|Systematic (IUPAC) name|
|Metabolism||Hepatic (CYP3A4, CYP2E1)|
|Biological half-life||53 hours|
|CAS Registry Number|
|Molecular mass||141.168 g/mol|
It is on the health system.
Medical uses 1
- Dosage 1.1
Adverse effects 2
Central nervous system 2.1
- Common 2.1.1
- Rare 2.1.2
- Gastrointestinal 2.2
- Genitourinary 2.3
- Hematopoietic 2.4
- Integumentary 2.5
- Ocular 2.6
- Central nervous system 2.1
- Complications 3
- Drug interactions 4
- Mechanism of action 5
- Availability 6
- See also 7
- Notes 8.1
- External links 9
It is approved for absence seizures. Ethosuximide is considered the first choice drug for treating absence seizures in part because it lacks the idiosyncratic hepatotoxicity of the alternative anti-absence drug, valproic acid.
Therapeutic drug concentrations are individualized according to response and tolerance. Common serum therapeutic range: 40-100 µg/mL. Potentially toxic serum concentration: >100 µg/mL.
Central nervous system
- stomach pain
- loss of appetite
- weight loss
- gingival hyperplasia
- swelling of tongue
- microscopic hematuria
- vaginal bleeding
The following can occur with or without bone marrow loss:
- systemic lupus erythematosus
- Stevens–Johnson syndrome
- pruritic erythematous rashes
- abnormal liver function
It may elevate serum phenytoin levels.
Mechanism of action
The mechanism by which ethosuximide affects neuronal excitability includes block of T-type Ca2+ channels, and may include effects of the drug on other classes of ion channel. The primary finding that ethosuximide is a T-type Ca2+ channel blocker gained widespread support, but initial attempts to replicate the finding were inconsistent. Subsequent experiments on recombinant T-type channels in cell lines demonstrated conclusively that ethosuximide blocks all T-type Ca2+ channel isoforms. Significant T-type Ca2+ channel density occurs in dendrites of neurons, and recordings from reduced preparations that strip away this dendritic source of T-type Ca2+ channels may have contributed to reports of ethosuximide ineffectiveness.
In March 1989, Coulter, Huguenard and Prince showed that ethosuximide and dimethadione, both effective anti-absence agents, reduced low-threshold Ca2+ currents in T-type Ca2+ channels in freshly removed thalamic neurons. In June of that same year, they also found the mechanism of this reduction to be voltage-dependent, using acutely dissociated neurons of rats and guinea pigs; it was also noted that valproic acid, which is also used in absence seizures, did not do that. The next year, they showed that anticonvulsant succinimides did this and that the proconvulsant ones did not. The first part was supported by Kostyuk et al. in 1992, who reported a substantial reduction in current in dorsal root ganglia at concentrations ranging from 7 µmol/L to 1 mmol/L.
That same year, however, Herrington and Lingle found no such effect at concentrations of up to 2.5 mmol/L. The year after, a study conducted on human neocortical cells removed during surgery for intractable epilepsy, the first to use human tissue, found that ethosuximide had no effect on Ca2+ currents at the concentrations typically needed for a therapeutic effect.
In 1998, Slobodan M. Todorovic and Christopher J. Lingle of Washington University reported a 100% block of T-type current in dorsal root ganglia at 23.7 ± 0.5 mmol/L, far higher than Kostyuk reported. That same year, Leresche et al. reported that ethosuximide had no effect on T-type currents, but did decrease noninactivating Na+ current by 60% and the Ca2+-activated K+ currents by 39.1 ± 6.4% in rat and cat thalamocortical cells. It was concluded that the decrease in Na+ current is responsible for the anti-absence properties.
In the introduction of a paper published in 2001, Dr. Juan Carlos Gomora and colleagues at the University of Virginia in Charlottesville pointed out that past studies were often done in isolated neurons that had lost most of their T-type channels. Using cloned α1G, α1H, and α1I T-type calcium channels, Gomora's team found that ethosuximide blocked the channels with an IC50 of 12 ± 2 mmol/L and that of N-desmethylmethsuximide (the active metabolite of mesuximide) is 1.95 ± 0.19 mmol/L for α1G, 1.82 ± 0.16 mmol/L for α1I, and 3.0 ± 0.3 mmol/L for α1H. It was suggested that the blockade of open channels is facilitated by ethosuximide's physically plugging the channels when current flows inward.
Ethosuximide is marketed under the trade names Emeside and Zarontin. However, both capsule preparations were discontinued from production, leaving only generic preparations available. Emeside capsules were discontinued by their manufacturer, Laboratories for Applied Biology, in 2005. Similarly, Zarontin capsules were discontinued by Pfizer in 2007. Syrup preparations of both brands remained available.
- "WHO Model List of EssentialMedicines" (PDF). World Health Organization. October 2013. Retrieved 22 April 2014.
- "Concern over ethosuximide capsule discontinuation". Pharm J 275. Oct 29, 2005. p. 539. Retrieved 2008-08-31. (paywalled archive)
- "Zarontin capsules discontinued". Retrieved 2012-10-24.
- ^ Patsalos, P. N. (November 2005). "Properties of Antiepileptic Drugs in the Treatment of Idiopathic Generalized Epilepsies". Epilepsia 46 (s9): 140–144.
- ^ Pharmaceutical Associates, Incorporated (2000). "Ethosuximide Approval Label" (PDF). Label and Approval History.
- ^ Katzung, B., ed. (2003). "Drugs used in generalized seizures". Basic and Clinical Pharmacology (9th ed.). Lange Medical Books/McGraw-Hill.
- ^ Andrulonis, P. A.; J. Donnelly; B. C. Glueck; C. F. Stroebel; B. L. Szabek (November 1980). "Preliminary data on ethosuximide and the
- ^ Coulter DA, Huguenard JR, Prince DA (Mar 13, 1989). "Specific petit mal anticonvulsants reduce calcium currents in thalamic neurons". Neurosci Lett 98 (1): 74–8.
- ^ Coulter DA, Huguenard JR, Prince DA (June 1989). "Characterization of ethosuximide reduction of low-threshold calcium current in thalamic neurons". Annals of Neurology 25 (6): 582–93.
- ^ Coulter DA, Huguenard JR, Prince DA (August 1990). "Differential effects of petit mal anticonvulsants and convulsants on thalamic neurones: calcium current reduction". British Journal of Pharmacology 100 (4): 800–6.
- ^ Kostyuk PG, Molokanova EA, Pronchuk NF, Savchenko AN, Verkhratsky AN (December 1992). "Different action of ethosuximide on low- and high-threshold calcium currents in rat sensory neurons". Neuroscience 51 (4): 755–8.
- ^ Herrington J, Lingle CJ (July 1992). "Kinetic and pharmacological properties of low voltage-activated Ca2+ current in rat clonal (GH3) pituitary cells". Journal of Neurophysiology 68 (1): 213–32.
- ^ Sayer RJ, Brown AM, Schwindt PC, Crill WE. "Calcium currents in acutely isolated human neocortical neurons." Journal of Neurophysiology. 1993 May;69(5):1596-606. PMID 8389832 Fulltext
- ^ Todorovic SM, Lingle CJ (January 1, 1998). "Pharmacological properties of T-type Ca2+ current in adult rat sensory neurons: effects of anticonvulsant and anesthetic agents". Journal of Neurophysiology 79 (1): 240–52.
- ^ Leresche N, Parri HR, Erdemli G, Guyon A, Turner JP, Williams SR, Asprodini E, Crunelli V (July 1, 1998). "On the action of the anti-absence drug ethosuximide in the rat and cat thalamus". Journal of Neuroscience 18 (13): 4842–53.
- ^ Gomora JC, Daud AN, Weiergraber M, Perez-Reyes E (2001). "Block of cloned human T-type calcium channels by succinimide antiepileptic drugs". Molecular Pharmacology 60 (5): 1121–32.
- ^ Bourgeois, BF (December 1988). "Combination of valproate and ethosuximide: antiepileptic and neurotoxic interaction". The Journal of Pharmacology and Experimental Therapeutics 247 (3): 1128–32.
- Ethosuximide Internet Mental Health.
- MedlinePlus Drug Information: Ethosuximide Oral
- Zarontin Pfizer.
- Zarontin Drug information, published studies and current trials