The illicit consumption of psychoactive compounds may cause short and long-term health problems and addiction. This is also true for amphetamines and cocaine, which target monoamine transporters. In the recent past, an increasing number of new compounds with amphetamine-like structure such as mephedrone or 3,4-methylenedioxypyrovalerone (MDPV) entered the market of illicit drugs. Subtle structural changes circumvent legal restrictions placed on the parent compound. These novel drugs are effectively marketed "designer drugs" (also called "research chemicals") without any knowledge of the underlying pharmacology, the potential harm or a registration of the manufacturing process. Accordingly new entrants and their byproducts are identified postmarketing by chemical analysis and their pharmacological properties inferred by comparison to compounds of known structure. However, such a heuristic approach fails, if the structures diverge substantially from a known derivative. In addition, the understanding of structure-activity relations is too rudimentary to predict detailed pharmacological activity. Here, we tested a combined approach by examining the composition of street drugs using mass spectrometry and by assessing the functional activity of their constituents at the neuronal transporters for dopamine, serotonin, and norepinephrine. We show that this approach is superior to mere chemical analysis in recognizing novel and potentially harmful street drugs.
The illicit consumption of psychoactive compounds may cause short and long-term health problems and addiction. This is also true for amphetamines and cocaine, which target monoamine transporters. In the recent past, an increasing number of new compounds with amphetamine-like structure such as mephedrone or 3,4-methylenedioxypyrovalerone (MDPV) entered the market of illicit drugs. Subtle structural changes circumvent legal restrictions placed on the parent compound. These novel drugs are effectively marketed "designer drugs" (also called "research chemicals") without any knowledge of the underlying pharmacology, the potential harm or a registration of the manufacturing process. Accordingly new entrants and their byproducts are identified postmarketing by chemical analysis and their pharmacological properties inferred by comparison to compounds of known structure. However, such a heuristic approach fails, if the structures diverge substantially from a known derivative. In addition, the understanding of structure-activity relations is too rudimentary to predict detailed pharmacological activity. Here, we tested a combined approach by examining the composition of street drugs using mass spectrometry and by assessing the functional activity of their constituents at the neuronal transporters for dopamine, serotonin, and norepinephrine. We show that this approach is superior to mere chemical analysis in recognizing novel and potentially harmful street drugs.
The use of illicit psychoactive
drugs such as amphetamine and cocaine is widespread, and it has been
increasing on a worldwide basis.[1] These
drugs induce addiction and carry the risk of a number of serious side
effects. Hence, they represent a serious health risk and impose a
major burden on the healthcare systems.[2]Amphetamines and cocaine-like drugs target the monoamine transporter
family and bind with different affinities to the transporters for
dopamine (DAT), norepinephrine (NET), and serotonin (SERT).[3] Both drug types lead to a similar increase in
the concentration of monoamine neurotransmitters in the synaptic cleft,
but they differ markedly in their molecular mechanism of action.[4] Amphetamine and its congeners are substrates
of all three monoamine transporters, while cocaine and its derivatives
are nontransported inhibitors.[5] Amphetamines
increase the concentrations of neurotransmitters by inducing a current
through the transporter[6] and thereby reversing
the direction of transport.[7] In addition,
they competitively inhibit reuptake of the physiological substrate.[8] Cocaine is a transport inhibitor: it docks to
the outward facing conformation of the transporter at a site, which
overlaps with the substrate binding site.[9]Historically, both cocaine and amphetamines have been used
in clinical medicine. However, their addictive properties were soon
recognized, their medical use was tightly regulated and eventually
abandoned, and finally they were found on the illicit drug market.
Furthermore, alternatives have always been sought and marketed, in
part by exploiting legal loopholes. MDMA (3,4-methylendioxymethamphetamine,
“ecstasy”) is an early example; other so-called “designer
drugs” can be found as part of a group of compounds called “bath
salts” which include 3,4-methylendioxypyrovalerone (MDPV),
4-methylmethcathinone (mephedrone), and 3,4-methylendioxymethcathinone
(methylone). Recently, these latter compounds have been classified
as Schedule I controlled substances in the United States.[10] Importantly, these three “bath salt”
members are related to the family of plant-derived stimulant cathinones.
Other analogues are still sold and widely distributed over the Internet
as “legal highs” without apparently incurring a risk
of prosecution. At present, these “bath salts” are not
readily classified with respect to their pharmacological mechanism
of action: mephedrone[11] is believed to
be a substrate/releaser while MDPV solely acts as an uptake inhibitor.[12,13]Many modifications are apparently tolerated, if amphetamine
is used as a starting point; the same is true for the tropane ring
system and related moieties. There is a large incentive to explore
the pertinent chemical space and to create structural modifications
which exploit legal loopholes and are marketed by under the appealing
brand “designer drugs”. In fact, the illicit drug market
provides revenues that readily cover the costs of the underlying chemical
innovation. Issues of quality control and contaminants are only considered
minor sources of concern and hence do not raise production costs.
In addition, more recently, combinations of these drugs have also
been marketed deliberately, for instance a combination of MDPV and
mephedrone.[14]Novel psychostimulants
or “combo applications” will only be recognized by the
authorities, if drug dealers are arrested, illegal chemical laboratories
are found, or the drugs are obtained from drug users. In this arms
race, the illegal chemistry is always one step ahead. The crucial
point is to reduce the time lag between market entry of a compound
and its identification and classification. The prevention project
“CheckIt!” in Austria provides an important window of
opportunity to recognize novel drugs entering the market: drug users
can anonymously test the content of the drugs, which they have bought,
without risking criminal prosecution. This drug prevention initiative
is based in Vienna, but it also reaches out to people at various venues
where rave parties, other major events, and musical performances take
place. Samples are analyzed on site (a few milligrams scratched into
a test tube) by mass spectrometry (in a bus that has been
changed into a mobile laboratory) and tested for any major
psychostimulants known to be on the market. The drug user receives
the information on the content of his sample immediately after the
end of the analysis. If a sample does not contain the usual suspected
drug, it will be classified as “unknown”. These samples
are especially precious because they allow for documenting market
entry of a novel drug. The state-of-the-art chemical analysis provides
the structural information by examining the fragments generated during
mass spectrometry. However, it suffers from a major limitation: it
cannot gauge the biological activity of the novel drugs.[15] The current project aims at overcoming this
limitation: we established a bioassay that relies on different cell
lines expressing the human isoforms of SERT, DAT, NET, and the rat
transporter for GABA 1 (GAT1) as negative control to complement the
highly sensitive analysis by mass spectrometry. We provide a proof-of-principle
by examining four samples that had been sold as psychostimulants,
mostly amphetamine-like drugs: for lack of pharmacological data, they
were initially classified as unknown. Accordingly, we determined their
ability to inhibit substrate uptake and to induce transporter-mediated
release.
Results and Discussion
We tested four different anonymously
supplied samples obtained from drug consumers. The consumers voluntarily
contacted the Viennese project “CheckIt! Check your drugs”
to have their purchased drugs analyzed. The drugs had been purchased
by the drug consumers as either traditional amphetamines such as “ecstasy”
(sample A) and “speed” (sample D) or novel amphetamine-like
drugs of the type 'bath salt” such as “mephedrone”
(sample C). Sample B was purchased as “2C-B”, which
does not readily qualify as an amphetamine: “2C-B” (4-Bromo-2,5-dimethoxyphenethylamine)
primarily targets serotonin receptors.[16] Therefore, it serves as an ideal control, because “2C-B”
is predicted to neither exert any effect on monoamine transporters
nor on the GABA transporter-1. The initial analysis of the samples
was done by mass spectrometry and did not reveal any known pharmacological
active compound. Thus, the drugs were classified “of unknown
content”.Limits on the further analytical strategy were
imposed by the following considerations: (i) the amount that was supplied
by the drug consumers was obviously small (only a few milligrams were
obtained from the purchased drug samples). (ii) The concentration
of the unknown amphetamine-like compounds was unknown. (iii) One part
of the sample had already been used for the initial mass spectrometric
analysis and the sample was to be analyzed by high-resolution mass
spectrometry. Hence, a substantial fraction of the residual material
had to be set aside. We assessed the pharmacological nature of the
compounds by studying their interaction profile at SERT, NET, DAT,
and GAT1 employing HEK293 cells that expressed the human isoforms
of the monoamine transporters and the rat isoform for GAT1. First,
we analyzed if the compounds inhibited uptake of transporter substrates.
In a second approach, we also determined if they acted as releasers,
that is, they promoted substrate efflux from preloaded cells, which
is the hallmark of an amphetamine-like action. We included the cell
line expressing ratGAT1 for control purposes in the uptake inhibition
experiments: although the transport direction can be reversed by GAT1
substrates,[17] amphetamines do not exert
any activity at this member of the NSS family.[18] However, contaminants may increase cell permeability and
hence inhibit substrate uptake by a nonspecific action. Because of
the limited quantity of compound, each experiment was characterized
in a single experiment done in triplicate; a second experiment was
conducted to confirm the results. For the sake of completeness, it
should be mentioned that Rothman et al.[19] have developed high-throughput assays to assess transporter substrate
activity in rat brain synaptosomes. While such assays might not be
suitable for the rapid combined analyses described, the results from
rat brain tissue can serve as a physiologically relevant comparator
for data obtained from transfected cells expressing DAT, NET, or SERT.Concentration–response curves were generated for six reference
compounds, that is, MDMA, 4-fluoramphetamine, d-amphetamine,
methylone, mephedrone, and methamphetamine. This choice reflected
the illicit market situation and included abundantly distributed amphetamines
and more rarely found amphetamines. The selected compounds differ
in their selectivity for individual transporters. This is evident
from Figure 1, which allows for grasping the
profile of each compound. The IC50 values are given in
Table 1; both the IC50 values and
the profile served as reference points for the analysis of the drugs
of unknown content.
Figure 1
Uptake inhibition by reference compounds. HEK293 cells
stably expressing DAT, NET, SERT, or rGAT1 were used for uptake inhibition
assays. Uptake was inhibited by increasing concentrations of reference
compounds as indicated. Cells were incubated with the test compounds
for 5 min before the tritiated substrates were added to the incubation
buffer. The concentration of tritiated substrates was 0.03 μM
in the case of [3H]5-HT while 0.05 μM was used for
[3H]MPP+. The radioactive counts under basal
conditions (i.e., no drugs added) were as follows (n = 26 randomly chosen values, the following values are given as mean
± SEM): HEK-NET: 52252 ± 1867 cpm, blank: 4921 ± 1933
cpm. HEK-DAT: 30168 ± 2209 cpm, blank: 2892 ± 141 cpm. HEK-SERT:
44339 ± 4245 cpm, blank: 3703 ± 185 cpm. HEK-GAT1: 14964
± 628 cpm, blank: 3892 ± 272 cpm. These values were set
100% to normalize for interassay variation. Data are shown as means
± SEM of three independent experiments.
Table 1
Inhibition Profiles (IC50 values) of Different Amphetamines for Transport of [3H]5-HT by Human SERT and [3H]MPP+ by Human
DAT and NETa
SERT
NET
DAT
GAT1
MDMA
88.3 ± 12.1
12.4 ± 1.8
9.1 ± 3.8
n.d.
4-fluoramphetamine
94.83 ± 9.2
10.3 ± 0.3
9.5 ± 0.1
n.d.
d-amphetamine
110.0 ± 14.7
1.5 ± 0.1
1.45 ± 0.2
n.d.
methylone
63.3 ± 6.4
13.9 ± 1.3
4.21 ± 0.3
n.d.
mephedrone
25.64 ± 4.0
6.8 ± 0.6
98.8 ± 9.1
n.d.
methamphetamine
182.1 ± 83.1
1.3 ± 0.1
1.17 ± 0.6
n.d.
Uptake of [3H]GABA
by the rat GABA transporter-1 (GAT) was assessed as a control for
possible non-specific toxic actions. All values are given as mean
± SEM in PM. n.d.: not detectable.
Uptake inhibition by reference compounds. HEK293 cells
stably expressing DAT, NET, SERT, or rGAT1 were used for uptake inhibition
assays. Uptake was inhibited by increasing concentrations of reference
compounds as indicated. Cells were incubated with the test compounds
for 5 min before the tritiated substrates were added to the incubation
buffer. The concentration of tritiated substrates was 0.03 μM
in the case of [3H]5-HT while 0.05 μM was used for
[3H]MPP+. The radioactive counts under basal
conditions (i.e., no drugs added) were as follows (n = 26 randomly chosen values, the following values are given as mean
± SEM): HEK-NET: 52252 ± 1867 cpm, blank: 4921 ± 1933
cpm. HEK-DAT: 30168 ± 2209 cpm, blank: 2892 ± 141 cpm. HEK-SERT:
44339 ± 4245 cpm, blank: 3703 ± 185 cpm. HEK-GAT1: 14964
± 628 cpm, blank: 3892 ± 272 cpm. These values were set
100% to normalize for interassay variation. Data are shown as means
± SEM of three independent experiments.Uptake of [3H]GABA
by the ratGABA transporter-1 (GAT) was assessed as a control for
possible non-specific toxic actions. All values are given as mean
± SEM in PM. n.d.: not detectable.Next, we examined the unknown samples (termed samples
A–D). The unknown samples were sequentially diluted by a factor
of 10 to cover 6 orders of magnitude and tested for their ability
to inhibit substrate uptake. Figure 2 shows
the inhibitory profile of each sample. It is worth noting that none
of the samples inhibited uptake of [3H]GABA. This ruled
out a nonspecific action (e.g., due to cellular toxicity, pore formation,
or other mechanisms that dissipate the ionic driving forces)
Figure 2
Uptake inhibition
by unknown samples. The four unknown samples (A–D) were serially
diluted six times by a factor of 10. For uptake inhibition experiments,
the cells were treated exactly as described under the figure legend
for Figure 1. Data are shown as means ±
SEM of two independent experiments performed in duplicate
Uptake inhibition
by unknown samples. The four unknown samples (A–D) were serially
diluted six times by a factor of 10. For uptake inhibition experiments,
the cells were treated exactly as described under the figure legend
for Figure 1. Data are shown as means ±
SEM of two independent experiments performed in duplicateInspection of the graphs in Figure 2 reveals characteristic fingerprints of the compounds: The
first of the four samples shows a significant effect on all three
monoamine transporters at similar potency but exerted no effect at
GAT1. However, even under the assumption that the consumer bought
the sample as “ecstasy”, the inhibitory pattern resembled
none of our reference compounds. At best, it came close to the observed
pattern with MDMA with the difference that MDMA has a somewhat smaller
effect at NET and DAT; this was not seen in sample A: in contrast,
the effect on NET and DAT was slightly higher than that on SERT. Sample
B did not exert any appreciable effect at any of the monoamine transporters,
and GAT1 was also unaffected. This was not surprising since the customer
bought the sample under the label “2C-B”. Therefore,
this explains why no significant change from baseline was to be observed.
When we examined sample C, we observed a diverse inhibition pattern
with the strongest inhibition exerted at DAT, followed closely by
NET. SERT was inhibited at lower potency, and, again, GAT1 was completely
unaffected, a pattern seen with mephedrone (Figure 1A). Because of experimental uncertainty in dilution curves
with limited amounts of data points, methylone must also be taken
into account as an alternative that is still compatible with the data
(cf. Figures 1B and 2C). Our assignment is consistent with the fact that sample C was
sold under the name of “mephedrone”. The fingerprint
of sample D resembled the inhibitory pattern of methamphetamine or d-amphetamine, that is, equipotent inhibition of DAT and NET
and poor activity at SERT (cf. Figures 2D and 1E,F). This profile is also compatible with the fact
that sample D was sold under the name “speed”. This
finding was somewhat surprising because amphetamine or methamphetamine
ought to have been detectable by the initial mass spectrometric analysis.
Thus, after our initial pharmacological assessment of the unknown
samples, we suspected amphetamine-like drugs in samples A, C, and
D. As expected, sample B did not inhibit any of the transporters examined
in this study.Inhibition of uptake indicates that a compound
interacts with the transporter.[3] However,
it does not prove that a compound can induce transporter-mediated
efflux.[4] Therefore, we examined samples
A, C, and D for their ability to induce efflux. A superfusion assay
is the gold standard to test transporter-mediated efflux in synaptosomes
or slices prepared from animal tissue[2] or
in heterologous expressing cell lines.[20] Superfusion provides a robust assay format to assess transporter-mediated
efflux, because confounding effects arising form back diffusion are
eliminated.[21] The disadvantage of superfusion,
however, is the large volume of superfusate and hence the need of
a larger amount of the compound under study. In this project, however,
the amount of the samples was limiting. Accordingly, we resorted to
the batch-release assay originally established by Rudnick and co-workers.[22] In the batch-release assay, the amount of releasing
compound needed is much smaller since the typical volume is 0.1 mL.
We preloaded the cells with tritiated MPP+ for 20 min and
initiated efflux over a time of 10 min by exchanging the buffer containing
tritiated label by buffer that included the unknown samples. We tested
the batch-release assay and confirmed that (i) our monoamine transporters
expressing HEK293 cells responded to a concentration of amphetamines
at IC50 value (for DAT, d-amphetamine 1 μM;
for NET, d-amphetamine 1 μM; and for SERT, MDMA 10
μM) and (ii) this efflux was specific, that is, inhibited by
a saturating concentration of selective inhibitors (for DAT and NET,
mazindole 10 μM; and for SERT, paroxetine, 10 μM). A representative
example of the assay is shown in Figure 3A.
Next, we studied efflux induced by the unknown samples A, C, and D
by using a dilution which inhibited the uptake of the pertinent substrate
by 50%. We hypothesized that sample A would be equieffective in inducing
efflux by all three transporters. In contrast, sample C was predicted
to have a stronger effect on DAT and NET. Finally, sample D should
be devoid of any effect on SERT-mediated efflux. Figure 3 shows the results from the batch-release assays. As expected,
all efflux induced by samples A, C, and D was specific since application
of the selective reuptake blockers mazindole (“+M”)
and paroxetine (“+P”) inhibited efflux similar to the
example shown in Figure 3A. As hypothesized,
sample A promoted efflux through all three transporters with comparable
efficacy. However, sample C only caused a pronounced substrate efflux
through NET and elicited release by DAT, albeit to a lesser extent;
furthermore, SERT-mediated efflux was low. The effects elicited by
sample D were as predicted for amphetamine or methamphetamine; that
is, the sample elicited efflux via DAT and NET, but it was ineffective
in promoting release by SERT. In fact, sample D elicited even less
efflux in the absence of paroxetine than in its presence. The intriguing
result that efflux in the presence of paroxetine was even more pronounced
could at best be explained as follows: in earlier publications, we
described “efflux” caused by paroxetine and other reuptake
inhibitors.[20,21,23] However, what seemed to be “efflux” was finally confirmed
to simply be pseudoefflux caused by (i) substrate diffusing out of
the cells and (ii) inhibition of reuptake. In a subsequent study as
well as this study, we intended to prevent this pseudoefflux by using
the charged substrate MPP+. However, we cannot rule out
that organic cation transporters expressed in the HEK293 cells used
may play a role in this context.
Figure 3
Release. HEK293 cells stably expressing
DAT, NET, or SERT were used for batch-release assays. They were seeded
into 96-well plates, and all were incubated for 20 min with [3H]MPP+ (0.05 μM) for the sake of simplicity.
After a gentle wash, the cells were overlaid with buffer containing
test compounds in the presence or absence of blocker (+M denotes mazindole,
10 μM; +P stands for paroxetine, 10 μM) for 10 min. The
dilution of the test compounds was chosen to be at the IC50 value. At the end, the buffer was removed and the cells were lysed
and counted for radioactivity. All data are expressed as percent of
control, that is, HEK293 cells that had received buffer only. All
experiments have been performed two to three times in duplicate.
Release. HEK293 cells stably expressing
DAT, NET, or SERT were used for batch-release assays. They were seeded
into 96-well plates, and all were incubated for 20 min with [3H]MPP+ (0.05 μM) for the sake of simplicity.
After a gentle wash, the cells were overlaid with buffer containing
test compounds in the presence or absence of blocker (+M denotes mazindole,
10 μM; +P stands for paroxetine, 10 μM) for 10 min. The
dilution of the test compounds was chosen to be at the IC50 value. At the end, the buffer was removed and the cells were lysed
and counted for radioactivity. All data are expressed as percent of
control, that is, HEK293 cells that had received buffer only. All
experiments have been performed two to three times in duplicate.The results of the batch-release assay supported
the notion that the samples under investigation exert amphetamine-like
actions, because their releasing effect was reduced by coapplication
of specific uptake inhibitors.Taken togther the data supported
the classification of sample B as a compound unrelated to amphetamine,
sample C as a putative member of the bath-salt family including methylone
and mephedrone, and sample D as methamphetamine or d-amphetamine.
However, the profile of sample A was most reminiscent of MDMA although
its activity at DAT and NET was too strong. Therefore, we reanalyzed
all samples by more extensive mass spectrometry than was possible
under field (i.e., street) conditions. Table 2 summarizes the qualitative and quantitative results of this analysis.
The identification of the compounds contained in the samples was ultimately
based on a comparison of their UV spectra, MS data, and retention
time to those of reference substances. The latter two are also listed
in Table 2.
Table 2
Qualitative and Quantitative Results
of the Mass Spectrometry Analysis
sample
purchased
as
compounds identified
amount (mg/g)
molecular ion [M+H]+
monoisotopic mass [M+H]+/ [M-H]-
retention
time (min)
A
ecstasy
amphetamine
48
136
136.10
4.01
mCPP
166
197
197.08
5.73
metoclopramide
n.q.a
300
300.14
5.51
B
2C-B
2C-B
n.q.a
260
260.02
4.85
C
mephedrone
mephedrone
610
178
178.12
5.02
caffeine
132
195
195.08
3.54
D
speed
amphetamine
60
136
136.10
4.03
caffeine
276
195
195.08
3.54
paracetamol
110
152
152.06
1.95
acetylsalicylic acid
n.q.a
179.04b
1.81
Not quantified.
Acquired using negative ionization mode.
Not quantified.Acquired using negative ionization mode.Figure 4 shows the mass spectra
acquired during the standard HPLC-MS screening procedure. The prevalence
of all identified substances listed in Table 2 was verified by measuring the exact monoisotopic molecular masses
with a high resolution Q-TOF mass spectrometer and by calculating
their chemical formula from the exact mass. Interestingly, sample
A contained a mixture of two psychostimulants: amphetamine and m-chlorophenylpiperazine (mCPP): this fact explains the
strong effect at SERT, which would not have been observed with amphetamine
alone: mCPP has been recognized earlier as a potent 5-HT releaser.[24−27] It is one of the most striking findings of the present study that
sample A is a so-called “combo”, a mixture of two different
psychostimulants. Such “combos” are often sold to customers
without their knowledge. “Combos” have already been
described in the literature;[14] they can
also be found on Internet portals in reports by drug consumers (www.erowid.org) and, most recently, even in the statistical
report on drug use in Austria (www.oebig.at). Typically,
combinations of drugs exert different side effects; synergism (i.e.,
overadditive effects) is not only seen for the intended actions but
can result in more debilitating adverse effects.
Figure 4
HPLC mass spectrometry.
Mass spectra of drugs acquired during standard HPLC screening procedure
under following conditions: ionization mode, ESI; polarity, +ev; probe
temperature, 280 °C; cone, 60 V; scan time, 1 s; x-axis, mass to charge ratio (m/z); y-axis, relative abundance (%).
HPLC mass spectrometry.
Mass spectra of drugs acquired during standard HPLC screening procedure
under following conditions: ionization mode, ESI; polarity, +ev; probe
temperature, 280 °C; cone, 60 V; scan time, 1 s; x-axis, mass to charge ratio (m/z); y-axis, relative abundance (%).The exact nature of sample D was still not unraveled
even after extensive reanalysis using a unit-resolution mass spectrometer
(Figure 5). Therefore, sample D was reanalyzed
using high resolution mass spectrometry to identify the two unknown
substances found in the primary screening. Finally, amphetamine and
acetylsalicylic acid were identified by direct injection into a high
resolution Q-TOF-MS followed by MS/MS. The values shown in Table 2 are the results of this high-resolution mass spectrometry.
Figure 5
HPLC mass
spectrometry. HPLC chromatogram (UV detection trace at 215 nm) of
the complex sample D containing acetylsalicylic acid, paracetamol,
caffeine, amphetamine, and the internal standard using the separation
conditions as described in the Methods section.
HPLC mass
spectrometry. HPLC chromatogram (UV detection trace at 215 nm) of
the complex sample D containing acetylsalicylic acid, paracetamol,
caffeine, amphetamine, and the internal standard using the separation
conditions as described in the Methods section.This result matches the predictions reasonably
well. In addition, it also substantiates the claim of the drug dealer
who sold the drug to the consumer under the brand name “speed”.
The adulteration by acetylsalicylic acid is not uncommon;[28] it is used to dilute psychostimulants, presumably
because it is readily available and it elicits a strong taste sensation,
which is suggestive of high drug content.It is evident that
medical professionals, street workers, and legal authorities face
an uphill battle in their attempt to confront the recent shifts in
the use of illicit drugs. One of the challenges is to remain up-to-date
in recognizing novel psychostimulants or new combinations of compounds
in various segments of the illicit marketplace. This is due to the
limits imposed by their detection. As exemplified in the current study,
we initially failed to identify rather common psychostimulant drugs
by mass spectrometry, but the bioassay employed was indeed sensitive
enough to detect the amphetamine-like actions of the drugs. In addition,
this assay reliably discriminated the various amphetamine-like drugs
from “2C-B” (or similar structural analogues). It also
deciphered the “combo” of amphetamine and mCPP. Hence,
it provides a relatively rapid screening tool that allows for sensitive
pharmacological detection of novel amphetamine-like drugs and unknown
“combo” applications. We are currently working on possibilities
to also assess release and uptake in a mobile format on-site, in parallel
to the mass spectrometry analysis. This may open an avenue to establish
an early warning system given the surge of novel compounds that reach
the markets, including formerly “legal highs”,[11] clinical implications that these drugs possess,[29] necessitates such a pharmacological assay as
an important tool to quickly respond to the rapidly changing market
conditions.
Methods
Materials
Dulbecco’s modified Eagle’s
medium (DMEM) and trypsin were purchased from PAA Laboratories GmbH
(Pasching, Austria). Fetal calf serum was purchased from Invitrogen.
[3H]5-HT ([3H]5-hydroxytryptamine; serotonin;
28.3 Ci/mmol) and [3H]GABA (35 Ci/mmol) were purchased
from PerkinElmer, Boston, MA. [3H]1-Methyl-4-phenylpyridinium
(MPP+; 85 Ci/mmol) was supplied by American Radiolabeled
Chemicals (St. Louis, MO). Serotonin (5-HT), s-(+)-3,4-methylenedioxymethamphetamine
(MDMA), paroxetine, methamphetamine, and d-amphetamine were
purchased from Sigma. Mephedrone and methylone were purchased from
Serobac (Vienna, Austria). 4-Fluoramphetamine was obtained from Lipomed,
Arlesheim, Switzerland. 1-Methyl-4-phenylpyridinium ion (MPP+) was purchased from Research Biochemicals International, Natick,
MA.
Sample Collection and Preparation
The samples used
in this study were obtained from drug users participating voluntarily
and anonymously in the Checkit! program. Three to ten milligrams of
substance were scraped into a test vial and weighed with an analytical
balance. The substance was diluted in 1 mL of methanol and vortex
mixed for 1 min. The solution was centrifuged for 3 min at 13 200
rpm/min. Ten microliters of the supernatant were diluted with 400
μL of internal standard solution (trazodone 50 μg/mL dissolved
in 10 mM aqueous ammonium formate buffer).
LC-ESI-MS Conditions of the Standard Screening Procedure
The samples were analyzed by employing an LC-Packings Ultimate High
Performance Liquid Chromatography (HPLC) system (Dionex, Netherlands)
equipped with a Dionex PDA-100 photodiode array detector and coupled
with a Finnigan Surveyor MSQ plus mass spectrometer (Thermo Electron
Corporation, San Jose, CA) with an ESI-probe. Separation was performed
on a 2.1 × 150 mm Luna PFP column (Phenomenex; Torrance, CA)
using fast gradient elution with 10 mM aqueous ammonium formate buffer
(pH 4.5) and acetonitrile (ACN), starting from 10% ACN and 90% buffer
at 0.0 min to 90% ACN and 10% buffer at 6.0 min with a total run time
of 7.5 min. The flow rate was set to 300 μL/min. Five microliters
of sample solution was injected into the HPLC system. After separation,
compounds were detected simultaneously by the PDA and the mass spectrometer.
The operation of the LC-MS and chromatographic analysis was carried
out by using Dionex Chromeleon 6.8 (SR 7) chromatography software.
For the identification of the compounds, retention time, UV spectra,
and mass spectra were obtained and compared to those of reference
substances previously measured. The quantitation was achieved by UV-detection
at a wavelength of 254 nm.
High Resolution ESI-Q-TOF Mass Spectrometric Analysis
Unidentified substance peaks acquired during standard screening were
subjected to an in-depth analysis: the sample solution was again diluted
with methanol to a concentration of approximately 10 μg/mL and
injected directly into the Q-TOF-MS (maXis, Bruker Daltonik GmbH,
Germany) instrument with a syringe pump at a flow rate of 5 μL/min.
The instrument used under the described conditions provided a mass
resolution of 50 000. Eligible molecular ions, known form the
previous HPLC-MS analysis, were identified, and MS/MS was performed
and recorded (ionization mode, positive and negative; capillary, 1.5
kV; temperature, 150 °C; collision energy, 10–30 eV).
MS and MS/MS spectra were interpreted, and elementary formulars were
calculated from the exact masses using Bruker Daltonics DataAnalysis
4.0 software.
Uptake and Release Assays
The generation of HEK293
cell lines expressing hSERT, hNET, hDAT, or rGAT1 (HEK-SERT, HEK-DAT,
HEK-NET, or HEK-GAT1, respectively) is described earlier.[7,17,30] hSERT was expressed under the
control of a tetracycline inducible promoter.[7]HEK293 cells stably expressing either neurotransmitter transporter
were seeded onto poly-d-lysine-coated 48-well plates (0.5
× 105 cells/well), 24 h prior to the experiment. For
inhibition experiments, the specific activity of the tritiated substrate
was kept constant: [3H]GABA, 0.03 μM; [3H]MPP+, 0.03 μM; [3H]5-HT, 0.03 μM.Assay conditions were as outlined.[31] In brief, the cells were washed thrice with Krebs–Ringer–HEPES
buffer (KHB; composition: 25 mM HEPES·NaOH, pH 7.4, 120 mM NaCl,
5 mM KCl, 1.2 mM CaCl2, and 1.2 mm MgSO4 supplemented
with 5 mM d-glucose). Then, the diluted reference and sample
compounds were added and incubated for 5 min to allow for equilibration
with the transporters. Subsequently, the tritiated substrates were
added and the reaction was stopped after 5 min. Cells were lysed with
SDS 1% and counted in a beta-counter (Packard instruments). All determinations
have been performed in duplicate or triplicate.For release
studies, HEK-SERT, HEK-NET, or HEK-DAT cells were grown in 96-well
plates (4 × 104 cells per well). The cells were preloaded
with 0.05 μM [3H]MPP+ for 20 min at 37
°C in a final volume of 0.1 mL/well. The cells were incubated
with the test compounds after three gentle wash steps with Krebs–Ringer–HEPES
buffer at room temperature. d-Amphetamine was used in release
assays as reference compound for all three monoamine transporters.
All compounds were used at the dilution where a 50% inhibition of
substrate uptake was observed during the uptake assays. The specificity
of drug-induced release was assessed by the addition of inhibitors
mazindole (10 μM; for DAT and NET), paroxetine (10 μM;
SERT), and tiagabine (10 μM; GAT1) to the test compound. After
10 min, the incubation buffer was removed and transferred into a counting
vial; the cells remaining in the well were overlaid with a 1% SDS
solution, thereby disintegrated and the resulting solution transferred
into a counting vial. All samples were subjected to standard liquid
scintillation counting (Packard Instruments). All determinations have
been performed in triplicate. The sum of the counts in the incubation
buffer and the cell lysate reveal 100% of [3H]MPP+ included in the assay. Hence, this sum is the control value to which
the released [3H]MPP+ is calculated as percentage:
the data shown in Figure 3 are expressed as
released [3H]MPP+ in percent of control, that
is, the sum of [3H]MPP+ released to the incubation
buffer and the [3H]MPP+ in the cell lysate.
Data Analysis
Data from uptake inhibition experiments
were fitted by nonlinear, least-squares curvilinear regression to
an equation for a rectangular hyperbola. The fit was not improved
by employing a logistic equation (Hill equation). The program used
to perform the fit was GraphPad Prism version 5.0d for MacOsX, GraphPad
Software, San Diego, CA, www.graphpad.com.
Authors: F Ivy Carroll; Anita H Lewin; S Wayne Mascarella; Herbert H Seltzman; P Anantha Reddy Journal: Ann N Y Acad Sci Date: 2011-11-17 Impact factor: 5.691
Authors: Stefan Seidel; Ernst A Singer; Herwig Just; Hesso Farhan; Petra Scholze; Oliver Kudlacek; Marion Holy; Karl Koppatz; Peter Krivanek; Michael Freissmuth; Harald H Sitte Journal: Mol Pharmacol Date: 2005-01 Impact factor: 4.436
Authors: L D Simmler; T A Buser; M Donzelli; Y Schramm; L-H Dieu; J Huwyler; S Chaboz; M C Hoener; M E Liechti Journal: Br J Pharmacol Date: 2013-01 Impact factor: 8.739
Authors: Sonja Sucic; Stefan Dallinger; Barbara Zdrazil; René Weissensteiner; Trine N Jørgensen; Marion Holy; Oliver Kudlacek; Stefan Seidel; Joo Hwan Cha; Ulrik Gether; Amy H Newman; Gerhard F Ecker; Michael Freissmuth; Harald H Sitte Journal: J Biol Chem Date: 2010-01-29 Impact factor: 5.157
Authors: Michael H Baumann; John S Partilla; Kurt R Lehner; Eric B Thorndike; Alexander F Hoffman; Marion Holy; Richard B Rothman; Steven R Goldberg; Carl R Lupica; Harald H Sitte; Simon D Brandt; Srihari R Tella; Nicholas V Cozzi; Charles W Schindler Journal: Neuropsychopharmacology Date: 2012-10-17 Impact factor: 7.853
Authors: Oliver Kudlacek; Tina Hofmaier; Anton Luf; Felix P Mayer; Thomas Stockner; Constanze Nagy; Marion Holy; Michael Freissmuth; Rainer Schmid; Harald H Sitte Journal: J Chem Neuroanat Date: 2017-06-12 Impact factor: 3.097
Authors: Marija Ilic; Marion Holy; Kathrin Jaentsch; Matthias E Liechti; Gert Lubec; Michael H Baumann; Harald H Sitte; Dino Luethi Journal: Front Pharmacol Date: 2020-05-19 Impact factor: 5.810
Authors: Tina Hofmaier; Anton Luf; Amir Seddik; Thomas Stockner; Marion Holy; Michael Freissmuth; Gerhard F Ecker; Rainer Schmid; Harald H Sitte; Oliver Kudlacek Journal: Neurochem Int Date: 2013-12-01 Impact factor: 4.297
Authors: Michael H Baumann; Simon Bulling; Tova S Benaderet; Kusumika Saha; Mario A Ayestas; John S Partilla; Syed F Ali; Thomas Stockner; Richard B Rothman; Walter Sandtner; Harald H Sitte Journal: Neuropsychopharmacology Date: 2013-11-28 Impact factor: 7.853
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5