Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT04858841 |
| Other study ID # |
A-BR-108-107 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
August 1, 2020 |
| Est. completion date |
July 31, 2023 |
Study information
| Verified date |
April 2021 |
| Source |
National Cheng Kung University |
| Contact |
Chin-Wei Huang, MD, PhD |
| Phone |
886-6-2353535 |
| Email |
huangcw[@]mail.ncku.edu.tw |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Advance in stroke treatment have resulted in a dramatic reduction in the stroke mortality,
however, the number of stroke survivors living with morbidity has increased significantly. As
we know, post-stroke epilepsy has been identified as a significant clinical issue in stroke
survivors and stroke is the most common cause of epilepsy in older adults and for patients
aged more than 65, post-stroke epilepsy accounts for 30-50% of new-onset seizures. Our
previous study documented seizures during stroke presentation and during hospitalization
would worsen the overall morbidity and mortality, suggesting the importance of awareness in
seizure care in acute ischemic stroke.
As current studies only focus on anti-seizure/anti-convulsion after the appearance of
late-onset seizures, without the intervention of the epileptogenesis, it is important to
develop a potential novel prophylactic treatment on patients with acute severe stroke to
prevent from late occurrence of seizures and epilepsy.
We have previously done researches on the medications that might have potential of
anti-epileptogenesis in pilocarpine-induced animal models, supporting the concept of
antiepileptogenesis, giving intervention immediately following a brain insult.
The results of some earlier anecdotal reports or small studies on prophylactic use of
antiepileptic drug (AED) therapy in stroke, either hemorrhagic or ischemic strokes, remain
inconclusive. There still lacks a well-established case-control study on prophylaxis of
post-stroke epilepsy, with the early intervention of AED therapy with potential of
anti-epileptogenesis in the phase of epileptogenesis.
Based on our clinical experience, and laboratory researches, we have noted two
non-conventional AEDs, levetiracetam (LEV) and perampanel (PER) with potential of
anti-epileptogenesis. It is justified to evaluate if early administration of LEV or PER in
patients with acute major stroke as a prophylactic therapy could hamper the development of
epileptogenesis and the later post-stroke epilepsy.
We aim to conduct a randomized case-control study to evaluate if early prophylactic
introduction of low dose AED therapy (LEV or PER) in patients with moderate to severe middle
cerebral artery infarct, could prevent the development of post-stroke epilepsy (primary
prevention).
Description:
Advance in stroke treatment have resulted in a dramatic reduction in the stroke mortality,
however, the number of stroke survivors living with morbidity has increased significantly.
Among the morbidities, seizures and epilepsy are not uncommon and post-stroke epilepsy has
been identified as a significant clinical issue in stroke survivors. As we know, stroke is
the most common cause of epilepsy in older adults and for patients aged more than 65,
post-stroke epilepsy accounts for 30-50% of new-onset seizures (Tanaka and Ihara, 2017). The
incidence of early seizures (occurring within the first 1-2 weeks of stroke) is between
2.4-5.4% and the risk of post-stroke late seizures (seizures occur later than 14 days of
stroke) is around 7-18% (Shetty, 2013; Tanaka and Ihara, 2017). The stroke severity, location
and type of pathological changes, genetic factors and pre-injury and post-injury exposure to
non-genetic factors such as exposome can divide patients with ischemic stroke into different
susceptibility (Pitkanen et al., 2016) and the standardized morbidity rate of developing
epilepsy is highest during the first year. Our previous study also documented seizures during
stroke presentation and during hospitalization would worsen the overall morbidity and
mortality (Huang et al., 2014), suggesting the importance of awareness in seizure care in
acute ischemic stroke. In addition, studies showed higher National Institutes of Health
Stroke Scale (NIHSS) score, cortical involvement younger age, central nervous system (CNS)
morbidities are associated with higher risk of post-stroke epilepsy (Tanaka and Ihara, 2017).
Occurrence of post-stroke epileptic seizure would lead to long-term poor prognosis and
increased mortality (Bladin et al., 2000; Labovitz et al., 2001), and the post-stroke
epilepsy has a high recurrence rate (Tanaka et al., 2017), which might lead to anxiety and
worsen quality of life in the stroke survivors. As current treatments only focus on
anti-seizure/anti-convulsion, based on our understanding of the epileptogenesis, we aim to
develop a potential prophylactic treatment on patients with acute severe stroke to prevent
from late occurrence of seizures and epilepsy.
Process of epileptogenesis is classically thought to occur in three phases: first the
occurrence of a precipitating injury or event; second, a 'latent' period during which changes
set in motion by the preceding injury act to transform the previously normal brain into an
epileptic brain; and third, chronic, established epilepsy. It is during the latent period
that the process of acquired epileptogenesis is thought to coalesce, and it is at this point
in the process that interventions might be used to prevent the subsequent development of
epilepsy (Goldberg and Coulter, 2013; Kikuyama et al., 2017). We have previously done
researches on the medications that might have potential of anti-epileptogenesis in
pilocarpine-induced animal models, supporting the concept of anti-epileptogenesis, giving
intervention immediately following a brain insult (Lai et al., 2018, Hung et al., 2019).
Potential medications with potential of anti-epileptogenesis Based on our clinical
experience, and laboratory researches (Huang et al., 2009, 2013; Lai et al., 2018; Hung et
al., 2019), we have noted two newer AEDs with potential of anti-epileptogenesis. LEV, a
current standard AED with a distinct synaptic vesicle modulating mechanism, has been
demonstrated its potential in ameliorating epileptogenesis (Itoh et al., 2016; Kikuyama et
al., 2017). Synaptic vesicle 2A (SV2A) is considered to play an important role for synaptic
vesicle recycling and neurotransmitter excretion to the synaptic cleft, because mice lacking
SV2A failed to grow, experienced severe seizures, and died within 3 weeks (Crowder et al.,
1999). A clear correlation was seen between the affinity of LEV and its analogues to SV2A and
the potency of their antiseizure protection in the mouse audiogenic model of epilepsy (Lynch
et al., 2004). Furthermore, the LEV-treated adult male Node epileptic rats showed a
significant increase of Bax/Bcl-2 mRNA expression ratio in the prefrontal cortex than the
control group, but no change in the Bax/Bcl-2 mRNA expression ratio in hippocampus,
suggesting the mechanism of acquired anti-epileptogenesis by LEV may be similar to
spontaneous recovery of idiopathic generalized epilepsy during adolescence (Kikuyama et al.,
2017). Our earlier study suggests its broad spectrum of modulating neuronal excitability
(Huang et al., 2009). It is not metabolized through the P-450 hepatic cytochrome system and
has not clinically relevant drug-drug interactions (Rosati et al., 2010). It has also been
suggested as a first-choice drug against post-stroke seizures, based on safety and efficacy
profiles in clinical studies (Belcastro et al., 2008). Thus, it is potentially worth
investigation in primary prevention for patients with acute major stroke.
Perampanel (PER), a current standard antiepileptic drug with a distinct mechanism of
selective non-competitive antagonist of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic
acid (AMPA)-type receptors, has also been demonstrated its efficacy in treatment
wide-spectrum epileptic seizures with good tolerability profile (Tyrlikova et al., 2008).
Based on its block of glutamate excitotoxicity, PER is theoretically capable of modulating
epileptogenesis and it has been demonstrated its potential in ameliorating epileptogenesis
(Mohammad et al., 2019; Dupuis et al., 2017). As we know, the AMPA receptor has become a
therapeutic target due to its involvement in ictogenesis and epileptogenesis. GluA2 subunit
plays a role in calcium permeability. Thereby, AMPA receptor-mediated calcium signaling
increases affects brain excitability. Recent report indicated that perampanel can block both
calcium permeable and calcium in permeable AMPA receptors (Barygin et al., 2016). Our recent
study on PER pharmacology also revealed it, for the first time, could inhibit voltage-gated
sodium channels, suggesting its broad-spectrum properties in modulating neuronal excitability
(Lai et al., 2019). Thus, it is potentially justified to evaluate if early administration of
PER in patients with acute major stroke as a prophylactic therapy could hamper the
development of epileptogenesis and the later post-stroke epilepsy.
Purpose of our study We aim to investigate if early administration of AEDs with potential
anti-epileptogenesis could prevent the development of post-stroke epilepsy (primary
prevention).
References:
1. Barygin OI. Inhibition of calcium-permeable and calcium impermeable AMPA receptors by
perampanel in rat brain neurons. Neurosci Lett 2016;633:146-151.
2. Belcastro V, Costa C, Galletti F, Autuori A, Pierguidi L, Pisani F, Calabresi P,
Parnetti L. Levetiracetam in newly diagnosed late-onset post-stroke seizures: a
prospective observational study. Epilepsy Res 2008;82:223-6.
3. Bladin CF, Alexandrov AV, Bellavance A, Bornstein N, Chambers B, Cote R, Lebrun L,
Pirisi A, Norris JW. Seizures after stroke: a prospective multicenter study. Arch Neurol
2000;57:e1617-22.
4. Crowder KM, Gunther JM, Jones TA, et al. Abnormal neurotransmission in mice lacking
synaptic vesicle protein 2A (SV2A). Proc Natl Acad Sci USA 1999;96:15268-73.
5. Dupuis N, Enderlin J, Thomas J, Desnous B, Dournaud P, Allorge D, Auvin S.
Anti-ictogenic and antiepileptogenic properties of perampanel in mature and immature
rats. Epilepsia 2017;58:1985-92.
6. Goldberg E, Coulter D. Mechanisms of epileptogenesis: a convergence on neural circuit
dysfunction. Nat Rev Neurosci. 2013;14:337-49.
7. Huang CW, Cheng JT, Tsai JJ, Wu SN, Huang CC. Diabetic hyperglycemia aggravates seizures
and status epilepticus-induced hippocampal damage. Neurotox Res 2009;15:71-81.
8. Huang CW, Tsai JJ, Huang CC, Wu SN. Experimental and simulation studies on the
mechanisms of Levetiracetam-mediated inhibition of delayed-rectifier potassium current
(Kv3.1): Contribution to the firing of action potentials. J Physiol Pharmacol
2009;60:37-47.
9. Huang CW, Lai MC, Cheng JT, Tsai JJ, Huang CC, Wu SN. Pregabalin attenuates
excitotoxicity in diabetes. PLOS One 2013;8:e65154-60.
10. Huang CW, Saposnik G, Fang J, Steven DA, Burneo JG. Influence of seizures on stroke
outcomes: a large multicenter study. Neurology 2014;82:768-76.
11. Hung TY, Chu FL, Wu DC, Wu SN, Huang CW. The protective role of peroxisome
proliferator-activated receptor-gamma in seizure and neuronal excitotoxicity. Mol
Neurobiol 2019;56:5497-506.
12. Ikeda K, Sawada M, Morioka H, Kyuzen M, Ebina J, Nagasawa J, Yanagihashi M, Miura K,
Ishikawa Y, Hirayama T, Takazawa T, Kano O, Kawabe K, Iwasaki Y. Clinical Profile and
Changes of Serum Lipid Levels in Epileptic Patients after Cerebral Infarction. J Stroke
Cerebrovasc Dis 2017;26:644-9.
13. Itoh K, Ishihara Y, Komori R. Levetiracetam treatment influences blood-brain barrier
failure associated with angiogenesis and inflammatory responses in the acute phase of
epileptogenesis in post-status epilepticus mice. Brain Res 2016;1652:1-13.
14. Kikuyama H, Hanaoka T, Kanazawa T, Yoshida Y, Mizuno T, Toyoda H, Yoneda H. The
Mechanism of Anti-Epileptogenesis by Levetiracetam Treatment is Similar to the
Spontaneous Recovery of Idiopathic Generalized Epilepsy during Adolescence. Psychiatry
Investig 2017;14:844-50.
15. Labovitz DL, Hauser WA, Sacco RL. Prevalence and predictors of early seizure and status
epilepticus after first stroke. Neurology 2001;57:200-6.
16. Lai MC, Hung TY, Lin KM, Sung PS, Wu SJ, Yang CS, Wu YJ, Jsai JJ, Wu SN, Huang CW.
Sodium Metabisulfite: Effects on Ionic Currents and Excitotoxicity. Neurotox Res
2018;34:1-15.
17. Lai MC, Lin KM, Yeh PS, Wu SN, Huang CW. The novel effect of immunomodulator-glatiramer
acetate on epileptogenesis and epileptic seizures. Cell Physiol Biochem 2018;50:150-68.
18. Lai MC, Tzeng RC, Huang CW, Wu SN. The Novel Direct Modulatory Effects of Perampanel, an
Antagonist of AMPA Receptors, on Voltage-Gated Sodium and M-type Potassium Currents.
Biomolecules 2019;9 pii: E638.
19. Lynch BA, Lambeng N, Nocka K, et al. The synaptic vesicle protein SV2A is the binding
site for the antiepileptic drug levetiracetam. Proc Natl Acad Sci U S A 2004;101:9861-6.
20. Mohammad H, Sekar S, Wei Z, Moien-Afshari F, Taghibiglou C. Perampanel but Not
Amantadine Prevents Behavioral Alterations and Epileptogenesis in Pilocarpine Rat Model
of Status Epilepticus. Mol Neurobiol 2019;56:2508-23.
21. Morgenstern LB, Hemphill JC 3rd, Anderson C, Becker K, Broderick JP, Connolly ES Jr,
Greenberg SM, Huang JN, Macdonald RL, Messe SR, Mitchell PH, Selim M, Tamargo RJ.
Guidelines for the Management of Spontaneous Intracerebral Hemorrhage. A Guideline for
Healthcare Professionals From the American Heart Association/American Stroke
Association. Stroke. 2010;41:2108-29.
22. Pitkanen A, Schwartzkroin PA, Moshe SM. Models of seizures and epilepsy. Burlington:
Elsevier Academic Press. 2006.
23. Pitkanen A, Roivainen R, Lukasiuk K. Development of epilepsy after ischemic stroke.
Lancet Neurol 2016;15:185-97.
24. Rosati A, Buttolo L, Stefini R. Efficacy and safety of levetiracetam in patients with
glioma. Arch Neurol 2010;67:343-6.
25. Shetty A. Prospects of levetiracetam as a neuroprotective drug against status
epilepticus, traumatic brain injury, and stroke. Front Neurol 2013;4:1-6.
26. Tanaka T, Ihara M. Post-stroke epilepsy. Neurochem Int 2017;107:219-28.
27. Tyrlikova I, Brazdil M, Rektor I, Tyrlik M. Perampanel as monotherapy and adjunctive
therapy for focal onset seizures, focal to bilateral tonic-clonic seizures and as
adjunctive therapy of generalized onset tonic-clonic seizures. Expert Rev Neurother
2018;18:1-12.
