CZ305903B6 - Nanofibrous sensor of scent trails for both olfactronic and olfactoric analyses - Google Patents

Abstract

In the present invention, there is disclosed a scent sensor being formed by a specific nanofibrous carrier for sensing and storage of scent trails, particularly for criminal technique, but also for use in a widest possible extent, including health service. The nanofibrous carrier is made of amphophilic materials, preferably of polyvinyl alcohol (PVA), or of polyvinyl butyral (PVB), or of polyvinyl pyrolidone (PVP). The scent trail sensor is made in a dust-free environment from materials with low scent background and additionally scent-exactly defined. The nanofibrous carrier is soluble inclusive of all substances in differently polar solvents. This enables to also apply other detection methods such as liquid chromatography and to lower s detection limit.

Description

Nanofiber odor trace sensor for olfactronic and olfactory analysis

Field of technology

The technical solution concerns materials for sensing and storing odor traces, especially for forensic technology, but also for use on the widest possible scale.

Prior art

Odor identification serves to identify a specific person through the odor trail created by him. Forensic odorology examines odor traces using analytical instruments (the so-called olfactronic method) or using animals, especially dogs (the so-called olfactory method). At present, odor marks in police practice are ensured by means of a non-woven fabric, which is composed of 75% cotton and 25% viscose. In the olfactory method, the odor sensor is then sniffed by a dog, in the olfactorial method it is then inserted into a detection device, typically a chromatograph, from where the odor traces are carried by a carrier gas into an injector and fed to the column for analysis.

Small liquid traces are provided in a similar way. The tracks are soaked in small nonwoven pads for later analysis.

The disadvantage of current approaches is the relatively high detection limit. Indeed odor traces usually contains only a very small amount of material suitable for analysis, estimated at 10 ⁹ to 10 grams. The concentration of this amount of volatile substances in a small volume is therefore not only essential for a reliable analysis by the olfatronic method, but absolutely essential for the olfactory approach. Currently used fabrics for securing odor traces are characterized by the fact that they are not prepared in an odor-clean environment, and are therefore characterized by a relatively high odor background. Another disadvantage of the application of current types of odor traps is their minimal polarity variability. Gauze or applied nonwoven fabric captures hydrophilic and hydrophobic odor molecules based on surface adhesion. However, low concentrations of highly hydrophilic and highly hydrophobic odor trace molecules can be adorated at very low concentrations, which may not easily reach the detection limit. However, these molecules may be essential for odor identification of the object. There are many indications that these missing molecules may be the cause of the occasional failure to identify an object by a dog, which in turn reduces the credibility of identifying an object by a dog and rejects it as forensic evidence.

A disadvantage of current approaches is also the analysis of the odor trace, which is typically carried out in the form of vapors which enter the gas chromatograph column at an elevated temperature for analysis. This approach partially eliminates the high odor background of currently used odor traps. In this way, however, the concentration of molecules to be analyzed is relatively considerably reduced, which is practically limited to gas chromatography.

The essence of the invention

The essence of the technical solution according to the present invention is, inter alia, the replacement of the nonwoven fabric of the odor sensor by a specific nanofiber carrier. The invention solves the disadvantages of the prior art, inter alia also because the odor sensor according to the invention can be easily prepared in an odor-clean environment, from materials with a low odor background, in addition to the odor precisely defined.

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The proposed invention allows both the collection of traces with high sensitivity, the concentration of odor molecules in a small volume and also their conversion into polar and non-polar solvents. In addition, the odor sensor according to the invention can easily be prepared from materials of different polarity.

The technical solution according to the invention allows the dissolution of all substances, including the carrier, in various polar solvents. This, on the one hand, ensures a higher concentration of molecules for analysis and, on the other hand, expands the application of other detection methods (eg liquid chromatography), which leads to a lowering of the detection limit.

The odor sensor according to the invention is characterized in that it comprises a nanofibrous support which is formed of either an amphiphilic or at least one hydrophobic or hydrophilic polymer, typically both simultaneously. Nanofibers are characterized by low basis weight and excellent sorption properties. The application of these nanofibrous materials therefore overcomes the possible limits of current odor sensors and thus achieves greater detection accuracy, or identification of the subject from a smaller amount of material. The application of a nanofiber layer prepared from a polymer of defined polarity will then allow the construction of an odor trace sensor for the selective adhesion of polar and non-polar molecules. The increased selectivity for selected substances may be completely specific, mainly due to the possibility of modifying the nanofiber layer of specificity with a specific antibody with the ability to bind a specific antigen. The sensor prepared in this way has a real chance to be included among the court evidence.

In the case of a hydrophilic material, typically polyvinyl alcohol (PVA), this material can be crosslinked or otherwise modified after the formation of the nanofiber structure in a controlled manner so that the resulting product decomposes in a time interval to be predetermined by the user. The result of such a crosslinked material is, on the one hand, the removal of a gaseous or liquid trace with high efficiency and sensitivity, and, on the other hand, the possibility of simple conversion of the entire system, including the removed material, into a liquid state. The sample thus prepared can then be analyzed by highly sensitive analytical methods, typically chromatographically or using fluorescent labels or antibody applications. By applying antibodies, it is possible to obtain specific evidence convicting the offender.

Examples of embodiments of the invention

Example 1

Odor sensor based on nanofiber carrier prepared from synthetic polymer polyvinyl butyral (PVB). Sensor for capturing gaseous or liquid traces based on a nanofiber support prepared from an amphiphilic material, typically polyvinyl butyral (PVB). This nanofiber textile carrier serves as an adhesive system for collecting odor traces of both hydrophilic and hydrophobic character. The sensor can also be characterized in that the outer layer can be removed after exposure in a gaseous or liquid sample or used directly as such for transfer to a liquid medium for further analysis.

Example 2

Odor sensor based on nanofiber carrier prepared from synthetic polymer polyvinyl butyral (PVB). Sensor for capturing gaseous or liquid traces based on a nanofiber carrier prepared from an amphiphilic material, typically polyvinylpyrilidone (PVP). This nanofiber textile carrier serves as an adhesive system for collecting odor traces of both hydrophilic and hydrophobic character. The sensor is also characterized in that the outer layer can be removed after exposure in a gaseous or liquid sample or used directly as such for transfer to a liquid medium for further analysis.

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Example 3

An odor sensor formed in such a way that at least one of its layers, preferably the outer layer, is formed by a nanofiber carrier of hydrophobic material. This outer layer serves as an adhesive system for collecting odor marks. The sensor is also characterized in that the outer layer can be removed after exposure in a gaseous or liquid sample or used directly as such for transfer to a liquid medium for further analysis.

Example 4

An odor sensor formed in such a way that at least one of its layers, preferably the outer layer, is formed by a nanofibrous carrier made of polyvinyl alcohol (PVA) suitable for subsequent chemical or physical crosslinking, which is subsequently partially crosslinked by glyoxal concentration so that its PVA half-life is 5 to 10 minutes.

Example 5

An odor sensor formed in such a way that at least one layer thereof, preferably an outer layer, is formed by a nanofiber carrier of a hydrophilic synthetic polymer suitable for subsequent chemical or physical crosslinking, which is subsequently partially crosslinked with a glyoxal concentration such that the PVA half-life is 5 to 10 minutes.

Example 6

An odor sensor formed in such a way that at least one of its layers, preferably the outer layer, is formed by a nanofibrous support of a hydrophilic natural polymer suitable for subsequent chemical or physical crosslinking, which is subsequently partially crosslinked by glyoxal concentration such that the PVA half-life is 5 to 10 minutes.

Example 7

The odor trace sensor for capturing a gaseous or liquid trace is formed on the basis of a nanofiber carrier, at least one layer thereof, preferably an outer layer, consisting of a partially nanofiber carrier of polyvinyl alcohol (PVA) suitable for subsequent chemical or physical crosslinking, and a partially hydrophobic nanofiber. layer. In practice, these are alternating stripes, concentric circles or other geometric shapes alternating from hydrophilic and hydrophobic material. The hydrophilic polymer nanofiber layer is then crosslinked in any known manner. An antibody that has the ability to specifically bind a characteristic protein or other specific antigen is bound to the surface thus treated.

Example 8

The odor sensor for removing gaseous and liquid traces is formed on the basis of a nanofiber carrier, at least one layer thereof, preferably an outer layer, consisting of a partially nanofiber carrier made of polyvinyl butyral (PVB) suitable for subsequent chemical or physical crosslinking, and a partially hydrophobic nanofiber layer. . In practice, these are alternating stripes, concentric circles or other geometric shapes alternating from hydrophilic and hydrophobic material. The nanofiber layer of hydrophilic polymer is then subsequently crosslinked by any known method

-3CZ 305903 B6 sobem. An antibody that has the ability to specifically bind a characteristic protein or other specific antigen is bound to the surface thus treated.

Example 9

The odor trace sensor for removing gaseous and liquid traces is formed on the basis of a nanofiber carrier, wherein at least one layer thereof, preferably an outer layer, consists of a partially nanofiber carrier of polyvinylpyrilidone (PVP) suitable for subsequent chemical or physical crosslinking, and a partially hydrophobic nanofiber layer. . In practice, these are alternating stripes, concentric circles or other geometric shapes alternating from hydrophilic and hydrophobic material. The nanofiber layer of hydrophilic polymer is then subsequently crosslinked in any known manner. An antibody that has the ability to specifically bind a characteristic protein or other specific antigen is bound to the surface thus treated.

Example 10

The odor trace sensor for capturing the gaseous and liquid traces is formed on the basis of a nanofiber carrier, at least one layer thereof, preferably an outer layer, consisting of a partially nanofibrous carrier of hydrophilic synthetic polymer suitable for subsequent chemical or physical crosslinking, and a partially hydrophobic nanofiber layer. In practice, these are alternating stripes, concentric circles or other geometric shapes alternating from hydrophilic and hydrophobic material. The nanofiber layer of hydrophilic polymer is then subsequently crosslinked in any known manner. An antibody that has the ability to specifically bind a characteristic protein or other specific antigen is bound to the surface thus treated.

Example 11

The odor trace sensor for capturing the gaseous and liquid traces is formed on the basis of a nanofiber carrier, at least one layer thereof, preferably an outer layer, consisting of a partially nanofiber carrier of natural polymer suitable for subsequent chemical or physical crosslinking, and a partially hydrophobic nanofiber layer. In practice, these are alternating stripes, concentric circles or other geometric shapes alternating from hydrophilic and hydrophobic material. The nanofiber layer of hydrophilic polymer is then subsequently crosslinked in any known manner. An antibody that has the ability to specifically bind a characteristic protein or other specific antigen is bound to the surface thus treated.

Industrial applicability

The technical solution according to the invention finds its use and application especially in the field of sensing and storing odor traces, especially for forensic technology, but also for use on the widest possible scale, e.g., among others, customs authorities, healthcare and the like.

Claims (4)

PATENT CLAIMS A nanofiber odor sensor for olfactronic and olfactory analysis, characterized in that it is formed on the basis of a nanofibrous support of prepared polyphinyl alcohol (PVA) or polyvinyl butyral (PVB) or polyvinylpyrilidone (PVP) materials. 2. A nanofiber odor sensor for olfactronic and olfactory analysis, characterized in that at least one layer thereof is formed by a nanofiber carrier prepared from polyvinyl alcohol (PVA) or another hydrophilic synthetic or natural polymer and the other layer is formed by a carrier of hydrophobic material. Nanofiber odor sensor, according to claim 2, characterized in that its second layer is formed by a nanofiber carrier of polyvinyl alcohol (PVA), polyvinyl butyral (PVB), polyvinylpyrilidone (PVP) or combinations thereof or a synthetic or natural polymer suitable for subsequent chemical or physical crosslinking and the second layer is formed by alternating stripes or concentric circles or other geometric shapes of hydrophilic and hydrophobic material. A nanofiber odor sensor according to the preceding claims, characterized in that the nanofiber carrier is physically modified and a specific antibody capable of binding a specific antigen is bound to its surface.