SYNTHETIC CATHINONE CHARACTERIZATION AND ISOMER
IDENTIFICATION USING ENERGY-RESOLVED TANDEM MASS
SPECTROMETRY (MS/MS)
By
Cynthia Jeanne Kaeser

A THESIS
Submitted to
Michigan State University
in partial fulfillment of the requirements
for the degree of
Forensic Science - Master of Science
2017

ABSTRACT
SYNTHETIC CATHINONE CHARACTERIZATION AND ISOMER
IDENTIFICATION USING ENERGY-RESOLVED TANDEM MASS
SPECTROMETRY (MS/MS)
By
Cynthia Jeanne Kaeser
The identification of emerging designer drug analogs, such as synthetic
cathinones and phenethylamines, is a necessary step in the control and regulation of these
illicit compounds. The standard technique for controlled substance analysis, gas
chromatography-mass spectrometry, provides reproducible results useful for comparison
to a library of mass spectra, but is hindered by low-resolution mass data that limit
accurate molecular formulae assignments. Extensive compound fragmentation makes
determination of intact molecules ambiguous. As an alternative analysis method,
collision-induced dissociation mass spectrometry (CID-MS) provides accurate mass data
that facilitates molecular formulae assignments. Controlled fragmentation is achieved
through the use of multiple collision energies, providing molecular formulae for both the
intact compound and fragments that reveal and distinguish structural features.
Using CID-MS, this work aims first to facilitate class assignment of cathinones
and phenethylamines by combining commonly observed fragmentation pathways for both
drug classes into a single flowchart. This scheme is built and tested using compounds that
represent the diversity of potential structural features within the drug classes.
Additionally, this work leverages the use of multiple collision potentials to distinguish
between cathinone isomers by specifically examining fragmentation differences between
isomers at each collision potential.

ACKNOWLEDGEMENTS

I would like to thank my advisor, Dr. Ruth Smith, for her guidance and support
through the challenges of not only this research but life in general over the past few
years. I would like to thank my doctoral advisor and committee member, Dr. A. Daniel
Jones, for sharing his insight into MS fragmentation mechanisms and instrumentation,
challenging my assumptions and directions as a researcher, and encouraging the risks
I’ve taken outside of research. Thank you also to Dr. Chris Smith for being the final
member of my committee and accommodating my unique situation as student residing
out of state. I would also like to thank my research advisor at LLNL, Dr. Elizabeth
Wheeler, for allowing me to finish this degree while working under her guidance.
I would also like to thank the past and current members of the Forensic Chemistry
Group for their support. Of this group, I am especially grateful to Fanny Chu for her
timely and thorough thesis revisions and to her and Kristen Reese for the lunchtime
research discussions and patience through practice talks.
I must also wholeheartedly thank my family for their love and unwavering
support not only in graduate school but in every pursuit I have undertaken. Thank you
also to Katie, my California family, the Inquiry Team, Thuan, and more people than I can
name for celebrating with me on the good days, supporting me on the bad ones, and
keeping me balanced through this process. And, most importantly, thank you to my Lord
and God for every blessing You have given, guiding my life even when it makes it appear
wilder than I could have ever imagined, and putting me back together every time I fall
apart. This has been quite the journey – now, on to the next one!

iii

TABLE OF CONTENTS

LIST OF FIGURES ........................................................................................................... vi
CHAPTER ONE: Introduction to Designer Drug Regulation and Identification................1
1.1 Introduction to designer drugs ...................................................................................1
1.1.1 Definition, prevalence, use, and abuse............................................................1
1.1.2 Cathinone and phenethylamine structures ......................................................2
1.1.3 Designer drug regulation.................................................................................3
1.1.4 Typical forensic analysis of controlled substances .........................................5
1.2 Objectives of this work ..............................................................................................7
1.3 CID-MS analysis........................................................................................................8
1.3.1 CID-MS overview...........................................................................................8
1.3.2 Precursor ion formation and isolation ...........................................................10
1.3.3 Ion fragmentation and detection ...................................................................13
1.3.4 CID-MS as a forensic tool ...........................................................................14
1.4 Summary and specific goals ............................................................................15
CHAPTER TWO: Fragmentation of Cathinones for Drug Class Identification ...............17
2.1 Introduction to cathinone fragmentation ..................................................................17
2.2 Materials and methods .............................................................................................17
2.2.1 Preparation of cathinone standards ...............................................................17
2.2.2 ESI-QTOF-MS analysis ................................................................................20
2.2.3 Data processing .............................................................................................20
2.3 Results and discussion .............................................................................................21
2.3.1 Mass spectral features of cathinone ring substitutions .................................21
2.3.1.1 Fragmentation at low collision potential........................................21
2.3.1.2 Fragmentation of aliphatic-substituted cathinones at increased
collision potentials ....................................................................................24
2.3.1.3 Fragmentation of methylenedioxy-substituted cathinones at
increased collision potentials .....................................................................29
2.3.2 Comparison of the fragmentation of cathinones and phenethylamines ........32
2.3.2.1 Comparison of buphedrone and 2-methylamino-1-phenylbutane .33
2.3.2.2 Additional phenethylamine (2C-E) and overall comparison .........34
2.3.3 Cathinone and phenethylamine classification ...............................................37
2.3.3.1 Development of a classification scheme ........................................37
2.3.3.2 Testing of the classification scheme ..............................................45
2.3.3.3 Literature comparison of the revised classification scheme ..........51
2.4 Conclusion ...............................................................................................................55
CHAPTER THREE: Characterization and Differentiation of Cathinone Isomers ............56
3.1 The isomer problem .................................................................................................56
3.2 Fragmentation of aliphatic-substituted cathinone isomers: Set 1 ............................58
3.3 Fragmentation of aliphatic-substituted cathinone isomers: Set 2 ............................63
3.4 Fragmentation of methylenedioxy-substituted cathinone isomers: Set 3 ................68
iv

3.5 Conclusion ...............................................................................................................76
CHAPTER FOUR: Conclusions and Future Work ...........................................................78
4.1 Conclusion ...............................................................................................................78
4.2 Future work ..............................................................................................................79
APPENDICES ...................................................................................................................81
APPENDIX A: CID-MS Spectra of Cathinones ...................................................82
APPENDIX B: CID-MS Spectra of Phenethylamines ..........................................94
REFERENCES ................................................................................................................101

v

LIST OF FIGURES

Figure 1.1. Core structures of a) cathinones and b) phenethylamines. ................................2
Figure 1.2. An example of a mass spectrum of buphedrone taken at a collision potential
of 10 V in positive ion mode....................................................................................9
Figure 1.3. Schematic of the components in the Waters Xevo G2-XS mass spectrometer.
The ion path is indicated by the dashed blue line. .................................................10
Figure 1.4. Mechanism of ion formation in electrospray ionization run in positive ion
mode.......................................................................................................................11
Figure 1.5. Ion isolation achieved by a quadrupole mass analyzer. ..................................11
Figure 2.1. Structures of the 14 synthetic cathinones analyzed in this study. ...................18
Figure 2.2. Structures of the eight synthetic phenethylamines analyzed in this study. .....19
Figure 2.3. CID-MS spectra for the cathinones a) buphedrone, b) 3-methylbuphedrone
and c) butylone at a collision potential of 10 V. All spectra collected in positiveion mode.................................................................................................................22
Figure 2.4. CID-MS spectra for the cathinone buphedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................25
Figure 2.5. CID-MS spectra for 3-methylbuphedrone at collision potentials of a) 10 V, b)
20 V and c) 40 V. All spectra were collected in positive-ion mode. .....................26
Figure 2.6. CID-MS spectra for butylone at collision potentials of a) 10 V, b) 20 V and c)
40 V. All spectra were collected in positive-ion mode. .........................................30
Figure 2.7. CID-MS spectra for the phenethylamine 2-methylamino-1-phenylbutane at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in
positive-ion mode. .................................................................................................34
Figure 2.8. CID-MS spectra for the phenethylamine 2C-E at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ...................36
Figure 2.9. CID-MS spectra of the training set phenethylamines collected in positive
mode at a collision potential of 10 V. ....................................................................38
Figure 2.10. CID-MS spectra of the training set cathinones collected in positive mode at a
collision potential of 10 V......................................................................................40

vi

Figure 2.11. CID-MS spectra of one phenethylamine and five cathinones from the
training set collected in positive mode at a collision potential of 20 V. ................41
Figure 2.12. Scheme for cathinone and phenethylamine class identification using the
most abundant ions present in the 10 and 20 V spectra. ........................................44
Figure 2.13. CID-MS spectra of one phenethylamine and five cathinones from the test set
collected in positive mode at collision potentials of 10 and 20 V. ........................46
Figure 2.14. Scheme for cathinone and phenethylamine class identification from Figure
2.12 with the addition of the test set of isomers (in bold). Incorrect assignments
are indicated by parentheses. .................................................................................47
Figure 2.15. Revised scheme for cathinone and phenethylamine identification using the
most abundant ions present in the 10 and 20 V spectra. ........................................50
Figure 2.16. Structures of cathinone and phenethylamine structures composing the
literature test set of compounds. ............................................................................52
Figure 3.1. Structures for cathinone isomers investigated. Set 1 isomers (molecular
formula C12H17NO) include a) N-ethyl-N-methylcathinone, b) 3ethylmethcathinone, and c) 3-methylbuphedrone. Set 2 isomers (molecular
formula C11H15NO) include d) buphedrone and e) 2-methylmethcathinone. Set 3
isomers (molecular formula C12H15NO3) include f) 2,3-ethylone isomer, g)
ethylone, and h) butylone. .....................................................................................57
Figure 3.2. CID-MS spectra for a) N-ethyl-N-methylcathinone, b) 3-ethylmethcathinone,
and c) 3-methylbuphedrone, collected in positive-ion mode at a collision potential
of 10 V. ..................................................................................................................58
Figure 3.3. CID-MS spectra for 3-ethylmethcathinone at a) 20 V and b) 40 V and 3methylbuphedrone at c) 20 V and d) 40 V. All spectra were collected in positiveion mode.................................................................................................................60
Figure 3.4. Breakdown curves showing the relative abundance of the charged fragment
for a) [C11H13N]Ÿ+ (m/z 159.10) and b) [C8H9]+ (m/z 105.07) in N-ethyl-Nmethylcathinone, 3-ethylmethcathinone and 3-methylbuphedrone. ......................61
Figure 3.5. CID-MS spectra for buphedrone at collision potentials of a) 10 V, b) 20 V and
c) 40 V. All spectra were collected in positive-ion mode. .....................................64
Figure 3.6. CID-MS spectra for 2-methylmethcathinone at a) 10 V, b) 20 V and c) 40 V.
All spectra were collected in positive-ion mode. ...................................................65

vii

Figure 3.7. Breakdown curves showing the relative abundance of fragments
corresponding to loss of water and either a) an ethyl group or b) a methyl group as
even electron (square, dashed line) and radical (diamond, solid line) fragments for
buphedrone (black) and 2-methylmethcathinone (grey). .......................................66
Figure 3.8. CID-MS spectra for a) 2,3-ethylone isomer, b) ethylone, and c) butylone
collected in positive-ion mode at a collision energy of 10 V. ...............................69
Figure 3.9. CID-MS spectra for butylone at a) 10 V, b) 20 V and c) 40 V. All spectra
were collected in positive-ion mode. .....................................................................71
Figure 3.10. CID-MS spectra for ethylone at a) 10 V, b) 20 V and c) 40 V. All spectra
were collected in positive-ion mode. .....................................................................72
Figure 3.11. CID-MS spectra for the 2,3-ethylone isomer at a) 10 V, b) 20 V and c) 40 V.
All spectra were collected in positive-ion mode. ...................................................73
Figure 3.12. Breakdown curves showing the relative abundance at each collision energy
of the charged fragments a) [C12H14NO2]+ (m/z 204.10) which corresponds to the
loss of water, b) [C11H12NO]+ (m/z 174.09) which corresponds to the loss of 48
Da, c) [C10H8NO2]+ (m/z 174.05), d) [C10H12N]+ (m/z 146.10), and e) [C9H9N]Ÿ+
(m/z 131.07). ..........................................................................................................74
Figure A.1. CID-MS spectra for the cathinone buphedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................86
Figure A.2. CID-MS spectra for the cathinone 3-methylbuphedrone at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ......87
Figure A.3. CID-MS spectra for the cathinone butylone at collision potentials of a) 10 V,
b) 20 V, and c) 40 V. All spectra collected in positive-ion mode..........................88
Figure A.4. CID-MS spectra for the cathinone benzedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................89
Figure A.5. CID-MS spectra for the cathinone naphyrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................90
Figure A.6. CID-MS spectra for the cathinone α-phthalimidopropiophenone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode. .....................................................................................................................91
Figure A.7. CID-MS spectra for the cathinone MTTA at collision potentials of a) 10 V, b)
20 V, and c) 40 V. All spectra collected in positive-ion mode. .............................92

viii

Figure A.8. CID-MS spectra for the cathinone α-pyrrolidinopropiophenone (α-PPP) at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in
positive-ion mode...................................................................................................93
Figure A.9. CID-MS spectra for the cathinone α-piperidinobutiophenone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.......................................................................................................................94
Figure A.10. CID-MS spectra for the cathinone 2,3-ethylone isomer at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ......95
Figure A.11. CID-MS spectra for the cathinone N-ethyl-N-methylcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.......................................................................................................................95
Figure A.12. CID-MS spectra for the cathinone 2-methylmethcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.......................................................................................................................96
Figure A.13. CID-MS spectra for the cathinone ethylone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................97
Figure A.14. CID-MS spectra for the cathinone 3-ethylmethcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.......................................................................................................................97
Figure B.1. CID-MS spectra for the phenethylamine 2-methylamino-1-phenylbutane at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in
positive-ion mode...................................................................................................98
Figure B.2. CID-MS spectra for the phenethylamine 2C-E at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....................99
Figure B.3. CID-MS spectra for the phenethylamine 2C-T at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ..................100
Figure B.4. CID-MS spectra for the phenethylamine 2C-B at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ..................101
Figure B.5. CID-MS spectra for the phenethylamine 2C-G at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ..................102
Figure B.6. CID-MS spectra for the phenethylamine 25E-NBOMe at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode. ....103

ix

Figure B.7. CID-MS spectra for the phenethylamine 3,4-MDPA at collision potentials of
a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode..........103
Figure B.8. CID-MS spectra for the phenethylamine venlafaxine at collision potentials of
a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode..........104

x

CHAPTER ONE: Introduction to Designer Drug Regulation and Identification

1.1 Introduction to designer drugs
1.1.1

Definition, prevalence, use, and abuse
Controlled substances have become a common type of evidence submitted for

forensic analysis. While the Drug Enforcement Agency (DEA) reports seizure of tens of
thousands of kilograms of cocaine, marijuana, and hallucinogens and more than 30,000
drug-related arrests for possession, sale, or manufacturing each year (1), statistics from
the Federal Bureau of Investigation (FBI) statistics indicate that drug-related arrests are
more likely to occur because of possession than for sale and manufacturing (2). The CDC
also reports that deaths associated with drug abuse now exceed those due to either
automobile accidents or firearm-related injuries (3). As they become an increasing public
health issue, regulation and control of synthetic designer drugs has been a growing
concern in recent years (3).
“Designer drugs” is a term given to compounds that are structurally similar to and
mimic the effects of an otherwise restricted or prohibited compound (4). These
compounds fall into several classes that include synthetic cannabinoids, cathinones, and
phenethylamines, although this work will focus only on these last two classes.
Compounds within each class are modeled after similar compounds of known
psychological activity that are either naturally occurring or that are developed by
pharmaceutical researchers for medicinal purposes. From known molecular templates,
clandestine chemists make small structural modifications, such as adding or removing

1

functional groups, to avoid regulation while maintaining the physiological effects of the
base compound.

1.1.2

Cathinone and phenethylamine structures
Synthetic cathinones are derivatives of the naturally occurring psychoactive

compound cathinone ((S)-2-amino-1-phenylpropan-1-one). With stimulative effects
similar to cocaine and amphetamines, these drugs originally gained popularity for
recreational use in part because of their unregulated status (5) and, while reports of their
use have been on the decline in recent years, they are still listed as “drugs of concern” in
the DEA’s resource guide (6). The core structure of cathinone, shown in Figure 1.1.a., is
a 6-membered aromatic ring with an ethyl (2-carbon) chain that terminates with an amine
group. The substitution at the alpha-carbon is a minimum of a methyl chain and a ketone
group is present at the beta-carbon.

β

α

β

a) cathinone

α

b) phenethylamine

Figure 1.1. Core structures of a) cathinones and b) phenethylamines.

Cathinones are closely related to another class of drugs of concern,
phenethylamines. The phenethylamine core structure, shown in Figure 1.1.b., is similar
but lacks the ketone group at the beta-carbon and does not have the methyl requirement at
2

the alpha-carbon. The “R” groups in both cathinones and phenethylamines represent
possible sites of substitution. Common substituents for these locations include aliphatic
(carbon and hydrogen only) chains of varying lengths, oxygen-containing groups, and
halogens (e.g., bromine, chlorine, or fluorine), among others (7,8). The presence of
multiple substitution sites also allows for structural isomers, or compounds with identical
molecular formulae but differing structural arrangements. Although the similarities in
structure among designer drugs are advantageous for maintaining the physiological
effects, the range of combinations of functional groups assembled around similar cores
can make identification of the exact structure challenging. However, definitive
identification of each compound is vital to the regulation process. As these new analogs
arrive on the market, forensic scientists are tasked with their identification while
lawmakers are tasked with their legislation (9).

1.1.3

Designer drug regulation
From a legislative standpoint, the Controlled Substances Act (1970) established

regulation to control the production, possession, and distribution of various drugs (10).
Under this Act, drugs are classified into one of five schedules based on their potential for
abuse, accepted medical use, and potential for psychological and physical dependence,
with Schedule I being the highest risk for abuse and Schedule V being the lowest (11). As
new pharmaceutical drugs receive approval by the Food and Drug Administration (FDA),
their placement as a scheduled or unscheduled drug is also determined. The scheduling
process for new drugs, both legally and illegally distributed, can be a lengthy process as
research in the areas of abuse and dependence must be performed and reviewed before a

3

classification can be made. With the rate of emergence of new analogs into the illegal
drug market exceeding that of legislation, a different approach was needed.
In 1986, the Federal Analog Act was enacted to allow analogs that are structurally
similar to Schedule I and II drugs to be prosecuted as though they are scheduled if the
drugs are intended for human consumption. This enabled lawmakers to side-step the
lengthy scheduling process and address the rapidly changing compounds on the market
while keeping them readily available for labs to build the research needed for the full
scheduling process. However, the two requirements of “structurally similar” and
“intended for human consumption” are ambiguous and can be interpreted differently (9).
With a broad range of possible chemical modifications, it is unclear at what point an
analog becomes structurally dissimilar, even among experts in the field. Additionally,
dealers often advertise designer drugs as “bath salts” or “plant food” in packages marked
“not for human consumption” in an attempt to circumvent the latter requirement.
While both Acts provide grounds for prosecution of individuals manufacturing
and distributing designer drug analogs, some analogs have still become widely available.
When specific analogs become particularly prevalent and pose an imminent hazard to
public safety, the compounds can be emergency scheduled as a Schedule I drug for a
period of up to one year with the option to extend the scheduling by six months or longer
if scheduling procedures are underway (12). For cathinones and phenethylamines, the
two drug classes most commonly found in “bath salts”, there are five cathinones and 27
phenethylamines categorized as Schedule I drugs as of November 2016 (13). Another 10
cathinones have been emergency scheduled, pending full scheduling.

4

Since federal action on illicit drug regulation is a slow process, individual states
have taken action to regulate these compounds on a more local level. Since 2011, all
states have placed some level of regulation on synthetic cathinones that range from
banning individual compounds to more general legislature that regulates compounds that
contain a specific structural feature or act on a specific chemical receptor (14). While no
consistent agreement among the states exists on how to best regulate these emerging
drugs, in all cases, the first step toward regulation remains the definitive identification of
emerging analogs.

1.1.4

Typical forensic analysis of controlled substances
A typical forensic analysis of a sample suspected to contain controlled substances

will include both presumptive and confirmatory tests. Presumptive tests, such as color
tests, ultraviolet-visible spectrophotometry, or microcrystalline tests are rapid,
inexpensive tests that establish whether an illicit drug may be present by indicating the
presence of structural features common in controlled substances. Some presumptive
techniques are specific enough to identify the class of the compound, but many lack the
specificity to accomplish this. For example, the clear, colorless liquid reagent in a
Liebermann’s color test will become colored in the presence of alkaloids, or nitrogencontaining compounds. This test will be positive for cathinones, phenethylamines, and
variety of other compounds including naturally occurring compounds (15). For complete
structural identification that can define both the drug class and the actual compound
present, confirmatory tests are required. Confirmatory tests include nuclear magnetic
resonance (NMR), infrared (IR) spectroscopy, and mass spectrometric (MS) analyses.

5

The most common confirmatory technique for controlled substance analysis, gas
chromatography-mass spectrometry (GC-MS), is the gold standard for identification of
the substance in a submitted sample (16). GC provides separation of compounds in a
mixed sample while the MS component gives information about the composition of each
individual compound in the mixture. The mass spectrometer in typical GC-MS
instruments uses an electron ionization (EI) source and a single quadrupole mass
analyzer. During electron ionization, energy imparted to the ion results in fragmentation.
When EI is coupled with high-resolution mass analysis, the mass of the intact molecular
ion gives the molecular formula of the compound while the fragment ion masses give
information about the structural arrangement of elements within the molecule. While the
reproducible fragmentation in EI allows comparison to a library of standards for
identification, it is often so extensive that no molecular ion is observed. If no library
standard is available, the lack of the molecular ion can limit the identification process.
Additionally, the low mass resolution from a single quadrupole mass analyzer
gives only nominal values for masses. Nominal mass data do not allow firm identification
of the molecular formula for many mass values as there can be multiple formulae that
have the same nominal mass but differing exact masses. Combined with a library match
to the fragmentation pattern of a known substance, this resolution is sufficient for
identification of the more traditional controlled substances submitted to laboratories.
However, for designer drugs, the rapid appearance of new analogs often outpaces the
availability of reference standards for comparison. Without a library reference, the lowresolution mass data is insufficient to definitively distinguish between the similar mass

6

spectra generated from structurally similar compounds. This makes the instrument
configuration in GC-MS ultimately insufficient for definitive cathinone analysis.
As an alternative method of analysis, collision-induced dissociation mass
spectrometry (CID-MS) has been proposed. CID-MS provides high-resolution mass data
that gives confidence in the molecular formulae assignment and a variable collision
potential provides some control over the extent of fragmentation observed.

1.2 Objectives of this work
Based on the limitations in standard forensic analyses and the potential use of
CID-MS for identification of emerging designer drugs, the aims of this work are twofold.
First, development of a characterization scheme facilitates differentiation between
cathinones and phenethylamines. Scheme development is accomplished by comparing the
most abundant fragments of cathinones and phenethylamines formed using CID-MS at
multiple collision potentials and combining these differences into a flow chart. The
scheme’s foundational sample set represents the diversity of structural substitutions
possible in these drug classes with further testing and refinement performed using both a
test set of compounds analyzed in-house as well as a data set obtained from the literature.
An overview of cathinone and phenethylamine fragmentation and the development of the
characterization scheme is covered in Chapter Two.
The second aim, covered in Chapter Three, addresses the issue of isomer
differentiation, specifically examining how the structural differences between isomers are
revealed when cathinones are fragmented at multiple collision potentials. This is
accomplished using three sets of cathinone isomers (eight compounds total) and three

7

collision potentials. The lowest collision potential provides information about the most
energetically favorable fragmentation pathways in these compounds, while higher
collision potentials yield more extensive fragmentation that reveals the structural
differences between isomers.

1.3 CID-MS analysis
1.3.1

CID-MS overview
Before considering the application of CID-MS for cathinone identification, the

underlying theory must first be understood. Mass spectrometry is an analytical technique
that determines the ratio of the mass to the charge (m/z) of gas phase ions (17). The
number of ions at each m/z are counted and displayed in a spectrum of m/z versus
intensity. The intensity of each ion is scaled to the most abundant ion, termed the base
peak. An example of a mass spectrum with the relevant terminology labeled is shown in
Figure 1.2. There are a variety of methods for ion generation, analysis, and detection that
can selected according to the sample type and each have their own advantages and
disadvantages. In forensic analyses, mass spectrometry is often paired with a separation
technique such as liquid or gas chromatography (LC or GC). Chromatography techniques
separate each compound in a mixture, providing many options that can be leveraged for
compound identification. While an additional confirmatory technique useful for designer
drug identification, chromatographic separation of these compounds is not the focus of
this work.

8

buphedrone
O

178.12

160.11

Fragment
Ions

H
N

Base Peak,
Molecular Ion

%

Ion Relative
Intensity

100

0
50

132.08

91.05

60 Buphedrone
70
80
Item #11283

90

100

110

120

130

147.08

140

150

160

170

180

190

m/z
200

Ion Mass-to-Charge (m/z)
131.07

100
%

Figure 1.2. An example of a mass spectrum of
buphedrone taken at a collision potential
130.07 132.08
91.06

of 10 V in positive ion mode.
0
50

60

70

80

90

105.04

100

145.09

117.06

110

120

130

140

150

160.11

160

170

180

190

m/z
200

130.07

100
%

There are several steps involved in the process of forming and fragmenting ions that
91.06 In this work,
128.05
144.08
yield the final spectrum
all steps
are performed using a Waters
77.04observed.103.06

0
50

60

70

80

90

100

110

120

130

140

150

160

170

180

190

m/z
200

Xevo G2-XS mass spectrometer (Figure 1.3). Since cathinones and phenethylamines are

not ionic compounds, they must first be ionized using an electrospray ionization (ESI) ion
source. Ions are separated from any uncharged molecules using an ion guide before the
ion of interest, called a precursor ion, is isolated using a quadrupole mass analyzer and
fragmented in a collision cell. The energy imparted during the collision step dictates the
extent of fragmentation of the precursor ion with increasing fragmentation occurring
when using increased collision potentials. The mix of intact precursor ions and fragment
ions are then pushed into a time-of-flight (TOF) mass analyzer and separated based on
their m/z ratio. Ions of each m/z ratio are then detected using an electron multiplier.

9

Electrospray
Ionization
Source
Ion
Guide
Quadrupole

Collision Cell

TOF Mass
Analyzer

Figure 1.3. Schematic of the components in the Waters Xevo G2-XS mass spectrometer
with the ion path indicated by the dashed blue line.

1.3.2

Precursor ion formation and isolation
The ESI process, summarized in Figure 1.4, includes several steps (18). First, a

charged spray needle draws the ions of one polarity present in the solution (either positive
or negative) to the tip of the needle. As ions of the same polarity are collected at the
needle tip, their repulsion of each other forms a Taylor cone. As charge builds up in the
tip, the end of the cone breaks off to form a droplet. This droplet is generally composed
of both analyte molecules and charged ions from the solvent. As the solvent evaporates,
the ions are forced to be physically closer to each other. The size at which the Coulombic
repulsion exceeds the surface tension that holds the droplet together is termed the
Rayleigh limit. At this point, a Coulombic explosion occurs, breaking the droplet into
smaller droplets. This process of evaporation and explosion is repeated until all of the
solvent has evaporated, leaving the analyte molecules ionized.

10

Spray needle tip
+

+
+
+
+
+
+
+
+

Taylor cone

Multiply-charged droplets

++ +
+ + + ++
+
++
+
+
Solvent
+
+
+ evaporation +
+
+
+
+
+
+
+
+
+
+
+++

+
Coulombic
explosion

+ + +
+
+ +

Analyte molecules
+ve

Power
Supply

-ve

Figure 1.4. Mechanism of ion formation in electrospray ionization run in positive ion
mode.

Considered a “soft” ionization method, ESI accomplishes ionization with minimal
fragmentation of the analyte. This ensures that the molecular ion remains present in high
abundance. However, to be sure that any fragments formed later correlate to the ion of
interest alone, the precursor ion is isolated in a quadrupole mass analyzer (Figure 1.5).

+-

-+
Figure 1.5. Ion isolation achieved by a quadrupole mass analyzer.

11

A quadrupole consists of four conducting parallel rods evenly-spaced to leave a
pathway for ions through the center. The four rods are charged so that the rods diagonally
opposite each other are of the same charge, either both positive or both negative (17).
These rods are connected to both direct current (DC) and alternating current (AC) power
sources. The AC power source produces radio frequency (RF) voltages and ultimately
alternates the charge on each rod between positive and negative. Thus, while two rods are
labeled as positive in Figure 1.5 at the moment of time pictured there, at another moment
in time, they will be negatively charged; likewise, the negatively charged rods will
become positive at the same time. This constant charge switching leads to a spiral
trajectory for the ions passing through the quadrupole.
Ion selection in the quadrupole is achieved through adjusting the DC and RF
potentials. An ion’s trajectory through the quadrupole will only be stable if these
potentials are appropriately set for the ion’s m/z value. An ion on an unstable path will
either strike one of the charged rods, as in the purple ion in Figure 1.5, or pass between
the rods and be pumped away by the vacuum, as with the yellow ion. An ion with a stable
path will pass through the quadrupole into the next part of the mass spectrometer. While
scanning through the DC and RF potentials can allow a quadrupole to be operated as a
mass analyzer, for the purposes of this study, it is operated at a single DC/RF setting to
act as an ion filter so that only the precursor ion is allowed to pass through to the
detector.

12

1.3.3

Ion fragmentation and detection
After isolation by the quadrupole, precursor ions are accelerated into the collision

cell. In the collision cell, the precursor ions collide with inert argon gas molecules. Upon
collision, some of the translational energy in the precursor ion is converted to internal
energy (17). If the internal energy is not sufficient to break bonds, then the ion continues
through the collision cell intact. However, if the internal energy is sufficiently high to
breaks bonds within the precursor ion, fragmentation will occur. The precursor ions
isolated in this work each have a single charge, so only one fragment formed during
fragmentation will remain charged. The charged fragment is termed a product ion while
the remaining uncharged fragment is called a neutral loss.
With a low collision potential, the precursor ion will have less kinetic energy
entering each collision that may result in minimal fragmentation. Similarly, a higher
collision potential will result in more extensive fragmentation. By using a series of
collision potentials that encompasses both low and high potentials, a range of fragments
are produced, revealing deep structural information about the precursor ion.
To determine the m/z value of the fragment ions produced, a time-of-flight (TOF)
mass analyzer is used. The ions leaving the collision cell are focused by a series of lenses
before entering the time of flight chamber (17). The ions are “pushed” into the chamber
by a pulse of applied voltage, giving them kinetic energy in the same way as upon
entering the collision cell. However, the pressure in the chamber is less than 10-6 mbar so
these ions experience no collisions as they travel through the chamber. While the amount
of the kinetic energy applied to each ion remains constant, the velocity at which the ions
travel through to the chamber toward the detector is inversely proportional to the square

13

root of the m/z value of the ion. This means that ions of lower m/z values will travel more
quickly through the chamber and reach the detector first, while those with higher m/z
values will take longer. The time from the voltage pulse to detection ultimately correlates
to the ions’ m/z value.
A TOF mass analyzer is advantageous because it has both high mass resolution
and high mass accuracy. High mass resolution means that ions of m/z value as similar as
0.001 Da can be distinguished from each other. Mass accuracy is defined by a low error
in the mass assignment, meaning the difference between the experimentally determined
value (accurate mass) and the actual value (exact mass) given in parts per million (ppm)
is small (<5 ppm) (17). The calculation for this can be seen in the following equation.
Error = Measured mass – Theoretical mass x 106
Theoretical mass

1.3.4

Eqn. 1

CID-MS as a forensic tool
CID-MS has been previously used to classify unknown compounds for both

biological (19-22) and forensic applications (7, 23-27). Work by Fornal (7, 25) and Zuba
(27) identified fragments that are common for cathinones. The loss of water commonly
occurs when the amine group is a primary or secondary amine. Fragmentation resulting in
the neutral loss of an amine group is also observed. Although less common, cleavage of
the bond between the alpha- and beta-carbons has been reported (7). In this case, the
charge can remain on either of the resulting fragments. For cathinones with a
methylenedioxy-substitution on the aromatic ring, the loss of 48 Da (CH4O2) is common.
Fornal (25) attributed this to a loss of the ring substitution as a methanediol group.

14

While the neutral losses noted above are those most commonly observed for
cathinones at low collision potentials and lay a foundation for cathinone identification,
there are no neutral losses that are universally present for all cathinones (7). Additionally,
these neutral losses are not specific to cathinones alone, as some of these are common
among other drug classes (e.g. amine group loss is also present in phenethylamines) (28).
This complicates assignment of the drug class when relying on the presence of a limited
number of fragments. For structural identification purposes, these neutral losses can
reveal some features of the molecule, but with multiple substitution sites on the aromatic
ring and alpha-carbon, differentiation between isomers based on these fragments alone
may not be possible. Thus, additional fragmentation pathways must be considered.

1.4 Summary and specific goals
Cathinones, a class of designer drugs commonly analyzed by forensic scientists,
encompasses diversity in both the composition and location of functional group
substitutions within the structure. As new synthetic cathinone analogs reach the market
before their standards reach the laboratory, the current technique for identification (GC
with low resolution EI-MS) is ill-suited for these emerging compounds because it fails to
yield molecular formulae or sufficient information to distinguish isomers. In this work,
CID-MS is investigated as an alternative method for cathinone identification. With this
technique, analysis can be performed over a range of collision energies, providing
information about the intact molecule, as well as the common fragments at both low and
high collision potentials. Additionally, the TOF mass analyzer obtains high resolution
mass data which allow the molecular formula of both the precursor ion and the product

15

ions to be assigned with confidence. Chapter 2 presents the fragmentation of cathinones
and compares the results to phenethylamines with the goal of identifying product ions
that distinguish between these two classes of designer drugs. Building upon this general
understanding of cathinone fragmentation, the capacity of CID-MS to differentiate
isomers will be explored in Chapter 3.

16

CHAPTER TWO: Fragmentation of Cathinones for Drug Class Identification

2.1 Introduction to cathinone fragmentation
The structural composition of a suspected illicit drug must be defined to confirm
its identity. This identification is an important step in the regulation of designer drugs. To
aid this process, collision-induced dissociation mass spectrometry (CID-MS), when
performed on a high-resolution mass spectrometer, provides the elemental composition of
both the intact molecule as well as fragments that give additional structural information.
Leveraging this, a structurally diverse set of cathinones were investigated and their CID
mass spectra used to identify not only their common structural features but also those that
distinguish cathinones from the structurally similar class of designer drugs,
phenethylamines.

2.2 Materials and methods
2.2.1 Preparation of cathinone standards
Cathinone and phenethylamine standards were purchased from Cayman Chemical
Company (Ann Arbor, MI). The selected compounds demonstrate the range of structural
diversity within these classes while also including isomeric compounds. Structures of the
cathinone and phenethylamine standards analyzed in this work are shown in Figures 2.1
and 2.2, respectively. Of these, buphedrone, butylone, naphyrone, ethylone, 2C-E, and
2C-B are currently Schedule I drugs. The remaining cathinones and phenethylamines are
currently unregulated. Each standard was prepared at a concentration of 5 µg/mL in

17

methanol (HPLC grade, Fisher Scientific, Pittsburgh, PA) for subsequent CID-MS
analysis.
O

O

H
N

H
N

a)
Buphedrone
Buphedrone

b) 3-methylbuphedrone
3-Methylbuphedrone
Item #12001
O

O
Item #11283

H
N

O

H
N

benzedrone
Item #11915

O

d) Benzedrone

c) Butylone
Butylone
Item #10393

O

O

O

N

N

O

alpha-phthalimidopropiophenone
f) α-phthalimidopropiophenone
Item
#17141

Naphyrone
e) Naphyrone
Item #10517
O

O
N
N
H

alpha-pyrrolidinopropiophenone (PPP)
h) α-pyrrolidinopropiophenone
Item #11484

MTTA
g)
MTTA
Item
#17121
O

O

O

N

alpha-Piperidinobutiophenone
i) α-piperidinobutiophenone
Item #9001513
O

H
N

O

2,3-Ethylone
isomer
j) 2,3-ethylone
Item #9002142
H
N

N

2-methylmethcathinone

N-ethyl-N-methylcathinone
k) N-ethyl-N-methylcathinone
Item #11604

l) 2-methylmethcathinone
O

O

H
N

H
N

O

isomer

O

O

m) Ethylone

bk-MDEA
Item #9001123

n) 3-ethylmethcathinone
3-Ethylmethcathinone
Item #9001082

Figure 2.1. Structures of the fourteen synthetic cathinones analyzed in this study.
18

O

H
N

NH 2

2C-E
Item #15699

a) 2-methylamino-1-phenylbutane
2-methylamino-1-phenylbutane
Item #15961

b) 2C-E
O

O

O
NH 2

2C-T
Item #13957

S

NH 2

2C-B
Br

c) 2C-T

d) 2C-B

O

O

O

O
H
N

NH 2

2C-G
Item #14064

25E-NBOMe
Item #14727

e) 2C-G

f) 25E-NBOMe

O

O

O

O

H
N

3,4-MDPA
g) 3,4-MDPA

OH
N

O

Venlafaxine
h) Venlafaxine
Item
#11567

Figure 2.2. Structures of the eight synthetic phenethylamines analyzed in this study.

19

O

2.2.2 ESI-QTOF-MS analysis
All standards were analyzed using a Xevo G2-XS QToF mass spectrometer
(Waters Corporation, Milford, MA). Flow injection analysis was performed using 75/25
(v/v) acetonitrile (HPLC grade, Sigma-Aldrich, St. Louis, MO) and Milli-Q® water (18.2
MΩ-cm, EMD Millipore, Billerica, MA), at a flow rate of 20 µL/min. The quadrupoletime of flight mass spectrometer was equipped with an electrospray ionization source
with a capillary voltage of 3.0 kV, desolvation temperature of 250°C, and source
temperature of 100°C. Nitrogen was used as the desolvation gas at a flow rate of 600 L/hr
and as the cone gas at a flow rate of 50 L/hr. Mass spectra were acquired in positive-ion
mode across the range of mass-to-charge ratios (m/z) 30-600. The collision gas was argon
at 2 x 10-3 mbar measured at the collision cell manifold. Separate injections were used for
each collision potential of 10, 20, or 40 V. Leucine enkephalin was used as a mass
reference standard with data acquisition rotating between ionization of the designer drug
standard and the mass reference standard. Scan times were 0.500 s for each acquisition,
with inter-scan delays of 0.014 s, and mass resolution (M/ΔM) at full width halfmaximum was 15000.

2.2.3 Data processing
For each designer drug standard at each collision potential, three spectra across
the signal maximum were averaged and the resulting ion list was exported from Waters
MassLynx software (version 4.1, Waters Corporation) into Microsoft Excel for Mac 2011
(Microsoft Corporation, Redmond, WA). The Elemental Composition tool in MassLynx
was used to assign molecular formulae to all ions. The starting composition of the

20

standard and a mass error of 50 ppm provided the upper bounds for formulae assignment.
Comparison of a fragment ion’s assigned formula to the formula of the protonated
molecule, [M+H]+, provided the associated neutral loss.

2.3. Results and discussion
2.3.1 Mass spectral features of cathinone ring substitutions
The core structure for a cathinone can be substituted at a number of locations
including the aromatic ring. There is a range of functional groups that can be used to alter
the structure, each resulting in a new drug analog. To analyze how the composition of the
ring substitution can be identified from a cathinone’s mass spectra, three cathinones were
selected for analysis. These cathinones have the same amine and alpha-carbon
substitutions, but vary in the aromatic ring substitutions to include having no ring
substitution (buphedrone), a methyl group (3-methylbuphedrone) and a methylenedioxy
group (butylone).

2.3.1.1 Fragmentation at low collision potential
The chemical structures of buphedrone, 3-methylbuphedrone, and butylone are
shown with example spectra taken at the lowest collision potential (10 V) in Figure 2.3.
Because each of these compounds has a different molecular formula, the protonated
molecules ([M+H]+) are different in each of these spectra: m/z 178.12 ([C11H16NO]+) for
buphedrone, m/z 192.14 ([C12H18NO]+) for 3-methylbuphedrone, and m/z 222.11
([C12H16NO3]+) for butylone. In all three cases, [M+H]+ is also the base peak.

21

buphedrone

[C11H14N]+[C11H16NO]
160.11 178.12

O
H
N

%

100

[C10H11O]+
[C9H10N]+
132.08 147.08

[C7H7]+
a) Buphedrone
91.05
Buphedrone

60

Item #11283

80

100

120

140

160

H
N

100

0

%

100

0

b) 3-methylbuphedrone

60

3-Methylbuphedrone105.07
Item #12001

80

O

100

120

140

180

200

[C11H11O3]+

Item #10393

100

220

m/z

120

140

160

180

220

m/z

[C12H16NO3]+
222.11
[C12H14NO2]+
204.10

[C11H12NO]+
174.09
191.07
161.06
146.10

c) Butylone Butylone

80

160
[C10H9O2]+

O

60

200

[C11H13O]+
[C10H12N]+
133.10 146.10 161.10

H
N

O

180

+
[C12H16N]+ [C12H18NO]
192.14
174.13

O

%

Ion Relative Intensity

0

+

200

205.11

223.06

220

m/z

Ion Mass-to-Charge (m/z)

Figure 2.3. CID-MS spectra for the cathinones a) buphedrone, b) 3-methylbuphedrone
and c) butylone at a collision potential of 10 V. All spectra collected in positive-ion
mode.

While the fragment ion masses differ, several fragment ions observed correspond
to common neutral losses. The fragment ions corresponding to the loss of water are the
most abundant fragment ion in each spectrum, observed at m/z 160.11 for buphedrone,
m/z 174.13 for 3-methylbuphedrone, and m/z 204.10 for butylone. Previous studies on
cathinone fragmentation reported that the loss of water involves protonation of the
ketone’s oxygen and a hydrogen shift from the amine (7, 27). Thus, this loss is only
observed when the amine group is a primary or secondary amine, having at least one
hydrogen present (7, 27). Also observed in the spectra of these three cathinones are the
fragment ions corresponding to the loss of methylamine at m/z 147.08 for buphedrone,

22

m/z 161.10 for 3-methylbuphedrone, and m/z 191.07 for butylone. This neutral loss of the
amine group provides evidence of the methylamino group common to all three
compounds.
To identify the aromatic ring substitution, other fragments must be considered. An
unsubstituted aromatic ring fragmented from a larger compound is often observed as the
ion [C7H7]+ (m/z 91.05) (29). This is present in the 10 V CID mass spectrum of
buphedrone, but is not present in CID mass spectra of the other two cathinones at this
collision potential. The presence of a methyl group on the aromatic ring in 3methylbuphedrone is indicated by the fragment [C8H9]+ (m/z 105.07), which is one
methylene unit (CH2) longer than the ring fragment in buphedrone. A similar fragment
with a methylenedioxy-substituted aromatic ring is not observed in butylone at 10 V.
However, the fragment [C10H11O]+ (m/z 147.08) in the CID mass spectrum of butylone
corresponds to the loss of 48 Da. Fornal (25) has previously identified this as a loss of the
methylenedioxy substitution from the aromatic ring as methanediol (CH4O2). However,
the loss of methanediol is unlikely owing to its low stability and this neutral loss is more
likely to be successive losses of formaldehyde (CH2O) and water (H2O). Regardless of
the exact mechanism of the loss, the cumulative loss of CH4O2 does indicate a
methylenedioxy substitution on the aromatic ring. While the fragments observed at 10 V
do indicate the composition of both the amine and aromatic substitutions, fragmentation
at higher energies provides confirmation of these features.

23

2.3.1.2 Fragmentation of aliphatic-substituted cathinones at increased collision
potentials
To further interrogate the structure of buphedrone, Figure 2.4 shows the chemical
structure of this compound as well as representative mass spectra collected using
collision potentials of 10, 20, and 40 V. As previously mentioned, commonly observed
cathinone ions including the [M+H]+, fragment ions corresponding to the losses of water
or the amine group, and the [C7H7]+ aromatic ring indicator are present at 10 V. However,
as the collision potential increases, more extensive fragmentation occurs owing to the
greater internal energy imparted to the [M+H]+. This results in an increase in the number
of fragments observed, a decrease in the average mass of these fragments, and the
occurrence of odd-electron species.
While not commonly generated during electrospray ionization, the formation of
odd-electron ions can occur in CID-MS during fragmentation of even-electron parent
ions (5) and are identified using the nominal mass and the molecular formula assignment
determined by the exact mass. Odd-electron species that contain no nitrogen or an even
number of nitrogen atoms will have an even number nominal mass, while even-electron
species with the same nitrogen content will have odd nominal masses. For species with
an odd number of nitrogen atoms, the reverse is true, with odd-electron species having an
odd-number nominal mass and even-electron species having an even-number nominal
mass. Of those odd-electron species identified in the cathinone spectra, one is observed in
the 20 V CID mass spectrum of buphedrone as the base peak ([C9H9N]Ÿ+, m/z 131.07)
(Figure 2.4.b). This fragment is part of a series of fragments that correspond to the loss of
water and an ethyl group as either ethene ([C9H10N]+, m/z 132.08), a radical species

24

([C9H9N]Ÿ+, m/z 131.07), or an even-electron species ([C9H8N]+, m/z 130.07). Fragments
from this series are observed at all collision potentials, although they are most dominant
at 20 V. Given the structure of buphedrone, the ethyl group loss may result from a
cleavage of the ethyl side chain at the alpha position. However, this cannot be confirmed
from the data presented here.

buphedrone

O

[C11H14N]+

H
N

160.11

%

100

Ion Relative Intensity

0
50

60

Buphedrone
Item
70 #11283
80

147.08

132.08

91.05

90

178.12

+
[C9H10N]+ [C10H11O]

[C7H7]+

a) 10 V

[C11H16NO]+

100

110

120

130

140

[C9H9N]Ÿ+

150

160

170

180

190

m/z
200

131.07

100

+
[C9H8N]+ [C9H10N]

130.07 132.08

]+

%

[C7H7

0
50

91.06

b) 20 V
60

105.04

70

80

90

[C10H11N]Ÿ+

[C8H7N]Ÿ+

100

145.09

117.06

110

120

130
130.07

%

100

c) 40 V
0
50

60

[C6H5]+
77.04

70

80

[C7H7]+ [C H ]+
8 7
91.06

90

103.06

100

110

128.05

120

130

140

150

[C11H14N]+
160.11

160

170

180

190

m/z
200

160

170

180

190

m/z
200

[C9H8N]+
[C10H10N]+
144.08

140

150

Ion Mass-to-Charge (m/z)

Figure 2.4. CID-MS spectra for the cathinone buphedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

Although present at a lower abundance, a similar series of odd- and even-electron
fragments results from the loss of water and a methyl group in buphedrone. These
fragments occur with the methyl group lost as either a radical species ([C10H11N]Ÿ+, m/z
145.09) or methane ([C10H10N]+, m/z 144.08). This methyl could be the result of cleavage
25

of the methyl substitution on the amine group or as a loss of part of the side chain at the
alpha position. It is likely that this fragment is due to a combination of the two pathways.
While these two series of radical and even-electron losses become more
prominent with increasing collision potentials, they have not been previously reported
among cathinone fragmentation. For these to be considered distinguishing or
characteristic fragments for cathinones, the fragments would need to be present in
multiple cathinones. Continuing the trend observed, these combined loss of water and an
alkyl group is also observed in 3-methylbuphedrone (Figure 2.5).

O

3-methylbuphedrone

%

100

174.13

[C10H12N]+

a) 10 V

0
50

60

70

3-Methylbuphedrone
80 #12001
90 100 110
Item

120

130

140

150

[C10H11N]Ÿ+
145.09

144.08

105.07

b) 20 V

119.05

91.05

60

70

80

90

[C9H9N]Ÿ+

100

110

120

131.07

130

161.10

160

146.10

150

190

m/z
200

180

190

m/z
200

180

190

m/z
200

180

159.10 174.13

158.10

140

170

[C11H13N]Ÿ+

[C10H10N]+

[C8H9]+

0
50

[C10H10N]+

161.10

160

170

144.08

100

%

[C11H13O]+

133.10 146.10

105.07

100

%

Ion Relative Intensity

H18NO]+
[C12H16N]+ [C12192.14

H
N

c) 40 V

0
50

[C6H5]+
77.04

60

70

80

[C9H8N]+ 143.07

[C7H7]+
91.05

90

105.07115.06

100

110

130.07

120

[C11H12N]+
158.10

142.06

130

140

Ion Mass-to-Charge (m/z)

150

160

170

Figure 2.5. CID-MS spectra for 3-methylbuphedrone at collision potentials of a) 10 V, b)
20 V and c) 40 V. All spectra were collected in positive-ion mode.

26

The chemical structure of 3-methylbuphedrone, as well as representative mass
spectra collected using collision potentials of 10, 20, and 40 V, are shown in Figure 2.5.
With increasing collision potential, 3-methylbuphedrone yields similar fragments as
buphedrone with the base peaks at 20 and 40 V corresponding to the combined loss of
water and an ethyl group as either a radical ethyl group ([C10H11N]Ÿ+, m/z 145.09) or
ethane ([C10H10N]+, m/z 144.08), respectively. The loss of water and the methyl
substituent as either a radical methyl group ([C11H13N]Ÿ+, m/z 159.10) or methane
([C11H12N]+, m/z 158.10) is also observed. While these fragments correspond to the same
neutral losses as observed in buphedrone, the fragments in 3-methylbuphedrone are
evident at m/z values ~14 Da higher because of the added mass of the methyl ring
substitution.
While not observed in buphedrone, the fragment ion corresponding to the
combined loss of water, an ethyl group, and a methyl group is present in 3methylbuphedrone as both the radical fragment [C9H9N]Ÿ+ (m/z 131.07) at 20 V and evenelectron fragment [C9H8N]+ (m/z 130.07) at 40 V. In 3-methylbuphedrone, the methyl
group lost in these fragments could be from either the amine group or the aromatic ring.
This loss does not readily occur in buphedrone, which has a similar methyl substitution
on the amine, so it is more likely that the aromatic methyl group is being lost during this
fragmentation.
These odd- and even-electron fragment ions are not specific to buphedrone and 3methylbuphedrone. Analogous ions are also observed in CID mass spectra of butylone
(Figure 2.6, discussed in detail in the following section) and structural isomers of these
three cathinones (discussed in detail in Chapter 3). However, these are not observed in

27

the other cathinones investigated in this study. Spectra of all cathinones are included in
Appendix A. Given that the loss of water involves the migration of a hydrogen from the
amine group and this series of fragments requires the loss of water, these fragments do
not occur when the amine group is a tertiary amine. Thus, the absence of these fragments
in the cathinone standards with tertiary amines (naphyrone, alphaphthalimidopropiophenone, alpha-pyrrolidinopropiophenone, and alphapiperidinobutiophenone) is unsurprising (Figure 2.1). In MTTA, the amine group is one
carbon further from the ketone than in a typical cathinone. The loss of water requires a
hydrogen migration from the amine to the oxygen on the ketone, a migration that requires
physical proximity. The longer carbon chain between the ketone and amine inhibits this
migration so the loss of water does not readily occur. The remaining cathinone,
benzedrone, has a secondary amine with a methyl-benzyl group substitution. Like other
cathinones with secondary amines, benzedrone does readily lose water. However,
benzedrone can fragment at either the ketone-aromatic bond or the methylbenzene-amine
bond to form a methyl-substituted aromatic ring as the charged species [C7H7]+. This ion
is resonance stabilized and dominates the higher collision potentials. The combined loss
of water and an aliphatic group present in other cathinones with secondary amines is not
observed.
As with the other cathinone fragments reported in the literature (7, 24), the loss of
water and aliphatic species as both radical and even-electron species at 20 and 40 V is not
common among all cathinones. However, this neutral loss composition could be used as
an indication of cathinones with aliphatic substitutions and a primary or secondary amine.

28

2.3.1.3 Fragmentation of methylenedioxy-substituted cathinones at increased collision
potentials
As a comparison to the aliphatic-substituted cathinones buphedrone and 3methylbuphedrone, butylone has the same amine and alpha-carbon substitutions but
differs with the presence of a methylenedioxy substitution on the ring. The chemical
structure for butylone as well as representative mass spectra collected using collision
potentials of 10, 20, and 40 V are shown in Figure 2.6. The ion corresponding to a neutral
loss of 48 Da (H2O + CH2O) at 10 V ([C11H12NO]+, m/z 174.09) is observed at 10 V and
has been previously noted to indicate a methylenedioxy substitution on the aromatic ring
(25). However, there are additional fragments that further distinguish this
methylenedioxy-substituted cathinone from those with aliphatic substitutions and can be
used to identify structural features associated with methylenedioxy substitutions.

29

butylone

[C10H9O2]+

%

100

Ion Relative Intensity

0

161.06

80

100

120

140

160

%

b) 20 V

146.10

200

105.07

60

80

100

161.06

131.07

120

191.07

140

220

m/z

160

180

204.10

209.01

200

220

m/z

Ÿ+

131.07 [C9H9N]

[C9H8N]+130.07
%

180

223.06

205.11

[C10H9O2]+ [C H NO ]Ÿ+
10 9
2
175.06
[C10H12N]+
[C12H14NO2]+

100

0

191.07
175.06

174.09 [C11H12NO]+

100

0

204.10

174.09
146.10

60

222.11

[C12H14NO2]+

[C11H12NO]+
a) 10 V

[C12H16NO3]+

[C11H11O3]+

[C10H9NO]Ÿ+
[C10H8NO2]+
174.06
[C11H10NO2]+

c) 40 V
[C H N]+
+ 8 8
+
[C
H
]
+
[C6H5] [C7H5] 8 7 118.07
77.04 89.04

60

80

146.10 159.07

103.05

100

120

140

160

Ion Mass-to-Charge (m/z)

175.06 188.07

180

200

209.01

220

m/z

Figure 2.6. CID-MS spectra for butylone at collision potentials of a) 10 V, b) 20 V and c)
40 V. All spectra were collected in positive-ion mode.

One fragment not previously discussed is present at m/z 161.06 in the 10 and 20 V
spectra of butylone (7, 27). This fragment corresponds to [C10H9O2]+ with an associated
neutral loss of C2H7NO from [M+H]+. Given the structure of butylone (Figure 2.6.a),
there is no single bond cleavage that would result in this loss, so the loss is most likely
due to a series of multiple fragmentation steps and rearrangements. One potential series
of losses involves the combined loss of both the methylamine group (CH5N) as well as
the loss of formaldehyde (CH2O) from a partial cleavage of the methylenedioxy ring. The
order of this series of losses cannot be confirmed from this data, although protonation of

30

the methylenedioxy group is more favorable. Protonation of the methyl group on the
aromatic ring in 3-methylbuphedrone is not likely, so a similar fragmentation pathway
involving the neutral loss of methylamine and a methyl group from the aromatic ring was
not observed in 3-methylbuphedrone. Thus, the fragmentation pathway leading to the
neutral loss of C2H7NO from butylone depends on the presence of the methylenedioxy
group on the aromatic ring.
As the collision potential increases and more extensive fragmentation occurs,
additional differences between butylone and the aliphatic-substituted cathinones are
observed. The fragments corresponding to the combined loss of water and an ethyl group,
as observed in buphedrone and 3-methylbuphedrone, are also present in butylone at m/z
175.06 ([C10H9NO2]Ÿ+) and m/z 174.06 ([C10H8NO2]+). However, these are present at
lower abundances in butylone than observed in buphedrone and 3-methylbuphedrone.
Notably, the base peak for butylone at 20 V corresponds to the loss of 48 Da (H2O +
CH2O) rather than the combined water and ethyl group loss. As observed with the loss of
methylamine and formaldehyde, the oxygens substituted on the aromatic ring provide
sites of protonation not present in buphedrone and 3-methylbuphedrone and lead to
alternate routes of fragmentation. In the case of butylone at 20 V, the fragments formed
through protonation and fragmentation of the ring substitution are present at higher
abundances than those produced through protonation of the ketone or amine.
Additionally, the fragments corresponding to the loss of water and a methyl group
or those for the loss of water, an ethyl group, and a methyl group are not observed in
butylone. This indicates that the pathway for fragmentation that leads to these water and
alkyl group losses is altered by the presence of the methylenedioxy group, which

31

provides more favorable losses. One of these butylone-specific losses is present as the
base peak at 40 V, which corresponds to the combined odd-electron loss of water,
formaldehyde, carbon monoxide, and a methyl group ([C9H9N]Ÿ+, m/z 131.07). Much like
in the water and alkyl losses of buphedrone and 3-methylbuphedrone, there is likely
rearrangement of the molecule during fragmentation, although the resulting losses here
indicate different rearrangements are occurring in butylone.
The comparison between buphedrone and 3-methylbuphedrone indicates that
similar structures yield analogous fragment ions. However, the differences in the number
and length of the alkyl chain substitution can still lead to fragment ions that allow
distinction between the cathinones, even when the same pathway is followed. The
comparison of CID mass spectra of buphedrone at the multiple collision energies with
those of butylone also demonstrates that, although they share a common core structure,
some substitutions can lead to different pathways. These differences in fragmentation
allow structural features unique to each cathinone to be identified and can aid in the
identification of new analogs.

2.3.2 Comparison of the fragmentation of cathinones and phenethylamines
The variation in fragmentation observed in cathinones that contain different
functional group substitutions can present an issue when distinguishing cathinones from
other designer drugs with similar core structures. This is especially true with
phenethylamines, whose core structure differs only by the lack of the ketone group.
Additionally, phenethylamines are often substituted with the same functional groups at
analogous positions as in the cathinones. To investigate how these classes of designer

32

drugs can be distinguished from each other, the cathinone buphedrone is compared to the
phenethylamine 2-methylamino-1-phenylbutane which has analogous functional group
substitutions.

2.3.2.1 Comparison of buphedrone and 2-methylamino-1-phenylbutane
Buphedrone fragmentation has been already discussed in section 2.3.1 (Figure
2.4), but several features are of note here. First, the most abundant ions observed at 10 V
correspond to [M+H]+, the loss of water, and the loss of methylamine. However, the base
peaks in the spectra collected at 20 and 40 V correspond to the loss of water plus the
ethyl group as odd- or even-electron species. Additionally, the range of fragment ions
grows increasingly complex as the collision potential increases.
The chemical structure for 2-methylamino-1-phenylbutane as well as
representative mass spectra collected using collision potentials of 10, 20, and 40 V are
shown in Figure 2.7. Although the difference in structure between 2-methylamino-1phenylbutane and buphedrone is only in the presence of the beta-ketone, the
fragmentation patterns of these compounds are markedly different. With no oxygen
present, 2-methylamino-1-phenylbutane does not (and cannot) lose water and the extent
of structural rearrangements is more limited, even at the highest collision potential. The
fragments that are present in 2-methylamino-1-phenylbutane are driven by the protonated
amine and indicate structural features common to both 2-methylamino-1-phenylbutane
and buphedrone. For example, the fragment [C10H13]+ (m/z 133.10) in 2-methylamino-1phenylbutane corresponds to the loss of the methylamine, while [C7H7]+ (m/z 91.05) and
[C5H5]+ (m/z 65.04) indicates the presence of an aromatic ring. These substructures are

33

present in both buphedrone and 2-methylamino-1-phenylbutane. However, with the
ketone in buphedrone providing an alternate site of protonation, the extent of
fragmentation and additional losses in buphedrone can be used to distinguish these two
drugs.

2-methylamino-1-phenylbutane
H
N

164.14

100
%

[C11H18N]+

Ion Relative Intensity

91.05

0
50

[C10H13]+

[C7H7]+

133.10

a)2-methylamino-1-phenylbutane
10 V
Item #15961
60
70

80

90

100

110

120

130

140

150

160

170

180

190

m/z
200

120

130

140

150

160

170

180

190

m/z
200

120

130

140

150

160

170

180

190

m/z
200

91.05 [C7H7]+

%

100

0
50

b) 20 V
60

70

80

90

100

110

91.05 [C7H7]+

100
%

c) 40 V
[C5H5]+

0
50

65.04

60

70

80

90

100

110

Ion Mass-to-Charge (m/z)

Figure 2.7. CID-MS spectra for the phenethylamine 2-methylamino-1-phenylbutane at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.

2.3.2.2 Additional phenethylamine (2C-E) and overall comparison
While the spectra for 2-methylamino-1-phenylbutane may suggest that extremely
simple fragmentation patterns are common among phenethylamines, there can be
extensive fragmentation when the phenethylamine is more intricately substituted. As an
34

example, the chemical structure for the phenethylamine 2,5-dimethoxyethylamphetamine
(2C-E) as well as representative mass spectra collected using collision potentials of 10,
20, and 40 V are shown in Figure 2.8. For 2C-E, the 10 V spectrum remains simple, with
the most abundant ions corresponding to the protonated molecule ([C12H20NO2]+, m/z
210.15), loss of ammonia ([C12H17O2]+, m/z 193.12), and loss of ammonia plus a methyl
radical ([C11H14O2]Ÿ+, m/z 178.10). The loss of ammonia plus ethene ([C10H13O2]+, m/z
165.10) is also present, albeit at low relative abundance (1.1%). These fragmentation
pathways are driven by protonation of the nitrogen in the amine group, a more polar site
than the oxygens in the ether functional groups of the methoxy substitutions. Thus, these
pathways are more common among phenethylamines than cathinones since the ketone
group of the cathinones is the more favorable site of protonation.

35

O

2C-E

NH 2

193.12

%

100

2C-E
Item #15699

a) 10 V

[C11H14O2]Ÿ+ [C12H20NO2]+
O

60

80

165.10

100

120

140

160

0

[C9H11O]+

b) 20 V

]+

[C8H9

105.07

91.06

60

80

]+

[C6H7
%

180

200

220

m/z

178.10

100

0

210.15

178.10

[C11H14O2]Ÿ+

100
%

Ion Relative Intensity

0

[C12H17O2]+

79.05

c) 40 V
60

100

[C8H9]+

140

160

193.13
179.11

180

210.08

200

220

200

220

m/z

[C10H11O2]+
163.07

7

103.06

[C7H7]+
91.06

80

120

105.07
+
H ]+ 115.05 [C9H7]

[C8

[C10H11O2]+

135.08
163.08
134.07
148.09

100

[C10H12O2]
133.07
164.08
145.06 149.06
124.08
120

140

160

180

Ÿ+

m/z

Ion Mass-to-Charge (m/z)

Figure 2.8. CID-MS spectra for the phenethylamine 2C-E at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

With increased collision potential again comes more extensive fragmentation for
2C-E. While some of these fragments are indicators of the aromatic ring (e.g. [C7H7]+ at
m/z 91.06 and [C6H7]+ at m/z 79.05), most fragments for 2C-E at 20 and 40 V are the
result of multiple losses and rearrangements. This observation is analogous to
fragmentation observed in the cathinones discussed in section 2.3.1 However, a main
difference between these compounds is that the loss of water from the ketone group is the
most abundant loss observed in the cathinones at 10 V, while the loss of the amine group

36

dominates for the phenethylamines, according to the acidity of the site of protonation.
Overall, these differences provide the basis for a classification scheme to facilitate
distinction of cathinones from phenethylamines.

2.3.3 Cathinone and phenethylamine classification
2.3.3.1 Development of a classification scheme
Given that the cathinone and phenethylamine classes include a variety of possible
functional groups as substitutions, a training set of nine cathinones and seven
phenethylamines was selected to represent a range of possible structures (Figures 2.1.a.-i.
and 2.2.a.-f., respectively). The spectra at 10 V for the phenethylamines (Figure 2.9) and
cathinones (Figure 2.10.) were initially interrogated to identify the molecular formulae
for ions of highest abundance. Of specific interest were the ion compositions or
corresponding neutral losses that were specific to only one of the two drug classes. Once
identified, these provided a foundation for the generation of a classification scheme. As
seen with the phenethylamine 2C-E discussed in the previous section, the base peak for
the all three 2C phenethylamines (2C-E, 2C-B, and 2C-T; Figure 2.9.a-c, respectively)
corresponds to the loss of the amine group rather than the protonated molecular ion,
denoted [M+H]+. Thus, these compounds can be distinguished from the rest of the
training set based on that characteristic.

37

2C-E
193.12

100

165.10 178.10

%

0
50

75

100

125

150

175

[M+H-NH3]+

210.15

200

%

100

0
50

75

100

250

125

150

175

200

%

196.06

75

100

125

150

175

200

225

%

75

100

125

100

150

135.04

75

100

125

175

200

%

0
50

[C7H7

91.05

75

100

163.08

150

250

175

200

b) 2C-B
300

250

%

100

275

300

[M+H-H2O]+ [M+H]+
278.21
260.20

225

250

275

325

m/z
350

m/z
350

d) Venlafaxine
300

325

m/z
350

[M+H]+

222.15
223.15

225

250

e) 3,4-MDPA
275

300

325

m/z
350

f) 2-methylamino-1-phenethylamine

133.10

125

150

175

200

125

150

225

250

275

300

175

200

225

250

275

325

m/z
350

[M+H]+

330.21
330.26

g) 25E-NBOMe

121.07

75

c) 2C-T

228.11

225

325

m/z
350

164.14

[M+H-C12H19NO]+

100

0
50

275

325

[M+H]+

]+

100

300

260.03

215.14

[M+H-C3H9N]+

0
50

275

[M+H-NH3]+
243.00 [M+H]+

100

0
50

a) 2C-E

[M+H-NH3]+
211.08
[M+H]+

%

Ion Relative Intensity

225

227.98

100

0
50

[M+H]+

300

325

m/z
350

Ion Mass-to-Charge (m/z)

Figure 2.9. CID-MS spectra of the training set phenethylamines collected in positive
mode at a collision potential of 10 V.

The remaining compounds in the training set all have [M+H]+ as the base peak.
Of those compounds with [M+H]+ as the base peak, one phenethylamine (venlafaxine,
Figure 2.9.d) and five of the cathinones (α-phthalimidopropiophenone, butylone,
buphedrone, 3-methylbuphedrone, and benzedrone; Figures 2.10.a-e, respectively) have
the fragment corresponding to the loss of water as the 2nd most abundant ion at 10 V. For

38

these cathinones and phenethylamine, their base peaks at 20 V can be used to distinguish
between them (Figure 2.11.). The only phenethylamine in this grouping, venlafaxine,
differs from the other phenethylamines in that it has an alcohol group that gives rise to
the loss of water at 10 V, a loss that is not otherwise observed among phenethylamines in
the training set. To differentiate venlafaxine from cathinones with similar base peak at 10
V, the base peak at 20 V can be used. At 20 V, venlafaxine fragments to leave the ion
[C8H9O]+ as the base peak (Figure 2.11.a), a fragment and corresponding neutral loss
(C9H19NO) that is unique among this group of compounds to venlafaxine, differentiating
it from the cathinones. The base peaks for the five cathinones at 20 V vary in
composition and include fragment ions corresponding to the loss of water in αphthalimidopropiophenone (Figure 2.11.b), the combined loss of water and formaldehyde
in butylone (Figure 2.11.c), and the combined loss of water and an alkyl radical in
buphedrone and 3-methylbuphedrone (Figure 2.11.d-e). The [C7H7]+ ion, an indicator of
an aromatic ring, is also the base peak for benzedrone at 20 V (Figure 2.11.f).

39

a-phthalimidopropione
O]+

[M+H-H2

%

100

0
50

133.07

75

174.06

[M+H]+

280.10
a) α-phthalimidopropiophenone
262.09 281.10

m/z
100 125 150 175 200 225 250 275 300
+
[M+H-H2O]+ [M+H]
222.11
204.10
161.06174.09

100

%

b) Butylone
0
m/z
buphedrone
50 75 100 125 150 175 200 225 250 275 300
+
[M+H-H2O] [M+H]+
160.11 178.12

%

100

0
50

0
50

%

100

0
50

174.13 192.14

100

0
50

146.10 161.10

d) 3-methylbuphedrone
m/z
75 100 125 150 175 200 225 250 275 300
[M+H]+
+
[M+H-H2O] 254.15
236.14 255.16 e) Benzedrone
91.05
146.10
m/z
75 100 125 150 175 200 225 250 275 300
[M+H]+
105.07

[M+H-C4H9N]+

%

Ion Relative Intensity

%

100

75

132.08 147.08

c) Buphedrone
m/z
100 125 150 175 200 225 250 275 300
[M+H-H2O]+ [M+H]+

91.05

f) α-PPP
m/z
100 125 150 175 200 225 250 275 300
[M+H]+
133.07

75

100

[M+H-C4H9N]+

%

0
50

211.11

75

%

100

0
50

75

282.19

g) Naphyrone
282.23

m/z
100 125 150 175 200 225 250 275 300
[M+H]+
+
[M+H-C2H5N] 190.12
147.08
h) MTTA
m/z
100 125 150 175 200 225 250 275 300
[M+H]+
232.17
232.21

%

100

0
50

204.14
204.18

75

i) α-piperidinobutiophenone
m/z
100 125 150 175 200 225 250 275 300
Ion Mass-to-Charge (m/z)

Figure 2.10. CID-MS spectra of the training set cathinones collected in positive mode at a
collision potential of 10 V.

40

venlafaxine

%

100
0

121.07

a) Venlafaxine
60

0

100
0

0

60

140

177.11

160

180

245.00

200

220

240

80

100

120

140

80

174.06

160

180

200

100

174.09
175.06

131.07 146.10

120

100

120

91.05 105.07

80

100

[C7H7]+
91.06

140

%

80

220

240

260

280

m/z
300

204.10 225.04

160

140

160

144.08 146.10
131.07

120

140

160

180

200

220

240

260

280

m/z
300

180

200

220

240

260

280

m/z
300

200

220

240

260

280

m/z
300

100

280

m/z
300

174.13

180

f) Benzedrone
131.07 146.10

60

280.10

[M+H-CH4O2]+

[M+H-H2O-C2H5]Ÿ+
e) 3-methylbuphedrone 145.09
[M+H-H2O]+
60

m/z
300

132.08 160.11

91.06

80

280

[M+H-H2O]+

220.07

[M+H-H2O-C2H5]Ÿ+
131.07
[M+H-H2O]+
d) Buphedrone 130.07
60

260

[M+H-H2O]+

105.07

60

278.21

262.09

133.07

c) Butylone

100
0

120

105.07
105.04

%

100

100

260.20

b) α-phthalimidopropiophenone

%

100

%

Ion Relative Intensity

0

80

[M+H-H2O]+

215.15

147.08 159.08

135.08

77.04 93.08

%

100

[C8H8O]+

120

140

162.09

160

180

236.14

204.10

200

220

240

254.16

260

Ion Mass-to-Charge (m/z)

Figure 2.11. CID-MS spectra of one phenethylamine and five cathinones from the
training set collected in positive mode at a collision potential of 20 V.

The remaining compounds in the training set compounds are the phenethylamines
3,4-MDPA, 2-methylamino-1-phenylbutane and 25E-NBOMe (Figure 2.9.e-g,
respectively) and the cathinones α-PPP, naphyrone, MTTA and αpiperidinobutiophenone (Figure 2.10.f-i, respectively). These compounds have [M+H]+
as the base peak but do not have the fragment corresponding to the loss of water as the

41

second most abundant ion. Like the 2C compounds, the phenethylamines 3,4-MDPA and
2-methylamino-1-phenylbutane also lose their amine group, although this peak is second
in abundance to the molecular ion (Figure 2.9.e-f). The second most abundant ion for the
remaining phenethylamine, 25E-NBOMe, at 10 V also results from the cleavage at the
amine bond (Figure 2.9.g). However, the NBOMe series of phenethylamines have a
second aromatic ring connected via the amine group and the most abundant fragment ion
corresponds to a cleavage at the amine with the charge on this second aromatic rather
than the one associated with the phenethylamine core structure. This is a driven by the
location of protonation - the nitrogen of the amine group. Charge-directed fragmentation
at the location of protonation is more kinetically favorable than a charge-remote
fragmentation of the other aromatic ring. Since the resulting fragment ions, both charged
aromatic rings, have the same resonance stability, it is the charge-directed fragmentation
that dominates.
The 2nd most abundant ion for the cathinones α-PPP, naphyrone, and MTTA
corresponds to the loss of their substituted amine group (Figure 2.10.f-h). The amine
groups in α-PPP and naphyrone are pyrrolidines, or 5-membered rings that include the
nitrogen, so there is no hydrogen on the amine group to facilitate the water loss observed
in other cathinones. While there are other hydrogens present in the molecule, those on the
nitrogen are more acidic (weaker held) than those bonded to carbons. Thus, it is not
thermodynamically favorable for a hydrogen migration to occur from an alkyl chain to
facilitate water loss.
Although classified as a cathinone, the amine group in MTTA is one alkyl chain
length farther from the ketone than in the typical cathinone. As noted previously, the loss

42

of water is also facilitated by the proximity of the ketone to the amine, then this increased
spacing is consistent with the amine loss for MTTA being the second most abundant ion
at 10 V (Figure 2.10.h). Interestingly, α-piperidinobutiophenone did not produce any
fragments greater than 1% relative abundance at 10 V (Figure 2.10.i) and the only ion
present is the [M+H]+ (no fragments observed). Leveraging all of these mass spectral
features, an initial scheme for classification was built (Figure 2.12).

43

Composition
of base peak
at 10 V

[M+H]+

Composition
2nd most
abundant ion
at 10 V

Phenethylamine
2C-T
2C-B
2C-E

[M+H-NCxH(2x+1)]+

Cathinone

No 2nd ion

α-piperidinobutiophenone

Phenethylamine

[M+H-C12H19NO2]+

25E-NBOMe

Cathinone
MTTA
α-PPP
Naphyrone

[M+H-NCxH(2x+1)]+

Phenethylamine
[M+H-NCxH(2x+3)]+

3,4-MDPA
2-methylamino-1-phenylbutane

[M+H-H2O]+

Cathinone

[M+H-H2O]+

α-phthalimidopropriophenone

Cathinone

[M+H-CH4O2]+

Composition
of base peak
at 20 V

Butylone

[M+H-H2O-CxH(2x+1)] Ÿ+

Cathinone
Buphedrone
3-methylbuphedrone

Cathinone

[C7H7]+

Benzedrone

Phenethylamine

[C8H9O]+

Venlafaxine

Figure 2.12. Scheme for cathinone and phenethylamine class identification using the
most abundant ions present in the 10 and 20 V spectra.

44

2.3.3.2 Testing of the classification scheme
While the scheme in Figure 2.12 correctly assigns the cathinones and
phenethylamines in the training set of compounds, this must be tested for use with an
additional set of compounds. A test set containing six isomers of compounds was
analyzed, including five cathinones and one phenethylamine, the structures of which can
be seen in Figures 2.1.j.-n and 2.2.g, respectively. The mass spectra for each compound at
collision potentials of 10 V and, when needed, 20 V (Figure 2.13) were used to classify
each compound according the scheme. The results of the classification are outlined below
and summarized in Figure 2.14.
Three compounds in the test set were correctly assigned. The base peak for the
phenethylamine 2C-G at 10 V corresponds to the loss of the amine group (Figure 2.13.a).
This is consistent with the 2C phenethylamines in the training set of compounds, so 2C-G
was correctly classified 2C-G as a phenethylamine. The base peak at 10 V for both
cathinones 3-ethylmethcathinone and ethylone (Figure 2.13.b and d, respectively) is the
molecular ion and both have the fragment corresponding to the loss of water as the 2nd
most abundant ion. At 20 V, the base peak for 3-ethylmethcathinone corresponds to the
loss of water and an ethyl group as a radical (Figure 2.13.c). This classifies 3ethylmethcathinone similarly to its isomer buphedrone and correctly assigns it as a
cathinone. For ethylone, the base peak at 20 V corresponds to the combined loss of water
and formaldehyde (Figure 2.13.e). This is similar to the fragmentation in butylone and
correctly assigns ethylone as a cathinone.

45

N-ethyl-N-methylcathinone

[M+H-NH3]+

178.10 193.12

%

100
0

163.11

60

80

100

120 140 160 180 200
[M+H-H2O]+174.13 [M+H]+
192.14

%

100
0

146.10

60

80

100

120 140 160 180
[M+H-H2O-C2H5]Ÿ+

%

100

105.07

0

bk-MDEA
60

80

100

%
%

0

100

%

Ion Relative Intensity

100

0

%

100
0

%

100
0

%

100
0

200

220

145.09
146.10 174.13
131.07

120

140

160

180

200

[M+H-H2O]+

100
0

[M+H]+
a) 2C-G
10 V
m/z
220 240

210.15

147.04

174.09

204.10

b) 3-ethylmethcathinone
10 V
m/z
240
c) 3-ethylmethcathinone
20 V
m/z
240

220
[M+H]+

222.11 d) Ethylone
222.2210 V

m/z
160 180 200 220 240
[M+H-CH4O2]+
174.09 [M+H-H O]+ e) Ethylone
2
204.10 222.22
20 V
146.10
119.05
m/z
60
80 100 120 140 160 180 200 220 240
[M+H-H2O]+ [M+H]+
160.11 178.12
f) 2-methylmethcathinone
10 V
119.09 145.09
m/z
60
80 100 120 140 160 180 200 220 240
[M+H]+
192.14
+
g) N-ethyl-N-methylcathinone
[M+H-C3H9N]
192.18
10 V
105.07 133.07
m/z
60
80 100 120 140 160 180 200 220 240
[C8H9]+
[M+H]+
105.07
h) N-ethyl-N-methylcathinone
192.14
133.07 146.10
77.04 86.10
20 V
m/z
60
80 100 120 140 160 180 200 220 240
[M+H]+
[M+H-CH4O2]+
222.11 i) 2,3-ethylone isomer
174.09
222.23
204.10
10 V
147.04
m/z
60
80 100 120 140 160 180 200 220 240
60

80

100

120

140

Ion Mass-to-Charge (m/z)

%

100

118.07

133.05 146.10

174.09

204.10

222.22

m/z
Figure02.13. CID-MS spectra of one phenethylamine and five cathinones
from the test set
60

80

100

120

140

160

180

200

220

240

collected in positive mode at collision potentials of 10 and 20 V.

46

Phenethylamine

Composition
of base peak
at 10 V

2C-T
2C-E

[M+H-NCxH(2x+1)]+

Cathinone

No 2nd ion

[M+H]+

α-piperidinobutiophenone

Phenethylamine

[M+H-C12H19NO2]+

Composition
2nd most
abundant ion
at 10 V

2C-B
2C-G

25E-NBOMe

Cathinone
[M+H-NCxH(2x+1)]+

MTTA
α-PPP
Naphyrone

Phenethylamine
3,4-MDPA
2-methylamino-1-phenylbutane
(N-ethyl-N-methylcathinone)

[M+H-NCxH(2x+3)]+
[M+H-H2O]+

Cathinone

[M+H-H2O]+

α-phthalimidopropriophenone

Cathinone

Composition
of base peak
at 20 V

[M+H-CH4O2]+

Butylone
Ethylone

[M+H-H2O-CxH(2x+1)] Ÿ+

Buphedrone
3-methylbuphedrone
3-ethylmethcathinone

Cathinone

Cathinone

[C7H7]+

Benzedrone

Phenethylamine

[C8H9O]+

Venlafaxine

Uncategorized Cathinones
2,3-ethylone isomer
2-methylmethcathinone

Figure 2.14. Scheme for cathinone and phenethylamine class identification from Figure
2.12 with the addition of the test set of isomers (in bold). Incorrect assignments are
indicated by parentheses.

47

Following the same method for classification, the cathinone N-ethyl-Nmethylcathinone is incorrectly categorized as a phenethylamine. Like other cathinones,
[M+H]+ is the base peak at 10 V for N-ethyl-N-methylcathinone (Figure 2.13.g).
However, the second most abundant ion corresponds to the loss of the amine in the form
of NCxH(2x+3). This incorrectly categorizes N-ethyl-N-methylcathinone as a
phenethylamine. To differentiate N-ethyl-N-methylcathinone from 2-methylamino-1phenylbutane and 3,4-MDPA, the base peak at 20 V can be used. The base peaks for 2methylamino-1-phenylbutane and 3,4-MDPA correspond to the amine loss (Figures B.1.
and B.7. in the Appendix) while the base peak for N-ethyl-N-methylcathinone
corresponds to an ethyl-substituted aromatic species, [C8H9]+(Figure 2.13.h). The
classification scheme will be revised to reflect this difference and correctly classify Nethyl-N-methylcathinone as a cathinone.
In addition to the incorrectly classified cathinone, two cathinones, 2methylmethcathinone and the 2,3-ethylone isomer, were categorized as neither a
cathinone nor a phenethylamine using the scheme produced by the training set. Unlike
other cathinones, the base peak at 10 V for 2-methylmethcathinone corresponds to the
loss of water (Figure 2.13.f). While this fragment is commonly observed in cathinones,
the loss of water was at a lower abundance than [M+H]+ in other cathinones. An
additional path through the flowchart can be added to classify 2-methylmethcathinone
based on the fragment corresponding to the loss of water as a base peak. The other
unclassified cathinone, the 2,3-ethylone isomer, is similar to its isomers butylone and
ethylone in that the base peak for the 2,3-ethylone isomer at 10 V is [M+H]+ (Figure
2.13.i). However, the next most abundant ion does not correspond to the loss of water but

48

rather corresponds to the combined loss of water and formaldehyde. While the combined
loss of water and formaldehyde distinguishes butylone and ethylone from other
cathinones as the base peak at 20 V, the classification scheme must be adjusted to add an
option of this loss as the second most abundant ion at 10 V to correctly classify the 2,3ethylone isomer as a cathinone.
The alterations described above were added to the classification scheme to
properly identify all compounds in the test set as either phenethylamines or cathinones.
The revised scheme is shown in Figure 2.15.

49

Phenethylamine
Composition
of base peak
at 10 V

[M+H]+

Composition
2nd most
abundant ion
at 10 V

[M+H-NCxH(2x+1)]+

2C-T
2C-E

2C-B
2C-G

Cathinone

[M+H-H2O]+

2-methylmethcathinone

Cathinone

No 2nd ion

α-piperidinobutiophenone

Phenethylamine

[M+H-C12H19NO2]+

25E-NBOMe

Cathinone
[M+H-NCxH(2x+1)]+

MTTA
α-PPP
Naphyrone

Cathinone

[M+H-CH4O2]+

2,3-ethylone isomer

[M+H-NCxH(2x+3)]+

Phenethylamine
Composition
of base peak
at 20 V

[M+H-H2O]+

Composition
of base peak
at 20 V

[M+H-NCxH(2x+3)]+

3,4-MDPA
2-methylamino-1-phenylbutane)

Cathinone

[C8H9]+

N-ethyl-N-methylcathinone

[M+H-H2O]+

α-phthalimidopropriophenone

Cathinone
Cathinone

[M+H-CH4O2]+

Butylone

Ethylone

Cathinone
[M+H-H2O-CxH(2x+1)] Ÿ+

Buphedrone
3-methylbuphedrone
3-ethylmethcathinone

Cathinone

[C7H7]+

Benzedrone

Phenethylamine

[C8H9O]+

Venlafaxine

Figure 2.15. Revised scheme for cathinone and phenethylamine identification using the
most abundant ions present in the 10 and 20 V spectra.

50

2.3.3.3 Literature comparison of the revised classification scheme
As an additional test for the revised scheme, spectra of cathinones and
phenethylamines analyzed by CID-MS techniques and published in three different studies
in the literature were assessed. These studies used a variety of cathinone and
phenethylamine standards (Figure 2.16) analyzed by different instruments and under
varying CID-MS conditions. The use of spectra from the literature gives an indication of
how accurate this classification scheme is when used by other laboratories.
In the first of these studies, Welter et al. used CID-MS to identify the
phenethylamines 6-APB and 6-MAPB, along with their associated 5-isomers, acetylated
ions, and metabolites from urine samples (30). The CID-MS spectra of unacetylated 6APB and 6-MAPB standards were presented. However, the exact collision potential used
was not clear but is presumed to not have varied between samples. From the published
spectra, the base peaks for 6-APB and 6-MAPB were identified to correspond to losses of
C2H7N and CH5N, respectively, from [M+H]+. Using the revised scheme in Figure 2.15,
these base peaks would correctly classify these compounds as phenethylamines. While
the collision potential used was unclear, the correct assignment of these phenethylamines
using the reported spectra is a positive indicator that this scheme can be used to correctly
assign spectra obtained across multiple laboratories.

51

a) 6-APB

b) 6-MAPB

c) Buphedrone

d) Pentedrone

e) 4-methylethcathinone

f) 3,4-dimethylcathinone

g) N-ethylcathinone

h) Methylone

i) Pentylone

j) MDPBP

k) MDPV

l) BMDP

Figure 2.16. Structures of cathinone and phenethylamine structures composing the
literature test set of compounds.
52

In the second study used to test the classification scheme, Snyder et al. used
cathinone isomers as part of a larger set of organic compounds to compare traditional
CID-MS with a multigenerational CID-MS method that would fragment the fragments
produced in CID-MS (31). CID-MS was performed using resonant excitation in a linear
ion trap with the collision potential used reported in “arbitrary units.” As such, it is
unclear how the voltage used to generate Snyder’s data set compares to those used here.
However, Snyder’s data set does include buphedrone, which was also analyzed in this
work. Visual comparison of the spectra, focusing on the composition of the fragments
present and the relative abundances, suggests that Snyder’s analysis using tradition CIDMS is most similar to the 10 V collision potential used in this work. One major
difference, though, is that the fragment corresponding to the loss of water is the base peak
in Snyder’s buphedrone spectrum, while this fragment is the peak of second highest
abundance in the 10 V buphedrone spectra generated in this work. However, using the
loss of water as the base peak at 10 V does correctly assign buphedrone as a cathinone,
even if it does not follow the same path through the flowchart as the buphedrone standard
in the training set. The other cathinones reported in Snyder’s studies (pentedrone, 4methylethcathinone, 3,4-dimethylcathinone, and N-ethylcathinone) all had the same
attribute of the base peak corresponding to the loss of water. Thus, all cathinones would
result in the correct assignment as cathinones when using the revised classification
scheme.
The final study, a work by Fornal in 2013 (25), is the most closely comparable
with the data collected here. Fornal’s work analyzed a series of 3,4-methylenedioxy
substituted cathinones using CID-MS with 10, 20 and 40 V collision potentials. The

53

cathinone butylone is included in both Fornal’s data set and the one reported here,
providing a point of direct comparison between the two data sets. The butylone spectra in
the literature exhibited [M+H]+ as the base peak at 10 V with the loss of water as the
second most abundant ion at this potential. At 20 V, the loss of 48 Da, attributed to
methanediol (CH4O2) by Fornal, is the base peak at 20 V. This series of fragments
correctly assigns butylone as a cathinone following the same progression through the
classification scheme as the butylone standard analyzed in this work. This indicates that
the data sets are comparable.
Four other cathinones in Fornal’s work are correctly identified using the revised
flow chart. The cathinones methylone, pentylone, MDPBP, and MDPV (Figure 16.h-k,
respectively), all shared the same pathway through the flowchart as butylone and
ethylone. The final cathinone, BMDP, remained uncategorized. This cathinone has the
same core structure as methylone but with an aromatic substitution on the amine, similar
to benzedrone (Figure 2.16.l). Unlike either methylone or benzedrone, the ion of second
highest abundance at 10 V does not correspond to the loss of water but rather is the
[C7H7]+ ion. Analogous to the observation of this ion as the base peak for benzedrone at
20 V, this loss occurs by cleavage of the aromatic ring substituted on the amine group.
However, given that this is more abundant than the loss of water at 10 V in BMDP, this
cathinone remains uncategorized, even under the revised scheme. This indicates that,
while the characterization scheme does successfully identify a number of literaturereported cathinones and phenethylamines, there remains room for improvement.

54

2.4 Conclusion
Designer drugs in the cathinone and phenethylamine classes have similar core
structures and, with a variety of different substituents and substitution sites, can include a
broad range of compounds. CID-MS at multiple collision potentials fragments these
compounds, allowing structural features of the compounds to be identified. These
features can be used to understand how the structure itself is arranged, including the
location and composition of the substituents. Additionally, the proposed scheme can
utilize the fragmentation as a method for distinguishing cathinones from
phenethylamines. The compounds investigated here covered a range of potential
substituents and structural arrangements. These built a foundational classification scheme
that successfully assigned cathinones from the literature, even when the conditions of
data acquisition were not identical. This facilitates incorporation of the scheme across
multiple laboratories for the identification of unknowns. The scheme can also be
continually expanded and refined as new standards become available for emerging
cathinone and phenethylamine analogs. Ultimately, the scheme provides a quick
reference for classifying suspected drugs as cathinones or phenethylamines and lays a
foundation for the identification of new analogs.

55

CHAPTER THREE: Characterization and Differentiation of Cathinone Isomers

3.1 The isomer problem
The previous chapter described the distinction of cathinones from the structurally
similar class of designer drugs, phenethylamines, based on characteristic mass spectral
features at a range of collision potentials. In this chapter, the focus is turned to the
specific identification of isomeric compounds. Isomers of a compound have the same
chemical formulae but differing structural arrangements. For isomers within the same
drug class, there are many similarities in the structures so the molecular ions and many of
the fragments at low collision potentials will have the same m/z value. While this allows
isomers to be identified as similar compounds, scheduling of emerging synthetic
cathinones requires the identity of the cathinone to be confirmed. To address how CIDMS can be used specifically for isomer differentiation, three sets of cathinone isomers
were investigated. The structures for each compound are shown in Figure 3.1.

56

O

O

a)

d)

f)

N

O
N-ethyl-N-methylcathinone
Item #11604
H
N

O
O

H
N

b)

H
N

c)

O

3-Ethylmethcathinone
Item #9001082 H

e)

3-Methylbuphedrone
Item #12001

N

O

O
2-methylmethcathinone

O

Buphedrone
Item #11283

O

H
N

g)O

H
N

H
N

O

O

2,3-Ethylone isomer
Item #9002142

h) O

bk-MDEA
Item #9001123

Butylone
Item #10393

Figure 3.1. Structures for cathinone isomers investigated. Set 1 isomers (molecular
formula C12H17NO) include a) N-ethyl-N-methylcathinone, b) 3-ethylmethcathinone, and
c) 3-methylbuphedrone. Set 2 isomers (molecular formula C11H15NO) include d)
buphedrone and e) 2-methylmethcathinone. Set 3 isomers (molecular formula
C12H15NO3) include f) 2,3-ethylone isomer, g) ethylone, and h) butylone.

The isomers in Set 1 and 2 have aliphatic substitutions, while those in Set 2 have
one less carbon present in the alkyl chains than those in Set 1. Of the five aliphaticsubstituted cathinones in Sets 1 and 2, only buphedrone is currently regulated as a
Schedule I drug. Isomer Set 3 includes three cathinones with a methylenedioxy
substitution on the aromatic ring: butylone, ethylone, and the 2,3-ethylone isomer. The
location of the methylenedioxy substitution and length of the aliphatic chain at the alphacarbon and amine position vary among the structures. Butylone and ethylone are
currently Schedule I substances while the 2,3-ethylone isomer is unregulated. With some
of the isomeric cathinones regulated and others not, it becomes increasingly important to
distinguish isomers from each other.

57

3.2 Fragmentation of aliphatic-substituted cathinone isomers: Set 1
Chemical structures for three aliphatic-substituted isomers (N-ethyl-Nmethylcathinone, 3-ethylmethcathinone, and 3-methylbuphedrone) and representative
mass spectra at 10 V are shown in Figure 3.2. These isomers differ in the alkyl chain
length at the 3-position on the aromatic ring, on the alpha carbon, and on the amine.

O

N-ethyl-N-methylcathinone

[C12H18NO]+

N

192.14

100
%

[C8H9]+
N-ethyl-N-methylcathinone
a) N-ethyl-N-methylcathinone
Item #11604

60

70

80

90

100

110

192.18

133.07

105.07

120

130

140

150

160

170

100

174.13

H
N

0
50

60

70

80

O

90

146.10

100

110

120

130

140

150

160

60

Item #12001

70

80

90

170

180

174.13

%

0
50

c) 3-methylbuphedrone
3-Methylbuphedrone

m/z
200

192.14

161.10

H
N

100

190

[C10H12N]+[C H O]+
11 13

b) 3-ethylmethcathinone
3-Ethylmethcathinone
Item #9001082

180

[C12H16N]+

O

%

Ion Relative Intensity

0
50

[C9H9O]+

[C10H13]+

133.10 146.10

105.07

100

110

120

130

140

Ion Mass-to-Charge (m/z)

150

190

m/z
200

192.14

161.10

160

170

180

190

m/z
200

Figure 3.2. CID-MS spectra for a) N-ethyl-N-methylcathinone, b) 3-ethylmethcathinone,
and c) 3-methylbuphedrone, collected in positive-ion mode at a collision potential of 10
V.

For all three isomers, [M+H]+ ([C12H18NO]+, m/z 192.14) is the base peak at 10 V.
In the spectra for 3-ethylmethcathinone and 3-methylbuphedrone (Figure 3.H, b and c),
the ion of second highest abundance is the fragment ion [C12H16N]+ (m/z 174.13). This

58

corresponds to the loss of water from the molecular ion, a common loss for cathinones
with a primary or secondary amine (7, 27). As N-ethyl-N-methylcathinone is a tertiary
amine, loss of water from the molecular ion is not observed (Fig. 3.2.a). This
distinguishes N-ethyl-N-methylcathinone from 3-ethylmethcathinone and 3methylbuphedrone.
The loss of the amine group is also a common loss in cathinones and can also be
used to distinguish N-ethyl-N-methylcathinone from the other two isomers (7, 27). In Nethyl-N-methylcathinone, loss of the amine group results in a fragment ion at m/z 133.07
([C9H9O]+) whereas, for the other two isomers, loss of the amine group results in a
fragment ion at m/z 161.10 ([C11H13O]+). In addition, the abundance of this fragment ion
differs between 3-ethylmethcathinone and 3-methylbuphedrone (6.0% compared to
22.2%, respectively), enabling distinction of these two isomers.
Further differentiation of the isomers 3-ethylmethcathinone and 3methylbuphedrone is realized at higher collision potentials. The CID spectra for 3ethylmethcathinone and 3-methylbuphedrone at 20 and 40 V are shown in Figure 3.3.
These spectra are extremely similar, with only a few differences. Specifically, there are
two fragments that are common to both isomers but have a greater than 10% difference in
relative abundance between 3-ethylmethcathinone and 3-methylbuphedrone at higher
energies: [C11H13N]Ÿ+ (m/z 159.10) and [C8H9]+ (m/z 105.07).

59

174.13

192.14

%

100

146.10

0
50

60

70

80

O

100

90

100

110

120

130

140

161.10

150

160

[C10H11N]Ÿ+

170

180

%

%
%

O

100

80
80

90
90

100
100

70

80

+

m/z
m/z
110 120
120 130
130 140
140 150
150 160
160 170
170 180
180 190
190 200
200
110

[C10H11N]Ÿ+
145.09

H
N

90

144.08
146.10

119.05

100

110

[C11H13N]Ÿ+

[C10H10N]+

105.07

c) 3-methylbuphedrone
20 V
91.05
60

192.14

[C
11H12N]
161.10
130.07 143.07
145.09
158.10
146.10
103.05
105.07115.05
133.10
91.06

[C8H9

0
50

174.13

[C9H8N]+

]+

%

Ion Relative Intensity

b) 3-ethylmethcathinone
40 V
[C6H5]+ [C7H7]+
70
70

m/z
200

146.10

144.08

100
100

60
60

190

[C10H10N]+

[C11H13N]Ÿ+174.13
[C8H9]+
a) 3-ethylmethcathinone
159.11
131.07
105.07
20 V
0
3-methylbuphedrone
50
60
70
80
90 100 110 120 130 140 150 160 170 180
[C10H10N]+

77.04

m/z
200

145.09

H
N

144.08

00
50
50

190

120

131.07

130

159.10 174.13

158.10

140

150

N]+

[C10H10

161.10

160

170

180

190

m/z
200

180

190

m/z
200

144.08

100
%

d) 3-methylbuphedrone
40 V
[C H ]+
[C6H5]+ 7 7

0
50

77.04

60

70

80

91.05

90

[C9H8N]+ 143.07
105.07115.06

100

110

130.07

120

[C11H12N]+
158.10

142.06

130

140

Ion Mass-to-Charge (m/z)

150

160

170

Figure 3.3. CID-MS spectra for 3-ethylmethcathinone at a) 20 V and b) 40 V and 3methylbuphedrone at c) 20 V and d) 40 V. All spectra were collected in positive-ion
mode.

As an alternative to viewing spectra side-by-side, breakdown curves can be used
to more readily visualize differences in ion abundances over a range of collision
potentials (32). Breakdown curves show how the relative abundance of a specific ion
changes with an increase in collision potential and are useful for comparing such changes
between multiple ions or compounds. For the differentiation of 3-ethylmethcathinone and

60

3-methylbuphedrone, breakdown curves for the fragment ions [C11H13N]Ÿ+ (m/z 159.10)

Percent Total
Ion Current (TIC)

and [C8H9]+ (m/z 105.07) are shown in Figure 3.4.

8%

40%

a)

b)

6%
4%

20%

2%
0%

0%
0

25
50
Collision Potential (V)
N-ethyl-N-methylcathinone
3-methylbuphedrone

0

25
50
Collision Potential (V)
3-ethylmethcathinone

Figure 3.4. Breakdown curves showing the abundance, expressed as a percent of the total
ion current, of the charged fragment for a) [C11H13N]Ÿ+ (m/z 159.10) and b) [C8H9]+ (m/z
105.07) in N-ethyl-N-methylcathinone, 3-ethylmethcathinone and 3-methylbuphedrone.

The first of these fragments, [C11H13N]Ÿ+, is an odd-electron species. While not
commonly generated from CID of even-electron precursors, these species can form in
CID-MS during fragmentation of even-electron precursor ions providing there is
delocalization of the unpaired electron (24). This fragment in particular corresponds to
loss of water and a methyl radical and shows similarly low abundance in all three isomers
at collision potentials of 10 V and 40 V (Fig. 3.4.a). However, at 20 V, differences in
abundance are apparent for N-ethyl-N-methylcathinone (0.5% TIC), 3-methylbuphedrone
(7.3% TIC) and 3-ethylmethcathinone (4.3% TIC). In N-ethyl-N-methylcathinone, the
loss of water does not readily occur at low energy, so this further fragmentation is also

61

unlikely to occur, yielding the low relative abundance of the [C11H13N]Ÿ+ ion. Both 3methylbuphedrone and 3-ethylmethcathinone have a secondary amine and two methyl
substitutions from where the radical loss could occur, providing the basis for the higher
relative abundance of this fragment ion. Although the position from which the methyl
radical is lost is not clear from these data, it is likely that a combination of methyl losses
from both substitution sites contributes to the ion abundances and the difference in
relative abundance between the isomers reflects the presence of structural differences.
The second fragment ion of interest, [C8H9]+ (m /z 105.07), is also present at
similar abundance in all three isomers at a collision potential of 10 V with distinction
between the isomers possible at higher collision potentials (Figure 3.4.b). At 20 V,
[C8H9]+ is the base peak for N-ethyl-N-methylcathinone and represents 37.8% of the total
ions in the spectra, but only represents 11.9% and 2.5% of the total ion currents in the 20
V spectra for 3-methylbuphedrone and 3-ethylmethcathinone, respectively. At 40 V, the
abundance of [C8H9]+ decreases for all isomers but remains significantly greater in Nethyl-N-methylcathinone (13.0% TIC) than in both 3-methylbuphedrone (4.7% TIC) and
3-ethylmethcathinone (0.6% TIC). Based on the molecular formula of this fragment,
[C8H9]+ corresponds to an ethyl-substituted aromatic ring. Given that this ion is present in
all three structures and an ethyl substitution is only present on the aromatic ring in in 3ethylmethcathinone, direct cleavage of the aromatic-ketone bond is not the primary
mechanism by which this fragment ion forms. Further, the high abundance of [C8H9]+ in
N-ethyl-N-methylcathinone indicates that this mechanism does not require the initial loss
of water in order to occur. In considering how this ion might be formed in N-ethyl-Nmethylcathinone where it is most abundant at 20 V, the losses of both the amine group

62

and the ketone as a CO group would need to occur, along with a shift of the alpha-carbon
side chain to the aromatic ring. However, following the same series of cleavages and
rearrangements in 3-methylbuphedrone and 3-ethylmethcahtinone would yield ions of
higher m/z, as their side chains and aromatic substitutions are longer than those in Nethyl-N-methylcathinone. Thus, additional fragmentation would be required to achieve
the [C8H9]+ in 3-methylbuphedrone and 3-ethylmethcahtinone, explaining the lower
abundance of this ion for these compounds. Overall, while these aliphatic isomers are
distinguishable from each other at 10 V, the higher collision potentials give additional
evidence regarding the structural differences of the isomers.

3.3 Fragmentation of aliphatic-substituted cathinone isomers: Set 2
Chemical structures for the other aliphatic-substituted isomers (buphedrone and 2methylmethcathinone) and representative mass spectra at each collision potential are
shown in Figures 3.5 and 3.6, respectively. There is one carbon less in the alkyl chains
for these isomers than those in the first set. Given that isomers in both Set 1 and Set 2
have aliphatic substitutions, the Set 2 isomers are expected to fragment similarly to those
in Set 1.

63

buphedrone

O

[C11H14N]+

H
N

160.11

%

100

Ion Relative Intensity

0
50

60

Buphedrone
Item
70 #11283
80

+

147.08

132.08

91.05

90

178.12

[C9H10N]+ [C10H11O]

[C7H7]+

a) 10 V

[C11H16NO]+

100

110

120

130

140

[C9H9N]Ÿ+

150

160

170

180

190

m/z
200

131.07

100

+
[C9H8N]+ [C9H10N]

%

[C7H7]+

0
50

60

[C8H7
105.04

70

80

90

[C10H11N]Ÿ+

N]Ÿ+

91.06

b) 20 V

130.07 132.08

100

145.09

117.06

110

120

130
130.07

%

100

c) 40 V
0
50

60

[C6H5]+
77.04

70

80

[C7H7]+ [C H ]+
8 7
91.06

90

103.06

100

110

128.05

120

130

140

150

[C11H14N]+
160.11

160

170

180

190

m/z
200

160

170

180

190

m/z
200

[C9H8N]+
[C10H10N]+
144.08

140

150

Ion Mass-to-Charge (m/z)

Figure 3.5. CID-MS spectra for buphedrone at collision potentials of a) 10 V, b) 20 V and
c) 40 V. All spectra were collected in positive-ion mode.

The chemical structure of buphedrone, as well as representative mass spectra
collected using a collision potentials of 10, 20, and 40 V, are shown in Figure 3.5. At 10
V, the base peak is [M+H]+ ([C11H16NO], m/z 178.12), while the next most abundant ion
corresponds to the loss of water ([C11H14NO]+, m/z 160.11). The fragment corresponding
to the loss of methylamine ([C10H11O]+, m/z 147.08) is also observed at 10 V. While the
same fragment ions are also present in high abundance at 10 V in the CID spectrum for 2methylmethcathinone (Figure 3.6.a), the loss of water is the base peak for this isomer.

64

2-methylmethcathinone

[C11H14N]+

O

100

[C10H11O]+

%

147.08

a) 10 V

0
50

2-methylmethcathinone

60

70

80

90

100

[C11H16NO]+
178.12

[C10H11N]+
[C9H11]+ 145.09 145.09

110

119.09

120

130

140

150

[C10H11N]Ÿ+

160

170

180

190

m/z
200

170

180

190

m/z
200

170

180

190

m/z
200

145.09

100

[C10H10N]+
144.08

%

Ion Relative Intensity

160.11

H
N

b) 20 V

0
50

60

160.11

[C9H8N]+

119.09 130.07

91.05

70

80

90

100

110

120

130

147.08

140

150

[C10H10N]+

160

144.08

100

%

[C9H7]+
c) 40 V

0
50

60

[C10H9N]Ÿ+

+
+
[C6H5]+ [C7H7] [C8H7]

77.04

70

80

91.06 103.06 115.05 130.06

90

100

110

120

143.07
142.07

130

140

145.09 156.08

Ion Mass-to-Charge (m/z)

150

160

Figure 3.6. CID-MS spectra for 2-methylmethcathinone at a) 10 V, b) 20 V and c) 40 V.
All spectra were collected in positive-ion mode.

With increasing collision energy, additional differences between these isomers are
observed. One distinctive difference is in the base peaks at 20 and 40 V. For buphedrone,
the base peaks at 20 and 40 V correspond to the loss of water and an ethyl group as either
a radical species ([C9H9N]Ÿ+, m/z 131.07) or an even-electron species ([C9H8N]+, m/z
130.07), respectively (Figure 3.5, b and c). This loss likely results from a cleavage of the
ethyl side chain at the alpha position alongside the loss of water. Similar losses of water
and the alpha-position side chain compose the base peaks at 20 and 40 V in 2methylmethcathinone, although the cleavage of the alpha position side chain in this
isomer involves the loss of a methyl group as either a radical ([C10H11N]Ÿ+, m/z 145.09) or

65

an even-electron species ([C10H10N]+, m/z 144.08) (Figure 3.6, b and c, respectively). To
more clearly compare these fragments, breakdown curves for these fragments are shown
in Figure 3.R.

Percent Total
Ion Current (TIC)

60%

60%

a)

40%

40%

20%

20%

0%

0%
0

25
50
Collision Potential (V)

b)

0

25
50
Collision Potential (V)

Figure 3.7. Breakdown curves showing the abundance, expressed as a percent of the total
ion current, of fragments corresponding to loss of water and either a) an ethyl group or b)
a methyl group as even electron (square, dashed line) and radical (diamond, solid line)
fragments for buphedrone (black) and 2-methylmethcathinone (grey).

The fragments shown in the breakdown curves in Figure 3.7 each represent less
than 7% of the total ion current in their respective spectra at the 10 V collision potential.
At 20 V, the loss of water with either an ethyl radical or a methyl radical are the base
peaks for buphedrone and 2-methylmethcathinone, respectively. While both of these
peaks are the most abundant peaks in their respective spectra, the base peak for
buphedrone (Figure 3.7a, black diamond, 35.6% TIC) at 20 V accounts for a lower
percentage of all ions present in its spectrum than the base peak for 2-

66

methylmethcathinone (Figure 3.7b, grey diamond, 50.4% TIC), represented by the lower
percent of total ion current for buphedrone. At 20 V, the even-electron fragments have
lower abundances than their odd-electron counterparts - 12.9% TIC for the loss of water
and ethane in buphedrone and 23.0%% TIC for the loss of water and methane in 2methylmethcathinone. At 40 V, the ratio between the odd and even electron fragments
changes with the abundances of the even electron fragments exceeding those of the oddelectron fragments that dominated at 20 V. The even-electron fragments are the base
peaks at 40 V, with the loss of water the ethyl group representing 52.9% of the total ion
current for buphedrone at 40 V and the loss of water and a methyl group representing
41.1% of the total ion current for 3-methylmethcathinone.
Given that buphedrone has an ethyl substitution at the alpha carbon and 3methylmethcathinone has a methyl group at the same location, it could be hypothesized
that these odd- and even-electron fragments are the result of a cleavage of the side chain
after the loss of water. However, the alpha carbon side chains in 3-methylbuphedrone and
3-ethylmethcathinone are also ethyl and methyl groups, respectively, but the dominant
series of odd- and even-electron fragments corresponds to the loss of water and an ethyl
group for both compounds (Figure 3.3, m/z 145.09 [C10H11N]*+ and 144.08 [C10H10N]+).
This indicates that the alpha side chain is not the only location at which the alkyl loss
could occur and this loss could also occur from an aromatic site. Given that radical alkyl
groups have increasing stability with increased size and substitution, the loss of an ethyl
group will be more energetically favorable than the loss of a methyl group. Thus, this
series of odd- and even-electron losses is not a specific indicator of the composition of

67

the alpha side chain, but the most abundant series gives evidence of the longest alkyl
chain present at either the alpha carbon or aromatic ring.

3.4 Fragmentation of methylenedioxy-substituted cathinone isomers: Set 3
Chemical structures for the three methylenedioxy-substituted cathinones (2,3ethylone isomer, ethylone, and butylone), as well as representative mass spectra collected
using a collision potential of 10 V are shown in Figure 3.8. For all three isomers, the base
peak is [M+H]+ ([C12H16NO3], m/z 222.11) while the next two ions of highest abundance
correspond to the loss of water ([C12H14NO2]+, m/z 204.10) and the loss of 48 Da from
[M+H]+ ([C11H12NO]+, m/z 174.09). The loss of 48 Da corresponds to a loss of CH4O2
and has been previously attributed to the loss of the methylenedioxy ring as methanediol.
However, the loss of methanediol is unlikely owing to its low stability and this neutral
loss is more likely to be successive losses of formaldehyde (CH2O) and water (H2O).
Since the identity and mechanism of this loss is unclear, it is referred to simply as a loss
of 48 Da.

68

2,3-ethylone isomer

[C10H9O3]+

100

[C12H16NO3]+
222.11

[C11H12NO]+
174.09

%

[C12H14NO2]+
a) 2,3-ethylone isomer

Ion Relative Intensity

0

60

80

100

147.04

120

140

166.12

160

177.06

180

%

[C11H12NO]+

223.11

220

m/z

[C12H14NO2]+
204.10

174.09

b) Ethylone
60

80

177.05

147.04

100

120

140

100

160

200

[C11H11O3]+

[C11H12NO]+

%

222.22

180

[C10H9O2]+

220

m/z

[C12H16NO3]+
222.11

[C12H14NO2]+
204.10

174.09

c) Butylone
0

200

222.23

+
16NO3]
[C10H9O3]+ [C12H222.11

100

0

204.10

60

80

146.10

100

120

140

161.06

160

191.07
175.06

180

223.06

205.11

200

220

m/z

Ion Mass-to-Charge (m/z)

Figure 3.8. CID-MS spectra for a) 2,3-ethylone isomer, b) ethylone, and c) butylone
collected in positive-ion mode at a collision energy of 10 V.

The loss of 48 Da indicates a methylenedioxy substitution on the aromatic ring
(25) and, as all three isomers contain methylenedioxy-substitutions on the ring, the
presence of this loss does not allow distinction. However, the difference in the alkyl
group substitution on the amine can be used to distinguish the isomers: butylone contains
a methyl group on the amine whereas, the ethylone isomers contain an ethyl group. Thus,
loss of the amine from the butylone [M+H]+ results in a fragment ion at higher m/z (m/z
191.07, 17.7% relative abundance) than the corresponding amine loss from the ethylone
isomers (m/z 177.05, 2.5% and 3.3% relative abundance for 2,3-ethylone isomer and
ethylone, respectively).

69

While the fragments at 10 V mainly represent common cathinone fragmentation
pathways, the fragment at m/z 161.06 in butylone, corresponding to [C10H9O2]+, is not
accounted for in these pathways. The neutral loss associated with this charged fragment is
C2H7NO. Given the structure of butylone (Figure 3.8.c), there is no single cleavage that
would result in this loss, so it is likely due to a series of multiple fragmentation steps and
rearrangements. One potential series of losses involves the initial loss of methylamine
(charged fragment observed at m/z 191.07, [C11H11O3]+) with a subsequent loss of
formaldehyde from a cleavage in the methylenedioxy ring. Similar observations are
observed at 10 V in the two ethylone isomers, with the loss of ethylamine (m/z 177.05,
[C10H9O3]+) and formaldehyde (m/z 147.04, [C9H7O2]+).
As the collision potential increases, so does the corresponding internal energy of
the ion after collision. With increased internal energy available to overcome the
activation energy of fragmentation pathways, a wider array of fragments can occur and
additional differences between the isomers observed. Spectra at the three collision
potentials for butylone, ethylone, and the 2,3-ethylone isomer can be seen in Figures 3.9,
3.10, and 3.11, respectively. Since the ethylone isomers differ only in the location of the
methylenedioxy ring substitution, fragmentation that involves the loss of more than one
oxygen atom, requiring cleavage of the methylenedioxy ring, provides a source of known
differences between these two isomers. Thus, breakdown curves were generated for
several fragment ions that correspond to neutral losses previously reported in the
literature as well as those that require the loss of one or more oxygen atoms. The
fragments plotted in Figure 3.12. include both the loss of water and the loss of 48 Da
(Figure 3.12.a and b, respectively), as well as the three fragment ions [C10H8NO2]+ (m/z

70

174.05), [C10H12N]+ (m/z 146.10) and [C9H9N]Ÿ+ (m/z 131.07) (Figure 3.12.c-e,
respectively).

butylone

[C10H9O2]+

%

100

Ion Relative Intensity

0

161.06

80

100

120

140

160

%

b) 20 V

146.10

200

60

80

100

161.06

131.07

105.07

120

191.07

140

220

m/z

160

180

204.10

209.01

200

220

m/z

Ÿ+

131.07 [C9H9N]

[C9H8N]+130.07
%

180

223.06

205.11

[C10H9O2]+ [C H NO ]Ÿ+
10 9
2
175.06
[C10H12N]+
[C12H14NO2]+

100

0

191.07
175.06

174.09 [C11H12NO]+

100

0

204.10

174.09
146.10

60

222.11

[C12H14NO2]+

[C11H12NO]+
a) 10 V

[C12H16NO3]+

[C11H11O3]+

[C10H9NO]Ÿ+
[C10H8NO2]+
174.06
[C11H10NO2]+

c) 40 V
[C8H8N]+
+[C8H7]+ 118.07
+
[C
H
]
[C6H5] 7 5
77.04 89.04

60

80

146.10 159.07

103.05

100

120

140

160

Ion Mass-to-Charge (m/z)

175.06 188.07

180

200

209.01

220

Figure 3.9. CID-MS spectra for butylone at a) 10 V, b) 20 V and c) 40 V. All spectra
were collected in positive-ion mode.

71

m/z

bk-MDEA

[C12H16NO3]+

222.11
[C10H9O3]+
[C12H14NO2]+
[C11H14NO]+
204.10

%

100

60

147.04

80

100

120

b) 20 V
0

60

119.05

80

100

%

[C7H7]+

]+

[C7H5 91.06
89.04
c) 40 V
60

160

180

80

120

140

130.06

107.07

100

120

175.06

146.10
149.05
145.06

200

146.06
149.06

140

204.10

175.09

160

[C8H7N]Ÿ+
+
117.06 [C9H9N]
131.07[C H NO]+
9 8

100

0

140

222.22

220

m/z

[C11H14NO]+ 174.09
[C10H9NO2]Ÿ+
[C11H11NO2]Ÿ+
+
[C12H14NO2]+
[C10H12N]

100
%

Ion Relative Intensity

0

174.09
177.05

[C9H7O2]+

a) 10 V

180

200

174.05 [C10H8O2]

222.22

220

m/z

+

[C11H14NO]+

159.06

160

Ion Mass-to-Charge (m/z)

174.10

180

200

220

m/z

Figure 3.10. CID-MS spectra for ethylone at a) 10 V, b) 20 V and c) 40 V. All spectra
were collected in positive-ion mode.

72

2,3-ethylone isomer

[C12H16NO3]+

100

174.09

[C12H14NO2]+ 222.23

%

a) 10 V

[C9H7O2]+
147.04

60

80

100

120

140

%

NO]+

[C11H14

146.10

200

220

m/z

60

80

100

120

[C8H7N]Ÿ+
117.06

[C7H7]+

c) 40 V
60

[C12H14NO2]+

147.04
103.06 118.07 133.05 146.06
166.12

100

0

180

223.11

[C10H12N]+
b) 20 V

0

160

204.10

177.06

166.12

174.09

100
%

Ion Relative Intensity

0

222.11

[C11H14NO]+

91.06

80

130.06

102.05

100

120

140

160

192.18

180

204.10

222.22

200

220

200

220

m/z

[C9H8N]+
[C9H14N]+

136.11
146.06 159.07 166.12

140

160

Ion Mass-to-Charge (m/z)

180

m/z

Figure 3.11. CID-MS spectra for the 2,3-ethylone isomer at a) 10 V, b) 20 V and c) 40 V.
All spectra were collected in positive-ion mode.

73

Percent Total
Ion Current (TIC)

30%

b)

Butylone

20%

Ethylone

25%
10%

2,3 ethylone isomer
0%

0%
0

Percent Total
Ion Current (TIC)

50%

a)

15%

25

0
25
50
Collision Potential (V)

50
20%

c)

d)

15%

10%

30%

e)

20%

10%
5%

10%

5%

0%

0%
0

25

50

0%
0
25
50
Collision Potential (V)

0

25

50

Figure 3.12. Breakdown curves showing the abundance, expressed as a percent of the
total ion current, at each collision energy for the charged fragments a) [C12H14NO2]+ (m/z
204.10) which corresponds to the loss of water, b) [C11H12NO]+ (m/z 174.09) which
corresponds to the loss of 48 Da, c) [C10H8NO2]+ (m/z 174.05), d) [C10H12N]+ (m/z
146.10), and e) [C9H9N]Ÿ+ (m/z 131.07).

While presence of fragments corresponding to both the loss of water
([C12H14NO2]+, m/z 204.10, Fig. 3.12.a) and loss of 48 Da ([C11H12NO]+, m/z 174.09, Fig.
3.12.b) are common for methylenedioxy-substituted cathinones, the breakdown curves
clearly represent the differences in abundance of these ions in ethylone and the 2,3ethylone isomer. These losses are present at similar abundances at higher collision
potentials, but differences are observed at 10 V. At 10 V, the abundance of [C12H14NO2]+
is 12.5% higher in ethylone than in the 2,3-ethylone isomer (Fig. 3.12.a) while the
abundance of [C11H12NO]+ is 13.4% higher in the 2,3-ethylone isomer (Fig. 3.12.b).

74

Differences between the two ethylone isomers are also observed in other losses.
Most notably, the base peak for ethylone at 40 V, [C10H8NO2]+ (m/z 174.05), is not
present in the 2,3-ethylone isomer but is present in butylone (Fig. 3.12.c). This fragment
corresponds to the neutral loss of water and ethane. Since a similar neutral loss has been
observed in other cathinones that do not have a methylenedioxy group, this loss does not
directly require cleavage of the methylenedioxy group. However, if one of the oxygen
atoms of the methylenedioxy group is the site of protonation, the change in position on
the aromatic ring could lead to different charge-remote fragmentation pathways occurring
for each isomer. The differences of the fragmentation pathway explains why
[C10H8NO2]+ is present at 40 V in both of the 3,4-substituted isomers but does not occur
in the 2,3-isomer.
The fragment ions at m/z 146.10 ([C10H12N]+) and m/z 131.07 ([C9H9N]Ÿ+) are
both the result of fragmentation pathways that require the loss of methanediol from the
ring. The first of these fragments, [C10H12N]+, is present in all three isomers at all three
collision potentials (Fig. 3.12.d). However, at 20 V, the abundance of this fragment in the
2,3-subsituted isomer is twice as high as in the 3,4-substituted isomers, indicating it is
more likely to occur with a 2,3-substitution. The [C9H9N]Ÿ+ fragment ion is an oddelectron species corresponding to the loss of C3H7O3. [C9H9N]Ÿ+ is present at low
abundance (<3% TIC) for all three isomers at 10 and 20 V, but at higher abundance for
butylone and ethylone at 40 V (24.2% and 8.5% TIC, respectively) (Fig. 3.12.e). It is not
present in the 2,3-ethylone isomer at 40 V, indicating it is more likely to occur with the
3,4-methylenedioxy substitution.

75

For both [C10H12N]+ and [C9H9N]Ÿ+, Thus, differences in the abundance of these
three ions reflect the ring position of the methylenedioxy group, and the 2,3-ethylone
isomer is distinguished from butylone and ethylone based on the higher abundance of
[C10H12N]+ at 20 V and the absence of [C10H8NO2]+ and [C9H9N]Ÿ+ at 40 V.

3.5 Conclusion
Cathinone isomers are distinguished using CID-MS at multiple collision
potentials. When the same fragments are present across multiple isomers and energies,
breakdown curves provide clear visualization of fragment abundances. While the
fragments present at low collision potential (10 V) are useful for characterizing these
compounds as cathinones and distinguishing isomers with differing amine substitutions,
more extensive fragmentation at higher energies (20 V and 40 V) is required to
distinguish isomers with the same amine groups.
In the case of methylenedioxy-substituted isomers, the fragments that firmly
distinguish between the 3,4- and 2,3-substitutions in ethylone involve cleavage of the
methylenedioxy ring and the loss of species that include multiple oxygen atoms with
fragmentation mechanisms that are driven by the site of protonation. Specifically,
differentiation can be achieved using the higher abundance of [C10H12N]+ in the 2,3isomer at 20 V and the absence of [C10H8NO2]+ and [C9H9N]Ÿ+ in this isomer at 40 V. For
the aliphatic-substituted isomers with the same amine-group substitutions (3ethylmethcathinone and 3-methylbuphedrone; buphedrone and 2-methylmethcathinone),
the discriminating losses involved loss of water and the longest alkyl substitution as
either a radical or neutral species. All of these losses highlight structural differences

76

between cathinone isomers and allow clear differentiation of them for compound
identification. Since isomer identification is not easily achieved using the current
standard method of analysis, this work addresses how the fragmentation of isomers under
multiple collision potentials in CID-MS can be leveraged to achieve isomer
differentiation.

77

CHAPTER 4: Conclusions and Future Work

4.1 Conclusion
The overarching goal in this research was to provide forensic scientists a simple
process for identification of emerging synthetic cathinone analogs, including isomers. To
accomplish this, the specific aims of this research were twofold. First, this work outlined
a workflow for identification and distinction of emerging cathinone analogs from the
structurally similar class of designer drugs, phenethylamines. High-resolution mass data
and controlled fragmentation obtained using collision-induced dissociation mass
spectrometry (CID-MS) with multiple collision potentials was used to investigate a
variety of cathinone and phenethylamine standards. Ultimately, a characterization scheme
was developed based on characteristic mass spectral features of these compounds. The
characterization scheme provides step-by-step instruction to facilitate the assignment of
unknown compounds as cathinones or phenethylamines, even when no standards are
available for comparison. This scheme does accurately assign cathinones based off
spectra obtained from multiple laboratories and be further expanded and refined as
additional standards are analyzed.
The second specific aim of this work was to address isomer distinction. Through
the investigation of three sets of cathinone isomers, differences in the mass spectral
features that reflect the differing structural arrangements were identified. In general,
isomers within each set had many fragment ions in common with each other. Breakdown
curves facilitated comparison of the relative abundances of these common ions across the
three collision potentials. The differences that emerged could be correlated to the

78

structural differences between the isomers and allowed isomer distinction. Overall, the
characterization scheme and isomer fragmentation analysis presented here highlight how
CID-MS can streamline the process of class assignment and isomer identification,
minimizing the resources required for the analysis of new cathinone analogs.

4.2 Future work
There are several directions for further analysis of cathinones and
phenethylamines using CID-MS. First, the fragmentation of these designer drugs could
be further probed. In this work, the molecular formulae of fragments are identified, but
the exact structure of each fragment and the mechanism through which the fragmentation
occurs remain unclear. Further studies using deuterium-labelled compounds would
indicate the specific locations from which hydrogens are being lost during each
fragmentation pathway. This would give added clarity as to which bonds are breaking
and what internal rearrangements are most likely to occur. The deeper understanding of
fragmentation mechanisms could then be further applied in the structure elucidation of
cathinones when no standards are available.
Another direction for the future would be in expanding and refining the
classification scheme. The analysis of additional cathinone and phenethylamine standards
would increase the accuracy of the classification scheme by taking into account an even
broader range of structural arrangements. The scheme could also be expanded to other
designer drug classes, such as synthetic cannabinoids, that are also plagued by the rapid
introduction of new analogs.

79

As forensic laboratories look to adopt this method of analysis, the reproducibility
of cathinone fragmentation by instruments across multiple laboratories must be
thoroughly assessed. As seen in the literature, there is currently not a standard operating
procedure for CID-MS analysis and the collision potentials used have been reported in
various formats. While similarities between data sets can be observed, the inconsistency
in procedure makes direct comparison of results obtained across multiple labs difficult.
Thus, additional work that standardizes data acquisition and compares the results between
labs is vital for the widespread adoption of CID-MS by the forensic community. Overall,
there are many available avenues of further investigation that can continue to show CIDMS as a powerful tool for the forensic analysis of designer drugs.

80

APPENDICES

81

APPENDIX A

CID-MS Spectra of Cathinones

buphedrone

O

[C11H14N]+

H
N

160.11

%

100

Ion Relative Intensity

0
50

60

Buphedrone
Item
70 #11283
80

100

110

120

140

[C9H9N]Ÿ+

150

+
[C9H8N]+ [C9H10N]

%

[C7H7]+
60

[C8H7
105.04

70

80

90

[C10H11N]Ÿ+

N]Ÿ+

91.06

b) 20 V

130.07 132.08

100

145.09

117.06

110

120

130
130.07

%

100

c) 40 V
0
50

130

160

170

180

190

m/z
200

131.07

100

0
50

147.08

132.08

91.05

90

178.12

+
[C9H10N]+ [C10H11O]

[C7H7]+

a) 10 V

[C11H16NO]+

60

[C6H5]+
77.04

70

80

[C7H7]+ [C H ]+
8 7
91.06

90

103.06

100

110

128.05

120

130

140

150

[C11H14N]+
160.11

160

170

180

190

m/z
200

160

170

180

190

m/z
200

[C9H8N]+
[C10H10N]+
144.08

140

150

Ion Mass-to-Charge (m/z)

Figure A.1. CID-MS spectra for the cathinone buphedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

82

O

3-methylbuphedrone

%

100

174.13

[C10H12N]+

a) 10 V

0
50

60

70

3-Methylbuphedrone
80 #12001
90 100 110
Item

120

130

140

150

[C10H11N]Ÿ+
145.09

144.08

105.07

b) 20 V

119.05

91.05

60

70

80

90

[C9H9N]Ÿ+

100

110

120

131.07

130

161.10

160

146.10

150

190

m/z
200

180

190

m/z
200

180

190

m/z
200

180

159.10 174.13

158.10

140

170

[C11H13N]Ÿ+

[C10H10N]+

[C8H9]+

0
50

[C10H10N]+

161.10

160

170

144.08

100
%

[C11H13O]+

133.10 146.10

105.07

100
%

Ion Relative Intensity

H18NO]+
[C12H16N]+ [C12192.14

H
N

c) 40 V

0
50

[C6H5]+
77.04

60

70

80

[C9H8N]+ 143.07

[C7H7]+
91.05

90

105.07115.06

100

110

130.07

120

[C11H12N]+
158.10

142.06

130

140

Ion Mass-to-Charge (m/z)

150

160

170

Figure A.2. CID-MS spectra for the cathinone 3-methylbuphedrone at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

83

butylone

[C10H9O2]+

%

100

Ion Relative Intensity

0

161.06

80

100

120

140

160

%

b) 20 V

146.10

200

105.07

60

80

100

161.06

131.07

120

191.07

140

220

m/z

160

180

204.10

209.01

200

220

m/z

Ÿ+

131.07 [C9H9N]

[C9H8N]+130.07
%

180

223.06

205.11

[C10H9O2]+ [C H NO ]Ÿ+
10 9
2
175.06
[C10H12N]+
[C12H14NO2]+

100

0

191.07
175.06

174.09 [C11H12NO]+

100

0

204.10

174.09
146.10

60

222.11

[C12H14NO2]+

[C11H12NO]+
a) 10 V

[C12H16NO3]+

[C11H11O3]+

[C10H9NO]Ÿ+
[C10H8NO2]+
174.06
[C11H10NO2]+

c) 40 V
[C H N]+
+ 8 8
+
[C
H
]
+
[C6H5] [C7H5] 8 7 118.07
77.04 89.04

60

80

146.10 159.07

103.05

100

120

140

160

Ion Mass-to-Charge (m/z)

175.06 188.07

180

200

209.01

220

m/z

Figure A.3. CID-MS spectra for the cathinone butylone at collision potentials of a) 10 V,
b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

84

benzedrone

[C17H20NO]+

O

100

254.15

%

H
N

a) 10 V
60

91.05

80

146.10

100

[C7H7]+

120

b) 20 V
0

60

131.07

80

%

100

]+

[C7H7

160

180

200

220

255.16

240

m/z
260

120

[C17H18N]+

[C10H12N]+
146.10

140

162.09

160

236.14 254.16

204.10

180

200

220

240

m/z
260

180

200

220

240

m/z
260

91.05

100

c) 40 V
115.06

0

140

236.14

91.06

100
%

Ion Relative Intensity

0

[C17H18N]+

benzedrone
Item #11915

60

80

100

[C9H8N]+
130.07

120

165.07

140

160

Ion Mass-to-Charge (m/z)

Figure A.4. CID-MS spectra for the cathinone benzedrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

85

Naphyrone

[C19H24NO]+

O

282.19

100
%

N

a) 10 V
60

80

100

120

100

140

160

180

200

220

60

80

126.13

100

120

160

180

[C11H9]+

[C10H7]+
%

m/z
300

[C19H24NO]+
282.19

[C17H17NO]+
239.13

200

220

240

260

280

m/z
300

240

260

280

m/z
300

141.07

100

0

280

211.11

155.05 169.07

140

260

[C15H15

141.07

0

240

O]+

[C11H9]+
b) 20 V

282.23

211.11

%

Ion Relative Intensity

0

[C15H15O]+

Naphyrone
Item #10517

127.05

c) 40 V

115.05

84.08

60

80

[C10H9O]+

100

120

145.07
155.05

140

178.08

160

180

210.13

200

220

Ion Mass-to-Charge (m/z)

Figure A.5. CID-MS spectra for the cathinone naphyrone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

86

a-phthalimidopropione

[C17H14NO3]+

O

100

280.10

O

%

N

[C17H12NO2]+

O

a) 10 V
60

80

100

0

120

160

180

262.09

200

220

240

260

281.10

280

[C17H12NO2]+

m/z
300

[C10H8NO2]+

105.07

b) 20 V
60

174.06
133.07 148.04
175.06

105.04

80

100

120

[C8H9]
[C8H7]+ 105.07

+

140

160

180

280.10

220.07

200

220

240

260

280

m/z
300

260

280

m/z
300

103.06

c) 40 V

115.05

60

80

130.03
130.04

77.04

0

140

[C8H9]+

100
%

133.07
174.06
alpha-phthalimidopropiophenone
Item #17141

262.09

100
%

Ion Relative Intensity

0

100

120

140

178.08

160

180

216.08

200

220

233.08

240

Ion Mass-to-Charge (m/z)

Figure A.6. CID-MS spectra for the cathinone α-phthalimidopropiophenone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

87

MTTA

[C12H16NO]+
190.12

O

100
%

N
H

a) 10 V

147.08

60

80

MTTA
100
Item #17121

120

60

%

[C10H11O]+

129.07
128.06
145.07

91.05

80

100

[C7H7]
]Ÿ+ 91.05

[C7H6

100

0

160

180

m/z
200

[C10H9]+
b) 20 V

0

140

147.08

100
%

Ion Relative Intensity

0

[C10H11O]+

+

120

160.07

140

160

180

m/z
200

140

160

180

m/z
200

[C9H7]+
115.05

90.05

[C6H5]+
c) 40 V
60

77.04

80

128.05

100

120

Ion Mass-to-Charge (m/z)

Figure A.7. CID-MS spectra for the cathinone MTTA at collision potentials of a) 10 V, b)
20 V, and c) 40 V. All spectra collected in positive-ion mode.

88

a-PPP

[C13H18NO]+

O

204.14

100
%

N

[C9H9O]+

a) 10 V
60

80

100

120

140

204.18

160

180

m/z
220

204.14

[C8H9]+

b) 20 V
0

200

[C13H18NO]+

100
%

Ion Relative Intensity

0

133.07
alpha-pyrrolidinopropiophenone
(PPP)
Item #11484

60

133.07

98.10

80

[C6H5]+

100

[C9H9O]+

[C6H12N]+105.07

160.11

100

[C8H9]+

120

140

160

184.11

180

200

m/z
220

200

m/z
220

98.10 105.07

%

77.04

0

c) 40 V

79.06

115.05

60

170.10 184.11

128.06 143.07

70.07

80

100

120

140

160

180

Ion Mass-to-Charge (m/z)

Figure A.8. CID-MS spectra for the cathinone α-pyrrolidinopropiophenone (α-PPP) at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.

89

alpha-piperidinobutiophenone

[C15H22NO]+

O

100

232.17

%

N

a) 10 V
60

232.21

80

alpha-Piperidinobutiophenone
100
120
140
160
Item #9001513

180

200

220

[C10H11O]+

b) 20 V

60

80

%

119.09

100

[C7H7]+
91.05

100

0

m/z

232.17

84.08 91.05

0

240

[C15H22NO]+

100
%

Ion Relative Intensity

0

120

140

203.13

160

180

200

220

240

220

240

m/z

[C8H16N]+
126.13

c) 40 V

105.03
77.04
84.08 98.10 117.06

60

[C13H17NO]+

147.08

126.13

80

100

120

[C9H8NO]+
146.06

140

174.13

160

184.11 202.12

180

200

m/z

Ion Mass-to-Charge (m/z)

Figure A.9. CID-MS spectra for the cathinone α-piperidinobutiophenone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

90

2,3-ethylone isomer

[C12H16NO3]+

100

222.11

[C11H14NO]+
174.09

%

[C12H14NO2]+ 222.23

a) 10 V

147.04

60

80

100

120

140

%

200

NO]+

[C11H14

146.10

220

m/z

[C12H14NO2]+

147.04
103.06 118.07 133.05 146.06
166.12

60

80

100

120

140

[C8H7N]Ÿ+
117.06

100

0

180

223.11

[C10H12N]+
b) 20 V

0

160

204.10

177.06

166.12

174.09

100
%

Ion Relative Intensity

0

[C9H7O2]+

[C7H7]+

c) 40 V

91.06

60

80

100

180

204.10

222.22

200

220

200

220

m/z

[C9H8N]+

130.06

102.05

160

192.18

[C9H14N]+

136.11
146.06 159.07 166.12

120

140

160

180

Ion Mass-to-Charge (m/z)

m/z

Figure A.10. CID-MS spectra for the cathinone 2,3-ethylone isomer at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.
N-ethyl-N-methylcathinone

[C12H18NO]+

O

192.14

100
%

N

60

70

105.07
N-ethyl-N-methylcathinone
Item #11604

80

90

100

110

192.18

133.07

120

130

140

150

160

170

180

190

m/z
200

[C8H9]+
105.07

100

[C12H18NO]+

[C9H9O]+
%

Ion Relative Intensity

0
50

[C9H9O]+

[C8H9]+

a) 10 V

0
50

b) 20 V
60

77.04

70

90

[C6H5]+

100

100

121.07131.07

110

120

[C8H7]+
103.05[C8H9]+

77.04

60

86.10

70

80

90

140

[C9H8N]+

79.06

c) 40 V

130

146.10

150

174.13177.12

160

170

180

190

m/z
200

180

190

m/z
200

130.07

105.07

[C6H7]+

%

0
50

86.10 103.05

80

192.14

133.07

[C5H12N]+

115.06

100

110

120

131.07 144.08

130

140

Ion Mass-to-Charge (m/z)

150

168.96

160

170

Figure A.11. CID-MS spectra for the cathinone N-ethyl-N-methylcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.
91

2-methylmethcathinone

[C11H14N]+

O

%

100

[C10H11O]+
147.08

a) 10 V
2-methylmethcathinone

60

70

80

90

100

0
50

%

178.12

110

119.09

120

130

140

150

[C10H11N]Ÿ+

160

170

180

190

m/z
200

170

180

190

m/z
200

170

180

190

m/z
200

145.09

[C10H10N]+
144.08

b) 20 V
91.05

60

160.11

[C9H8N]+

119.09 130.07

70

80

90

100

110

120

130

147.08

140

150

[C10H10N]+

160

144.08

100

0
50

[C11H16NO]+

[C10H11N]+
[C9H11]+ 145.09 145.09

100

%

Ion Relative Intensity

0
50

160.11

H
N

[C9H7]+
c) 40 V
60

[C10H9N]Ÿ+

+
+
[C6H5]+ [C7H7] [C8H7]

77.04

70

80

91.06 103.06 115.05 130.06

90

100

110

120

143.07
142.07

130

140

145.09 156.08

Ion Mass-to-Charge (m/z)

150

160

Figure A.12. CID-MS spectra for the cathinone 2-methylmethcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

92

bk-MDEA

[C12H16NO3]+

222.11
[C10H9O3]+
[C12H14NO2]+
[C11H14NO]+
204.10

%

100

147.04

60

80

100

120

140

b) 20 V
0

60

80

100

120

200

]+

[C7H5 91.06
89.04
c) 40 V
60

80

175.06

140

107.07

100

130.06

160

146.06
149.06

120

140

204.10

175.09

180

[C8H7N]Ÿ+
+
117.06 [C9H9N]
131.07[C H NO]+
9 8

[C7H7]+

%

180

146.10
149.05
145.06

119.05

100

0

160

222.22

220

m/z

[C11H14NO]+ 174.09
[C10H9NO2]Ÿ+
[C11H11NO2]Ÿ+
+
[C12H14NO2]+
[C10H12N]

100
%

Ion Relative Intensity

0

174.09
177.05

[C9H7O2]+

a) 10 V

200

174.05 [C10H8O2]

222.22

220

m/z

+

[C11H14NO]+

159.06

174.10

160

180

Ion Mass-to-Charge (m/z)

200

220

m/z

Figure A.13. CID-MS spectra for the cathinone ethylone at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.
2-ethylmethcathinone

+

[C12H16N]+[C12H18NO]

O

174.13

100

%

H
N

[C10H12N]+[C H O]+
11 13

a) 10 V
60

146.10

70

3-Ethylmethcathinone
80 Item90
100 110
#9001082

120

130

140

160

170

190

m/z
200

180

190

m/z
200

180

190

m/z
200

180

[C10H10N]+
[C8H9]+

b) 20 V
60

105.07

70

80

90

100

110

146.10

[C11H13N]Ÿ+174.13
159.11

131.07

120

130

140

150

[C10H10N]+

160

170

144.08

%

100

c) 40 V
0
50

150

[C10H11N]Ÿ+

144.08

0
50

161.10

145.09

100

%

Ion Relative Intensity

0
50

192.14

60

[C9H8N]+

]+

[C6H5]+ [C7H7
77.04

70

80

91.06 103.05 115.05

90

100

110

130.07 143.07

120

130

[C11H12N]+

145.09 158.10

140

150

160

170

Ion Mass-to-Charge (m/z)

Figure A.14. CID-MS spectra for the cathinone 3-ethylmethcathinone at collision
potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

93

APPENDIX B

CID-MS Spectra of Phenethylamines
2-methylamino-1-phenylbutane
H
N

164.14

100
%

[C11H18N]+

Ion Relative Intensity

91.05

0
50

[C10H13]+

[C7H7]+

133.10

a)2-methylamino-1-phenylbutane
10 V
Item #15961
60
70

80

90

100

110

120

130

140

150

160

170

180

190

m/z
200

120

130

140

150

160

170

180

190

m/z
200

120

130

140

150

160

170

180

190

m/z
200

91.05 [C7H7]+

%

100

0
50

b) 20 V
60

70

80

90

100

110

91.05 [C7H7]+

100
%

c) 40 V

0
50

[C5H5]+
65.04

60

70

80

90

100

110

Ion Mass-to-Charge (m/z)

Figure B.1. CID-MS spectra for the phenethylamine 2-methylamino-1-phenylbutane at
collision potentials of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion
mode.

94

O

2C-E

NH 2

193.12

%

100

2C-E
Item #15699

a) 10 V

[C11H14O2]Ÿ+ [C12H20NO2]+
O

60

80

165.10

100

120

140

160

0

[C9H11O]+

b) 20 V

]+

[C8H9

105.07

91.06

60

80

]+

[C6H7
%

180

200

220

m/z

178.10

100

0

210.15

178.10

[C11H14O2]Ÿ+

100
%

Ion Relative Intensity

0

[C12H17O2]+

79.05

c) 40 V
60

100

[C8H9]+

140

160

193.13
179.11

180

210.08

200

220

200

220

m/z

[C10H11O2]+
163.07

7

103.06

[C7H7]+
91.06

80

120

105.07
+
H ]+ 115.05 [C9H7]

[C8

[C10H11O2]+

135.08
163.08
134.07
148.09

100

[C10H12O2]
133.07
164.08
145.06 149.06
124.08
120

140

160

180

Ÿ+

m/z

Ion Mass-to-Charge (m/z)

Figure B.2. CID-MS spectra for the phenethylamine 2C-E at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

95

O

2C-T

[C11H15O2S]+

NH 2

211.08

%

100
2C-T
Item #13957

S

a) 10 V
60

80

100

120

140

160

180

100

[C9H10O]+
134.07

0

60

91.06

80

100

[C7H7]+

120

160

m/z

211.08

181.03
181.07 197.06

149.06

140

240

180

211.10

228.17

200

220

240

200

220

240

m/z

91.06

100

%

[C9H9O2S]+
c) 40 V

0

115.05119.05

164.08

220

[C11H15O2S]+

196.06

b) 20 V

228.11

200

[C10H12O2S]+

%

Ion Relative Intensity

0

[C11H18NO2S]+

196.06

O

60

119.05123.02

147.05151.02

77.04

80

181.03

166.05

100

120

140

160

180

m/z

Ion Mass-to-Charge (m/z)

Figure B.3. CID-MS spectra for the phenethylamine 2C-T at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

96

2C-B

O

[C10H12O2Br]+

NH 2

100

243.00

[C10H15NO2Br]+

%

2C-B

60

O

80

100

227.98

120

140

160

180

200

100

[C10H12O2]+

b) 20 V
0

220

244.01

240

260

m/z

[C9H9O2Br]+
227.98 [C10H12O2Br]+
243.01

%

Ion Relative Intensity

0

260.03

Br

a) 10 V

60

119.05 134.08149.06

80

100

120

140

164.09

160

[C8H6O2Br]+
197.97

180

212.96

200

220

[C8H6O2Br]+

240

260

240

260

m/z

212.96

100
%

+

c)
0

[C7H7]+ [C7H6O]

106.04
91.06
40 V
119.05 134.07149.06 156.97
78.05

60

80

100

120

140

160

184.96

180

197.97

200

227.98

220

m/z

Ion Mass-to-Charge (m/z)

Figure B.4. CID-MS spectra for the phenethylamine 2C-B at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

97

2C-G

O
NH 2

100

%

[C11H14O2]Ÿ+

178.10

a) 10 V
80

100

120

140

160

180

[C11H14O2]Ÿ+

220

m/z

[C10H11O2]+
163.08

60

80

100

[C7H7]+
[C6H5]+
c) 40 V
60

120

]+

[C9H7

91.05

163.11

133.10 148.09

105.07

100

%

200

178.10

%

Ion Relative Intensity

60

210.12

163.11

b) 20 V

0

[C12H20NO2]+
210.15

100

0

193.12

2C-G
Item #14064
O

0

[C12H17O2]+

140

160

[C10H11O2]+

[C9H10O]+

180

193.12

200

220

m/z

163.08

115.05
135.08
117.07

105.07
79.05

80

103.05

100

133.07

120

147.08

140

178.10

160

180

208.13

200

220

m/z

Ion Mass-to-Charge (m/z)

Figure B.5. CID-MS spectra for the phenethylamine 2C-G at collision potentials of a) 10
V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

98

25E-NBOMe

O

[C20H28NO3]+

H
N

100

330.21

%

25E-NBOMe
Item #14727

[C8H9O]+

O

330.26

121.07

60

80

100

120

140

160

180

200

220

240

260

280

300

320

m/z

340

[C8H9O]+
121.07

100

[C20H28NO3]+

[C12H17O2]+
%

Ion Relative Intensity

0

a) 10 V

O

0

b) 20 V
60

%

178.10

100

120

[C7H7]+

140

160

180

208.13

200

313.18

220

240

260

280

300

320

340

220

240

260

280

300

320

340

m/z

91.06

100

0

91.06

80

330.21

[C11H14O2]+ 193.12

[C8H9O]+ [C10H12O2]+

c) 40 V
60

163.08 178.10

93.07 121.07

77.04

80

100

120

140

160

180

200

Ion Mass-to-Charge (m/z)

m/z

Figure B.6. CID-MS spectra for the phenethylamine 25E-NBOMe at collision potentials
of a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.
3,4-MDPA
100

[C13H20NO2]+
222.15

H
N

O

[C10H11O2]+

%

163.08
3,4-MDPA

0

60

80

100

120

140

[C8H7O2]+

[C10H11O2]+

79.06

60

80

[C6H5]+
c) 40 V

200

220

180

200

220

180

200

220

m/z

163.08

103.05

222.15

100

[C8H7

120

140

[C8H7O2]+

103.05

80

102.05

100

160

m/z

135.04

]+

[C9H7O2]+

79.05
91.06

60

180

105.07

b) 20 V

77.04

%

160

[C9H9O]+ 135.04
133.07
[C8H9]+

100

0

223.15

135.04

100
%

Ion Relative Intensity

0

a) 10 V

O

147.04
148.05

121.03

120

140

160

Ion Mass-to-Charge (m/z)

m/z

Figure B.7. CID-MS spectra for the phenethylamine 3,4-MDPA at collision potentials of
a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.
99

venlafaxine

[C17H28NO2]+

%

100

N

[C17H26NO]+

a) 10 V
60

O

80

100

260.20

Venlafaxine
Item #11567

120

140

215.14

160

180

200

[C8H9O]+
121.07 [C H O]+
10 11

100

220

240

[C15H19O]+

0

60

80

100

120

140

m/z
300

173.10
177.11 198.11

135.08

77.04 93.08

280

260.20

159.08

b) 20 V

260

[C17H26NO]+

215.15

147.08

%

Ion Relative Intensity

0

278.21

OH

160

180

200

278.21

245.00

220

240

260

280

m/z
300

260

280

m/z
300

[C8H9O]+
100

[C7H7]+

121.07

%

91.05

0

c) 40 V

115.06

77.04

60

80

100

132.06

120

140

145.07

173.10 199.11

160

180

210.24 231.00

200

220

240

Ion Mass-to-Charge (m/z)

Figure B.8. CID-MS spectra for the phenethylamine venlafaxine at collision potentials of
a) 10 V, b) 20 V, and c) 40 V. All spectra collected in positive-ion mode.

100

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101

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