Patent Description:
The present-day illicit drug trade is a large, lucrative, global industry. Technological advances and the ingenuity of rogue chemists continues to present ongoing challenges for law enforcement authorities and for scientists and engineers developing the technology to support them.

In recent years, the recreational drug market has seen an increase in the abuse of Drug Analogues and New Psychoactive Substances, known collectively as (DANPS). DANPS are substances that are structurally or functionally similar to a prohibited or scheduled parent compound. They are of great concern due to the number and diversity of compounds involved and a lack of knowledge about their mode of action, side effects and toxicity. DANPS are often deliberately mislabelled by suppliers in order to avoid legal barriers (cathinones are often labelled "bath salts"), or they are presented to customers as "legal" alternatives to illicit drugs.

One particular class of DANPS are the cathinones. Cathinones are psychoactive compounds which can be a relatively inexpensive alternative to more established drugs. Synthetic cathinones as a class have accounted for the highest proportion of DANPS seizures in Australia since <NUM>. In <NUM>-<NUM>, the number of synthetic cathinone seizures made up <NUM> per cent of those analysed. Similar trends have been observed elsewhere in the world, for instance, in Europe.

The general chemical structure of synthetic cathinones is shown below.

R<NUM>, R<NUM>, R<NUM> and R<NUM> can be modified independently to provide and an almost unlimited number of cathinone-type substances.

In order to prosecute offenders, it is necessary to be able to identify the drugs involved. Like most small molecules, cathinones can be identified by techniques such as Gas Chromatography-Mass Spectrometry (GC-MS) and High Performance Liquid Chromatography-Mass Spectrometry (HPLC-MS) and comparison with reference libraries and reference standards. These techniques combine separation power with spectroscopic analysis and are considered to be the 'gold standard' for routine analysis. Although these tests are highly reliable, such instruments are not ideal for high throughput sample analysis owing to their high cost of running, the need for trained personnel, lengthy analysis times, and optimization and maintenance requirements.

The large number of illicit drug seizures means that simple, rapid, inexpensive, and accurate field tests are highly desirable.

Presumptive screening tests are designed to provide an indication of the presence or absence of certain drug classes in a test sample. They need to be simple to carry out and sufficiently reliable such that they can form the basis for detaining suspects until definitive tests can be completed.

Colour 'spot' tests are a particularly useful type of field test that result in a colour change when applied to a sample containing a drug of interest. The chemical reaction occurring between the colour reagent and the drug of interest provides a very rapid first line screening tool which can, in some cases, be quite selective.

The increase in prevalence of synthetic cathinones in illicit drug seizures has resulted in a number of commercially available test kits for synthetic cathinones being developed. However, these tests often employ hazardous substances, demonstrate a lack of selectivity toward the cathinone class, or have not been screened on a large number of available synthetic cathinone substances. Inadequate screening tests can result in new psychoactive substances going undetected or being incorrectly identified.

Cathinone itself is a naturally occurring psychoactive alkaloid found in the Khat plant, which is native to Eastern Africa. Cathinone from the Khat plant was described by <NPL>. <NPL> describe a test regime that could be used to detect a range of synthetic cathinones. However, although this test showed good specificity, it was inherently unsuitable for field use as it required a heating step at <NUM> for at least <NUM> minutes in order to develop a suitable colour. Without heating, the test in Philp et al required around <NUM> hours to develop a suitable colour. The use of either a heating step or a lengthy time frame is unsuitable for field tests and is unlikely to be used by field officers.

<NPL>, describes the development and validation of a presumptive color test method employing test reagent, copper(II)-<NUM>,<NUM>-dimethyl-<NUM>,<NUM>-phenanthroline (Cu(ll)-neocuproine). The procedure is based on the reduction of copper(II) to copper(I) in the presence of the drug, followed by formation of a yellow-orange colored complex with maximum absorbance at <NUM>. The highly stable Cu(ll)-neocuproine test reagent has potential for use in preliminary screening of unknown samples for cathinones in forensic laboratory testing.

<NPL>, describes the potential avenues for creating and developing new optical screening methods for the class of NPS, the synthetic cathinones. Chapter <NUM> specifically describes the development of a chemical colour spot test using the reaction between synthetic cathinones and the neocuproine reagent to produce a chromophoric compound. Chapter <NUM> further describes eliminating the potential limitations of the protocol. This included the requirement for heating, and the false negative results observed with several cathinone analogues. The improved chemical colour test protocol was successfully achieved through the use of a small amount of organic solvent to extract the coloured product and metal halide salts that behaved as a catalyst.

It is an object of the present invention to overcome or ameliorate at least one of the disadvantages of the prior art, or to provide a useful alternative.

According to a first aspect the invention provides a method of detecting the presence of a cathinone moiety in a sample, as further defined in the accompanying claims.

According to a second aspect, the invention provides a method of detecting the presence of a cathinone moiety in a sample, the method comprising the steps of:.

According to a third aspect, the invention provides a method of detecting the presence of a cathinone moiety in a sample, the method comprising the steps of:.

According to a fourth aspect, the invention provides the use a test reagent for detecting the presence of a cathinone moiety in a sample, the reagent comprising neocuproine, a source of copper(II) and an alkali metal halide catalyst as further defined in the accompanying claims.

Preferably, the colour change is observed at environmental temperature within <NUM> minutes, more preferably within <NUM> minutes and most preferably within <NUM> minutes.

The solution is preferably an aqueous solution.

The buffer is preferably a mild acidic buffer to keep the pH in the range <NUM>-<NUM> or even <NUM>-<NUM>. An acetate buffer, such as sodium acetate is preferred.

The sample, the neocuproine, the source of copper(II), the catalyst and the buffer are added in any order or may be added simultaneously.

Preferably, the source of copper(II) is copper nitrate. Preferably the buffer is sodium acetate.

The catalys is selected from the group consisting of alkali metal halides, more preferably from the group consisting of lithium fluoride, potassium fluoride, potassium chloride. Most preferably the catalyst is lithium fluoride or potassium chloride. In one embodiment, the mechanical elements are beads, preferably the beads are selected from glass beads, polyethylene balls and polyvinyl acetate spheres and silica gel particles. Glass beads are most preferred. Preferably, the method is carried out in a malleable container, for example, a bag.

The methods of the present invention may also include the use of a discrete organic phase. In one embodiment, the discrete organic phase is denser than the aqueous phase. In that case, the organic phase may be, for example, dichloromethane or chloroform. In another embodiment, the organic phase is less dense than the aqueous phase. In that case, the organic phase may be a hydrocarbon solvent, including but not limited to hexane or heptane for example, or it may for instance be ethyl acetate.

Preferably, the organic phase has a volume less than a volume of the aqueous phase. In some embodiments, the method takes place in a vessel having a reduced or tapering cross section at a lower portion of the vessel. In other embodiments, non-tapered vials, such as GC vials, may be used. Those skilled in the art will readily be able to select a suitable vial type based on the specific intended use.

In the present invention, the sample may be an unknown drug sample, or the sample may be a biological fluid including, for example saliva, blood or urine.

The method of the present invention may be useful, for instance, as a presumptive test for a suspected illicit substance, a presumptive test for a suspected overdose or a presumptive test in sport or workplace testing.

According to a fifth aspect, a kit for the detection of a cathinone moiety, the kit comprising the test reagent of the fourth aspect is herein described. The kit may further comprise a colour standard or comparison chart.

According to a sixth aspect, a strip for the detection of cathinone, the strip comprising a fibrous or paper substrate and deposited thereon an intimate mixture of neocuproine a source of copper(II) and sodium acetate is herein described.

The disclosure also describes devices for carrying out the methods of the present invention.

The term "environmental temperature" refers to the range of temperatures that would be expected to be present when field officers are conducting the presumptive tests, which would be any range of temperatures where humans can survive. Examples of environmental temperature ranges are, for instance, the range -<NUM> to <NUM>, <NUM> to <NUM> or <NUM> to <NUM>.

The chemical basis for the present test is based upon the reduction-oxidation reaction between the cathinone moiety and a copper(II)-neocuproine complex to form the highly coloured copper(I)-neocuproine chelate complex.

The proposed chemical basis for the reaction is shown below:
<CHM>.

<NUM>,<NUM>-Dimethyl-<NUM>,<NUM>-phenanthroline (neocuproine) is reacted with a source of copper(II), such as copper nitrate in the presence of a buffer, such as sodium acetate. The resultant product is the proposed copper(ll)-neocuproine complex. The copper(II)-neocuproine complex is a light blue colour but otherwise there is little absorbance in the visible part of the UV spectrum.

The copper(ll)-neocuproine complex, when contacted with a suitable reductant, such as the cathinone moiety, in the presence of heat, is oxidised to a copper(I)-neocuproine complex. The copper(I)-neocuproine complex is strongly orange coloured, having a significant absorbance peaking at around <NUM>. Thus, there is a very clear indication of the different species present. The UV visible spectrum for the copper(II)-neocuproine and the reduced, cathinone complexed form is shown in <FIG>. This clearly illustrating the dramatic increase in absorbance at around <NUM> that takes place upon cathinone complexation.

A very important factor for tests seeking to establish a presumptive test is their level of reliability. It is important that the test does not have too many false negatives (in this case, missing many cathinone derivatives), or too many false positives (leading to the detention of too many suspects that will ultimately not lead to convictions).

As shown in Philp et al, the neocuproine test was highly specific for cathinones.

The test in Philp et al against <NUM> cathinone samples showed a positive result in <NUM> of those cases. That is a positive detection rate of <NUM>%.

The test was carried out using the methods of the present invention (catalyst and discrete organic phase) against the same <NUM> cathinone samples and all of those showed a positive result. That is a positive detection rate of <NUM>%. Thus, the methods of the present invention enabled a significantly higher detection range than previously observed. The following table illustrates the range of cathinones tested:.

In addition to being able to reliably identify the class of substances targeted, a presumptive test should minimise the amount of false positives, i.e. should not give positive results on other substances. This is particularly the case in drug tests, where target substances are often adulterated with a variety of household chemicals.

The neocuproine test for cathinones was also carried out against a range of other recreational drugs. A sample of <NUM> drugs tested showed only <NUM> false positives.

The neocuproine test was also carried out against a range of bulking agents and adulterants commonly used. Again, out of <NUM> commonly used adulterants, only <NUM> gave a false positive test.

Thus, out of a range of <NUM> non-cathinone compounds tested, only <NUM> gave false positive results. The neocuproine test thus is able to detect about <NUM>% of cathinones and does not provide a false positive in more than about <NUM>% of substances commonly encountered in drug operations.

Another important factor for presumptive testing, alongside selectivity, is sensitivity. In Philp et al the he neocuproine test, under laboratory conditions, was shown to be capable of visualizing a colour change with just <NUM>µg of sample present. Accordingly, based on calculations using established principles, this would correspond to an operational detection limit of <NUM>µg. Of course, if the cathinone was present in much larger amounts, the colour developed much more rapidly.

Using the methods of the present invention, under laboratory conditions, it was shown to be possible to visualize a colour change with just <NUM>µg of sample present. Based on established principles, this would correspond to an improved operational detection limit of <NUM>µg.

The colour persisted for around four hours after reaching maximum intensity, which is sufficient for a presumptive test.

The test in Philp et al, when conducted on a small scale, involved the method being performed in a microwell plate using Pasteur pipettes to add drop-sized amounts of reagents. To a pin-head sized amount of seized material was added: Cu(II) (<NUM> × <NUM>-<NUM> mol/L, <NUM> drops), Neocuproine (<NUM> × <NUM>-<NUM> mol/L, <NUM> drops), acetate buffer (<NUM>, <NUM> drops) and the plate heated for <NUM> on a boiling water bath or hotplate. The colour development was then observed.

However, the test disclosed in Philp et al was unsuitable as a field test because of the requirement that the sample was heated.

The present inventors have found that adaptations of the test described in Philp can result in the test giving a definitive result in two minutes without the need to apply external heating.

It has been found that the addition of certain agents can function to activate or catalyse the reaction and lead to the formation of a coloured complex indicative of cathinone which is fully developed within a few minutes.

The table below shows the identity of the catalyst added to the well and the time taken for a colour change to occur was recorded. Catalyst addition after drug (<NUM>-MMC HCl (mephedrone)) and reagents was also tested. In the method and use of a test reagent of the invention, the catalyst is an alkali metal halide. The other catalysts are described for illustrative purposes only.

Suitable catalysts included alkali metal halides, such as sodium halides, potassium halides and lithium halides. Alkali metal fluorides, chlorides and bromides were also suitable. Most preferred from this group were lithium fluoride, potassium fluoride and potassium chloride.

Alternatively, catalysts having surface active modifications could also catalyse the reaction, such as silica gel, molecular sieves or Amberlyst A-<NUM>. Without wishing to be bound by theory, it is possible that these catalysts allow the coloured product to be adsorbed onto their surface and thus allow for a faster visualisation of any colour change.

Silica gel, KCI and KF showed fastest colour changes.

The use of the heat activators, KF and KCI significantly increased the rate of reaction which led to a faster colour change for all drugs tested (within <NUM> minutes). In addition, the colour intensity of the results was usually enhanced.

The most sensitive catalysts, those which required the least amount to provide the desired, faster result were LiF, molecular sieves, KCI.

Molecular sieves absorbed the coloured product and appeared orange. A range of molecular sieves was tested, 3Å, <NUM>Å and <NUM>Å, both activated and unactivated. The unactivated sieves worked significantly better than the activated sieves and the <NUM>Å sieves, with the smallest pore size, afforded the fastest colour change. <FIG> shows the colour change visible with molecular sieves.

In addition to the above, it has also been found that the application of mechanical stimuli to the reaction in the appropriate form can be used to further decrease the time required to achieve a positive result. A moderate degree of mechanical stimulation of the reaction would be acceptable in the context of field test.

Particularly, it has been found that the application of modest amounts of mechanical stimuli, in conjunction with the catalytic effect observed above, can lead to sufficient acceleration of the reaction to produce a clear presumptive result in a field test within the target time of two minutes.

A variety of mechanical elements ("microbeads") were tested, including glass beads, polyethylene balls and polyvinyl acetate spheres, silica gel particles. A hard bead surface is desirable to create more friction. It is also desirable if the mechanical elements are white so as to allow better visualisation of any colour change. Silica gel was quite useful as it could act as both a catalyst and mechanical stimulus with suitable hardness and colour.

Small polyethylene bags were used to contain the microbeads and provide the housing for the colour test 'device'. The cathinone sample, (approximately 100µg) and reagents were added sequentially, but again the order of addition was found to have no effect on the final outcome.

Gently rubbing the polyethylene bags during the course of the test was found to result in a further reduction in time required to fully develop the colour required for a positive cathinone test. Colour changes without the use of heat were observed in every case where mechanical stimulus was applied to an activated or catalysed test system. However, two combinations were found to be particularly useful - these were:.

In both the above cases, colour could be seen to develop after <NUM> seconds. A useable colour for a presumptive test was present after two minutes and the colour change was fully developed after <NUM> minutes. <FIG> shows the presence of colour developed by a variety of microbeads.

The use of catalysts significantly improved the rate of the reaction at environmental temperature. In combination with a friction mechanism or portable heating device, the colour test time is reduced to under <NUM> minutes at environmental temperature.

It has also been found possible to intensify the colour change developed by the reaction. This method involves the addition of a small amount of a solvent which is non miscible with the aqueous phase in which the reaction takes place. As the coloured complex develops, it is extracted into the non-miscible (organic phase) which, because of the smaller volume, leads to an increased concentration and increase in colour intensity.

Organic phases can include those that are less dense than water (ether or ethyl acetate) and form a top coloured layer, or those that are more dense than water (chloroform, dichloromethane etc) and form a coloured bottom layer. The addition of the bottom layer is preferred as the colour tends to be easier to observe if concentrated in the bottom of the tube. In addition, the tube can be shaped so as to reduce the effective volume of organic solvent and thereby intensify the colour density. For example, the tube can be tapered so that a small amount of intensely coloured dense solvent sits at the bottom of the tube and can be easily identified. The use of catalysts such as alkali metal halides is also thought to enhance the migration of the coloured complex into the organic phase by a salting out effect. However, the use of an organic phase alone, such as dichloromethane or chloroform, also appears to speed up the development of the colour. Without wishing to be bound by theory, it is possible that migration of the coloured complex into the organic phase assists in driving the equilibrium in the aqueous phase towards the complex.

A device suitable for detection the detection of the colour change is shown in <FIG>. A collection swab has an absorbent end section <NUM> which can be used to collect particles of the suspected drug material for collection. The absorbent portion is mounted on an elongate shaft <NUM> which connects to the inside of a cuvette lid <NUM>. In use, the absorbent end of the swab is inserted into the cuvette <NUM> and the cuvette lid is sealingly engaged with the cuvette. The cuvette contains the necessary aqueous reagents <NUM> to detect cathinone. Upon sealing engagement, the absorbent portion contacts the aqueous reagents and the complexation begins, thereby developing the necessary colour when a cathinone moiety is present. The cuvette as exemplified is of square cross section and has equal optical paths in the x-y plane. This would render the cuvette suitable for both naked eye and instrument detection.

In <FIG>, the cuvette <NUM> can also have an adjacent reference cuvette <NUM> integrally formed therewith, which would show the background solution colour and make the colour change more obvious.

In <FIG>, the cuvette <NUM> can also have another chamber <NUM> attached in proximity thereto which contains no reagents to allow for simultaneous collection and retention of a portion of the sample for further analysis in the event that the validity of the presumptive test is challenged.

A particular example of the test kit is shown in <FIG>. A collection swab <NUM> has an absorbent end section <NUM> which can be used to collect particles of the suspected drug material for collection. The absorbent portion <NUM> is mounted on an elongate shaft <NUM> which connects to the inside of a tube lid <NUM>. In use, the absorbent end of the swab is inserted into the tube <NUM> and the tube lid <NUM> is sealingly engaged with the tube, e.g. by means of interlocking threads <NUM>. The tube <NUM> contains the necessary aqueous reagents <NUM> and a dense organic layer <NUM>. Upon sealing engagement, the absorbent portion <NUM> contacts the aqueous reagents <NUM> and the complexation begins, thereby developing the necessary colour, which extracts into the organic layer <NUM>. The tube desirably has a reduced cross section at the lower portion to enable better examination of a small amount of solvent.

The lower tip shown in <FIG> is conical, although this is not a necessary condition and in many cases it is preferred that the reduced path has a lower portion of reduced cross section with a constant profile. A lower portion of reduced but constant square cross section for example may be more amenable for use in instrumental analysis.

It was noted that the order of addition of catalyst, cathinone, or neocuproine had no effect upon the final colour produced by the test. The relative amounts of the compounds were also found, within reason, not to impact on the outcome of the test. It is important to bear in mind that in the field, the amount of seized material tested, and the relative amount of cathinone contained therein will not be known with any precision. Field tests need to be quite robust and relatively insensitive to the exact amount of drug. The methods of the present invention are suitably robust and in general, the tests can be carried out using rough or approximate quantities of drug and reagent without obtaining a materially different test outcome.

The amount of the drug used or contained within the sample does however affect the time for the colour change to occur.

Also, a very large excess of neocuproine relative to copper resulted in inherent colour changes prior to contact with ant potential drug containing sample. However, those skilled in the art will readily be aware of the unsuitability of a coloured pre-prepared reagent prior to attempting any testing.

A porcelain well plate containing a neocuproine solution and copper II was treated with a sample of cathinone at environmental temperature. No colour change was detectable. A small amount of catalyst was then added and the mixture further observed for a short time, whereupon the distinctive yellow orange colour of the cathinone neocuproine complex was observed.

Similarly, a porcelain well plate containing a small amount of catalyst was treated with a sample of cathinone at environmental temperature. No colour change was detectable. A small amount of neocuproine was then added and the mixture further observed for a short time, whereupon the distinctive yellow orange colour of the cathinone neocuproine complex was again observed.

It was found that the test could be simplified significantly by combining the reagents together in a single test formulation. The three reagents: copper(II) nitrate, neocuproine and sodium acetate were combined into one solution in the ratio <NUM>:<NUM>:<NUM> molar ratio, respectively. This test solution was used on several drug samples and afforded results identical to those from adding the reagents sequentially. In addition, it was found that the test solution was effective for at least several months after preparation.

A potential drawback of any test that relies upon inspection by the naked eye is that there can be numerous factors impacting upon what would be considered to constitute a determinative colour change. This can be particularly challenging in the case of field tests for drugs where the lighting conditions and stresses on the analyst would generally be much less favourable than those in the laboratory. Instrumental analysis can help overcome this potential problem.

Non-limiting examples of some colorimetric analysis devices envisaged to be suitable for carrying out the tests described are shown in <FIG>. In all the examples shown, the device <NUM> has a cavity designed to hold a sample tube <NUM> and an inspection window or windows configured to allow spectroscopic analysis of a relevant coloured section of the material contained in the tube. The cavity is configured so as to generally occlude the rest of the tube apart from the inspection window or windows. This functions so as to provide controlled light conditions inside the device.

The specific device in 6A and 6A' has two opposed windows to allow a light from a light source <NUM> to enter from a first window <NUM> and exit to a detector <NUM> at an opposed window <NUM>. The detector could be any sort of visible detector, or even a simple RGB detector. In <FIG>, the tube <NUM> is of continuous cross section, whereas in 6A', it is of reduced cross section <NUM> at its lower end to accommodate the heavy organic phase with increased concentration of the coloured complex.

Alternatively, the device as shown in 6B and 6B' could have a single window <NUM> with an opposed reflective portion, where the light enters and exits via the same window <NUM>, after passing twice through the sample, before entering detector <NUM>. 6B' also has a region of reduced cross section <NUM>.

Alternatively, the device as shown in 6C and 6C' could be configured for hand held use. The device has a through passage <NUM> to enable visual inspection of the tube <NUM> (or reduced portion <NUM>) without interference. Light passing through the sample is simply observed with the naked eye. This aspect could advantageously contain a reference sample for side-by side comparison.

Colorimetric devices can be made in portable or mobile form, and the accompanying software can be configured to analyse the output of the RGB or other detector and provide simply a positive or negative result for the presence of a cathinone.

The present invention is also amenable to use in the form of a paper-based microfluidic test device. A strip of filter paper was spotted with <NUM>, <NUM>, <NUM>µL of each copper nitrate (<NUM>), neocuproine (<NUM>) and sodium acetate (<NUM>) solutions. The strip was allowed to dry. The dry strip was then dipped into a solution containing 4MMC, (<NUM>-methylmethcathinone). Exposure of the strip to mild warming led to development of a coloured spot characteristic of a cathinone moiety. The colour was clearly detectable after ten minutes. <FIG> shows the results of a positive cathinone test on a paper strip. A blank sample showed no such colour change.

The use of the strip in conjunction with a colorimetric detector would facilitate detection of the coloured complex indicative of cathinone in a short time. Such a test can be readily used for example in hospitals to screen for drugs (as part of an array of tests to diagnose potential overdoses) or as a part of a sport or work based drug testing policy, where the speed and simplicity of a presumptive test are desirable, but where a rapid conclusion is not essential.

As well as strips, the test would be amenable on other solid supports, such as beads.

It was also found possible to prepare the reagents in the form of a single part solution. The three reagents: copper nitrate, neocuproine and sodium acetate were combined into one solution in the ratio <NUM>:<NUM>:<NUM>, respectively. This test solution was used on several drug samples and afforded results identical to those from adding the reagents sequentially.

This single-part test solution was found to remain effective months after preparation. The use of a single-part solution will make the test method significantly simpler to use in the field.

It is known that after ingestion cathinone is partially excreted in the urine in unmetabolised form. Accordingly, the methods of the present invention, due to their selectivity and sensitivity are useful in detecting cathinone post use, where no trace of the undigested material is present.

A sample of blood, urine or saliva is subjected to the test methodology described above where a layer of organic solvent such as chloroform is included. The reaction to form the copper(I)-neocuproine takes place as described above and the coloured complex, where present, moves into the organic layer where it can be visually detected. The application of a test under such circumstances is qualitative however, it is highly useful as a rapid presumptive test particularly if a drug overdose is suspected.

The test described can be used in a standalone form, for cathinones only, but it is envisaged that it may be beneficial to employ the test as part of a kit of multiple distinct tests for various specific individual illicit substances. In this way, an unidentified sample can be subjected in parallel to many tests seeking to make a presumptive identification.

In one particular non-limiting embodiment, the test is as follows:
A few crystals of the drug material are placed into a micro test tube. A combined reagent solution is added.

The combined reagent solution contains three aqueous reagent solutions, copper(II) <NUM>, in the form of copper nitrate, neocuproine (<NUM>) and sodium acetate (<NUM>) in a <NUM>:<NUM>:<NUM> ratio. Chloroform (<NUM> drops, about. <NUM>) is added. Approximately <NUM> of salt is added. The tube is then shaken or flicked to allow adequate mixing.

The colour change is then observed - a good colour change was observed after <NUM> minutes, allowing for confirmation of the presence of cathinone moieties.

A number of synthetic cathinones were prepared and tested in the embodiments of the present invention and the results showed that the catalytic and mechanical acceleration did not affect the usefulness of the presumptive neocuproine test. The results are shown in the table below. The range of substituents chosen was considered to represent a selection of the range of substituents most commonly encountered in illicit seizures.

Claim 1:
A method of detecting the presence of a cathinone moiety in a sample, the method comprising the steps of contacting the sample with a solution comprising neocuproine, a source of copper(II) and an alkali metal halide catalyst to catalyse the formation of a cathinone neocuproine complex and observing a colour change, where present, that correlates with the presence of cathinone, and wherein the method takes place at environmental temperature.