum rack. In Table 2, aluminum lakes are omitted in the designation for convenience of description. For example, in Table 2, yellow No. 4 refers to yellow No. 4 aluminum lakes.

Aluminum ray keuneun water-soluble aluminum aluminum sulfate as a general term for a salt compound of a food dye _{(Al 2 (SO 4) 3} ) or aluminum chloride (AlCl ₃₎ sodium salt of aluminum hydroxide obtained was added to _{(NaHCO 3) (Al (OH} ) 3 ) Form. ≪ / RTI > The aluminum lake dyes were remarkably low in acidity without the use of any additive, and the fingerprints could be easily obtained by the brushing method because the brushing did not occur due to brushing. This may sulfonates present two to three dogs per dye ^molecule a (-SO ₃ Na ⁺⁾ parts are produced by reaction with aluminum hydroxide (Al (OH) ₃₎ aluminum ^{_{((-SO 3 -) 3 Al}} + ⁺⁺ ).

In addition, the composition of the present invention may further comprise 50 to 200 parts by weight of at least one aluminum rack selected from the aluminum lacquers listed in Table 2, based on 100 parts by weight of the at least one food dye selected from the edible dyes shown in Table 1 above have. The following food dyes are highly dispersible and can not be easily used for the development of latent fingerprints alone. However, when they are mixed with aluminum lake dyes, the saturation level is kept high and the acidity is significantly lowered, It was easy to distinguish it from the surface color on the surface of the material, and the effect of the present invention was greatly improved. When the mixing ratio of the aluminum racks is low, the acidity is still too large to be applied to the shoveling method, and when the mixing ratio of the aluminum racks is too high, the effect of the present invention is low.

In the following examples, the composition was prepared with the binding agent and evaluated for its efficacy, which is intended to make the formulation in a compact form that is easy to use. Although no specific data was presented, there was no problem in applying the dyeing method even when a mixed composition was prepared using an edible dye and an aluminum lacquer that did not contain a binder, Also improved.

As described above, when the aluminum lake dye and the edible dye are mixed, it is preferable that the dyes to be mixed so as to maintain high saturation have the same series of hues. Here, the term " hue of the same series " means red, yellow, blue, and the like as contained in the name of the dye. For example, the yellow No. 4 aluminum lake has the yellow No. 4, yellow No. 5, It is preferable to mix it with at least one edible dye of the yellow No. 13. However, mixing of dyes of different colors is not excluded, and colors may be mixed and used so as to complement the background of the sample. It is also desirable to mix the dyes having different structural characteristics so that the various functional groups can activate the interaction with the potential fingerprint components. For example, as a ternary dye, a blue color No. 5, which is a triarylmethane dye having a high hydrophobicity, is additionally mixed with a blue No. 2 aluminum lake and an azo dye, .

The composition of the present invention may further comprise 3 to 15 parts by weight of a binder for color cosmetics, based on 100 parts by weight of the edible dye. The binding agent for cosmetics is harmless to the human body, but greatly reduces the acidity of the food dye, thereby facilitating the application of the dyeing method and greatly enhancing the effect of developing potential fingerprints. Any binder may be used as long as it is used in cosmetics for the purpose of increasing the bonding force between particles. In the following examples, only polydimethylsiloxane was used as a binding agent for cosmetics. However, the present invention is not limited to the use of polydimethylsiloxane as a binder for cosmetics. However, it is also possible to use polydimethylsiloxane as a binder for cosmetics. It was also confirmed that isostearyl di-isostearate, isopropyl lanolate, isopropyl myristate, and isopropyl palmitate also greatly reduce the acidity of edible dyes and increase the fingerprinting efficacy. When the additional ratio of the binder was less than 3 parts by weight, it was difficult to lower the acidity, and when the additional ratio was more than 15 parts by weight, the fingerprint development efficacy was lowered.

The effect of adding the binder was not so great because the aluminum rake itself was low in acidity, and the effect of fingerprint development in the case of containing 3 to 15 parts by weight of the binder in 100 parts by weight was similar to that in the case of not including the binder. Therefore, a binder may be included for the production of the compressed powder to be described below.

The composition of the present invention may further contain additives for color cosmetics such as excipients, preservatives and perfumes in addition to the binder. In this case, each of the additives other than the binder is preferably 3 to 5 parts by weight based on 100 parts by weight of the food dye, and the total amount of additives including the binder is preferably less than 20 parts by weight. When the total amount of the additive was 20 parts by weight or more, the effect of the fingerprint development was deteriorated as the proportion of the dye was decreased. In the following examples, only the results of a composition containing polymetacylate to exhibit a silky feel by a preservative and a film formation other than the binder were described, but in the preliminary experiment, the addition of the binder is most important for the lowering of the acidity and the polymetacylate Although it was effective to apply the powder more smoothly, it did not significantly reduce the scattering property or improve the efficacy with the preservative.

Generally, in the case of scientific fingerprints, the powdered fingerprint sensor is applied only to non-porous materials because it is very low in efficiency of development of potential fingerprints flowing in porous materials. Therefore, when developing potential fingerprints on a porous material such as papers, a liquid ninhydrin solution is conventionally used as a spraying or dipping method. However, detection by the ninhydrin method in liquid form is likely to compromise additional evidence on paper. The compositions of the present invention are very innovative in that the porous paper such as A4 paper or A4 paper is excellent in fingerprint development efficiency and thus the liquid method should be used for the development of fingerprint of porous paper, . Furthermore, the compositions of the present invention are highly sublime in water, which is believed to be impossible in the prior art, and are highly effective in developing potential fingerprints even in dried underwater fingerprints and toilet paper, resulting in a large effect on the presence or absence of porosity on various material surfaces Was not received.

The compositions for developing potential fingerprints of the present invention can be molded and used in the form of compressed powder so as to be portable and easy to use. The compressed powder is advantageous in that it can be easily carried and used when it is manufactured in a state in which it is contained in a case like a compact which is a color cosmetics. Even if the detailed description is omitted, the molding of the compressed powder is carried out by a press with a binder together with a binder. However, those skilled in the art will understand that the technique applied to compression powder molding of a fingerprint masking agent according to the prior art or a method for forming a compact or a shadow in color cosmetics Technology can be easily applied.

The present invention also relates to a method of developing a latent fingerprint, characterized in that the latent fingerprint is developed by a chiral method using the composition. According to the present method, in the prior art, latent fingerprint development in the semi-porous transparent vinyl or porous material (paper and toilet paper) samples, in which the potential fingerprint is hardly or almost impossible to achieve by the chain method, In the underwater fingerprints, the efficiency of emergence was very good.

As described above, according to the composition and method of the present invention, when it is considered impossible to advance by the conventional powder method, not only the potential fingerprint that is oiled on the porous surface material but also the potential fingerprint that is oiled on the underwater evidence immersed in water It is possible to quickly and accurately identify high-resolution latent fingerprints under various conditions.

In addition, the composition and method of the present invention are distinguishable from the color on the surface of the material on which the potential fingerprint is circulated by various color dyes, so that it can be visually recognized without using a separate light source, UV; 425 ~ 635 nm), the clearness becomes clearer, and a clear fingerprint image can be obtained.

The composition and method according to the present invention basically use an edible dye and the stability of the human body is secured, thereby providing a more safe and sensible environment to the on-site detectors.

FIGS. 1 and 2 are images showing the result of potential fingerprinting using a composition for potential fingerprinting according to an embodiment of the present invention including a food coloring agent. FIG.
Figure 3 is an image showing the result of potential fingerprinting using a composition for potential fingerprinting according to an embodiment of the present invention including an aluminum lake dye.
FIGS. 4 and 5 are images showing the result of potential fingerprinting using a composition for potential fingerprint detection according to an embodiment of the present invention including a food coloring agent. FIG.
6 is an image showing the result of potential fingerprinting using a composition for potential fingerprinting according to an embodiment of the present invention including an aluminum lake dye.
FIGS. 7 and 8 are images showing potential fingerprinting results using a composition for potential fingerprinting according to an embodiment of the present invention including a food coloring agent. FIG.
FIG. 9 is an image showing the result of potential fingerprint detection using a composition for potential fingerprint detection according to an embodiment of the present invention including a two-component dye. FIG.
FIG. 10 is an image showing the result of potential fingerprint detection using a composition for potential fingerprint detection according to an embodiment of the present invention including a three-component dye. FIG.
Fig. 11 is an image showing a representative example of a good development of latent fingerprints by two-component and three-component detergent compositions. Fig.

Hereinafter, the present invention will be described in more detail with reference to the accompanying examples. However, these embodiments are merely examples for explaining the content and scope of the technical idea of the present invention, and thus the technical scope of the present invention is not limited or changed. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the technical idea of the present invention based on these examples.

Example: Comparison of Potential Fingerprints

Unless otherwise noted in the following examples, the latent fingerprint development efficacy was evaluated by the following method.

To obtain a uniform potential fingerprint sample, the right thumb of the same experimenter was rinsed with acetone at room temperature and dried. After rubbing the forehead, nose, and hair of his / her body in sequence, put the material to be fingerprinted on the load cell (CAS NT 203A, Korea) and apply a force of 1.2kgf / 10N constantly. And fingerprint samples were prepared. In order to increase the applicability to the field, it was left for 3 hours and used for powder coating experiment. Potential fingerprint samples were applied by CSI Brush (ID TECH Co.) to the potential fingerprint samples using a shading method, and the white balance (AWB; Auto White Balance (AWB)) was applied to a Samsung digital camera (NX 300 model; bundle lens 20-50 mm) ) Were automatically adjusted so that the contrast effect was maximized. Then, the number of feature points was compared using AFIS (Automated Fingerprint Identification Systems) operated by the NPA. In order to compare the effectiveness of the present invention, the potential of the fingerprints was compared using the black powder used for the potential fingerprints. Each experiment was repeated two or more times to confirm its reproducibility.

Example 1 Evaluation of Potential Fingerprints Using Food Dyes

1) Estimation of Potential Fingerprints in Porous and Non Porous Samples of Food Dyes

Fifteen kinds of edible dyes (Table 1) were used to evaluate the potential for developing potential fingerprints in porous and nonporous samples. Fifteen food dyes were purchased from Aldrich-Sigma and Emerald Performance Materials LLC. Before use, they were placed in a fine powder dry grinder and pulverized to obtain a uniform particle size distribution. The particle size was maintained at 20 nm or more, which does not affect the skin at a level similar to that of the particles. As a comparative example, the black powder used in the conventional method was purchased from Samhwa Corporation. The powders for developing the potential fingerprint were activated by dehydration at 50 ° C for 2 to 3 hours immediately before use.

Since the edible dyes are very acid-resistant, the rolling method was applied because it was difficult to handle the fingerprints when using fingerprints. The Rolling method is a method in which the powder is sprinkled excessively on the sample potential fingerprint and the material with the fingerprint is shaken gently to the left and right so that the fingerprint is uniformly adsorbed without being damaged and then the excessive powder is removed. The black powder was exposed to latent fingerprints by brushing.

Porous materials such as A4 paper and non - porous glass slides (glass) were used as samples with potential fingerprints. At this time, in order to confirm the effect of the background color, evaluation of the effect of developing each A4 paper from the number of minutia points of the potential fingerprints which were developed on the white paper (A4 white paper) and black paper (A4 black paper)

Table 3 shows the number of minutiae points measured using edible dyes or black powders in each sample, and Figs. 1 to 2 are each latent fingerprint images.

The black powder of the comparative example of the prior art shown in Table 3 had a good appearance in non-porous glass, but it revealed the problem of the prior art that it is difficult to identify the porous specimen because the number of characteristic points is small in the porous paper. It was confirmed that the edible dyes exhibit good developability exceeding the result of applying to non-porous materials in porous paper which is hard to be detected as black powder and can be usefully used for developing latent fingerprint in addition to black powder .

2) Estimation of Potential Fingerprint Advantages Using Aluminum Lakes

Although edible dyes are excellent in current output in porous samples, they are difficult to handle due to their high acidity, which is problematic for application to the dyeing method. In this study, it was concluded that the aluminum complex, which is an aluminum complex of food dye, had a lower specific gravity than that of food dye. The seven aluminum lake dyes used (Table 2) were purchased from Aldrich-Sigma and Emerald Performance Materials LLC.

The aluminum lakes were also subjected to pretreatment of fine powder dry pulverization and dehumidification as in the case of edible dyes and then used for potential fingerprint development according to the method described in 1). As a result, as expected, the aluminum rake was significantly lower in the acidity, so that it was possible to apply the method without any problems to the spinning method.

Table 4 shows the number of feature points measured using edible dye or black powder in each sample, and Fig. 3 is an image of each potential fingerprint image. In the following tables and drawings, denoted by an asterisk (*) next to the number of minutiae and images indicates that the test is black.

As can be seen in Table 4 and FIG. 3, the compositions of Production Examples 16 to 22 containing aluminum rake showed a remarkable effect in comparison with the black powder in the non-porous glass sample, The result showed that the efficiency was higher. From this, it was confirmed that the composition including the aluminum rack can be usefully used for the development of latent fingerprints in a sample which is difficult to identify by the conventional technique by the chain method.

3) Estimation of Potential Fingerprints of Edible Dye Composition

As another method to lower the acidity of edible dyes, a binder for use in color cosmetics was added to prepare a composition for developing potential fingerprints, and the physical properties and outcome of the composition were evaluated.

First, potential fingerprinting agents containing edible dyes were prepared according to the composition shown in Table 5 below. The ingredients in Table 5, except edible dyes, were purchased from Stepan Company. The mixture having the composition shown in Table 5 was dry-pulverized by fine powder and then dehumidified at 50 ° C for 2 to 3 hours for activation. The composition of the present invention was significantly lower in acid-fastness than that of the food dye, and thus it was easy to apply the shading method. The potential fingerprints were obtained according to the method described in 1).

Table 6 shows the number of minutiae points measured in each sample using the composition of Table 5, and Figs. 4 to 5 are each latent fingerprint images. The names of the dyes in Table 6 indicate the kinds of the edible dyes used in the composition. From these results, the composition shown in Table 5 also exhibited a remarkable salting ability similar to that of aluminum lakes, and there was no problem in recognizing potential fingerprints even on paper made of a porous material.

Example 2 Evaluation of Detection Efficiency in Specimens for which Conventional Detection is Impossible

According to the results of Example 1 showing that the present emulsifying agents of the present invention exhibit excellent effect on porous materials, the present invention has evaluated the effect of the present invention on a sample which is recognized to be almost impossible to develop with conventional powders. In other words, it attempted to extract potential fingerprints from underwater fingerprints and toilet paper (Monariza Co., Ltd. cosmetic toilet paper) which had been immersed in water that had not been applied as a porous sample. In order to detect underwater fingerprints, potential fingerprints on A4 white paper were immersed in water for 3 hours and then completely dried after 24 hours. In addition, the present invention also evaluated the effect of potential fingerprints on the semi-porous PVC transparent vinyl, which was difficult to identify by conventional techniques.

Production potentials 16-22 and aluminum dye-containing compositions 23-37 were used to develop latent fingerprints from each sample using the shading method, and the number of feature points was shown in Tables 7 and 8, and fingerprint images Are shown in Figs.

First, as expected in the black powder of the prior art, no feature points were detected in underwater fingerprints or toilet paper samples immersed in water, and only six characteristic points were observed in transparent vinyl. On the other hand, the compositions of Production Examples 16 to 22, which were made of aluminum lacquer, exhibited better appearance than those of conventional powders such as fingerprints partially developed in water underwater. In the toilet paper, fingerprints were partially formed in the composition containing the red No. 40 aluminum lacquer, but in the other compositions, the fingerprint development was poor as in the comparative example. In the case of semi-porous transparent vinyl, most of the preparation examples showed better appearance than the black powder.

The compositions of Production Examples 23 to 37 composed of edible dyes and additives exhibited a high output power that could be utilized in actual detection in both underwater fingerprints, toilet paper and transparent vinyl that were immersed in water.

Example 3 Evaluation of Potential Fingerprints Using Aluminum Lake and Food Dye Composition

The compositions of Production Examples 16 to 22, which are composed of aluminum lacquer, are low in non-acidity, but the low output power of underwater fingerprints and toilet paper has a lower saturation than that of the edible dyes themselves, It is difficult to handle cursors, but it has a high saturation and is advantageous in comparison with the surroundings. Therefore, when the aluminum rake and the food dye are mixed, it is expected that the potential effect of the potential fingerprint will be improved.

Thus, a composition comprising two-component or three-component dyes was prepared by mixing the compositions selected from Preparations 1 to 15 and the compositions selected from Preparations 16 to 22 in the ratio shown in Table 9 below. The prepared composition was not highly acidic and had no problems in applying the chiral method.

Thereafter, a composition containing two or three component dyes was prepared by mixing the composition selected from Preparations 23 to 37 containing the binder and the composition selected from Preparations 16 to 22, and the composition was prepared in the same manner as in Example 1 The effects of latent fingerprints on submerged fingerprints, toilet paper, and vinyl specimens were evaluated. In addition, the results of potential fingerprints on glass slide specimens 24 hours after the potential fingerprints were circulated were also shown.

Table 9 and Figure 9 show the results of potential fingerprinting of a composition comprising a two-component dye. The compositions of Preparations 38 to 44 contained edible dyes but were significantly low in acidity and thus facilitated the potential fingerprinting by the chiral method.

As can be seen from Table 9 and FIG. 9, the compositions of the present invention were excellent in fingerprint development effect in not only underwater fingerprints immersed in water but also in toilet paper. , Which is superior to the single component type dye. In particular, the compositions of Production Examples 41, 42 and 44 exhibited excellent potential for developing potential fingerprints in all kinds of samples.

The following Tables 10 and 10 show very good results as in the case of the compositions of Production Examples 23 to 29 containing two-component dyes as a result of the composition containing the three-component dyes. In Table 7 and FIG. 10, a positive (+) sign indicates that a different light source (Polilight FLARE + manufactured by ROFIN, Australia, 450 nm) was used.

Fig. 11 shows a representative example of good presentation of potential fingerprints under various conditions by compositions of two-component and three component compositions. In particular, the application of the Cyanoacrylate (CA) fumigation method to the low emission of potential fingerprints on the PVC showed a higher enhancement potential of the potential fingerprints than the case of using the conventional crystal violet. This effect provided good saturation of the black, blue and green dyes with high chroma as well as the mixed composition.

Claims (10)

delete delete delete delete To 100 parts by weight of at least one edible dye selected from the edible dyes shown in the following Table 1,
And 3 to 15 parts by weight of a binding agent for cosmetics.
[Table 1]

6. The method of claim 5,
Wherein the cosmetic binder is selected from the group consisting of polydimethylsiloxane, potato starch, guar gum, dextrin, lanolin alcohol, lanolin wax, rosin, locust bean gum, methylcellulose, wax, wheat starch, ceresin, cellulose gum, isostearyl isosate, Propyl myristate, isopropyl myristate, and isopropyl palmitate. ≪ RTI ID = 0.0 > 11. < / RTI >
delete A compressed powder for potential fingerprint development according to claim 5, wherein the composition for forming a latent fingerprint is formed in the form of compressed powder.
delete A potential fingerprinting method according to claim 5, wherein the potential fingerprint is developed by a chirping method using the composition for developing a potential fingerprint.

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