199. Drug-Induced Myoclonus: A Systematic Review

Article type: Literature Review
Article title: Drug-Induced Myoclonus: A Systematic Review

Journal: Medicina
Year: 2025
Authors: Jamir Pitton Rissardo, Ana Letícia Fornari Caprara, Nidhi Bhal, Rishikulya Repudi, Lea Zlatin, and Ian M. Walker
E-mail: jamirrissardo@gmail.com

ABSTRACT
Background and Objectives: Myoclonus is already associated with a wide variety of drugs and systemic conditions. As new components are discovered, more drugs are suspected of causing this disabling abnormal involuntary movement. This systematic review aims to assess the medications associated with drug-induced myoclonus (DIM). Materials and Methods: Two reviewers assessed the PubMed database using the search term “myoclonus”, without language restriction, for articles published between 1955 and 2024. The medications found were divided into classes and sub-classes, and the subclasses were graded according to their level of evidence. Results: From 12,097 results, 1115 were found to be DIM. The subclasses of medications with level A evidence were intravenous anesthetics (etomidate), cephalosporins (ceftazidime, cefepime), fluoroquinolones (ciprofloxacin), selective serotonin reuptake inhibitors (citalopram, escitalopram, paroxetine, sertraline), tricyclic antidepressant (amitriptyline), glutamate antagonist (amantadine), atypical antipsychotics (clozapine, quetiapine), antiseizure medications (carbamazepine, oxcarbazepine, phenytoin, gabapentin, pregabalin, valproate), pure opioid agonist (fentanyl, morphine), bismuth salts, and mood stabilizers (lithium). The single medication with the highest number of reports was etomidate. Drug-induced asterixis is associated with a specific list of medications. The neurotransmitters likely involved in DIM are serotonin, dopamine, gamma-aminobutyric acid (GABA), and glutamate. Conclusions: DIM may be reversible with management that can include drug discontinuation, dose adjustment, and the prescription of a medication used to treat idiopathic myoclonus. Based on the main clinical constellation of symptoms and pathophysiological mechanisms found in this study, DIM can be categorized into three types: type 1 (serotonin syndrome), type 2 (non-serotonin syndrome), and type 3 (unknown).
Keywords: myoclonus; neurotoxicity; encephalopathy; drug-induced myoclonus; adverse effect; myoclonus/chemically induced; antidepressant-induced myoclonus; opioid-induced myoclonus; anti-seizure medication-induced myoclonus; antibiotic-induced myoclonus

Full text available at:

DOI

Citation
Rissardo JP, Fornari Caprara AL, Bhal N, Repudi R, Zlatin L, Walker IM. Drug-Induced Myoclonus: A Systematic Review. Medicina 2025;61(1):131.

Abstract Figure. Drug-induced myoclonus (DIM). Abbreviations: ASM, antiseizure medications; CBZ, carbamazepine; GABA, gamma-aminobutyric acid; GBP, gabapentin; IV, intravenous; OXC, oxcarbazepine; PGB, pregabalin; PHT, phenytoin; SSRIs, selective serotonin reuptake inhibitors; TCA, tricyclic antidepressants; VPT, valproate.

Figure 1. PRISMA flowchart of the screening process.

Figure 2. Classification of drug-induced myoclonus based on possible pathophysiological mechanisms.

Figure 3. Algorithm of management of drug-induced myoclonus.

Table 1. Drug-induced myoclonus and level of evidence.

Table 2. Proposed mechanisms for drug-induced myoclonus.

Table 3. Proposed classification for drug-induced myoclonus.

Table S1. Articles of Myoclonus Associated with Drugs in PubMed.

Table S2. Anesthetic-Induced Myoclonus.

Table S3. Antibiotic-Induced Myoclonus.

Table S4. Antidepressant-Induced Myoclonus.

Table S5. Antipsychotic-Induced Myoclonus.

Table S6. Antiseizure Medication-Induced Myoclonus.

Table S7. Opioid-Induced Myoclonus.

Table S8. Drug-Induced Asterixis.

198. Accepted

197. Galantamine-memantine combination in the treatment of Parkinson’s disease dementia

Article type: Literature Review

Article title: Galantamine-Memantine Combination in the Treatment of Parkinson’s Disease Dementia

Journal: Brain Science
Year: 2024

Authors: Emma D. Frost, Swanny X. Shi, Vishnu V. Byroju, Jamir Pitton Rissardo, Jack Donlon, Nicholas Vigilante, Briana P. Murray, Ian M. Walker, Andrew McGarry, Thomas N. Ferraro, Khalid A. Hanafy, Valentina Echeverria, Ludmil Mitrev, Mitchel A. Kling, Balaji Krishnaiah, David B. Lovejoy, Shafiqur Rahman, Trevor W. Stone, and Maju Mathew Koola
E-mail: jamirrissardo@gmail.com

ABSTRACT
Parkinson’s disease (PD) is a progressive neurodegenerative disorder that affects over 1% of population over age 60. It is defined by motor and nonmotor symptoms including a spectrum of cognitive impairments known as Parkinson’s disease dementia (PDD). Currently, the only US Food and Drug Administration-approved treatment for PDD is rivastigmine, which inhibits acetylcholinesterase and butyrylcholinesterase increasing the level of acetylcholine in the brain. Due to its limited efficacy and side effect profile, rivastigmine is often not prescribed, leaving patients with no treatment options. PD has several derangements in neurotransmitter pathways (dopaminergic neurons in the nigrostriatal pathway, kynurenine pathway (KP), acetylcholine, α7 nicotinic receptor, and N-methyl-D-aspartate (NMDA) receptors) and rivastigmine is only partially effective as it only targets one pathway. Kynurenic acid (KYNA), a metabolite of tryptophan metabolism, affects the pathophysiology of PDD in multiple ways. Both galantamine (α7 nicotinic receptor) and memantine (antagonist of the NMDA subtype of the glutamate receptor) are KYNA modulators. When used in combination, they target multiple pathways. While randomized controlled trials (RCTs) with each drug alone for PD have failed, the combination of galantamine and memantine has demonstrated a synergistic effect on cognitive enhancement in animal models. It has therapeutic potential that has not been adequately assessed, warranting future randomized controlled trials. In this review, we summarize the KYNA-centric model for PD pathophysiology and discuss how this treatment combination is promising in improving cognitive function in patients with PDD through its action on KYNA.

Keywords: cognition; drug combination; galantamine; kynurenic acid; memantine; N-acetylcysteine; neuropharmacology; Parkinson’s disease dementia; Parkinson’s disease treatment

Full text available at:
https://www.mdpi.com/2076-3425/14/12/1163

DOI
https://doi.org/10.3390/brainsci14121163

Citation
Frost ED, Shi SX, Byroju VV, Rissardo JP, Donlon J, Vigilante N, et al. Galantamine-memantine combination in the treatment of Parkinson’s disease dementia. Brain Sci 2024;14:1163.

Figure 1. Kynurenine pathway. An abbreviated depiction of the kynurenine pathway showing the major steps.

Figure 2. Overview of the kynurenine pathway in the brain and its effects. Depiction of the differential expression of the KP in cells of the central nervous system. Astrocytes lack the full complement of KP enzymes, hence KP activation in astrocytes terminates in the production of neuroprotective KYNA. However, as microglia fully express KP enzymes, KP activation in microglia can result in the production of neurotoxic metabolites 3-HK and QUIN. KP = Kynurenine Pathway; TRP = Tryptophan; KYNA = Kynurenic Acid; IDO = Indoleamine 2,3-dioxygenase; TDO = Tryptophan-2,3-dioxygenase; QUIN = Quinolinic Acid; 3-HAA = 3 Hydroxyanthranilic Acid; 3-HK = 3-hydroxykynurenine; KMO = Kynurenin-3-monooxygenase; KYN = Kynurenine.

Figure 3. Kynurenine pathway-centric pathophysiology model. Depiction of some of the receptors, pathways, and processes affected by increased levels of major kynurenine pathway metabolites KYN, KYNA, 3-HK, and QUIN after pathway activation. AhR = aryl hydrocarbon receptor; α7nAChR = Alpha7 nicotinic receptor; BCL-2 = B-cell Lymphoma 2; GABA = γ-aminobutyric acid; KYN = Kynurenine; KYNA = Kynurenic Acid; NMDA = N-methyl-D-aspartate; QUIN = Quinolinic Acid; 3-HK = 3-hydroxykynurenine. ↑, increased process; ↓, decreased process.

Figure 4. Magic bullet versus shotgun approach. The magic bullet approach has long been thought to be the answer to treating complex medical conditions. Pharmaceutical companies hoped that they would be able to develop a single drug to treat many conditions. However, this has failed countless times. We argue that the shotgun approach is more effective. Using multiple drugs (shotgun approach) to target multiple pathways implicated in a disease is likely to a more effective treatment approach.

Table 1. Meta-analyses of randomized controlled trials in schizophrenia: potential medications in Parkinson’s disease (PD).

196. Rasmussen Encephalitis: Clinical Features, Pathophysiology, and Management Strategies—A Comprehensive Literature Review

Article type: Literature Review

Article title: Rasmussen Encephalitis: Clinical Features, Pathophysiology, and Management Strategies—A Comprehensive Literature Review

Journal: Medicina
Year: 2024
Authors: Ana Leticia Fornari Caprara, Jamir Pitton Rissardo, Eric P. Nagele
E-mail: jamirrissardo@gmail.com

ABSTRACT
Rasmussen encephalitis (RE) is a rare and progressive form of chronic encephalitis that typically affects one hemisphere of the brain and primarily occurs in pediatric individuals. The current study aims to narratively review the literature about RE, including historical information, pathophysiology, and management of this condition. RE often occurs in individuals with normal development, and it is estimated that only a few new cases are identified each year in epilepsy centers. Approximately 10% of cases also occur in adolescents and adults. The hallmark feature of RE is drug-resistant focal seizures that can manifest as epilepsia partialis continua. Also, patients with RE usually develop motor and cognitive impairment throughout the years. Neuroimaging studies show progressive damage to the affected hemisphere, while histopathological examination reveals T-cell-dominated encephalitis with activated microglial cells and reactive astrogliosis. The current therapy guidelines suggest cerebral hemispherotomy is the most recommended treatment for seizures in RE, although significant neurological dysfunction can occur. Another option is pharmacological management with antiseizure medications and immunomodulatory agents. No significant progress has been made in understanding the pathophysiology of this condition in the last decades, especially regarding genetics. Notably, RE diagnosis still depends on the criteria established by Bien et al., and the accuracy can be limited and include genetically different individuals, leading to unexpected responses to management.

Keywords: rasmussen encephalitis; rasmussen syndrome; encephalitis; epilepsy; hypometabolism; epilepsia partialis continua; refractory epilepsy; cerebral hemiatrophy

Citation
Fornari Caprara AL, Rissardo JP, Nagele EP. Rasmussen Encephalitis: Clinical Features, Pathophysiology, and Management Strategies—A Comprehensive Literature Review. Medicina 2024; 60:1858.
Figure 1. The natural history of Rasmussen’s encephalitis.

Figure 2. Schematic diagram of the proposed mechanisms for the drugs related to Rasmussen’s encephalitis management. 1—Inhibition of lymphocyte T proliferation (tacrolimus, mycophenolate mofetil, and azathioprine). 2—Diapedesis blockage (natalizumab). 3—Pro-inflammatory cytokines blockage (adalimumab, anakinra, and infliximab). 4—Antibody blockage/ clearance (intravenous immunoglobulin, plasmapheresis, and adsorption). 5—Inhibition of lymphocyte B proliferation (rituximab). 6—Inhibition of T and B lymphocytes (alemtuzumab, mitoxantrone, cyclophosphamide). 7—Unknown etiology (ganciclovir). 8—Broad-spectrum anti-inflammatory action (corticosteroids).

Figure 3. Management of Rasmussen’s encephalitis. First, surgery eligibility should be assessed. Second, medical treatment can be used independent of the indication of the surgical procedure. The first-line therapies are corticosteroids ± intravenous immunoglobulin (IVIg) ± plasmapheresis/immunoadsorption. Second-line therapies are related to targeting lymphocytes, pro-inflammatory cytokines, and other mechanisms. The data is scarce in providing specific definitions for most second-line therapies in RE.

Table 1. Histological classification proposed by Robitaille et al. (1991)

Table 2. Neuroimaging stages of Rasmussen’s encephalitis proposed by Bien et al. (2005)



Table 3. Clinical criteria for Rasmussen encephalitis, adapted from Bien et al. (2005)

Table 4. Critical analysis of cases described by Olson et al. (2013)

Table 5. Medical treatment of Rasmussen’s encephalitis.

Table 6. Seizure outcomes in children with Rasmussen’s encephalitis undergoing resective or hemispheric epilepsy surgery.

Table 7. Cognitive outcome after hemispherectomy in patients with RE.

Table 8. Differential diagnosis of RE and explorations, adapted from Bien et al. (2005)

Table 9. Neuroimaging of some cerebral hemi-atrophy causes.

Visual syndromes & cortical blindness

Visual syndromes related to cortical blindness

Syndromes
Anton syndrome
Balint syndrome
Charles Bonet
Capgras delusion
Cortical blindness
Fregoli syndrome
Prosopagnosia
Riddoch syndrome
Subjective doubles
Visual agnosia


Anton versus Charles Bonet
Anton - no insight, cortical lesion
Charles bonnet - insight, cataracts

Stroke - Lipids

Stroke - Lipids

Atorvastatin
10 mg/d - no stroke and LDL at goal, or stroke and low LDL
20 mg/d - stroke and LDL is at goal
80 mg/d -  stroke and LDL high or undefined

DSA - Preprocedure

Digital subtraction angiography - Pre-procedure
António Caetano de Abreu Freire Egas Moniz
Portuguese neurologist and the developer of cerebral angiography

Definition
- DSA means that everything that is not moving is subtracted

Pre-procedure
- anesthesia evaluation
> NPO for 6 hours
- informed consent
> if medical emergency, consent can be waived
- foley catheter insertion after anesthesia
- proper patient positioning
- handwashing
- cleaning of puncture site
- draping

Instrumentation
- test equipament w/ NS heparinized

Access needle
- size 18/19 G
- one versus two versus micro-puncture
one-piece
> sharp, guidewire direct introduction, both A&V access
two-piece
> blunt, before guidewire remove stylet, arterial access
micro-puncture
> small access, use dilator
- dilator
> plastic catheter for dilation

Sheaths
> open at one end w/ capped hemostatic valve in the other
> prevent bleeding

Guidewires
- double-cover, preventing unwinding if it breaks
- lower G than access
- SIM1, SIM2

Contrast
- normal eGFR - up to 800 ml omnipaque
- CKD - iodixanol

Radiation safety
- lead apron
- radiation monitoring batch

Technique
- every time you remove the catheter, you need to double-flush
- long-run or road map
- only two ways to manipulate cattheter, in-out or rotation

Stroke - Afib and LAAL and LAAO

Stroke - Afib and LAAL and LAAO

Considerations
- stroke due to Afib after full anticoagulation
- stroke due to Afib and cannot use anticoagulation

LAAO and LAAL
LAAO
- watchman and amulet

LAAL
- lariat and sierra


Clinical trial - APLS and stroke

Clinical trial - APLS and stroke

Clinical trials
APASS-WARSS (2004)
- warfarin has the same effect of ASA in preventing ischemic episodes

RAPS (2016)
- warfarin has the same effect of rivaroxaban in preventing ischemic episodes

TRAPS (2018)
- warfarin is superior to rivaroxaban in preventing ischemic episodes

ASTRO-APS (2022)
- warfarin is superior to rivaroxaban in preventing ischemic episodes

RISAPS (ongoing)
- warfarin versus rivaroxaban

Clinical trial - apixaban and stroke

Clinical trial - apixaban and stroke

Clinical trials
ARISTOTLE (2011)
- apixaban is superior to warfarin in stroke prevention and lower bleeding

AVERROES (2011)
- apixaban is superior to ASA in stroke prevention and same bleeding risk

ARISTOTLE INR (2014)
apixaban is superior to warfarin in stroke prevention and lower bleeding

AUGUSTUS (2019)
- apixaban monotherapy is superior to VKA or a combination of apixaban to ASA, regarding bleeding risk
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