(R)-MDMA explained

(R)-3,4-Methylenedioxy-N-methylamphetamine ((R)-MDMA), also known as (R)-midomafetamine or as levo-MDMA, is the (R)- or levorotatory (l-) enantiomer of 3,4-methylenedioxy-N-methylamphetamine (MDMA; midomafetamine; "ecstasy"), a racemic mixture of (R)-MDMA and (S)-MDMA.^[1] Like MDMA, (R)-MDMA is an entactogen or empathogen. It is taken by mouth.

The drug is a serotonin–norepinephrine releasing agent (SNRA) and weak serotonin 5-HT_2A receptor agonist. It has substantially less or no significant dopamine-releasing activity compared to MDMA and (S)-MDMA. In preclinial studies, (R)-MDMA shows equivalent therapeutic-like effects to MDMA, such as increased prosocial behavior, but shows reduced psychostimulant-like effects, addictive potential, and serotonergic neurotoxicity. In clinical studies, (R)-MDMA produces similar effects to MDMA and (S)-MDMA, but is less potent and has a longer duration.

(R)-MDMA was first described in enantiopure form by 1978. Under the developmental code names EMP-01 and MM-402, it is under development for the treatment of post-traumatic stress disorder (PTSD), social phobia, and pervasive development disorders (PDDs) such as autism.^{[2] [3] [4]} It is thought that (R)-MDMA might have a better safety profile than MDMA itself whilst retaining its therapeutic benefits.

Pharmacology

Pharmacodynamics

Preclinical studies

Activities of MDMA, its enantiomers, and related compounds

Compound	Monoamine release (nM)
			Dopamine
(S)-Amphetamine (d)	698–1765	6.6–7.2	5.8–24.8
(R)-Amphetamine (l)
(S)-Methamphetamine (d)	736–1291.7	12.3–13.8	8.5–24.5
(R)-Methamphetamine (l)	4640	28.5	416
	160	108	190
(S)-MDA (d)	100	50	98
(R)-MDA (l)	310	290	900
	49.6–72	54.1–110	51.2–278
(S)-MDMA (d)	74	136	142
(R)-MDMA (l)	340	560	3700
	47	2608	622
(S)-MDEA (d)	465
(R)-MDEA (l)	52	651	507
	540	3300	>100000
	114	117	1334
Notes: The smaller the value, the more strongly the compound produces the effect. Refs: [5] [6] [7] [8] [9]

MDMA is a well-balanced serotonin–norepinephrine–dopamine releasing agent (SNDRA).^{[10] [11] [12]} (R)-MDMA and (S)-MDMA are both SNDRAs similarly. However, (R)-MDMA is several-fold less potent than (S)-MDMA in vitro and is also less potent than (S)-MDMA in vivo in non-human primates. In addition, whereas MDMA and (S)-MDMA are well-balanced SNDRAs, (R)-MDMA is comparatively much less potent as a dopamine releasing agent (~11-fold less potent in releasing dopamine than serotonin), and could be thought of instead more as a serotonin–norepinephrine releasing agent (SNRA) than as an SNDRA. In non-human primates, (S)-MDMA demonstrated significant dopamine transporter (DAT) occupancy, whereas DAT occupancy with (R)-MDMA was undetectable. Similarly, MDMA and (S)-MDMA were found to increase dopamine levels in the striatum in rodents and non-human primates, whereas (R)-MDMA did not increase striatal dopamine levels.^[13] As such, (R)-MDMA may be less psychostimulant-like than MDMA or (S)-MDMA.

In addition to its actions as an SNDRA, MDMA has weak affinity for the serotonin 5-HT_2A, 5-HT_2B, and 5-HT_2C receptors, where it acts as an agonist. (R)-MDMA shows higher affinity for the serotonin 5-HT_2A receptor than (S)-MDMA or MDMA. In addition, (R)-MDMA is more potent as an agonist of the serotonin 5-HT_2A receptor, acting as a weak partial agonist of this receptor, whereas (S)-MDMA shows very little effect. Conversely however, (S)-MDMA is more potent as an agonist of the serotonin 5-HT_2C receptor.^[14] Based on these findings, it has been hypothesized that (R)-MDMA may be more psychedelic-like than (S)-MDMA. However, although (R)-MDMA partially substitutes for lysergic acid diethylamide (LSD) in animal drug discrimination tests, it did not produce the head-twitch response, a behavioral proxy of psychedelic effects, at any tested dose.^[15]

MDMA is a well-known serotonergic neurotoxin and this has been demonstrated both in animals and in humans. There is evidence that the serotonergic neurotoxicity of MDMA may be driven primarily by (S)-MDMA rather than (R)-MDMA. (R)-MDMA shows substantially lower or potentially no neurotoxicity compared to (S)-MDMA in animal studies. This has been the case even when doses of (R)-MDMA were increased to account for its lower potency than (S)-MDMA. However, more research is needed to confirm this in other species, such as non-human primates. In contrast to (S)-MDMA, (R)-MDMA does not produce hyperthermia in rodents, and this may be involved in its reduced risk of neurotoxicity, as hyperthermia augments and is essential for the serotonergic neurotoxicity of MDMA. The reduced potency of (R)-MDMA as a dopamine releasing agent may also be involved in its reduced neurotoxic potential, as dopamine release is likewise essential for the neurotoxicity of MDMA. The hyperthermia of MDMA may in fact be mediated by dopamine release. As (R)-MDMA is less neurotoxic than (S)-MDMA and MDMA or even non-neurotoxic, it may allow for greater clinical viability and prolonged regimens of drug-assisted psychotherapy.

(R)-MDMA and (S)-MDMA have shown equivalent effects in terms of inducing prosocial behavior in monkeys. However, (S)-MDMA shows higher potency, whereas (R)-MDMA shows greater maximal effects. Conversely, (S)-MDMA does not increase prosocial behavior in mice, whereas both MDMA and (R)-MDMA do so. MDMA and (S)-MDMA increase locomotor activity, a measure of psychostimulant-like effect, in rodents, whereas (R)-MDMA does not do so.^[16] (R)-MDMA likewise showed fewer reinforcing effects than (S)-MDMA in non-human primates. These findings further add to (R)-MDMA showing reduced psychostimulant-like and addictive effects compared to MDMA and (S)-MDMA.

Clinical studies

The first modern clinical study of the comparative effects of MDMA, (R)-MDMA, and (S)-MDMA was published in August 2024.^{[17] [18]} It compared 125mg MDMA, 125mg (S)-MDMA, 125 and 250mg (R)-MDMA, and placebo. (R)-MDMA increased any drug effect, good drug effect, drug liking, stimulation, drug high, alteration of vision, and alteration of sense of time ratings similarly to MDMA and (S)-MDMA. However, (S)-MDMA 125mg was more potent in increasing subjective effects, including stimulation, drug high, happy, and open, among others, than (R)-MDMA 125 or 250mg or MDMA 125mg. Ratings of bad drug effect and fear were minimal with MDMA, (R)-MDMA, and (S)-MDMA. In contrast to expectations, (R)-MDMA did not produce more psychedelic-like effects than (S)-MDMA. Besides subjective effects, (R)-MDMA increased heart rate, blood pressure, and body temperature similarly to MDMA and (S)-MDMA, though it was less potent in producing these effects. Body temperature was notably increased to the same extent with (R)-MDMA 250mg as with MDMA 125mg and (S)-MDMA 125mg.

The differences in effects between (R)-MDMA and (S)-MDMA may reflect the higher potency of (S)-MDMA rather than actual qualitative differences between the effects of (S)-MDMA and (R)-MDMA. It was estimated that equivalent effects would be expected with (S)-MDMA 100mg, MDMA 125mg, and (R)-MDMA 300mg. The findings of the study were overall regarded as not supporting the hypothesis that (R)-MDMA would produce equivalent therapeutic effects as (S)-MDMA or MDMA whilst reducing safety concerns. However, more clinical studies were called for to assess the revised estimated equivalent doses of MDMA, (R)-MDMA, and (S)-MDMA.

Pharmacokinetics

The elimination half-life of (S)-MDMA is 4.1hours, whereas the half-life of (R)-MDMA is 12 to 14hours. In the case of racemic MDMA administration, the half-life of (S)-MDMA is 5.1hours and the half-life of (R)-MDMA is 11hours. (R)-MDMA shows cytochrome P450 CYP2D6 inhibition and lower levels of the metabolite 4-hydroxy-3-methoxymethamphetamine (HMMA) than (S)-MDMA.

History

(R)-MDMA was first described in the scientific literature in enantiopure form by 1978.^[19] It was described in a paper authored by Alexander Shulgin, David E. Nichols, and other colleagues.

Clinical development

(R)-MDMA is under development separately by Empath Biosciences (EmpathBio) and MindMed.^[20] It is being developed by Empath Biosciences for the treatment of PTSD and social phobia and it is being developed by MindMed for the treatment of PDDs or autism. As of 2024, the drug is in phase 1 clinical trials for both PTSD, social phobia, and PDDs/autism.

See also

• List of investigational hallucinogens and entactogens
• List of investigational autism and pervasive developmental disorder drugs
• List of investigational social anxiety disorder drugs

Notes and References

1. Pitts EG, Curry DW, Hampshire KN, Young MB, Howell LL . (±)-MDMA and its enantiomers: potential therapeutic advantages of R(-)-MDMA . Psychopharmacology . 235 . 2 . 377–392 . February 2018 . 29248945 . 10.1007/s00213-017-4812-5 .
2. Web site: EMP 01 (R-MDMA) . AdisInsight . 20 August 2024 . 28 October 2024.
3. Web site: R(-)-Methylenedioxymetamfetamine (MM-402; R(-)-MDMA) . AdisInsight . 30 January 2024 . 28 October 2024.
4. Web site: Delving into the Latest Updates on EMP-01 with Synapse . Synapse . 1 November 2024 . 2 November 2024.
5. Rothman RB, Baumann MH, Dersch CM, Romero DV, Rice KC, Carroll FI, Partilla JS . Amphetamine-type central nervous system stimulants release norepinephrine more potently than they release dopamine and serotonin . Synapse . 39 . 1 . 32–41 . January 2001 . 11071707 . 10.1002/1098-2396(20010101)39:1<32::AID-SYN5>3.0.CO;2-3 . 15573624 .
6. Rothman RB, Partilla JS, Baumann MH, Lightfoot-Siordia C, Blough BE . Studies of the biogenic amine transporters. 14. Identification of low-efficacy "partial" substrates for the biogenic amine transporters . The Journal of Pharmacology and Experimental Therapeutics . 341 . 1 . 251–262 . April 2012 . 22271821 . 3364510 . 10.1124/jpet.111.188946 .
7. Marusich JA, Antonazzo KR, Blough BE, Brandt SD, Kavanagh PV, Partilla JS, Baumann MH . The new psychoactive substances 5-(2-aminopropyl)indole (5-IT) and 6-(2-aminopropyl)indole (6-IT) interact with monoamine transporters in brain tissue . Neuropharmacology . 101 . 68–75 . February 2016 . 26362361 . 4681602 . 10.1016/j.neuropharm.2015.09.004 .
8. Nagai F, Nonaka R, Satoh Hisashi Kamimura K . The effects of non-medically used psychoactive drugs on monoamine neurotransmission in rat brain . European Journal of Pharmacology . 559 . 2–3 . 132–137 . March 2007 . 17223101 . 10.1016/j.ejphar.2006.11.075 .
9. Halberstadt AL, Brandt SD, Walther D, Baumann MH . 2-Aminoindan and its ring-substituted derivatives interact with plasma membrane monoamine transporters and α2-adrenergic receptors . Psychopharmacology (Berl) . 236 . 3 . 989–999 . March 2019 . 30904940 . 6848746 . 10.1007/s00213-019-05207-1 .
10. Rothman RB, Baumann MH . Monoamine transporters and psychostimulant drugs . European Journal of Pharmacology . 479 . 1–3 . 23–40 . October 2003 . 14612135 . 10.1016/j.ejphar.2003.08.054 .
11. Rothman RB, Baumann MH . Therapeutic potential of monoamine transporter substrates . Current Topics in Medicinal Chemistry . 6 . 17 . 1845–1859 . 2006 . 17017961 . 10.2174/156802606778249766 .
12. Setola V, Hufeisen SJ, Grande-Allen KJ, Vesely I, Glennon RA, Blough B, Rothman RB, Roth BL . 6 . 3,4-methylenedioxymethamphetamine (MDMA, "Ecstasy") induces fenfluramine-like proliferative actions on human cardiac valvular interstitial cells in vitro . Molecular Pharmacology . 63 . 6 . 1223–1229 . June 2003 . 12761331 . 10.1124/mol.63.6.1223 . 839426 .
13. Acquas E, Pisanu A, Spiga S, Plumitallo A, Zernig G, Di Chiara G . Differential effects of intravenous R,S-(+/-)-3,4-methylenedioxymethamphetamine (MDMA, Ecstasy) and its S(+)- and R(-)-enantiomers on dopamine transmission and extracellular signal regulated kinase phosphorylation (pERK) in the rat nucleus accumbens shell and core . Journal of Neurochemistry . 102 . 1 . 121–132 . July 2007 . 17564678 . 10.1111/j.1471-4159.2007.04451.x .
14. Kaur H, Karabulut S, Gauld JW, Fagot SA, Holloway KN, Shaw HE, Fantegrossi WE . Balancing Therapeutic Efficacy and Safety of MDMA and Novel MDXX Analogues as Novel Treatments for Autism Spectrum Disorder . 2023 . Psychedelic Medicine . 1 . 3 . 166–185 . 10.1089/psymed.2023.0023 .
15. Dunlap . Lee E. . Development of Non-Hallucinogenic Psychoplastogens . University of California, Davis . 2022 . 18 November 2024 . Finally, since R-MDMA is known to partially substitute for LSD in animal models we decided to test both compounds in the head twitch response assay (HTR) (FIG 3.3C).3 The HTR is a well-validated mouse model for predicting the hallucinogenic potential of test drugs. Serotonergic psychedelics will cause a rapid back and forth head movement in mice. The potency measured in the HTR assay has been shown to correlate very well with the human potencies of psychedelics.18 Neither R-MDMA or LED produced any head twitches at all doses tested, suggesting that neither has high hallucinogenic potential..
16. Curry DW, Young MB, Tran AN, Daoud GE, Howell LL . Separating the agony from ecstasy: R(-)-3,4-methylenedioxymethamphetamine has prosocial and therapeutic-like effects without signs of neurotoxicity in mice . Neuropharmacology . 128 . 196–206 . January 2018 . 28993129 . 5714650 . 10.1016/j.neuropharm.2017.10.003 .
17. Bedi G . Is the stereoisomer R-MDMA a safer version of MDMA? . Neuropsychopharmacology . October 2024 . 39448866 . 10.1038/s41386-024-02009-8 . free .
18. Straumann I, Avedisian I, Klaiber A, Varghese N, Eckert A, Rudin D, Luethi D, Liechti ME . 6 . Acute effects of R-MDMA, S-MDMA, and racemic MDMA in a randomized double-blind cross-over trial in healthy participants . Neuropsychopharmacology . August 2024 . 39179638 . 10.1038/s41386-024-01972-6 . free .
19. Anderson GM, Braun G, Braun U, Nichols DE, Shulgin AT . Absolute configuration and psychotomimetic activity . NIDA Research Monograph . 22 . 8–15 . 1978 . 101890 .
20. Web site: Delving into the Latest Updates on MM-402 with Synapse . Synapse . 1 November 2024 . 2 November 2024.