[This article requires serious revision as I have been made aware of a great deal of data that I hadn't yet seen when I wrote this. There are many more moieties and specific moiety relationships that produce active compounds in vitro that are not mentioned as such here. I'll get around to it when I'm done some other projects!]
Preface:
Hello, This is the first in a new
series I have been working on.
I have previously written a great deal
on experiencing drugs firsthand and then on the properties of little-known
substances. It was while investigating this that I realized the next direction
to go- as a lot of these obscure substances were analogues of more familiar
ones- interesting modifications on some basic themes, yielding variations that
were for the most part obscure and novel. Drug design is both seemingly
infinite in its possibility yet constrained to sets of rules within discreet
categories. It is reading the paths that have been taken, and taking one step
in a slightly different direction, and perhaps as your knowledge builds you can
begin to reliably predict larger untested leaps of faith into more creative and
curious designs. This requires recognizing patterns across fields of substances
of recognizing which structures and combinations of structures will govern how
our body will respond to said substance.
It is my hope that I have been
successful in recognizing these patterns to the best of my ability and
extrapolating from that. I would like to present ideas that I so far have not
yet seen for producing novel psychoactive compounds of different properties. My
main focus will be on hallucinogens, namely psychedelics and dissociatives.
My method to doing this is to assess
all existing compounds within a class of chemical, not only those that have
been on the consumer market but ones that are mentioned in passing as being active
in literature, and ones that have so far only displayed activity in vitro or in
other animals. From there, I can try and determine which properties may be shared
across several different compounds with different structures. I can (hopefully)
make educated guesses about the properties certain substituents generate and
conserve across structures. I can try and presume that other structures that
have not yet been attempted but are biologically analogous to known active
structures will also be active- for example in psychoactive substances,
different halogens can often be exchanged for one another and activity will be
conserved- or in certain structures a sulfur can be exchanged for an oxygen
with a degree of activity conserved. I hope what is written in this series
proves to be useful in aiding the development of new compounds with a range of
exploratory and therapeutic applications.
CONTENTS:
1. Introduction
2. A Flowchart for developing novel Arylcyclohexylamines
3. The Moieties
-The
Cyclohexane
-Ring
Substititions
-The
Amine
-The
Aromatic
-A
Footnote: Conformational Constraints
4. What to study from here?
Introduction
This first post is about
dissociatives, specifically the class of compounds known as
Arylcyclohexylamines. This class of compounds offers extremely diverse
possibilities that for now are limited mostly only by the imagination. Perhaps
someday clearer limits be determined. To demonstrate the absurd degree of
possibilities, I made a handy flowchart that you can use to design a novel molecule!
I then go into extensive detail on why I selected each component of this chart,
under “The Moieties”. You can skip that part if you want. I finally go into
what I would like to see in terms of development in this class of chemical,
perhaps some ideas for an enterprising researcher.
One fairly obscure word I use a lot that
would be good to know is “Moiety”- This is a general term that denotes some kind
of defined structure within a molecule. You could consider a molecule an assemblage
of different moieties. In this case, I use it to refer to the various structures
within an arylcyclohexylamine that can be swapped out for other structures to create
different effects.
So Arylcyclohexylamine. That’s a big
word that I will be using a lot. What does it mean? What does it look like? If
you are reading this you probably already know, you can skip the next
paragraph. If you don’t know though:
It is perhaps best to understand the
Arylcyclohexylamines by familiarizing yourself with some examples: Ketamine,
PCP, MXE, 3-MeO-PCP, O-PCE, Deschloroketamine, MXPr. These are all well-known
specifically as dissociative drugs, formally known as NMDAr antagonists. They
produce physical analgesia and lead to interesting hallucinatory cognitive
effects characterized by a pleasant depersonalization. Not all
Arylcyclohexylamines act as dissociatives or are active compounds, but the
majority of them that have been explored do. Some examples are opioids or
stimulants.
What denotes a molecule being an
Arylcyclohexylamine? Its standard structure! What does that look like? Let’s
break it down, which we can do by name. Aryl- refers to an aromatic ring, that
is a ring structure with that allows electron flow freely throughout the entire
ring, which locks its shape in place and creates an extremely stable structure.
This is represented on molecular diagrams as a pattern of double bonds. The
best-known example of this is the six-carbon benzene ring, referred to as a
phenyl group when it’s a component of a larger molecule. -Cyclohexyl- meanwhile
refers to the basic cyclohexane molecule, that is a ring of six carbons in a
hexagon, single bonded to each other. It is possible that other compounds could
be exchanged for the Cyclohexane; I speak more on that later in this post. Amine,
meanwhile, refers to any organic molecule that contains a nitrogen single
bonded to other atoms, in this case it is a nitrogen bonded to the cyclohexane
ring with some other group extending from it. So that gives us an aromatic ring
attached to a central cyclohexane ring, with an amine attached to the same spot
as the aromatic ring. These compounds can then have substitutions- in the case
of arylcyclohexylamines, substitutions are additional molecules attached to
different places on the ring structures. These attachments often conserve
activity but alter the specific effects each compound will have on a human
subject. Herein lies the exciting sea of possibilities- as all different
compounds known so far seem to be unique in their effects!
Arylcyclohexylamines have a
standardized though informal nomenclature that lets you quickly determine the
structure from the name of a compound. The names are structued X-YCZ.
The X represents any substitutions, listed with the site they are attached to.
A lone number denotes an attachment on the aromatic ring, a ‘ after the number
denotes an attachment on the cyclohexane ring, and a “ denotes an attachment on
any amine ring structures that may be present. The Y represents the aromatic
ring. Typically this is represented by a “P”, as a phenyl is the most commonly
used aromatic ring. The C will always be “C”, to represent the cyclohexane
ring. The Z meanwhile represents the amine group, usually abbreviated to the
first or first few letters. So PCP for example, is Phenyl-Cyclohexyl-Piperidine.
3-MeO-PCE is 3-Methoxy-Phenyl-Cyclohexyl-Ethylamine.
It has been documented that
Arylcyclohexylamines can see a variety of alterations that conserve activity.
The first place to look as the aromatic group- the vast majority of
Arycyclohexylamines use a phenyl ring, but it is known that a thiophene ring
can be active too. This opens two possibilities- that aromatic rings with
either 5 or 6 members will remain active, and that aromatic rings with other
atoms on them beyond carbon will remain active. Below the flowchart I will
explain my reasoning in depth for selecting the possible aromatic rings that I
did. The next modification can come on the amine moiety. A huge ocean of
possibilities opens up here, with all sorts of structures yielding viable amines.
It should be noted that it seems as though only fully saturated carbons
directly adjacent to the nitrogen are tolerated. In other words, this means no
double bonds anywhere near the nitrogen (with one known exception)! Otherwise,
have fun.
Anywhere where you have a ring, you
may hypothetically attach a range of substitutions- which range from alkanes,
Alkoxy groups, Ketone oxygens, Hydroxy groups, Halogens, Halogenated alkanes, ethers,
esters, ring structures, and possibly thioalkanes, all being available to strap
onto rings at almost any available position, given they are substantially
lacking in bulk and don’t create steric interference with other parts of the molecule.
Of course I’m not necessarily saying
you can freely do all of this- unexpected exceptions and pitfalls arise
everywhere. According to self-reporting by bluelight user “adder” for example,
a 2’-Oxo substitution on PCP also yields an opioid-like compound, a
substitution that is an active dissociative with a chain alkane as the amine.
Sometimes it appears changes in substitutions or substituents give you
unexpected shifts in which receptors the molecule will interact with.
Nonetheless, rapid shifts in activity are for now, the exception and not the
rule, and it seems the majority of them preserve dissociative activity so long
as those basic components are fulfilled. While a lot of these structures have
been studied and determined active in animals, that activity was often pinned
simply to basic tests of analgesia, meaning the compound could behave either as
an opioid or an NMDA antagonist. Tests like the capsaicin test or a naloxone
inhibition test would help clarify.
It’s worth mentioning I have a very
poor background in Organic chemistry. While I understand the rudiments of
structural properties of molecules, synthesis and reactions are a foreign,
incomprehensible world to me. I know nothing of what the process of actually
producing any of these compounds is like, what the safety or viability or price
or legality of any of that would be. I can not spot from afar which compounds
may be synthetically impossible, prohibitively difficult or expensive, or which
compounds may simply end up being unstable. I hope someone with more knowledge
in that area can chime in- but for the time being I did not give synthetic
viability any regard in my designs.
Before sharing this chart, I figure I
should give a warning on potential danger. As you stray further and further
from familiar compounds you may see more and more unexpected effects. You may
be able to reliably predict a simple substitution modification on a compound
with a phenyl ring and some familiar alkane amine. Not to say that such a
compound can be immediately presumed safe, but I would say the chance is
greater than with something much more experimental. Say you are running with
something that has no known immediate analogues for reference- for example’s
sake, 3-TFM-FCEBF. Refer to the chart for the structure of that one. But
nothing very similar exists- we don’t know what exactly a furan ring as the
aromatic does, what a Trifluromethane substitution does or an ethylbenzofuran
amine. What would be the safest way to approach such a compound?
There are also a number of ways
chronic toxicity is reported to present with NMDA antagonists, mainly neurotoxicity
and cytotoxicity. In terms of neurotoxicity, there are the infamous Olney’s
lesions, a form of brain damage, that has been observed in other animals,
though they have still not officially been observed in humans yet [43]. However,
a recent study reportedly observed some form of damage in the brain of extremely
frequent users of ketamine [44]. The other main reported symptom that indicates
toxicity is urinary toxicity [45, 46], supposedly a result of damage to the
epithelial cells lining the bladder caused by direct toxicity from ketamine
metabolites. This has so far only been officially reported with ketamine,
though there are anecdotal reports of it occurring in frequent users of other
dissociatives. There is also a potential for cognitive dysfunction from extreme
repeated use of dissociatives, mostly in the form of “brain fog” and memory
loss, though there is some literature on the matter [47].
These substances also carry the risk
of generating dangerous behaviors that can be damaging to one’s life
circumstances and relationships, both through the dangerous interplay of prohibition
and substance, and in properties inherent to the chemicals themselves. One key
risk is addiction- while physical dependence to dissociatives is significantly
more rare than with other classes of substance, it is entirely possible and
psychological dependence is commonly reported. Frequent usage significantly
increases the chance of toxic effects or cognitive dysfunction presenting. Other
substances, such as PCP, are notorious for causing intense mania that can push
into psychosis, which can lead to violence, damaging relationships, and legal
trouble. All of these risks are real and it is up to the user to determine what
methods personally work best for mitigating them, including total abstinence if
necessary.
I would suggest, in a perfect world
(keep in mind this is all very handwaved, this actual process can be expensive,
difficult, and extremely time consuming)- First, doing a virtual docking
simulation of the compound. This of course is not a surefire way to determine
activity, but can perhaps give warning of possible unexpected activity or help
to rule out certain options as being less viable. The compound can be
synthesized from there, at which point it must be properly characterized via
NMR and GC/MS analysis. From there, an in-vitro receptor affinity study can be
done to confirm or deny certain targeted activities in nerve cells in comparison
to familiar reference compounds, like PCP, Ketamine, MK-801 or Morphine. The
safest step from there would be in-vivo studies in animals, also compared to a
control group of reference compounds. Behavioral tests can be done for
comparison to any references, and drug substitution tests can help indicate
similarity to the references. There is a huge variety of animal tests that can
be done in combination with each other and with various controls to really
narrow down possible mechanism of action depending on what a researcher has at
their disposal. In-vivo tests also help to determine an mg/kg dosage range and
possible acute or chronic toxicity, or even an LD-50. Only after it has been
presumed nontoxic and its likely activities have been characterized should one
even consider human testing. This must also be done in the context of extremely
precise doses, titrated upwards from a microgram range, with the subject
physically monitored by a healthcare professional. If you want to get really
fancy, this can be performed in a double blind test with a placebo.
Of course not all those processes or
resources are available to every researcher. Those are all long, difficult,
expensive processes that may require specialty equipment, facilities, and
faculty. Many researchers of psychoactive compounds have opted to skip some or
most or all of those steps, and prohibition absolutely makes obtaining any of
those resources extremely difficult. I would recommend approaching with maximum
caution, but I’m also not the boss of anyone and can’t make anyone do anything,
and understand how the spirit of curiosity can sometimes overcome a lack of
available resources. Ideally a team of researchers could easily have
infrastructure to efficiently run multiple compounds through that gauntlet of
safety determinations. But this world is less than ideal. Please just for the
love of god, be safe, be smart, be responsible.
A flowchart for developing
Novel Arylcyclohexylamines
You can enlarge the image here:
https://i.imgur.com/DcKXhv6.png
You can find a pdf version of this chart here:
That was a doozy.
So what about each and every
substitution and substituent? Fuck, this is my blog, I can do what I want and
write what I want and make a post as long as I want. This will probably not be
interesting, but it’s a form of data, here we go:
THE MOIETIES:
The Cyclohexane
(and others):
We start with looking at the
Cyclohexane Ring-This is the one consistent component in Arylcyclohexylamines.
It’s right there in the name. But-there is evidence it is not our only option!
I mention this in the footnotes of the chart, and as this article is on Arylcyclohexylamines,
all other moieties and substitutions I mention will be under the assumption of
being anchored on an arylcyclohexylamines. For the sake of interest though, I
will briefly mention those other possibilities. It should be noted that
derivatives of the following compounds would technically not be
Arylcyclohexylamines as a result of them not having a cyclohexane group. An
alternative game is given after each possibility, and this entire series of
structures and their derivatives could broadly be referred to as Aryl[x]amines.
I may bring attention to these in a future article, as I think it is highly
worthy of consideration and shouldn’t just be buried in this post. Anyways:
Thiane- Arylthianylamine: A Thiane ring, that is a
Cyclohexane if you replaced one of the carbons with a sulfur. It appears with
this type of substitution, it is best to keep the electronegative atom as far
from the aromatic/amine bond as possible. If I remember my naming conventions
properly it would be 3-[Aromatic],[Amine]-Thiane, with the sulfur at the 1
position. This structure was alleged on a bluelight thread, where a user stated
that they remembered reading a study that found evidence of activity in a EJoMC
article, but were unable to find the article anymore. One active compound cited
by this use was a thiane derivative of PCiPr, you could call it PTiPr if you’d
like. Despite the lack of evidence for now, It’s an interesting hypothesis and
nothing stands out to me that would invalidate it. If anyone can find more
information on this please let me know!
Oxane- Aryloxanylamine: As I will state several
times throughout this article, an oxygen can sometimes be substituted for
sulfur to retain bioactivity in many molecules, as they have similar binding
properties. Though there has been 0 published conjecture on this, I believe it
remains as a possibility.
Adamantane- Aryladamantylamine: Described in [13], this
is a very very interesting variation, with the complex 3-dimensional adamantane
serving as the central structure, the aryl and amine bonded to one location on
one of the cyclohexane rings that composes its form. Interestingly,
adamantanylamines compose their own class of dissociative, with the simplest
Amantadine, and the dimethylsubstituted Memantine being very non-potent but
ultimately powerful dissociatives. So perhaps its intuitive to combine the two
classes. This one study found lower toxicity (you can read that as lower potency
perhaps) but enhanced anesthetic effect relative to PCP [13]. Very promising-
an adamantane also has several potential locations for substitutions. This
would open the door to dizzying possibilities.
Bicyclo-Heptane (Arylbicycloheptylamine): Described in [10],
another 3d polycyclic structure like adamantane, but toned down a bit. The
particular compound that displayed activity had an ethyl-piperidine attached to
the amine site, an interesting and unique substitution. This structure is also
called Norbomane.
Tetralyl (Aryltetralylamine): Shown in [2], where a
Tetralyl (That is two conjoined six member rings- a cyclohexane and a phenyl) analogue
of 3-Meo-PCP is presented. In the animal trials, it was shown to act as an
analgesic with specific properties that indicate it may function more as an
opioid instead of a dissociative- nonetheless it’s an interesting avenue for
development that may be open to all kinds of substitutions. Having an aromatic
butted up directly against the cyclohexane surely has some interesting
implications for activity.
 |
| Alternative structures to a cyclohexane |
Now that that’s out of the way, lets
get to the meat of things.
Ring
Substitutions:
From here on out, it is assumed that
we will be using a cyclohexane ring, producing a true Arylcyclohexylamine.
The first thing we’ll look at are the
available ring substitutions. There are a lot of potential options! The general
rule for known substitutions that can conserve NMDA activity are: Alkane
chains, Ether chains, Hydroxy, Ketone Oxygen (only on a saturated ring!), Amine,
Halogens, Halogenated Alkanes, Halogenated Ether chains, Aromatic Rings, Esters,
and hypothetically thioalkane chains. Substitutions can be placed on any ring
structure, whether it be an aromatic, the cyclohexane, or any ring structures
on the amine. Whichever ring it is determines which substitutions will work-
something that helps is to know how molecular diagrams work- pretty much any
carbon on the ring that has an open hydrogen can have that hydrogen swapped for
some other substitution. In general, it seems that substitutions on the
3-position of an aromatic ring, a 2’-Oxo substitution, and substitutions on the
para-position of other amine ring structures show the most promise.
I have proposed several options for
substitutions that appear viable- lets dissect them a bit.
Alkane
substitutions:
Me (Methyl): The simplest carbon and
3-hydrogens. The Methyl substitution is well understood to conserve activity,
and in some cases it even brings about activity where it did not exist in the
base structure [4]. I will not even cite all the sources here because they are
too varied, but placing Methyl substitutions on at least one position on every
viable ring seems to conserve some kind of activity, depending on what other substitutions
are lurking about. Proceed with this one confidently.
Et (Ethyl): [19] and [24] both show an
ethyl substitution, but in the unique place of a. being a substitution on the
piperidine ring of PCP, and b. sharing that substitution site with something
else, typical a methyl group. These were demonstrated to be active, but the
exact method of determining that activity and whether that’s NMDAr antagonist
or Opioid activity still remains to be seen. Such changes in activity would
likely come from jamming two substitutions onto one carbon though, not anything
inherent to the ethyl group, which by all means seems normal and benign. I
would most like yo see it as a 3 position substitution on a phenyl ring, to
just help establish what the SAR pattern of extending alkane chains may be
like.
Pr (Propyl): I don’t see why this
wouldn’t work but it hasn’t been attempted yet. A 3-Pr substitution on a phenyl
ring would probably be the best place to start.
iPr (Isopropyl): I don’t see why this
wouldn’t work but it hasn’t been attempted yet. A 3-iPr substitution on a
phenyl ring would probably be the best place to start.
cP (Cyclopropyl): In several other
psychoactive molecules, a cyclopropane can often stand in as a possible
substitution. It has never been attempted on an arylcyclohexylamine so its
effects within that context are for now, unknown. But It’s possible! Once
again, a 3-cP substitution would be the best place to start.
Bu (Butyl): In other psychoactive
molecule series, there is a steep drop in potency when an alkane chain gets too
bulky- 4 carbons usually seems to be it. I don’t look into any aliphatic alkane
longer than this, but a butyl substitution remains a possibility, best at the 3
position. However, this is evidence that a bulkier substitution may actually
lead to an increase in potency, at least for PCP (see BuO substitution)
iBu (Isobutyl): An isobutyl would
probably be similar to a Butyl chain, but less bulky. This may show ore promise
than a straight butyl chain in fact. Best at the 3 position.
sBu (sec-Butyl): Another configuration
that may show promise. Also best at 3 position.
tBu (tert-Butyl): With a tert-Butyl
structure you run the risk of inactivity due to steric interference of so many
carbons crammed so close together. This leads to compounds that may be unstable
or are exceedingly difficult to manufacture. I wouldn’t put much stock in tert-butyl
substitutions being possible or active, but I included it for completion.
Ether Substitutions:
MeO (Methoxy): This is a classic
substitution that has clear demonstrated activity in a variety of structures
and when combined with other substitutions. Combination with a 2’-Oxo group has
produced a line of well renowned compounds like MXE or MXPr. 3/4 substitutions
on the phenyl ring are clearly active, as in 3-MeO-PCP. A 4’ substitution on
the cyclohexane may be promising, a would a 3”/4” substitution on say, the
piperidine ring of PCP. More experimental data also see it strapped on to all
sorts of compounds with outlandish amine structures. There is evidence that it
retains activity when substituted onto a Piperidine ring [6] opening that ring
up for more possibilities. Seems to offer a lot no matter where you pit it.
EtO (Ethoxy): Similar to the Ethyl vs.
Methyl group, this hasn’t been attempted but I see no reason it wouldn’t work. [32]
saw a compound with a butoxy group retain in vitro activity, so I imagine
everything between methoxy and butoxy could be active. Best to start on the 3
position again.
PrO (Propoxy): Hasn’t been attempted
but is a likely candidate. See above.
iPrO (Isopropoxy): Hasn’t been
attempted but is a likely candidate. See above.
BuO (Butoxy): PCP analogues with 3 and
4 BuO substitutions were found to be not only active but potentially highly
potent in an in vitro study [32]. This suggests several interesting ideas: The
first is that everything alkoxy group between a Butoxy and a Methoxy in length
on the 3 or 4 position would be active. The second is that a bulkier
substitution actually leads to an increase in potency. Psychoactive
substitutions usually cap off around a pentane but perhaps with
arycyclohexylamines it is worth exploring further.
iBuO (Isobutoxy): Same idea as a
Butoxy group- I can see the various rearrangements of the butane isomers as
maintaining similar properties when bonded to the 3 or 4 position.
sBuO (sec-Butoxy): Same idea as a
Butoxy group- I can see the various rearrangements of the butane isomers as
maintaining similar properties when bonded to the 3 or 4 position.
tBuO (tert-Butoxy): Same idea as a
Butoxy group- but with the same stipulations as mentioned with a tert-butyl
group before. If this did work/was stable/was feasible to produce it would
certainly be interesting.
Hydroxy
Substitution:
HO (Hydroxy): This little substitution
has been placed on the 3 position of the phenyl ring for a handful of familiar
compounds with exciting results. People have proposed combining it with a
2’-Oxo group ala MXE and friends, with the 3-HO group replacing the 3-MeO group.
There is promise in this, and such compounds have been promised for years, but
their existence for now seems to remain a rumor or confined to a very tight
market. A number of researchers have sought to explore the role of an -OH on
the piperidine ring of a PCP (most notable a pcp metabolite excreted in urine
is 4”-HO-PCP aka PCHP, I don’t know if its psychoactive in its own right
though). There are a dizzying amount of study compounds with this, which really
suggests this is a substitution that can be wantonly thrown around to maintain
activity. Play around with it. Some examples can be seen in [1, 3, 9, 14, 19]
Oxygen
Substitution:
Oxo (O): This is an oxygen double
bonded as a substitution, turning the compound into a ketone. It’s a highly
notable substitution, most notably appearing in the ketamine molecule. An Oxo
group can only be placed on a fully saturated ring structure- so far we’ve only
seen it on cyclohexane and piperidine/pyrollidine bases, but perhaps it could
be placed on a saturated side chain amine ring structure. Almost everywhere
this substitution has been seen has placed it on the 2’ position on the
saturated middle ring. This is seen in Ketamine, DCK, 2F-DCK, O-PCE etc.
Supposedly, when attached to PCP it becomes more of an opioid with negligible
dissociative effects [33]. A 4’-Oxo PCP substitution was also attempted, which
was similar [33]. Adder, author of that thread, suggested that a bulkier amine
paired with an x’-Oxo substitution would reduce NMDA activity. Indeed
2’-Oxo-PCM (DCK) and 2’-Oxo-PCE (O-PCE) are very clearly dissociatives. Because
it is fairly unique as far as arylcyclohexylamine substitutions go with weird
activity patterns, this is one that should be treated with caution, especially
when pairing it with unfamiliar amines or attaching it to different locations
on the cyclohexane ring- or dare I say placing it on a saturated amine ring-
maybe inactivity, maybe something entirely unexpected- hard for me to discern.
Thioalkane
Substitutions:
MeT (Methylthio): This is pure
Hypothetical territory running on the principle that you can sometimes swap an
oxygen for a sulfur in structures and retain activity. This is the realm of
someone who understands pharmacology better than me but I figure I could at
least suggest it. A 3- position substitution would be safest to try first.
EtT (Ethylthio): More pure conjecture
but from multiple angles now- two purely
hypothetical ideas unite here. I can’t say anything on this really other than
it should also be tried on a 3- position.
PrT (Propylthio): Same as before,
perhaps the hypothesized pattern with potency seen in the alkoxy compounds
would apply to the thioalkanes too. But that is truly nothing more than a wild
guess. I would say one should figure out if a sulfur does anything in the first
place before starting to venture into longer chains or different isomers.
Amine
Substitution:
A (Amino): What gives,
arylcyclohexylamines already have an amine! Well here’s another, but elsewhere.
Bluelight user adder stated a 3-Amino substitution was effective [33]. Several
other studies have found this compound active and potent, including the big old
assessment by Kalir in 1981 [19]. This can be assumed a green light for
development! Synthetic difficulties aside.
Halogenated Substitutions:
F (Fluoro): This was first seen on the
market in 2F-DCK, where it replaced what is ordinarily a chlorine in ketamine
at the 2 position. It appears activity is still retained when the oxygen is
removed from the cyclohexane ring, suggesting that a simple 2-substituted
halogen will hold up in that situation. Fluorine has also been attempted on the
3 position on PCP- an interestingly novel but fairly lackluster dissociative
with a pretty low potency. I am curious about how this would function with
other amines. Halogens in general seem to kill potency, but still create
worthwhile compounds that you just need more of. Fluorine is a good basic one
to start with and lay out patterns. Placing it at the para position of another
ring also seems like it may work. Apparently a 4-F substitution is inactive [33].
Cl (Chloro): Things seem to stay
active as we sit at the top of the periodic table. This substitution is most
notably in ketamine, on the 2 position. As said before, a 2-chloro substitution
without the oxygen on the cyclohexane still appears to be active. This is certainly
an interesting route to explore. A 3-Chloro PCP analogue has also come out
recently, and though I haven’t been able to try it as of this writing, initial
reports claim it is similar to 3-F-PCP in potency and experience. As before,
para substitutions may be another way to go with this one.
Br (Bromo): Adder didn’t see much
promise in the halogenations as you went down the table, labeling 3-Br-PCP as
inactive [33]. I think it is worth revisiting however. A bromo substitution is
fairly easy from what I understand and a logical route to go when testing
halogens. It likely would require a very high dose- perhaps outside the range
of the chemicals being tested in that thread. Activity in the lower halogens
suggest that a 3-Br substitution would continue that pattern but things are
also hard to predict. I imagine it would work best on the 2 or 3 position.
I (Iodo): Purely hypothetical, hasn’t
been attempted. If 3-Br-PCP is inactive, 3-I-PCP definitely is. I would imagine
that if it was active it would require a massive dose for activity. It is
probably most effective on the 2 or 3 position if at all. Iodine can be seen as
conserving activity in some psychoactive drugs, namely psychedelics like 2C-I
or 25I-NBOMe.
TFM (Trifluoromethyl): Purely
hypothetical but such a reactive group is always an interesting avenue when it
comes to substitutions and I surely think it is worth trying as an
arylcyclohexylamine. I would suggest only trying this on the 3 or 4 position of
a phenyl ring or the 4” position of a piperidine ring for now.
TFE (Trifluoroethyl): A slight
variation on the same as above. I figure the same properties would stand.
Halogenated Ether
Chains:
TFMeO (Trifluoromethoxy): This is
based on the compound following this, which features the trifluoromethane
bonded directly to the oxygen. Whether it would work so close to the oxygen may
be up for debate. I don’t have much faith in this one.
TFEtO (Trifluoroethoxy): This
substitution was demonstrated to be mostly active in vitro in [32]. This seems
a really out of left field idea for a substitution as far as I know, but hey,
it seems feasible. Perhaps that extra carbon keeping the intense bristling
fluorines away from the oxygen stabilizes its activity a bit. It was tested on
the 3-position of the phenyl ring in PCP, I wouldn’t stray further from that if
attempting this.
Aromatic Ring
Substitutions:
Ph (Phenyl): Strapping on an entire
new aromatic group as a mere substitution seems absurd- could you perhaps
attach substitutions to this? Nonetheless several active compounds have been
discovered in vitro from this odd substitution, mostly on the Piperidine ring
of PCP. Some of these compounds are also suggested to be opioids, so be wary!
They can be seen in [9, 16].
Bn (Benzyl): Who knows what a Benzyl
group as a substitution would do, but the possibility is on the table. If a
phenyl can retain some activity, a Benzyl might too? But I would perhaps expect
an opioid to come from this.
Ester
Substitutions:
AcO (Acetoxy): al Deeb et al [9]
demonstrated a variety of odd compounds that were analogues of TCP. Most of
these featured a double substitution on the 4”-position of the piperidine ring,
with obscure phenyl groups, but more importantly with a series of esters that
despite their large structures retained activity. A 4”-AcO-TCP proved to be the
second most potent compound of this series. These compounds varied in suggested
opioid vs. NMDA antagonist activity. Whether ester substitutions would work on
other rings in the arylcyclohexylamine compound is entirely unknown- for now I
would suggest just developing along 4-Piperidine analogues.
PrOa (Propanoate): A larger ester that
also demonstrated activity in al Deeb et al [9]. Also sufficiently active.
Whether ester substitutions would work on other rings in the
arylcyclohexylamine compound is entirely unknown- for now I would suggest just
developing along 4-Piperidine analogues.
iPrOa (Isopropanoate): Conjectured
ester that retains activity based on what other active esters are. I see no
reason this wouldn’t work. Whether ester substitutions would work on other
rings in the arylcyclohexylamine compound is entirely unknown- for now I would
suggest just developing along 4-Piperidine analogues.
BuOa (Butanoate): Conjectured ester
that retains activity based on what other active esters are. I see no reason
this wouldn’t work. Whether ester substitutions would work on other rings in
the arylcyclohexylamine compound is entirely unknown- for now I would suggest
just developing along 4-Piperidine analogues.
BnO (Benzoate): The bulkiest and most
complex ester substitution put forth, which demonstrated the highest potency of
the entire series attempted in [9]. A promising route. Whether ester
substitutions would work on other rings in the arylcyclohexylamine compound is
entirely unknown- for now I would suggest just developing along analogues where
the substitution is found on the 4-position of the piperidine.
MD (Methylenedioxyl): This is a
substitution that for now will probably show the best results bonded to the 3,4
position of a phenyl ring (as the aromatic). There are other positions and
other rings where it can be wedged in but a 3,4 substitution shows the most
promise. A 3,4-Methylenedioxy group is best known as a component of MDMA. But
that has no relation to an NMDA antagonist beyond a shared substituent.
Nonetheless, it can be expected that at the very least, bioactivity an be
conserved with this substitution.
Fu (Furanyl): Similar to the last, I
am really only accounting for it being bonded on the 3,4 position of a phenyl
ring, forming the famous benzofuran group found a variety of unrelated
psychoactive substances. If there was any ring shaped substitution that would
present activity beyond a 3,4-MD group, I would suspect it would be a Furan,
forming a benzofuran.
THF (Tetrahydrofuranyl): Purely conjectural.
Probably should also only be placed as a 3,4 substitution.
THP (Tetrahydropyranyl): Purely
conjectural. Probably should also only be placed as a 3,4 substitution.
Now we get to the meat of the meat-
let’s dive into the vast vast diverse field of Amine Moieties. This will be
long. Sit back.
The Amine
Denoted by the tail end of the term
“arylcyclohexylamine”, we find ourselves at perhaps the most diverse avenue for
variation on this molecular backbone. The amine allows for a dizzying diversity
of possibilities. For a quick lesson- a amine is a nitrogen bonded to carbons.
Nitrogen typically only can bond with three things at a time. A primary amine
is a nitrogen bonded to a carbon structure and two hydrogens, a secondary amine
sees it bonded to two carbon structures and one nitrogen, and a tertiary amine
sees it bonded to three carbon structures. The choices I made were determined
by a few observations I had made on patterns, like
-It appears that any carbons directly
adjacent to the amine must be saturated. Thus a enamine would not be active but
an allyl would. This also manifests in ring structures, where it appears an
aromatic tertiary amine ring should not be tolerated- however in [5] it was
found that a pyrrole group could conserve activity only if it was paired with a
methyl group on the phenyl ring. Curious, but a researcher may find more
success exploring the saturated ring structures for now.
-In a Tertiary amine, a bulky
substituent paired with a smaller one seems to reduce activity (eg; some long
ester paired with a methyl group as seen in [17]). It makes sense to keep these
to modest alkane chains for now.
With this in mind, I set out to list
out which viable possibilities I could brainstorm:
Primary Amine:
-A (Amine): The simplest option we
have on hand, the base primary amine where the nitrogen sits alone with its two
hydrogens. When paired with the 2-Cl-2’-Oxo substitutions of ketamine, it is
known as norketamine, which is one of the many metabolites of ketamine in the
human body. Evidence suggests however that norketamine is active in its own
right [31]. This opens the door to other variations on this structure.
Alkane Chains:
Alkane Chains are the simplest
substitutions you can add to an amine on an arylcyclohexylamine. They are reliably
active and are known to tolerate a variety of substitutions. Most of our known
familiar compounds that have hit the market (Ketamine, DCK, 2F-DCK, MXE, O-PCE,
3-MeO-PCE, 3-HO-PCE, MXPr, MXiPr etc.) are variations on simple alkane chain
amines.
-M (N-Methylamine): A methyl group is
the simplest alkane that can be strapped to an arylcyclohexylamine. It may
perhaps be the basis for the most familiar arylcyclohexylamine, namely
ketamine, which could also be known as “2-Cl-2’-Oxo-PCM”. PCM and its analogues
are by far the best studied of the arylcyclohexylamines. With the variety of
other compounds like 2F-DCK, DCK, MXM etc., it can be assumed that a
methylamine will tolerate all sorts of variations, a stable base that can be
consistently trusted to deliver worthwhile compounds.
-E (N-Ethylamine): An Ethyl group is
another tried and true amine. The unsubstituted form, known as PCE, is potent
and was once upon a time sold on the street as an alternative to PCP [26]. Several
other very well known compounds use this base, most notably MXE, or
3-MeO-2’-Oxo-PCE. 3-MeO-PCE is a personal favorite of mine, and many others
have found favorites among the various PCE variations. With the sheer amount of
substitutions and combinations of substitutions that are possible, it’s likely
that PCE will always be a gift that will keep on giving for drug development.
-Pr (N-Propylamine): Developing alkane
substitutions follows a predictable path of just adding one carbon at a time,
and here we are with a propylamine. It’s certainly active, though this has only
been demonstrated with 3-MeO-2’Oxo-PCPr, also known as MXPr. Other
substitutions would almost certainly see some sort of interesting activity. I
conjecture they may show lower potency than their PCE counterparts however.
Contrary to that however, [33] mentions that the base PCPr was similar in
potency to PCP.
-iPr (N-Isopropylamine): Pretty much
same as above, reconfigure the propylamine and you get another active compound,
as demonstrated in MXiPr (3-MeO-2’Oxo-PCiPr). [33] mentions that the base PCiPr
was similar in potency to PCP. Lots of room for variation here, we’ve only
scratched the surface! Best to keep on chugging.
-Bu (N-Butylamine): Logically the next
step is of course a butyl, 4 carbons. Adder in his bluelight thread on PCP
analogues gave this one a passing mention as being active but less potent than
PCP [33]. This raises a curious pattern- if the PCPr analogues are also
suspected to show a drop in potency relative to a group with less carbons, it
can be conjectured that you see potency go down as you extend the alkane chain.
To that end I would hypothesize that you would see serious diminishing returns
in potency once you go past a butyl, similar to substitutions on psychedelics. However,
it is clear that bulk of the amine alone doesn’t determine potency, as some
very large and bulky amines are not only tolerated for conserving activity, but
are actually quite potent, like PCP for example. Fairly long reverse esters
also conserve activity, but this might be due to being prodrugs for something
else. So I would feel comfortable saying that there is an inverse relationship
betweem amine bulk and potency only in the non-cyclic alkanes.
-iBu (N-Isobutylamine): This has never
been attempted but I see no reason it wouldn’t work.
-sBu (N-sec-butylamine): This has
never been attempted but I see no reason it wouldn’t work.
-tBu (N-tert-butylamine): This has
never been attempted. Tert-Butyl groups can be tricky to work with
synthetically so I’m not sure about the physical feasibility of this one. But
if it can be made I would imagine it and its analogues would be active.
Amine Ether
Alkane Chains:
Some enterprising users on theehive
found out that NMDA antagonist activity is conserved in ether amines, which is
laid out in detail by Hamilton Morris and Jason Wallach in [26], where such
compounds are referred to as Arylcyclohexylalkoxyamines. Such compounds were
apparently available on the market in Europe for a brief time. If I had
invented this series I would’ve chosen a different set of naming conventions
for them, at least something in the name to indicate that they are ethers or an
oxygen is involved somewhere. Someone else already began naming them however,
and thus all the hypothetical ether amines I present follow their conventions.
Their method seemed to just be the letter for the chain after the oxygen, the chain
before the oxygen, and an A to indicate the amine. Whatever I guess.
-MMA (N-Methyl-Methoxyamine):
For now I consider the whole series of N-methyl ethers to be dubious in
activity, based on a sort of unfounded gut instinct that having the oxygen too
close to the nitrogen reduces activity. It is suggested in Jose et al 2013 [17]
however that potency is a function of the size of the chain after an oxygen
rather than between the oxygen and nitrogen. But that was also with reverse
ethers, so who knows. For now I would say the N-methyl ethers are all possible
but dubious.
-EMA (N-Methyl-Ethoxyamine): See
above- possible but dubious.
-PMA (N-Methyl-Propoxyamine): See
above- possible but dubious. I only go as far as a propyl chain extending past
the oxygen. Maybe arbitrary, but I feel like diminish returns would come from
strapping longer chains there.
-iPMA (N-Methyl-Isopropoxyamine): See
above- possible but dubious.
-MEA (N-Ethyl-Methoxyamine): This is a
confirmed active moiety. How it may interact with ring substitutions elsewhere
in the structure is unknown, but this PCMEA was apparently an active compound
on the market at one point in time. It had enough potency and activity to be
sold, but there exists little information on what the actual experience was
like. It is mentioned in [26].
-EEA (N-Ethyl-Ethoxyamine): This is a
confirmed active moiety. How it may interact with ring substitutions elsewhere
in the structure is unknown, PCEEA was apparently an active compound on the
market at one point in time. It had enough potency and activity to be sold, but
there exists little information on what the actual experience was like. It is
mentioned in [26].
-PEA (N-Propyl-Ethoxyamine): If PCMEA
and PCEEA are active I see no reason for PCPEA to not also be.
-iPEA (N-Isopropyl-Ethoxyamine): If
PCMEA and PCEEA are active I see no reason for PCiPEA to not also be.
-MPA (N-Methyl-Propoxyamine): This is
a confirmed active moiety. How it may interact with ring substitutions
elsewhere in the structure is unknown, PCMPA was apparently an active compound
on the market at one point in time. It had enough potency and activity to be
sold, but there exists little information on what the actual experience was
like. It is mentioned in [26].
-EPA (N-Ethyl-Propoxyamine): PCEPA is
mentioned in an analytical and pharmacokinetic study published in 2006 by Sauer
et al [28]. This study seems to contextualize it as a novel drug of abuse, which
is curious as I could find no other evidence of its existence or use. None of
that work would’ve been done if it was inactive though, so its definitely worth
investigating further.
-PPA (N-Propyl-Propoxyamine): If PCMPA
is active I see no reason for PCPPA to not also be.
-iPPA (N-Isopropyl-Propoxyamine): If
PCMPA is active I see no reason for PCiPPA to not also be.
-MBA (N-Methyl-Butoxyamine): Now we’re
getting into unknown territory. If my arbitrary conjecture about activity being
conserved in the distance between the nitrogen and oxygen holds up, then this
should certainly be active. But I simply do not have enough knowledge to
predict that.
-EBA (N-Ethyl-Butoxyamine): Same as
above.
-PBA (N-Propyl-Butoxyamine): Same as
above.
-iPBA (N-Isopropyl-Butoxyamine): Same
as above.
Other Oxygenated
Alkane Chains & Esters:
Here’s some other structures with
oxygen in them. Most of these are pure conjecture, sorry.
-HOMA (N-Methyl-Hydroxyamine): Per the
hypothesis I mention in the N-Methyl ethers, I wonder if it would still stand for
a hydroxy alkane? Who knows. This one is probably conjecture for now.
-HOEA (N-Ethyl-Hydroxyamine): This is
an active moiety This is demonstrated in [17], and then mentioned in [26] as
having been on the market at some point too, the product of some bees on
theehive and a brief flash in the euro market. No information on how it
interacts with other substitutions or what the actual experience is like
however.
-HOPA (N-Propyl-Hydroxyamine): A
hypothetical moiety that’s never been attempted, if one wanted to explore
further with hydroxyalkane amines I would think it would make more sense to go
in this direction vs. in the direction of a methyl if the ethyl hydroxyalkane is
the reference point. Perhaps a butyl chain would function too. There simply
isn’t enough data to confidently guess.
-AcAL (N-Acetalamine): Pure
conjecture. Nothing screams inactivity about this to me though. This is where
pharmacokinetics come into play- I really do not understand pharmacokinetics
and I am not sure if there is some obvious metabolic activity in response to an
aldehyde that would render this either inactive or highly toxic. Someone who
knows their stuff better than me should approach this one.
-PrAL (N-Propanalamine): Pure
conjecture. Nothing screams inactivity about this to me though. This is where
pharmacokinetics come into play- I really do not understand pharmacokinetics
and I am not sure if there is some obvious metabolic activity in response to an
aldehyde that would render this either inactive or highly toxic. Someone who
knows their stuff better than me should approach this one.
-MAcO (N-Methyl-Acetoxyamine): The
standard acetoxy ester on an ethyl chain is active in vitro, as a short acting
compound (more on that in a bit). Would a methyl acetoxy group do the same? Acetoxy
groups are well known as substitutions on tryptamines that yield unique and
lovely effects. Not that that has anything to do with arycyclohexylamines, an
entirely different class of drug with entirely different pharmacology.
EAcO (N-Ethyl-Acetoxyamine): This was
demonstrated as active in [17], the only “forward” ester that was produced in a
series of “reverse” esters that were tested alongside it. It was produced as a
ketamine analogue (that would be 2-Cl-2’-Oxo-PCEAcO), and was shown to be the
most potent in the series, with similar properties to the others in terms of
rapid metabolism and action and short duration. Opens the door to more
variations on this theme perhaps.
Reverse Ester
Alkane Chains:
This is an interesting and obscure
series of compounds that have not yet been tried in humans. First to clarify
some terms- an ester is an organic functional group that sees an alkane chain
meet an oxygen, which is in turn bonded to another carbon with a double bonded
oxygen, which is in turn bonded to a further alkane chain. Just google it it’s
hard to explain. Looking at the flowchart however, you will see that this
series of compounds does not fit that description- these are “reverse” esters.
What you call the front and back end of an ester is really just a matter of
semantics. The side that connects to the bridging oxygen is is typically the
“front” and the side that extends from the carbon that bears the -Oxo group is
the “back”. Basic sense would dictate that you would call the larger more
complex side the “front”, as is done with these compounds, thus the ester
appears in reverse, with the big complex arylcyclohexylamine on the side of the
chain with the -Oxo group, and a small alkane chain extending from the bridging
oxygen. You could see these as a forward ester if you consider that little
alkane bit to be the “base” of the structure and the entire unwieldly
arylcyclohexylaine as the tail, but its harder to describe it that way, so they
are just referred to as reverse esters. Semantics.
Anyways, weird nomenclature aside,
these compounds have really interesting properties! All of them were produced
in the context of ketamine analogues (meaning they had 2-Cl-2’-Oxo
substitutions)[15] [17]. In that case, they seem to consistently produce
extremely rapid and short lived experiences (in mice), with relatively low
potencies. This doesn’t sound the most fun for the recreational user but has
interesting possibilities for medical purposes. Certain compounds saw
experiences that lasted even shorter than ketamine by several magnitudes [17]. What
would be interesting would be to see how these compounds behave on their own
without any substitutions and the implications that would have for potency and
duration. After all, a 2-Cl substitution is known to greatly decrease potency. This
may be of interest to someone out there, and it is worth fiddling with the
structures in ways that would increase potency, perhaps by swapping the phenyl
group for a thiophene, or as mentioned before, leaving it wholly unsubstituted?
[17] lays out that activity seems to
be conserved as a function of the alkane chain extending past the oxygen, and
that there was no correlation between potency and the distance between the
oxygen and the nitrogen. It appears that building up to and past a straight
propyl chain after the oxygen causes a steep drop in activity. I am going to
take their word for it and my conjectures on activities are based on that.
-MAc (N-Methylacetate-amine): Of all
hypothetical esters presented here I would consider this to be the least likely
to be meaningfully active or potent. But it still may be. No one knows until
they try.
-EAc (N-Ethylacetate-amine): See
above. I would guess the chance of activity and increased potency increases as
you extend the alkyl chain after the oxygen. Just a guess though.
-PAc (N-Propylacetate-amine): See
above. I would guess the chance of activity and increased potency increases as
you extend the alkyl chain after the oxygen. Just a guess though.
-iPAc (N-Isopropylacetate-amine): See
above. I would guess the chance of activity and increased potency increases as
you extend the alkyl chain after the oxygen. Just a guess though.
-MPOa (N-Methyl-propanoate-amine): See
below. I see no reason this wouldn’t work. Other moieties with a methyl after
the oxygen seem to work fine. Other propanoate amines conserved activity too.
-EPOa (N-Ethyl-propanoate-amine): Now
we get into real activity. Most of the basic variations on adding an alkane
chain to a propanoate were attempted in animals and seemed to serve as a
baseline for developing other reverse esters as analgesics. This was a short
acting rapidly metabolized compound that demonstrated analgesic activity in
mice. It was about half as potent as ketamine [17].
-PPOa (N-Propyl-propanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was significantly less potent than ketamine [17].
-iPPOa (N-Isopropyl-propanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was the most potent of the pronanoate series, but was still less
potent than ketamine [15] [17].
-MBOa (N-Methyl-butanoate-amine): See
below. I see no reason this wouldn’t work. Other moieties with a methyl after
the oxygen seem to work fine. Other butanoate amines conserved activity too.
-EBOa (N-Ethyl-butanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was some close to ketamine in potency, though ultimately less
potent [17].
-PBOa (N-Propyl-butanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was significantly less potent than ketamine, just like the -PPOa
moiety. It can then be presumed that an alkane chain extending too far past that
oxygen will kill potency and activity. [17].
-iPBOa (N-Isopropyl-butanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was a bit less potent than ketamine [17] [15].
-MPeOa (N-Methyl-pentanoate-amine):
I’m typically averse to building something longer than a butyl chain but other
workers have determined that you still get activity with something as big as a
pentanoate. This compound was a bit les potent than ketamine [17][15].
-EPeOa (N-Ethyl-pentanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was a bit less potent than ketamine [17]
-PPeOa (N-Propyl-pentanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was a good bit less potent than ketamine [17]. Interestingly
though, it didn’t see as deep a drop in potency as other propyl esters did.
-iPPeOa (N-Isopropyl-pentanoate-amine):
Another one active in mice, similar properties to the others with respect to
duration. This was a bit less potent than ketamine [17]
Thioalkyl Chains:
This is purely hypothetical territory.
As far as I know, a thioalkylamine on an arylcyclohexylamine has never been
attempted. I’m just assuming that this series of compounds would have similar
properties to the ethers in terms of what variations are available. My
reasoning for which of these I think would be most likely to have activity is based
on my reasoning for determining the activity of ethers. Once again, pure
conjecture, not scientific at all.
-MTMA (N-Methyl-Methylthioamine): See series description.
-ETMA (N-Ethyl-Methylthioamine): See series description.
-PTMA (N-Propyl-Methylthioamine): See
series description.
-iPTMA (N-Isopropyl-Methylthioamine):
See series description.
-MTEA (N-Methyl-Ethylthioamine): See
series description.
-ETEA (N-Ethyl-Ethylthioamine): See
series description.
-PTEA (N-Propyl-Ethylthioamine): See
series description.
-iPTEA (N-Isopropyl-Ethylthioamine):
See series description.
-MTPA (N-Methyl-Propylthioamine): See
series description.
-ETPA (N-Ethyl-Propylthioamine): See
series description.
-PTPA (N-Propyl-Propylthioamine): See
series description.
-iPTPA (N-Isopropyl-Propylthioamine):
See series description.
Tertiary Alkane
Amines:
Tertiary amines, as stated before, see
some sort of carbon bonded to every available bond they have. This creates
dialkylamines, which may perhaps be recognizable as the pattern of alterations
seen in the tryptamine family of psychedelics. This has no real relation,
they’re entirely different classes of drug, but its an example of how to
develop that particular structure. I only go so far as propyl and isopropyl
groups- it is likely that butylamines would retain some sort of activity, but
there were simply too many permutations and combinations of butylamines to list
out here. To get an idea of what options are at our disposal you can look at
this post here.
There is evidence that suggests that
the tertiary amines aren’t active chemicals themselves, but rather serve as
prodrugs for corresponding secondary alkane amines [36]. This has so far been
demonstrated with PCDE, which was metabolized into PCE [36]. Thus I would
presume something like a PCMiP would split into some proportion of both PCM and
PCiP. That is pure conjecture for now though. It is also unknown for now how a
tertiary amine moiety would interact with other substitutions.
-DMA (Dimethylamine): This has been
presented as PCDMA, a compound that has been demonstrated as being active in mice
[17]. On the hypothesis that it would be metabolized to a secondary amine, this
may very well be a prodrug to PCM, an interesting prospect. It was a little
less potent than ketamine.
It should be noted that tertiary
amines with esters on side will be inactive if the other side has an alkane.
Eg, an arylcyclohexylamine with a methyl group and a propanoate on the nitrogen
would be inactive [12]. It is unknown if this is a function of bulk or the
unique metabolic properties of the ester.
-EM (Ethylmethylamine): This has not
been attempted yet but I see no reason it wouldn’t be active or a prodrug for
an active compound.
-DE (Diethylamine): Another compound
with demonstrated activity in mice. In PCDE form it is also known as
Dieticyclidine. In rats it appeared to metabolize into PCE, though it also
seemed to have a synergistic effect on its own [36]. It was included in a suite
of drugs published in an analytical paper intended for forensic investigation
in 1982, suggesting that it was known about at the time and had the potential
to be abused [21]. It would be very interesting to see more work on this.
-EP (Ethylpropylamine): This has not
been attempted yet but I see no reason it wouldn’t be active or a prodrug for
an active compound.
-DP (Dipropylamine): This has not been
attempted yet but I see no reason it wouldn’t be active or a prodrug for an
active compound.
-MiP (Methylisopropylamine): This has
not been attempted yet but I see no reason it wouldn’t be active or a prodrug
for an active compound.
-EiP (Ethylisopropylamine): This has
not been attempted yet but I see no reason it wouldn’t be active or a prodrug
for an active compound.
-PiP (Propylisopropylamine): This has
not been attempted yet but I see no reason it wouldn’t be active or a prodrug
for an active compound.
-DiP (Diisopropylamine): This has not
been attempted yet but I see no reason it wouldn’t be active or a prodrug for
an active compound.
-MCp (Methylcyclopropylamine): It is
not yet known whether a cyclopropane group would retain activity on the amine
of a nitrogen, but if it did it could probably function alongside a methyl
group.
-ECp (Ethylcyclopropylamine): Same as
the last, this may have a lower chance of being active or feasible though due
to steric interference from the (slightly) larger ethyl group. But maybe that
isn’t a factor. Someone who understands this better than me would know.
Allyl Chains
(Secondary and Tertiary):
An enamine would be inactive but you
can move that double bond just a little further down the chain to get an allyl
group, which has been found to retain activity in mice in various iterations
[20]. I would make a conjecture that but-3-enyl groups would also retain activity,
but there is as of now no evidence to suggest that and the allyl groups are
poorly understood as it stands. Perhaps that idea will come along later.
-AL (N-Allylamine): This was
demonstrated to be active in vitro and in mice [20]. It had a slightly lower
potency than PCP, but was more potent than any tertiary allyl amines that were
attempted.
-MAL (Methylallylamine): Also active
in mice per [20], and less potent than PCP. If the tertiary amine prodrug
hypothesis holds, this may metabolize into PCAL and PCM.
-EAL (Ethylallylamine): Also active in
mice per [20], and less potent than PCP. If the tertiary amine prodrug
hypothesis holds, this may metabolize into PCAL and PCE.
-PAL (Propylallylamine): This has not
been attempted yet but based on the other active allylamines I can see no
reason it wouldn’t work.
-iPAL (Isopropylallylamine): This has
not been attempted yet but based on the other active allylamines I can see no
reason it wouldn’t work.
-DAL (Diallylamine): Also active in
mice per [20], and less potent than PCP. If the tertiary amine prodrug
hypothesis holds, this may metabolize into PCAL.
Tertiary Heterocyclic
Amine Rings:
-Py (Pyrollidine): This is structure
that has gotten itself into some hot water and has been studied a bit despite
its obscurity. It is seen in the compound PCPy, or Rolicyclidine, and its
limited presence as a street drug landed it as a schedule 1 substance, illegal
to possess or produce in almost any context. The effects of PCPy are described
as being less stimulating than PCP, with lower potency. It would be an
otherwise exciting potential structure to work with- perhaps a 3-MeO or 3-HO
substitution would be fruitful. There is also a possibility of strapping
substitutions to the pyrrolidine ring, only one example of which I could find
in literature, an old lit review from 1981 by Asher Kalir, which had a vague
mention of some sort of activity in a 3”-Methyl-ethyl substituted version of
PCPy [19].
-Oz (Oxazolane): Purely hypothetical-
I don’t see how this would break any of the rules for an active compound
however. Ether Moieties are demonstrably active as NMDA antagonists, the
carbons adjacent to the nitrogen are fully saturated, and the oxygen wouldn’t
alter the size and shape of the 5 member heterocycle much more than the
confirmed active Pyrrollidine. I am still only going on conjecture but I think
it may be worthwhile to investigate. But also Oxazolane moieties are fairly
uncommon, who knows.
-P (Piperidine): This is it, this is
the main one, this is by far the most extensively studied amine substitution in
terms of analogue development and structure activity relationships. It is best
known in the infamous street drug and the king of arylcyclohexylamines, PCP.
Its reputation as a street drug aside, the non-opioid analgesic properties of
PCP, its psychotomimetic effects and its high potency has fascinated
researchers for decades, who have tried a massive variety of slight variations
on the structure to try and identify and draw out certain desired effects. I
won’t even list all the sources here that work with some variation of PCP,
there are simply too many. It is the gold standard for arylcyclohexylamine
research and is the standard control for comparing novel analogues to. Slight
substitutions, like the addition of a 3-MeO or 3-HO group have yielded exciting
substances that have seen massive appeal on the grey market. Adder fanned out to
many variations on the PCP theme in his legendary bluelight thread [33], where
he discovered that things like a 2’-Oxo or 4’-Oxo group supposedly turn it into
an opioid. You can throw a dart at a study in the sources and further reading
and you have probably a 50% of finding something with a novel PCP analogue-
many attempts were made to add substitutions directly to the piperidine ring,
which often retained activity- in some cases extremely bulky esters were bonded
to the same site as another alkane on the piperidine and activity was retained
[9]. This suggests a truly dizzying amount of possible variations on this
familiar drug and so many different novel experiences it can provide.
-Mo (Morpholine): This is seen in the
base compound PCMo, of which 3-substituted analogues have been attempted. PCMo
is less potent than PCP. 3-MeO-PCMo was the most popular iteration of PCMo to
hit the market, and it would follow that other substitutions would yield
similarly promising results.
-TMo (Thiomorpholine): No such thing
has ever been attempted, but I conjecture it could retain activity in the
structural similarity a thiomorpholine would have to a regular morpholine.
-Pz (Piperazine): This has not been
attempted, however a piperazine placed into a secondary amine is active, so
long as some kind of substitution is placed on the open end of the other
nitrogen, the simplest being a methyl [8]. I wonder if that activity would be
conserved in a tertiary amine? We don’t know until we try!
Secondary Amine
Cycloalkanes
No member of this series has ever been
attempted. The premise is quite simple- just attach a cycloalkane directly to
the nitrogen. Because I really have no points of reference it is for now
impossible to say whether this will achieve any of the desired effects. If they
did, I would venture to guess that the potency/likelihood of activity would
decrease as the ring grew larger. You could possibly add additional
substitutions to the rings also. Not sure how that would affect activity. I
don’t know, there really isn’t much to say on any individua iteration of this
series they’re all as hypothetical as the last.
-cP (N-Cyclopropylamine): This is in
my opinion, the analogue most likely to be active. Small and simple. I don’t
know if it could accommodate additional substitutions.
-cBu (N-Cyclobutylamine): See series
description.
-cPe (N-Cyclopentylamine): See series
description.
-cH (N-Cyclohexylamine): See series
description.
Secondary Amine
Heterocyclic Amine Rings:
Here’s where we start to get big.
These are extremely bulky substitutions, but certain iterations have shown to
be active in vitro, which compels me to search their possibilities more. These
rather extreme variations on this theme set boundaries at either end of the
possible options in terms of molecular bulk. I hypothesize that the structures
with a bulk that lies between those bounds will show some degree of activity
too. With a lengthening chain between the cycloalkane and nitrogen I leave out
the amine rings that haven’t even been tested as tertiary amines yet.
-APy (N-Pyrollidinylamine): I have
nothing to indicate this would be active, but I guess I’m going on the fact
that a pyrrolidine is active as a tertiary amine, and secondary amine-amine
ring moieties are active in vitro, so that’s two bits of support for possibly
investigating this moiety.
-AOz (N-Oxazolanylamine): I have even
less to go on with this one, as we don’t yet even know if an oxazole is active
as a tertiary amine, much less with this lesser understood SAR pattern.
-AP (N-Piperidinylamine): I have
nothing to indicate this would be active also, but I once again guess I’m going
on the fact that a piperidine is active (and very potent) as a tertiary amine,
and secondary amine-amine ring moieties are active in vitro, so that’s again
two bits of support for possibly investigating this moiety too.
-APz (N-Piperazinylamine): In the
paper where this compound is produced and tested, it’s technically a
methylpiperazine, with a methyl group extending from the 4” nitrogen [8]. It
was produced as a ketamine analogue (2-Cl-2’-Oxo-PCAPz). I am doubtful that a
piperazine with a free nitrogen would work, but who knows. So this probably
comes with the caveat that you’re safer strapping some alkane to that nitrogen.
It showed similar activity to regular ketamine, displaying slightly more phase
2 pain relief and slightly more motor inhibition. Maybe it’s a prodrug to
regular ketamine, with that piperazine ring being cleanly clipped off. Someone
who knows pharmacokinetics better could answer that maybe.
-AMo (N-Morpholinylamine): Also
produced and tested in [8], this showed similar potency and properties to the
methylpiperazine analogue, which in turn had similar properties to ketamine.
This analogue displayed slightly less activity than ketamine.
-ATMo (N-Thiomorpholinylamine): I have
even less to go on with this one, as we don’t yet even know if a Thiomorphine
is active as a tertiary amine, much less with this lesser understood SAR
pattern.
-MPy (N-Methylpyrollidinylamine): An
ethylpyrollidinylamine was active in vitro (though not the most potent)
combined with a bicycloheptane ring as the base [10](more on that later), so
toning it down by one carbon may retain that activity.
-MP (N-Methylpiperidinylamine): An ethylpiperidinylamine
was active in vitro (though not the most potent) combined with a bicycloheptane
ring as the base [10](more on that later), so toning it down by one carbon may
retain that activity.
-MPz (N-Methylpiperazinylamine): Based
on the n-piperazine being somewhat active in vitro [10]. This could achieve
similar results perhaps. Just a guess. This would probably also require an
alkane substitution at the 4”-N.
-MMo (N-Methylmorpholylamine): This
would probably be some degree of active- the base amine and ethyl derivative
show varying degrees of activity and this would sit there too. But we don’t
know until we try. Neither of the morpholine analogues that have been made have
been as active as secondary amine piperidines or pyrrolidines though, so this
may not be the most promising route to go.
-EPy (N-Ethylpyrollidinylamine): This
compound was devised by Ates-Alagoz et al, and was shown to be moderately
active, somewhere between PCP and ketamine in potency (as far as I can
interpret the data)[10]. The caveat however- is that it was attached to a
bicycloheptane ring instead of a cyclohexane in the middle. That almost
certainly had some effect on its potency and activity- it is unknown what that
base compound even behaves like with more familiar moieties for reference
(other than with a primary amine, which was shown to be even less potent than
ketamine). So this is a big maybe.
-EP (N-Ethylpiperidinylamine): Another
compound devised as a moiety on a bicycloheptane ring, this was the most potent
of the series that was tested [10]. As stated before, it is unknown if this
moiety would retain activity attached to a regular cyclohexane ring.
-EPz (N-Ethylpiperazinylamine): Extending
the piperazine ring a bit further. Who knows if this would work. This would
probably also require an alkane substitution at the 4”-N.
-EMo (N-Ethylmorpholylamine): Haha
this one is sad 😊 But anyways, this was another variation produced
in [10], it saw fairly low affinity. I included it just to map out that
pattern, it wasn’t entirely inactive, but I wouldn’t expect anything in terms
of potency with this. But this is also with that bicycloheptane ring- maybe it
would show more activity on a regular cyclohexane.
Aromatic
Secondary/Tertiary Amine Rings:
-Bn (N-Benzylamine): A Benzyl group
has been demonstrated to be active in female wistar rats with similar potency
and activity to ketamine (though only derivatives with a 4”-Me or 4”-MeO
substitution were attempted- it is unknown if an unsubstituted benzyl group
will conserve activity [6].
-BF (N-Benzofuranylamine): Pure
conjecture. Benzofurans serve as active groups in many other drugs, though of
course this cannot be fully extrapolated to arylcyclohexylamines, I can still
take a stab in the dark that this may be worthwhile.
-MDBn (N-Methylenedioxybenzylamine):
Similar to the last moiety. A Methylenedioxy group retains moderate activity on
the phenyl ring of PCMo [37]. I hypothesize it may do so elsewhere, like on a
benzyl ring for example.
-Ind (Indoline): Tertiary substituted
indole-like structure, in this case a 2-Indoline. This retains the carbons
bonded directly to the nitrogen being saturated, which may retain activity.
Worth trying in my opinion.
-AI (N-Aminoindane): Similar to the
last but with a secondary amine. No reason jumps out at me that this wouldn’t
work. Worth trying.
-Pyr (Pyrrole): This is an exception
to the saturated adjacent carbon rule. There are always exceptions it seems. Ahmadi
and his team, pioneering creative new arylcyclohexylamines, devised this as a
novel derivative producing PCPyr along with 3-Me-PCPyr and later 3-MeO-PCPyr
[4, 5]. Interestingly, when unsubstituted, PCPyr is barely active. Only with a
substitution on the 3-position of the phenyl ring does acute analgesic activity
present in mice. This opens the door perhaps to other aromatic monocyclic amines,
but I don’t know enough to dare venture into that. One I would maybe suggest
would be a secondary amine with a pyrrole ring attached to the nitrogen. Other
phenyl substitutions might make this one shine, perhaps halogens? Though you’d
likely see a steep drop in potency.
-MK-801: I made this as a joke. I
highly doubt it’s active or worthwhile to explore. But who knows.
The Aromatic Ring
(and others):
Now let’s get onto the last round of
modifications- We’ve dealt with the “cyclohexyl” and the “amine” part of
arylcyclohexylamines. All that’s left is that first bit, the “aryl” or a
shorthand for an aromatic group. An aromatic group is a ring structure that is
held in a flat planar shape, stabilized by a consistent flow of electrons
around the structure. This is represented on a molecular diagram as an
alternating pattern of double bonds. The best known aromatic ring is the
Benzene Ring, also called a phenyl group, which is seen in a vast multitude of
organic molecules. Arylcyclohexylamines are shown to retain activity with a
variety of aromatic groups, although almost all of the ones that have been on
the market use a phenyl ring. In addition, most market examples of substituted
arylcyclohexylamines have seen those substitutions added to the phenyl ring. Substitutions
are likely possible on other aromatics too, though this has been poorly
explored. Furthermore, there is (very scant) evidence that you don’t even need
a ring here- that other straight chain structures will also be active. Very
peculiar. I will go into that obscure bit of information later. Let’s dive into
some of the possibilities!
P- (Phenyl): By far the most common
and best studied aromatic group used in arylcyclohexylamines, in fact this
could be considered a sort of “default” structure, as it is often broadly assumed
that an arylcyclohexylamine will have a Phenyl as its aromatic. This can take
substitutions on the 2 position (as seen in Ketamine, 2-Cl-2’-Oxo-PCM), the 3
position (as seen in 3-HO-PCE, 3-HO-PCP, 3-MeO-PCE 3-MeO-PCP, 3-F-PCP, MXE
(3-MeO-2’-Oxo-PCE) and many others), or the 4 position (as seen in 4-MeO-PCP).
It appears that 3-position substitutions are the most effective in terms of
preserving potency and yield some of the most interesting results. Known
2-position substitutions see a steep drop in potency (as in ketamine), as do
4-position substitutions [33]. There is a lot to be done here.
Bn- (Benzyl): BnCP appeared as a
street drug briefly in 1989 but drew enough attention to make it into a
forensics journal, where a sample from Canada was analyzed [23]. There are
several assumptions I will make here- first is that BnCP is active if it was
being found in samples of actively sold street drugs. Second is that it was
likely sold as a substitute of PCP, which would imply that it is reasonably
potent. I am not sure how substitutions would behave on a benzyl group but
perhaps all the same ones that can be placed upon a phenyl could be applied
there. I have to wonder about a substitution on the chain carbon of the benzyl
group too- whether something like a ketone or a methyl group there would affect
activity or potency. Lots to investigate here but this report gives us
something to potentially work off of.
2-Pyd- (2-Pyridine): This is a
substitution with a fully bonded nitrogen built into an aromatic ring. The
number simply denotes the position of the nitrogen, if you consider the
nitrogen to be the 1 position and assign a number to the position at which the
cyclohexane would be bonded. This structure appears to be moderately active in
vitro but not very potent at all, according to the one study in which it was
produced and analyzed [32]. The 2-Pyd analogue would allow for potential
substitutions on the 3, 4, 5 and 6 positions. Lots of possibilities there, but
it is unknown if these would just shake off activity, potentiate it, interact
with the nitrogen in some way? Or how it would interact with other moieties?
Lots of mystery here, and maybe not the most promising route to pursue.
3-Pyd- (3-Pyridine): Same as previous
but this specific iteration was never made or tested. Sees a nitrogen on the 3
position relative to the cyclohexane bond. It would be interesting to make this
entire series to see how shifting the position of the nitrogen affects
activity. Substitutions maybe possible on the 2, 4, 5, and 6 positions.
4-Pyd- (4-Pyridine): Same as previous
but this specific iteration was never made or tested. Sees a nitrogen on the 4
position relative to the cyclohexane bond. It would be interesting to make this
entire series to see how shifting the position of the nitrogen affects
activity. Substitutions maybe possible on the 2 and 3 positions.
2-H-Pyr- (2-H-Pyrroline): Another pure
hypothetical. I conjecture that activity is retained only when the nitrogen is
fully bonded within the aromatic ring- that means with no loose hydrogen on it.
This is of course- pure conjecture and could easily be proven or disproven. I
would like to see someone test it out. Also a nitrogen with two bonds could
perhaps be stabilized with a methyl substitution extending off of it. Not much
to say on this until someone gives it a spin and compares it to other similar
compounds, the best would be a regular Pyrrole ring bonded to the cyclohexane
at the 2 or 3 position relative to the nitrogen, and both with or without a
methyl group bonded to that nitrogen.
T- (Thiophene): Even among drug nerds,
the existence of thiophene arylcyclohexylamines is back shelf obscure
knowledge, but it is still probably the second best known aromatic possibility
behind a phenyl. This is a 2-Thiophene to be specific. It presents some very
interesting possibilities- it has so far appeared as the drug TCP, sold on the
street as a substitution for PCP. TCP however, is significantly more potent.
PCP is already noteworthy for its potency and its fascinating that there’s even
more powerful analogues out there. Another known active compound is tiletamine
(2’-Oxo-TCE). The thiophene ring offers the possibility of very potent and
interesting active compounds that bear some similarity to the phenyl based
structures. It is possible to attach substitutions to the thiophene ring too-
numbered with regards to the S being at position 1. A 3-MeO-TCP is known to be
active, per a personal correspondence, but that’s all that’s known so far. So
3-substitutions are perhaps also the way to go with these structures. One study
attached a number of bulky and unwieldly moieties onto the piperidine ring of
TCP, including esters and phenyl ring paired on the same carbon, which were
surprisingly active, at least in delivering analgesia [9]. So it seems this
structure can tolerate a lot of peculiar and bulky substitutions.
3-T- (3-Thiophene): A Thiophene is
active, I see no reason for a 3-thiophene to lose that activity, but SAR is
full of surprises! Especially if you aren’t the best at it like me 😊
F- (Furan): In this case a 2-Furan. I
suppose if a 3-Thiophene is active a 3-Furan would be too. But we still don’t
know if a furan remains active. Nonetheless, I hypothesize that it will. I can
see no reason that stands out that would render it inactive. I think FCP would
be a good compound to begin with.
Oz-(Oxazole): Now I am getting
obscure- we don’t know if an oxazole or a similar oxazolane are active in any
context with an arylcyclohexylamine. So there’s no saying if an oxazole as the
aromatic would conserve activity, but I see no reason why it wouldn’t for now.
Who knows. It would hypothetically accept a 3 or a 5 substitution.
iOz-(Isoxazole): Same as above.
Probably just as likely to work or not work. Would accept a 4 or a 5
substitution.
Tz- (Thiazole): Even more hypothetical
than the last. Worth trying but completely uncharted territory. Probably best
to prioritize other developments for now.
iTz- (Isothiazole): Same as above.
ODz- (1,2,5-Oxadiazole): Same as
above.
TDz- (1,2,5-Thiodiazole): Same as
above.
Before going on, there is one last set
of compounds we must discuss. These compounds have only been mentioned in a
single source, a review by Asher Kalir from 1981 of phencyclidine derivatives
[19]. In this report, there are a few scant mentions of straight chain moieties
replacing the aromatic ring and conserving some sort of activity. These would
be xCP type compounds, with a piperidine as the amine. These compounds included
alkanes, alkenes, and alkynes. I leave these as a highly hypothetical footnote
because this is the only source to mention them and it appears that no one else
has done any work with them since then. All of the cited sources in Kalir’s
review are his own work or his associate’s work and I was unable to track any
of it down. The data is not the most promising in terms of activity and
potency, but the loose and vague descriptions of subjective effects pique my
interest: “The potency was enhanced by introducing an unsaturated bond. The
propargyl derivative, when tested in monkeys produced PCP-like effects, thus
suggesting a hallucinogenic property.” This is probably the most wild goose
chase option of the moieties I have presented here, but I figured it was worth
mentioning. The Moieties Kalir cites as active, from most to least potent were:
PrE- (Propene)>Ete- (Ethene)>Pr- (Propane)>Pry- (Propargyl)
This potency ranges from about the
same as PCP (PrE) to… well…the rest showed a central potency that was only
about 5% that of PCP. Yet with the Propargyl, Kalir specifically mentioned
observed behavioral effects consistent with PCP. Curious. An Ethane and Butane
moiety were also attempted (along with an Octane) and were either inactive or
so impotent they might as well be. It appears that past a certain point larger
moieties aren’t tolerated, it seems the Butane is the line. The other compounds
I include are just filling in the gaps or guessing at possibilities. This is
all conjecture for now.
A footnote:
Conformational Constraints
There is so much you can do! One
possibility is the world of conformational constraints- Many of the simper
arylcyclohexylamines can have their moieties freely rotate around their bond on
the central ring, allowing us to disregard stereochemistry. Others have
enantiomers with various configurations, for example (R)- and (S)- Ketamine.
These are often administered as racemic mixtures although one enantiomer is
typically more active than the other.
With a conformational constraint
however, the structure is strictly bound by some sort of structure rigidly
joining the rings together, disallowing free rotation of the aromatic ring. There
is still stereoisomerism in the positioning of the amine and the corresponding
hydrogen on the new 2’ position bond. There are many ways that this can manifest.
The first I wrote a brief article
about, which can be found here.. This features a series of obscure arylcyclohexylamines
with three conjoined rings, formed by joining the 2’ position of the
cyclohexane with the 2 position on the aromatic ring. Doing so with PCM yielded
compounds that were highly potent and active in vitro. This was done by joining
the two rings with 1 carbon (yielding a cyclopentane between the other two
rings, aka PD-137889) and 2 carbons (yielding a cyclohexane between the other
two rings, aka PD-138289). The authors also suggest the possibility of bridging
them with an oxygen or sulfur, forming a 5-member heterocyclic ring. As
mentioned before, the two tested examples of this were very potent. I think
this is a worthwhile path to investigate, especially experimenting with any of
the aforementioned amines, aromatics, and substitutions. Perhaps the bridging
carbons between the rings could also serve as sites for substitution,
increasing the possibilities several-fold. An ethyl bridge/cycloheptane ring is
a possibility, as may be other heterocycles. The imagination is the limit with
these possibilities until their activity is better clarified by further study.
 |
| Some ideas for a variety of Conformationally Constrained Tricyclic Structures similar to PD-137889 and PD-138289 |
Another way conformational constraints
can manifest is through a structure that is already tricyclic- PCP. This
compound, called 8A-PDHQ (I will have a separate article out about this
compound eventually!), sees the cyclohexane ring bonded to the piperidine ring
at two points, effectively binding those rings together end to end, in this
case restricting the free rotation of the amine. It should note that the
cyclohexane in this case is no longer bonded directly to the nitrogen, but
rather it is bonded to another part of the piperidine ring, leaving the
nitrogen with a free hydrogen. This sort of structure may only work with other
tertiary ring amines. Possible substitutions can still be placed on all of the
rings, but the most promising may be substitutions on the 3 position of the
freely rotating phenyl ring. The alternating (-) enantiomer of 8A-PDHQ was
demonstrated to be about half as potent as PCP, perhaps promising.
 |
| Some ideas for structures related to 8A-PDHQ |
What to study
from here?
Well there’s my reasoning behind the
inclusion of everything I included in this chart. I hope it was informative! It
was long. It’s a lot of information to take in. So, having gathered all that
information, perhaps you’re looking for direction- Though I have no credentials
and am a humble amateur I would like to offer some suggestions for what may be
the most promising directions for future development.
With a running interesting in organization and systematics and classification,
I am of course compelled to break down the possibilities into substances of
personal interest and substances of research interest.
Where substances of personal interest
are those that pique my curiosity as one who seeks unique experiences from
arylcyclohexylamines for my own exploratory purposes. Substances of research
interest are the ones that would in my opinion be the most effective at establishing
reference points for possible patterns of SAR, which would further aid informed
development of new compounds and more reliable prediction of the effects of
certain structures and moieties. It is up to you to determine what you personally
consider more relevant to your interests.
Substances of
Personal Interest:
I will be presenting these as series
of compounds. An * denotes ones I am particularly interested in sampling.
Alkanes and such
+ substitutions:
3-MeO-2’-Oxo-PCA (MXA), 3-MeO-PCM,
3-MeO-PCPr, 3-HO-2’-Oxo-PCiPr (HXiPr), 3-MeO-PCiPr, PCsBu, 3-MeO-PCsBu,
3-MeO-2’-Oxo-PCsBu, 3-MeO-PCAL, 3-Me-PCDMA
Here we mostly see variations on some
familiar alkane backbones, primarily via substitutions. It should be known that
MXE, a 3-Meo-2’-Oxo substitution on a PCE, was one of the greatest discoveries
in the history of arylcyclohexylamine development and many have sought to
replicate that pattern on all variety of other compounds, myself included. Call
it safe or uninspired, but for the sake of those going boldly into the unknown
I think it offers confidence in obtaining some degree of interesting activity.
Already PCPr and PCiPr have appeared on the market only as this variation. I
personally find a 3-MeO substitution to greatly enhance compounds and yield
fascinating experiences. Thus I think a 3-MeO-PCM, 3-MeO-PCPr, 3-MeO-PCiPr, and
3-MeO-PCsBu are in order. Why sBu instead of Bu? Arbitrary, just my personal
interests. I would like to see that backbone both on its own and with the MXE
substitution pattern. The MXE substitution pattern is purported to retain
interesting effects with a 3-HO instead of a 3-MeO too. 3-MeO-PCAL and
3-Me-PCDMA are purely experimental, really no way to predict what they might be
like. If the prodrug hypothesis of tertiary chain amines holds up, I wonder if
this would yield just 3-Me-PCM? The MXE substitution on a PCA would also be
interesting in my opinion.
PCE variations:
3-Me-PCE, 3-Et-PCE, 3-iP-PCE,
3-EtO-PCE, 3-F-PCE, 3-TFM-pCE, 3,4-MD-PCE, 3,4-Fu-PCE (BZFCE), 3-MeT-PCE,
4’-F-PCE, 3-Me-2’-Oxo-PCE, 3-MeO-4’-PCE
The PCE base has produced some of my
favorite compounds. While there is an absolutely dizzying variety of amines out
there, I feel like there is so much that can be done on this comfortable and
familiar base. It seems like a good consistent platform to experiment with a
variety of substitutions to tease out what their individual effects may be. To
that end I think it would be super interesting to see really any of these compounds.
It’s all just me kinda randomly brainstorming there isn’t any specific
rationale for each choice.
Alkoxyamine compounds:
PCHOPA, PCiPBA, 3-Me-PCiPEA,
3-Me-PCPEA
Several ether amines have already made
it to market, though they have remained obscure and no information on their
subjective experience exists. This is just filling in the blanks of compounds
that haven’t been made yet but follow logical paths of development with ones
that have. I offer a 3-Me substitution as a possible safe bet to combine with
an ether amine, but in reality, I have no idea how such moieties interact.
Thioalkanes:
PCMTEA, PCETEA, PCPTEA, PCiPTEA
No thioalkanes have ever been
attempted as the amine moiety. I have no idea if they would work or what they
would feel like. I would love to find out though. These compounds may be a good
place to start.
Tertiary Amine
Rings:
3-Br-PCP, 3”-Br-PCP, 3”-MeO-PCP,
3-MeO-4’-Me-PCP, 3,4-Fu-PCP (BZFCP), 3,4-MD-PCP, 3-MeO-2’-Oxo-PCPy (MXPy)
Like PCE, PCP provides a tried and
true familiar base from which to build interesting and exciting compounds from.
It also presents a whole new ring to which substitutions can be added. There is
an ocean of possibilities here. I present some miscellaneous ones that jumped
out to me, along with a PCPy with the MXE substitutions.
Secondary Amine
Rings:
PCcP, 3-MeO-PCcP, 3-MeO-2’-Oxo-PCcP,
PCAPy, PCAP, 3-MeO-PCAP, PCEP, 3-MeO-PCBn, 3-MeO-2’-Oxo-PCBn (MXBn), 4-Me-PCBn,
4”-F-PCBn, 3”-MeO-PCBn, PCBF, PCMDBn
These are not understood nearly as
well as the tertiary amine rings. It is known that a secondary amine aromatic
ring can tolerate substitutions, per [6]. First, we look at PCcP, and the
corresponding 3-MeO and MXE substitution pattern. PCcP is a real interesting
possibility but there isn’t much reference for what it may be like. Such a
small ring may show similarities to a chain alkane in vivo. PCAPy and PCAP also
seem to provide an interesting possible substrate for activity (to understand
why see their section in the moiety descriptions, I don’t feel like copying and
reformatting it all). Lastly there are Benzyl groups, which according to [6]
can take a substitution on the benzyl ring, so some possibilities of that are
explored, along with of course, the MXE substitutions. Lastly is PCBF and
PCMDBn, two polycyclic rings that could prove interesting with the benzyl
group.
Thiophene Esters
TCEBOa, TCiPBOA
There were so many ester moieties
available, I wanted to delve into them a bit. The ester amine moieties present something
interesting- extremely fast and short acting compounds. This was added to a
ketamine base- so how would it behave in a different context? For such a rapid
experience, I suspect it may benefit from jacking up potency as much as possible-
To that end I suggest a Thiophene in place of a phenyl ring, as that tends to
yield greater potency. The possible moieties I chose were filling in gaps
between ones that had already been produced and tested. But honestly you could
take your pick from the list, there’s so many promising and interesting
options. Perhaps this will be a dud, the short duration would be no fun,
perhaps it would be real fascinating though, it’s hard to say with the data
that exists for now.
Furan Compounds
FCE, FCPy, FCP
None of these have ever been tried!
They seem super promising though I think it would be interesting to see an
attempt made.
Benzyl Aromatics:
BnCE, 3-MeO-BnCE, 3-MeO-2’Oxo-BnCE, 3-MeO-BnCP,
α-M-BnCP
Here are some compounds that expand on
the theme of using a benzyl instead of a phenyl as the aromatic. Just working
in the basic and familiar possibilities- perhaps more interesting and
abstracted variations can be built on it once we figure out what these
substitutions do. One variation that I don’t mention in the flow chart is the
addition of an α-methyl group on the carbon between the cyclohexane and the
phenyl ring in the benzyl group. What this may do is entirely unknown. Worth a
shot I think! Indeed, the base structure of BnCx is very very obscure and
poorly understood.
Substances to
Research:
I’m not using “research” as a
euphemism here, as it so often appears in this community. I think it would be
great to see formal studies done on these sets of compounds just for the sake
of characterizing them and systematically discerning clear SAR patterns. I
would suggest production, characterizing, an in vitro affinity assay, and
perhaps animal behavioral and analgesia tests for each series of compounds. This
can help indicate specific receptor activity, potency, and toxicity. In
characterizing SAR of these series, it provides us with a more robust framework
for developing new compounds and reliably predicting their specific effects,
and thus their therapeutic and exploratory applications and contraindications.
Series 1: Alkane
Amine Chains
Analysis of this series would clarify
a few properties of the Alkane Amine chains of arylcyclohexylamines. Namely,
the correlation between chain length/configuration and potency or activity. PCP
and PCPy are included as reference compounds. Performing this study would allow
for more reliable prediction of what substitutions on these bases will
accomplish and how they change effects in relation to amine bulk.
Series 2:
Variable Substitutions on PCE
This series uses PCE as a standard- it
provides a reliable base with known effects for adding substitutions, by which
alterations in activity and potency can be observed. PCM would also be a
reasonable base for such a study. While PCP is the gold standard, the ring
structure may cause unpredictable effects in relation to substitutions. It
could very well be done as a separate analysis however. This concerns only
alkane chains and alkane ethers for now. I am particularly interested in seeing
the correlation between substitution bulk and potency/activity.
Series 3:
Thioalkane Amines
As mentioned before Thioalkanes have
not been attempted yet as amine moieties. This series would help to clarify if
they are active in the first place and the correlations between chain size and
activity.
Series 4:
Aldehyde Amines
Aldehyde amines have not been
attempted either and it would be interesting to determine their activity and
possible toxicity.
Series 5: Furan
Aromatic Arylcyclohexylamines
Also as mentioned before, Furans as
the aromatics have not yet been attempted but show promise. This is a very
basic series of compounds to feel out relationships between structure and
activity/potency.
Series 6:
Pyridinyl Aromatic Arylcyclohexylamines
This series is to determine how the
position of the nitrogen on a Pyridinyl ring as the aromatic affects potency
and activity. 2-Pyd is the only one that has been manufactured so far, and it
was only moderately active. Others may show other interesting effects.
There is little more I can do beyond
this, it’s out of my hands and beyond my skillset and I pray that this
information is useful enough to serve those with the ability to further study
this fascinating class of compounds! Godspeed you researchers.
Sources and Further Reading:
[1] Ahmadi A, Khalili M, Abbassi S, Javadi M, Mahmoudi A, Hajikhani R (2009) Synthesis and study on analgesic effects of 1-[1-(4-methylphenyl) (cyclohexyl)] 4-piperidinol and 1-[1-(4-methoxyphenyl) (cyclohexyl)] 4-piperidinol as two new phencyclidine derivatives. Arzneimittelforschung. 59(4):202-6
[2] Ahmadi A, Khalili M, Mihandoust F, Barghi L (2010) Synthesis and determination of acute and chronic pain activities of 1-[1-(3-methylphenyl) (tetralyl)]piperidine as a new derivative of phencyclidine via tail immersion and formalin tests. Arzneimittelforschung 60(1):30-5
[3] Ahmadi A, Solati J, Hajikhani R, Onagh M, Javadi M (2010) Synthesis and analgesic effects of 1-[1-(2-methylphenyl)(cyclohexyl)]-3-piperidinol as a new derivative of phencyclidine in mice. Arzneimittelforschung. 60(8):492-6
[4] Ahmadi A, Solati J, Hajikhani R, Pakzad S (2011) Synthesis and analgesic effects of new pyrrole derivatives of phencyclidine in mice. Arzneimittelforschung 61(5):296-300
[5] Ahmadi A, Solati J, Hajikhani R, Pakzad S (2011) Synthesis and analgesic effects Methoxy-Pyrrole derivatives of phencyclidine in mice. Arzneimittelforschung 23(12):5429-32
[6] Ahmadi A, Khalili M, Hajikhani R, Horiesadat H, Afshin N, Nahri-Niknafs B (2012) Synthesis and study of the Analgesic effects of new analogues of ketamine on female Wistar rats. Journal of Medicinal Chemistry 8(2):246-251
[7] Ahmadi A, Khalili M, Marami S, Ghadiri A, Nahri-Niknafs B (2014) Synthesis and pain perception of new analogues of phencyclidine in NMRI male mice. Mini Rev Med Chem. 14(1):64-71
[8] Ahmadi A, Khalili M, Asadi A, Nahri-Niknafs B (2014) New morpholine and piperazine derivatives of ketamine: synthesis and anti-nociceptive effects. Bulgarian Chemical Communications 46(3):556-562
[9] al-Deeb OA (1996) New analgesics derived from the phencyclidine analogue thienylcyclidine. Arzneimittelforschung. 46(5):505-8
[10] Ates-Alagoz Z, Sun S, Wallach J, Adejare A (2011) Syntheses and pharmacological evaluations of novel N-substituted bicyclo-heptane-2-amines at N-methyl-D-aspartate receptors. Chemical Biology & Drug Design. Jul;78(1):25-32
[11] Bigge CF (1993) Structural requirements for the development of potent n-methyl-d-aspartic acid (NMDA) receptor antagonists. Biochem. Pharmacol. 45(8):1547-1561
[12] Dimitrov I, Denny WA, Jose J (2018) Syntheses of ketamine and related analogues: a mini review. Synthesis 50(21): 4201-4215
[13] Ferle-Vidović A, Kaštelan M, Petrović D, Šuman L, Kaselj M, Škare D, Mlinarić-Majerski K (1993) Synthesis and biological activity of phencyclidine and its adamantylamine derivatives. European Journal of Medical Chemistry 28(3):243-250
[14] Hajikhani R, Ahmadi A, Naderi N, Yaghoobi K, Shirazizand Z, Rezaee NM, Niknafs BN. (2012) Effect of phencyclidine derivatives on anxiety-like behavior using an elevated-plus maze test in mice. Adv Clin Exp Med. 21(3):307-12
[15] Harvey M, Sleigh J, Voss L, Jose J, Gamage S, Pruijn F, Liyanage S, Denny W (2015) Development of Rapidly Metabolized and Ultra-Short-Acting Ketamine Analogs. Anesth Analg. 121(4):925-33
[16] Itzhak Y, Kalir A, Weissman BA, Cohen Sasson (1981) New analgesic drugs derived from phencyclidine. Journal of Medicinal Chemistry 24(5):496-499
[17] Jose J, Gamage SA, Harvey MG, Voss LJ, Sleigh JW, Denny WA (2013) Structure-activity relationships for ketamine esters as short-acting anaesthetics. Bioorg Med Chem. 21(17):5098-106.
[18] Kalir A, Edery H, Pelah Z, Balderman D, Porath G (1969) 1--Phenylcycloalkylamine derivatives. II. Synthesis and pharmacological activity. Journal of Medicinal Chemistry 12(3): 473-477
[19] Kalir A (1981) Chapter 5: Structure Activity Relationships of Phencyclidine Derivatives. Domino EF PCP (Phencyclidine): Historical and Current Perspectives (31-46) NPP Books
[20] Kalir A, Teomy S, Amir A, Fuchs P, Lee SA, Holsztynska EJ, Rocki W, Domino EF (1984) N-allyl analogues of phencyclidine: chemical synthesis and pharmacological properties. J Med Chem. 27(10):1267-71
[21] Kelly RC, Christmore DS (1982) Identification of phencyclidine and its analogues at low concentrations in urine by selected ion monitoring. J Forensic Sci. 27(4):827-36
[22] Linders JTM, Furlano DC, Mattson MV, Jacobson AE, Rice KC (2010) Synthesis and Preliminary Biochemical Evaluation of Novel Derivatives of PCP. Letters in Drug Design & Discovery 7(2):79-87
[23] Lodge BA, Duhime R, Zemecnik J, MacMurray P, Brousseau R (1992) New street analogs of Phencyclidine. Forensic Science International 55(1):13-26
[24] Maddox VH, Godefroi EF, Parcell RF (1965) The Synthesis of Phencyclidine and other 1-Arylcyclohexylamines. Journal of Medicinal Chemistry 8(2):230-235
[25] McQuinn RL, Cone EJ, Shannon HE, Su T-P (1981) Structure-Activity Relationships of the Cycloalkyl Ring of Phencyclidine. Journal of Medicinal Chemistry 24 (12):1429-1432
[26] Morris H, Wallach J. From PCP to MXE: a comprehensive review of the non-medical use of dissociative drugs. (2014) Drug Test Anal. 6(7-8):614-632.
[27] Pang K, Johnson SW, Maayani S, Freedman R (1986) Structure-activity relationships of phencyclidine derivatives in rat cerebellum. Pharmacology Biochemistry and Behavior 24(1):127-134
[28] Sauer C, Peters FT, Staack RF, Fritschi G, Maurer HH (2006) New designer drug N-(1-phenylcyclohexyl)-3-ethoxypropanamine (PCEPA): studies on its metabolism and toxicological detection in rat urine using gas chromatographic/mass spectrometric techniques. J Mass Spectrom. 41(8):1014-29
[29] Wallach J, Brandt SD (2018) Phencyclidine-Based New Psychoactive Substances. Handb Exp Pharmacol. 252:261-303.
[30] Wallach J, Brandt SD. (2018) 1,2-Diarylethylamine- and Ketamine-Based New Psychoactive Substances. Handb Exp Pharmacol. 252:305-352.
[31] Zanos P, Ruin M, Morris PJ, Riggs LM, Highland JN, Georgiou P, Pereira EFR, Albuquerque EX, Thomas CJ, Zarate CA Jr., Gould TD (2018) Ketamine and Ketamine Metabolite Pharmacology: Insights into Therapeutic Mechanisms. Pharmacological Rev. 70(3):621-660
[32] Zarantonello P, Bettini E, Paio A, Simoncelli C, Terreni S, Cardullo F. (2011) Novel analogues of ketamine and phencyclidine as NMDA receptor antagonists. Bioorg Med Chem Lett. 21(7):2059-2063
[33] https://www.bluelight.org/xf/threads/pcp-analogs-cumulative-retrospective-bioassays.504286/
[34] https://erowid.org/archive/rhodium/chemistry/pcp/pcp_index.html
[35] https://erowid.org/archive/rhodium/chemistry/pcp.shulgin.html
[36] Cho AK, Hiramatsu M, Schmitz DA, Vargas HM, Landaw EM (1993) A behavioral and pharmacokinetic study of the actions of phenylcyclohexyldiethylamine and its active metabolite phenylcyclohexylethylamine. The Journal of Pharmacology and Experimental Therapeutics 264(3):1401-5
[37] Colestock T, Wallach J, Mansi M, Filemban N, Morris H, Elliott SP, Westphal F, Brandt SD, Adejare A (2017) Syntheses, analytical and pharmacological characterizations of the “legal high” 4-[1-(3-methoxyphenyl)cyclohexyl]morpholine (3-MeO-PCMo) and analogues. Drug Testing and Analysis 10(2)
[38] 1-Nicholson KL, Balster RL (2003) Evaluation of the phencyclidine-like discriminative stimulus effects of novel NMDA channel blockers in rats. Psychopharmacology (Berl). 170(2):215-224
[39] Hays SJ, Novak PM, Ortwine DF, Bigge CF, Colbry NL, Johnson G, Lescosky LJ, Malone TC, Michael A (1993) Synthesis and pharmacological evaluation of hexahydrofluorenamines as noncompetitive antagonists at the N-methyl-D-aspartate receptor. Journal of Medicinal Chemistry 36 (6): 654-670
[40] Bigge CF, Malone TC (1993) Overview: Agonists, Antagonists and Modulators of the N-methyl-D-aspartic acid (NMDA) and α-amino-3-hydroxy-5- methyl-4-isoxazolepropanoic acid (AMPA) Subtypes of Glutamate Receptors. Current Opinion on Therapeutic Patents 3(7): 951-989
[41] Elhallaoui M, Laguerre M, Carpy A, Ouazzani FC (2002) Molecular modeling of noncompetitive antagonists of the NMDA receptor: proposal of a pharmacophore and a description of the interaction mode. J Mol Model 8:65–72
[42] Chen C, Kozikowski AP, Wood PL, Reynolds IJ, Ball RG, Pang YP (1992) Synthesis and Biological Activity of 8a-Phenyldecahydroquinolines as Probes of PCP’s Binding Conformation. A New PCP-like Compound with Increased in Vivo Potency. J. Med. Chem. 35(9):1634-1638
[43] Olney JW, Labruyere J, Price MT (1989) Pathological changes induced in cerebrocortical neurons by phencyclidine and related drugs. Science 244(4910):1360-2
[44] Wang C, Zheng D, Xu J, Lam W, Yew DT (2013) Brain damages in ketamine addicts as revealed by magnetic resonance imaging. Front Neuroanat. 7:23
[45] Srirangam S, Mercer J (2012) Ketamine bladder syndrome: an important differential diagnosis when assessing a patient with persistent lower urinary tract symptoms. BMJ Case Rep. bcr2012006447
[46] Shen CH, Wang ST, Lee YR, Liu SY, Li YZ, Wu JD, Chen YJ, Liu YW (2015) Biological effect of ketamine in urothelial cell lines and global gene expression analysis in the bladders of ketamine injected mice. Mol Med Rep. 11(2):887-95
[47] Morgan CJ, Riccelli M, Maitland CH, Curran HV (2004) Long-term effects of ketamine: evidence for a persisting impairment of source memory in recreational users. Drug Alcohol Depend. 75(3):301-8
Wow!! Allow me to extend my encouragement to all involved. Astounding commentary always by the infamous nervewing.
ReplyDeleteHats off.
Thank you!
DeleteWhat's the capsaicin test?
ReplyDeleteIt's a test to determine whether a substance is an NMDA antagonist- it pretty much measures a mouse's pain response to capsaicin. NMDA antagonists suppress neurogenic pain so their pain response will be suppressed if the substance is an NMDA antagonist (vs. mu opioid agonists which suppress mechanical and thermal pain responses more)
DeleteI just discovered your astounding blog via this breathtaking chart. Truly a work of art and passion.
ReplyDeleteOne small error: "A Thiane ring, that is a Cyclohexane if you replaced one of the carbons with a nitrogen."
Should read: "...with a sulfur."
Good catch thank you!
DeleteArylcyclohexylamines are a class of pharmaceutical chemicals known for their neurological and anesthetic properties. The chemical class contains around 90 compounds based on variation in the structure and functional group. The representative chemical for the class is composed of a cyclohexylamine unit paired with an aryl functional group. The aryl functional group is commonly a phenyl ring with possible additional components. https://realchems.com/arylcyclohexalamines
ReplyDeleteThis comment has been removed by the author.
ReplyDeletedaedalus said...
ReplyDeleteThank you /so/ much for all your work into the ACH's! I mean I thought I'd gone pretty far down the rabbit hole but this is amazing! There's analogues here I hadn't even come close to conceiving of. There's a fine line between the ACHs and Pethidine though, so whoever follows up on this needs to stay on the straight and narrow; get AIHKAL on the shelves...then dip your toes in PAIHKAL!
PS: PM me if you need a tester!!