Medical use of stimulant medication

Amphetamines

Amphetamine (1-phenylpropan-2-amine) is a racemic molecule owing to its single chiral carbon and is a mixture of dextro- (or d-) and levo- (or l-) isomers, with d-amphetamine being the more active isomer of the two. Pharmacologically active molecules in this group are predominantly stimulant and sympathomimetic drugs; however, not all molecules with a similar structure to amphetamine are pharmacologically active, and all molecules vary in potency. Some amphetamine structural analogues belong to other drug classes, including the monoamine oxidase inhibitors tranylcypromine and selegiline (also known as deprenyl). A further indication of the structural similarities of the molecules is that small amounts of l-methamphetamine and l-amphetamine are formed as metabolites of selegiline. Some amphetamine analogues are used for their sympathomimetic properties rather than their stimulant properties, for example, pholedrine and dioxethedrine.

The structural relationships between amphetamines; precursors, derivatives, analogues, and stereoisomers, and their neural substrates, DA, and NE, are shown in Figure 1. The structures included are not exhaustive but do include all medicinal amphetamines.

Amphetamines are viewed primarily as catecholamine-releasing agents. Through action facilitated by the inhibition of the vesicular monoamine transporter 2 (VMAT-2), amphetamine can induce DA and NE release from presynaptic vesicles, bind to presynaptic dopaminergic and noradrenergic neurons inducing monoamine release at the nerve terminal, and bind to the DAT and NE reuptake transporter (NET), reversing the direction of monoamine transport from the nerve terminal into the synaptic cleft.Reference Baig^46, Reference Faraone⁴⁷

Amphetamines were heavily marketed in the 1930s and were very widely used in the Second World War, resulting in large numbers of people developing use disorders as well as a familiarity with these drugs. In the post-war period, amphetamines, known as “pep-pills” were well known to long-haul truck drivers.Reference Riley⁴⁸ Concerns with amphetamine abuse led to their prohibition by 1962⁴⁹; however, by that time they had already become well known in night clubs and an illicit trade had developed.⁵⁰ International data from wastewater monitoring demonstrates that amphetamine and methamphetamine are among the most widely used illicit recreational drugs, although the rate of use is not evenly distributed and peaks in East and North–Central Europe, with methamphetamine peaking in the United States and Australia.Reference Gonzalez-Marino⁵¹

Phenidates

The psychostimulant methylphenidate remains the only “phenidate” medication approved for prescriptive use in the US and elsewhere. Although a plethora of new methylphenidate therapeutics have been approved by various regulatory agencies and made it into the marketplace for the treatment of ADHD since the 1960s, their differences are limited to the introduction of a variety of modified-release oral dosage forms as racemic mixtures and single isomer (d-methylphenidate) products and a transdermal patch. Similar to the scenario described above for the development of the d-amphetamine prodrug lisdexamfetamine as a less abusable dosage form, a prodrug of d-methylphenidate was developed called serdexmethylphenidate in hopes of receiving a lower scheduling status but having the same clinical benefits as methylphenidate. The prodrug was designed to be pharmacologically inactive until it is gradually metabolized in the lower intestinal tract, releasing d-methylphenidate. Its inactivity as a prodrug discourages abuse by the intranasal and iv routes, and the slower release rate of the oral formulation decreased the “likeability” by stimulant abusers in targeted studies. However, the slow release and onset of action that decreased the likeability of the drug in stimulant abusers appeared to be the same pharmacokinetic:pharmacodynamic profile that produced suboptimal performance in clinical trials for the treatment of ADHD—particularly in the first several hours following dosing. To resolve this issue, it was decided to add to the formulation a fraction of the immediate-release d-methylphenidate. Ultimately, the final formulation receiving FDA approval in 2021 (trade name Azstarys®) was a combination containing both the prodrug serdexmethylphenidate (70%) and immediate-release d-methylphenidate (30%), which provided more immediate clinical effects as well as coverage throughout the day.

A number of other phenidate derivatives are in existence and can be found largely described in the new psychoactive substances (NPS) biomedical literature (Figure 2). NPS refers to a large and diverse group of substances of abuse not yet completely controlled by international drug conventions. A complete review of NPS is beyond the scope of the present chapter, but a few comments here on this phenomenon are useful. Many of the NPS substances were synthesized and patented many decades ago, but only recently have had their chemistry modified to produce new substances with similar subjective effects to established recreational drugs.Reference Schifano⁵² These so-called “designer” or synthetic drugs that are frequently structural analogues of existing prescriptive controlled drugs or other known drugs of abuse. These compounds are specifically created to produce substances with similar or enhanced psychoactive effects to other controlled substances or illicit drugs.Reference Shafi⁵³ These structural changes to the compounds can make substance identification problematic and pose problems for toxicologists and emergency response personnel responding to NPS intoxication or overdose scenarios. Identification NPS has found their way into cryptomarkets for internet purchases. Phenidates in general are chemical analogues of methylphenidate.Reference Klare^54–Reference Portoghese and Malspeis⁵⁶ Portoghese and Malepeais (1961) initially reported on the synthesis and characteristics of a series of alkyl esters of methylphenidate. Among these were ethylphenidate, n-propylphenidate, and n-butylphenidate.

Figure 2. Examples of phenidates.

Ethylphenidate

Ethylphenidate (EPH) is the ethyl acetate analogue of MPH (ethyl phenyl (2-piperidinyl) acetate, Figure 2). It is an amphetamine-like stimulant that inhibits both DAT and NET in the CNS. The affinity of EPH to DAT and NET is similar to those of MPH, but its affinity to NET and inhibition potency are substantially different, indicating qualitative differences between the pharmacodynamics of MPH and EPH.Reference Williard⁵⁷ An additional curiosity regarding ethylphenidate is that it can also be found as a biotransformation product formed via a carboxylesterase 1 (CES1)-catalyzed transesterification reaction when ethanol is co-consumed with methylphenidate (Figure 3).Reference Markowitz⁵⁸ The amount of the ethylphenidate metabolite formed endogenously by this reaction is fairly low and appears to proceed largely in a stereoselective process, being formed as l-ethylphenidate. However, large quantities of dl-ethylphenidate became available over the dark web and were marketed as a powder or a crystal and are frequently consumed by insufflation or injected intravenously.Reference Markowitz and Patrick⁵⁹ This is significant in that these dosing routes avoid the substantial first-pass effects that occur with orally administered methylphenidate, which limit its bioavailability to less than 25%. Intravenous use produces 100% bioavailability, and intranasal administration almost certainly provides greater exposure than oral dosing. Ethylphenidate is considered to be a highly abusable substance, and a number of fatalities have been reported.

Figure 3. Ethylphenidate formation via transesterification with ethyl alcohol.

Isopropylphenidate

Isopropylphenidate (IPH) is the isopropyl acetate analogue of MPH (isopropyl phenyl(2-piperidinyl) acetate (Figure 2).Reference Markowitz, Zhu and Patrick⁶⁰ It appeared on the cryptomarket in 2013 but was first discussed in the literature in 1961. IPH binds DAT and NET with an affinity similar to that of EPH.Reference Markowitz, Zhu and Patrick⁶⁰

Beyond ethylphenidate, a number of other analogues of MPH have been produced through a simple extension of the carbon side chain (eg, isopropylphenidate, propylphenidate). Furthermore, substitution of the phenyl ring with a 1-naphthyl ring is a further modification producing CNS active derivatives, including ethylnaphthidate and methylnaphthidate. Other substituted “phenidates,” which appear to be potential substances of abuse with likely CNS stimulatory effects include propylphenidate, N-benzyl-ethylphenidate, methylmorphenate, 3,4-dichloromethylphenidate, 3,4-dichloroethylphenidate, 4-fluoroethylphenidate, 4-fluoromethylphenidate, and 4-methylmethylphenidate.

Pemoline

Pemoline (2-imino-5-phenyl-4-oxazolidinone) was a third psychostimulant molecule available to treat ADHD that was originally approved by the US FDA in 1975. Marketed under the trade name Cylert®. Though less frequently prescribed than amphetamine and methylphenidate formulations and thought to have lower abuse potential, the drug was removed from the US market in 2005 due to accumulating reports of pemoline-associated hepatotoxicity. Although seemingly structurally dissimilar to amphetamine and methylphenidate, the shared phenethylamine structure, a common pharmacophore between it and the other stimulants, can be appreciated in bold (Figure 1). Pemoline is a presynaptic DA-releasing agent and re-uptake blocker. Pemoline was used to treat ADHD but was withdrawn from sale due to rare but serious cases of liver toxicity. Pemoline abuse has been reported.Reference Polchert and Morse⁶¹

Modafinil

In 1974, while screening molecules to detect analgesic properties, French chemists R. Gombert and E. Assous from the pharmaceutical company L. Lafon Ltd. found that the molecule CRL 40028 was pharmacologically active.Reference Billiard and Broughton⁶² Studies found that CRL 40028 increased locomotor activity in mice, and this hyperactivity did not occur when CRL 40028 was given to mice that had been pre-treated with a blocker of α-adrenergic receptors.Reference Duteil⁶³ CRL 40028 was later named adrafinil. The mechanism of action of adrafinil as a stimulant is adrafinil has metabolites modafinil (CRL 40476) and an acid (CRL 40467). Modafinil (Figure 4) is further metabolized into a sulfone. Acid and sulfone metabolites are pharmacologically inactive. Armodafinil the R-enantiomer of modafinil,Reference Milgram, Heather and Siwak⁶⁴ was approved by the US FDA in 2007 under the trade name Nuvigil® as an enantiopure formulation with approved indications to improve wakefulness in adult patients with excessive sleepiness associated with obstructive sleep apnea, narcolepsy, or shift work disorder (SWD).

Figure 4. Miscellaneous examples of psychostimulants.

Adrafinil and modafinil are racemic mixtures. Derivatives have been synthesized, including fluorinated derivates fladrafinil, flmodafinil, and modafiendz, as well as heterocyclic derivatives. For several derivatives, there is a paucity of published research, especially from human trials.

Among these drug analogues, modafinil has been the most thoroughly researched. Nevertheless, even for modafinil, the detailed mechanism of action is not fully known. Stimulant pharmaco-activity is prevented by blocker of α-adrenergic receptors, but modafinil has not been shown to be an α-adrenergic receptor agonist.Reference Garnock-Jones, Dhillon and Scott⁶⁵ Unlike amphetamines, modafinil is not a catecholamine-releasing agent.Reference Sousa and Dinis-Oliveira⁶⁶ Modafinil and armodafinil bind to DAT, but not with the high binding affinity of other stimulants such as cocaine. Modafinil increases DA in the striatum and cortex.Reference Sousa and Dinis-Oliveira⁶⁶ Armodafinil has a greater binding affinity for DAT than modafinil. Modafinil does not bind to presynaptic DA receptors.Reference Sousa and Dinis-Oliveira⁶⁶ Modafinil does not bind to serotonin (SERT) or NE transporters (NET). The mechanism of action of modafinil as a stimulant is through DA and NE; however, modafinil has also been shown to influence gamma-amino butyric acid (GABA), serotonin (5HT), glutamate, histamine, and orexin/hypocretin.Reference Sousa and Dinis-Oliveira⁶⁶

Modafinil is administered by oral dose and reaches a blood plasma concentration maximum (C _max) after 2–4 h. The elimination half-life (t⅟₂) is 12–15 h for the R-enantiomer armodafinil and 4–5 h for the S-enantiomer.Reference Sousa and Dinis-Oliveira⁶⁶ Consequently, modafinil is not useful for immediate alertness, and armodafinil has benefits over modafinil for duration of action.

Modafinil and related drugs have a low potential for addiction or dependence, as they lack the pleasurable effects of classic stimulants. Cases of dependence have been reported, manifesting as dose escalation.Reference Krishnan and Chary⁶⁷ The favorable safety profile of modafinil resulted in its use as the preferred military anti-fatigue drug, used currently by pilots.Reference Wingelaar-Jagt⁶⁸ Modafinil is indicated for the treatment of sleep disorders, including narcolepsy, obstructive sleep apnea/hypopnea syndrome, and shift work sleep disorder. The use of modafinil to treat ADHD is off-label.

Controversially, modafinil and related drugs have been used as nootropic (cognitive enhancer) agents by students sitting examsReference Cakic⁶⁹ and as a performance-enhancing drug in sports. Modafinil is included as a prohibited substance in the World Anti-Doping Agency (WADA) prohibited list for drugs in sport.⁴⁵ Modafinil was shown to be superior to placebo for improvement to spatial working memory, planning, and decision making in non-sleep-deprived health volunteers,Reference Muller⁷⁰ although benefits are at best modest.

Bupropion

Bupropion, classified as an aminoketone antidepressant (Figure 4), is a mild stimulant due to DA and NE re-uptake inhibition. It was initially FDA-approved for the treatment of depression in 1989 and later as a smoking cessation aid.Reference Wilkes⁷¹ In 2022, a fixed combination of bupropion and the N-methyl D-aspartate (NMDA) receptor antagonist and sigma-1 receptor agonist, dextromethorphan, was approved under the trade name (Auvelity®) with an indication for the treatment of major depressive disorder in adults. This fixed combination appears to reduce depressive symptoms more quickly than bupropion alone. Bupropion has been evaluated for the treatment of ADHD but appears to offer only small reductions in symptoms for most patients. Bupropion abuse has been reported, including recreational ingestion, nasal insufflation of crushed tablets, and intravenous injection.Reference Stall, Godwin and Juurlink⁷² Bupropion has emerged as a drug of abuse in prisons.Reference Aikoye⁷³

Solriamfetol

Solriamfetol (Figure 4) is a newer stimulant approved for excessive daytime sleepiness (hypersomnia) associated with narcolepsy and obstructive sleep apnea.Reference Markham⁷⁴ A pilot trial randomized individuals (N = 60) to solriamfetol or placebo and found that solriamfetol was well tolerated and superior to placebo for several outcome measures,Reference Surman⁷⁵ including clinical global impression and ADHD symptoms. Elsewhere, a case report described an ADHD patient who had responded poorly to atomoxetine and methylphenidate, who subsequently responded to solriamfetol treatment.Reference Naguy⁷⁶

Solriamfetol is a low potency, selective DA, and NE reuptake inhibitor. It is not associated with locomotor effects observed with higher potency stimulants.Reference Baladi⁷⁷

Cocaine

Cocaine, a tropane alkaloid (Figure 4), is a powerful stimulant extracted from coca leaves. Use of coca leaves by indigenous communities in South America has a long history and cultural significance. Consumption of coca leaves and use of cocaine are in no way equivalent.Reference Bauer⁷⁸ The use of coca leaves is outside of the scope of this chapter. Cocaine was first extracted from coca leaves in Germany in the 1850s by Friedrich Gaedcke, who first isolated crystal in 1855,Reference Gaedcke⁷⁹ and Albert Niemann, who published an improved method for extracting cocaine in his PhD thesis published in 1860.Reference Niemann⁸⁰

The medicinal value of cocaine was soon investigated, first demonstrated for use as a topical anesthetic for eye surgery in 1884, the anesthetic properties of cocaine quickly became its greatest success as a medicinal agent,Reference Altman, Albert and Fournier⁸¹ and it is still used today in solutions varying from 1% to 10% concentration on mucosal surfaces for ophthalmology and otolaryngology. Cocaine was also important in some pioneering research into local anesthesia, as a nerve blocking agent and forerunner for local anesthetics, including procaine and lidocaine.Reference Markel⁸²

The stimulant properties of cocaine were also quickly recognized, and it was recommended for medical and non-medical use, often by physicians who had tried it on themselves or were regular users over some period of time. Sigmund Freud consumed cocaine and used it to treat his patients, publishing his work “Über Coca” in 1884, where he enthusiastically praised cocaine hydrochloride as a treatment for physical and neurological conditions.Reference Musto⁸³ Over a period of years, Freud enthused over the potential for cocaine to treat addiction, including alcoholism and morphine abuse, but later accepted that cocaine also had abuse potential. His support for cocaine to treat melancholia lasted a bit longer, but his last published works regarding cocaine were in 1887.Reference Musto⁸³

Cocaine has been marketed as a hay fever remedyReference Altman, Albert and Fournier⁸¹ and a treatment for headache, among many other uses.Reference Drake and Scott³ In addition, it has been an ingredient in Coca ColaReference Altman, Albert and Fournier⁸¹ and in Vin Mariani, famously endorsed by Pope Leo XIII.Reference Redd⁸⁴

Reports of harm from cocaine use emerged from the 1880s, leading to restrictions on the importation, manufacture, and distribution of cocaine in the USA with the Harrison Narcotics Act in 1914.Reference Drake and Scott³ Currently, cocaine is estimated to cause 50 000 death per year worldwide.Reference Drake and Scott³ There is no current interest from the medical community in the stimulant properties of cocaine as a pharmacotherapy.

Stimulant effects of cocaine are due to inhibition of DAT and NET. Cocaine is also an antagonist of adrenergic receptors. Local anesthetic effects are due to inhibition of voltage-gated sodium channels blocking neuronal potentiation.Reference Drake and Scott³ Cocaine pharmacokinetics varies depending on the route of administration, with intravenous injection, nasal insufflation, and smoke inhalation all being common. Cocaine is extensively metabolized with two major metabolites, benzoylecgonine and ecgonine methyl ester, among 11 known metabolites.Reference Drake and Scott³

Caffeine and nicotine

Caffeine and nicotine (Figure 4) are classified as mild stimulants. Caffeine is an antagonist of A1 and A2 adenosine receptors and has beneficial effects for wakefulness. Stimulant properties are through binding with adenosine receptors that have formed heteromers with DA receptors, modulating the activity of the DA receptors.Reference Ferre⁸⁵ There is limited evidence to suggest caffeine may have beneficial effects for some cancers, has anti-inflammatory effects, and may be neuroprotective.Reference Saraiva⁸⁶ Nicotine binds to nicotinic acetylcholine receptors, activating the dopaminergic system.Reference Picciotto and Mineur⁸⁷ Nicotine is not suitable for medical use as it is highly addictive, other than nicotine replacement therapy for smokers. These two substances are frequently consumed together in the form of coffee and other beverages by tobacco smokers. Caffeine is reported to potentiate the reinforcing and stimulant effects of nicotine, which may make nicotine use more rewarding.Reference Jones and Griffiths⁸⁸