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Background Lafora disease (LD) is a rare fatal autosomal recessive form of progressive myoclonus epilepsy. It affects previously healthy children or adolescents, causing pharmacoresistant epilepsy, myoclonus and severe psychomotor deterioration. This work aims to describe the clinical course of LD and identify predictors of outcome by means of a prognostic systematic review with individual participant data meta-analysis. Methods A search was conducted on MEDLINE and Embase with no restrictions on publication date. Only studies reporting genetically confirmed LD cases were included. Kaplan–Meier estimate was used to assess probability of death and loss of autonomy. Univariable and multivariable Cox regression models with mixed effects (clustered survival data) were performed to evaluate prognostic factors. Results Seventy-three papers describing 298 genetically confirmed LD cases were selected. Mean age at disease onset was 13.4 years (SD 3.7), with 9.1% aged ≥ 18 years. Overall survival rates in 272 cases were 93% [95% CI 89–96] at 5 years, 62% [95% CI 54–69] at 10 years and 57% [95% CI 49–65] at 15 years. Median survival time was 11 years. The probability of loss of autonomy in 110 cases was 45% [95% CI 36–55] at 5 years, 75% [95% CI 66–84] at 10 years, and 83% [95% CI 74–90] at 15 years. Median loss of autonomy time was 6 years. Asian origin and age at onset < 18 years emerged as negative prognostic factors, while type of mutated gene and symptoms at onset were not related to survival or disability. Conclusions This study documented that half of patients survived at least 11 years. The notion of actual survival rate and prognostic factors is crucial to design studies on the effectiveness of upcoming new disease-modifying therapies.

Lisa Taruffi,1 Lorenzo Muccioli,2 Francesca Bisulli1,2 1IRCCS Istituto delle Scienze Neurologiche di Bologna, Bologna, Italy; 2Department of Biomedical and Neuromotor Sciences, University of Bologna, Bologna, ItalyCorrespondence: Lorenzo Muccioli, Email lorenzo.muccioli@gmail.com

Background Complete resection of the epileptogenic zone (EZ) is the strongest predictor of seizure freedom in drug-resistant epilepsy (DRE). However, even in MRI-positive cases with anatomo-electro-clinical concordance, the EZ may not be clearly delineated, complicating intraoperative decision-making. Intraoperative ultrasound (ioUS) provides real-time anatomical feedback, while depth-electrode intraoperative electrocorticography (iECoG) enables electrophysiological delineation of epileptogenic tissue beyond the cortical surface, sampling deep regions not accessible to subdural electrodes. Their integration may improve intraoperative precision in defining resection limits and optimizing resective surgery. Methods This study describes the workflow and feasibility of combining ioUS and depth-electrode iECoG for intraoperative guidance in MRI-positive focal DRE with an ill-defined EZ. In all cases, concordant anatomo-electro-clinical data identified a single EZ for which SEEG was not required, yet the suspected EZ remained poorly delineated. ioUS was used for real-time lesion visualization, verification of electrode trajectories, and guidance of resection depth and extent. Pre- and post-resective depth-electrode iECoG and ioUS were used in combination to delineate the resection margins, by identifying interictal epileptiform discharges (IEDs) and confirming lesion boundaries and resection completeness. Results Six patients underwent resective surgery using the combined ioUS–iECoG workflow. The technique was feasible and safe in all cases, with no intraoperative or postoperative complications (37 depth-electrode insertions). iECoG revealed IEDs in four patients (66%), prompting resection extension in two. MRI confirmed complete resection in all cases. At last follow-up (6–40 months), 5/6 patients were seizure-free (Engel I). Histopathology revealed FCD IIb in three cases, a gliotic lesion related to an encephalocele in one, a gliotic scar post–arachnoid cyst marsupialization in another, and a tuberous sclerosis–related lesion in a case of tuberous-sclerosis-complex. Conclusion The integration of ioUS and depth-electrode iECoG offers real-time anatomical and electrophysiological data, refining EZ delineation and resection assessment in complex MRI-positive epilepsy cases where SEEG is not clinically indicated.

Objective Many neurological manifestations are associated with COVID‐19, including a distinct form of encephalopathy related to cytokine storm, the acute systemic inflammatory syndrome present in a subgroup of COVID‐19 patients. Cytokine storm is also associated with immune effector cell‐associated neurotoxicity syndrome (ICANS), a complication of chimeric antigen receptor T‐cell (CAR‐T) therapy, a highly effective treatment for refractory hematological malignancies. We investigated whether COVID‐19‐related encephalopathy, ICANS, and other encephalopathies associated with cytokine storm, share clinical and investigative findings. Methods Narrative literature review. Results Comparisons between COVID‐19‐related encephalopathy and ICANS revealed several overlapping features. Clinically, these included dysexecutive syndrome, language disturbances, akinetic mutism and delirium. EEG showed a prevalence of frontal abnormalities. Brain MRI was often unrevealing. CSF elevated cytokine levels have been reported. A direct correlation between cytokine storm intensity and severity of neurological manifestations has been shown for both conditions. Clinical recovery occurred spontaneously or following immunotherapies in most of the patients. Similar clinical and investigative features were also reported in other encephalopathies associated with cytokine storm, such as hemophagocytic lymphohistiocytosis, sepsis, and febrile infection‐associated encephalopathies. Interpretation COVID‐19‐related encephalopathy and ICANS are characterized by a predominant electro‐clinical frontal lobe dysfunction and share several features with other encephalopathies associated with cytokine storm, which may represent the common denominator of a clinical spectrum of neurological disorders. Therefore, we propose a unifying definition of cytokine storm‐associated encephalopathy (CySE), and its diagnostic criteria.

ObjectiveTo report on efficacy and safety of intravenous immunoglobulin (IVIg) therapy in a case series of patients with COVID-19-related encephalopathy.MethodsWe retrospectively collected data on all patients with COVID-19 hospitalized at two Italian hospitals who developed encephalopathy during disease course and were treated with IVIg.ResultsFive patients (two females, mean age 66.8 years) developed encephalopathy after a mean of 12.6 days, since the onset of respiratory/constitutional symptoms related to COVID-19. Four patients suffered severe respiratory distress, three of which required invasive mechanical ventilation. Neurological manifestations included impaired consciousness, agitation, delirium, pyramidal and extrapyramidal signs. EEG demonstrated diffuse slowing in all patients. Brain MRI showed non-specific findings. CSF analysis revealed normal cell count and protein levels. In all subjects, RT-PCR for SARS-CoV-2 in CSF tested negative. IVIg at 0.4 g/kg/die was commenced 29.8 days (mean, range: 19–55 days) after encephalopathy onset, leading to complete electroclinical recovery in all patients, with an initial improvement of neuropsychiatric symptoms observed in 3.4 days (mean, range: 1–10 days). No adverse events related to IVIg were observed.ConclusionsOur preliminary findings suggest that IVIg may represent a safe and effective treatment for COVID-19-associated encephalopathy. Clinical efficacy may be driven by the anti-inflammatory action of IVIg, associated with its anti-cytokine qualities.

Abstract Objective The differential diagnosis between sleep-related hypermotor epilepsy (SHE) and disorders of arousal (DOA) may be challenging. We analyzed the stage and the relative time of occurrence of parasomnic and epileptic events to test their potential diagnostic accuracy as criteria to discriminate SHE from DOA. Methods Video-polysomnography recordings of 89 patients with a definite diagnosis of DOA (59) or SHE (30) were reviewed to define major or minor events and to analyze their stage and relative time of occurrence. The “event distribution index” was defined on the basis of the occurrence of events during the first versus the second part of sleep period time. A group analysis was performed between DOA and SHE patients to identify candidate predictors and to quantify their discriminative performance. Results The total number of motor events (i.e. major and minor) was significantly lower in DOA (3.2 ± 2.4) than in SHE patients (6.9 ± 8.3; p = 0.03). Episodes occurred mostly during N3 and N2 in DOA and SHE patients, respectively. The occurrence of at least one major event outside N3 was highly suggestive for SHE (p = 2*e-13; accuracy = 0.898, sensitivity = 0.793, specificity = 0.949). The occurrence of at least one minor event during N3 was highly suggestive for DOA (p = 4*e-5; accuracy = 0.73, sensitivity = 0.733, specificity = 0.723). The “event distribution index” was statistically higher in DOA for total (p = 0.012) and major events (p = 0.0026). Conclusion The stage and the relative time of occurrence of minor and major motor manifestations represent useful criteria to discriminate DOA from SHE episodes.

Background Lafora disease (LD) is a rare, lethal, progressive myoclonus epilepsy for which no targeted therapy is currently available. Studies on a mouse model of LD showed a good response to metformin, a drug with a well known neuroprotective effect. For this reason, in 2016, the European Medicines Agency granted orphan designation to metformin for the treatment of LD. However, no clinical data is available thus far. Methods We retrospectively collected data on LD patients treated with metformin referred to three Italian epilepsy centres. Results Twelve patients with genetically confirmed LD (6 EPM2A , 6 NHLRC1 ) at middle/late stages of disease were treated with add-on metformin for a mean period of 18 months (range: 6–36). Metformin was titrated to a mean maintenance dose of 1167 mg/day (range: 500–2000 mg). In four patients dosing was limited by gastrointestinal side-effects. No serious adverse events occurred. Three patients had a clinical response, which was temporary in two, characterized by a reduction of seizure frequency and global clinical improvement. Conclusions Metformin was overall safe in our small cohort of LD patients. Even though the clinical outcome was poor, this may be related to the advanced stage of disease in our cases and we cannot exclude a role of metformin in slowing down LD progression. Therefore, on the grounds of the preclinical data, we believe that treatment with metformin may be attempted as early as possible in the course of LD.

Background Lafora disease (LD) is a fatal form of progressive myoclonic epilepsy caused by biallelic pathogenic variants in EPM2A or NHLRC1 . With a few exceptions, the influence of genetic factors on disease progression has yet to be confirmed. We present a systematic review and meta-analysis of the known pathogenic variants to identify genotype–phenotype correlations. Methods We collected all reported cases with genetically-confirmed LD containing data on disease history. Pathogenic variants were classified into missense (MS) and protein-truncating (PT). Three genotype classes were defined according to the combination of the variants: MS/MS, MS/PT, and PT/PT. Time-to-event analysis was performed to evaluate survival and loss of autonomy. Results 250 cases described in 70 articles were included. The mutated gene was NHLRC1 in 56% and EPM2A in 44% of cases. 114 pathogenic variants (67 EPM2A ; 47 NHLRC1 ) were identified. The NHLRC1 genotype PT/PT was associated with shorter survival [HR 2.88; 95% CI 1.23–6.78] and a trend of higher probability of loss of autonomy [HR 2.03, 95% CI 0.75–5.56] at the multivariable Cox regression analysis. The population carrying the homozygous p.Asp146Asn variant of NHLRC1 genotype was confirmed to have a more favourable prognosis in terms of disease duration. Conclusions This study demonstrates the existence of prognostic genetic factors in LD, namely the genotype defined according to the functional impact of the pathogenic variants. Although the reasons why NHLRC1 genotype PT/PT is associated with a poorer prognosis have yet to be fully elucidated, it may be speculated that malin plays a pivotal role in LD pathogenesis. Key points What is already known on this topic : Lafora disease (LD) is a fatal form of progressive myoclonic epilepsy caused by biallelic pathogenic variants in the EPM2A or NHLRC1 genes. With a few exceptions, the influence of genetic factors on disease progression has yet to be confirmed. What this study adds : The study identified prognostic genetic factors in LD and demonstrated a correlation between certain genotypes and worse prognosis. Specifically, biallelic truncating variants in NHLRC1 were associated with a higher probability of loss of autonomy and shorter survival. The study also confirmed that the homozygous p.Asp146Asn variant of NHLRC1 has a more favourable prognosis. How this study might affect research, practice, or policy : The study sheds light on the potential genetic factors affecting the prognosis of LD, which could inform future research into treatments and therapies. This study’s findings should be taken into account when launching trials of disease-modifying therapies, to ensure that outcomes are correctly interpreted.

We report our single-center experience on the neurological manifestations of long COVID. This is a retrospective observational study. All consecutive patients referred to the neurological long COVID outpatient clinic of our institute from January 21 2021 to December 9 2021 underwent a general neurological objective examination. Treatments and investigations (brain MRI, neuropsychological evaluation, or others) were prescribed on an individual basis as per standard clinical practice. A follow-up visit was performed when appropriate. Descriptive statistics were presented as absolute and relative frequencies for categorical variables and as means, median, and ranges for continuous variables. One hundred and three patients were visited (mean age 50.5 ±36 years, 62 females). The average time from acute COVID-19 infection to the first visit to our outpatient clinic was 243 days. Most patients presented with a mild form of acute COVID-19, with only 24 cases requiring hospitalization. The neurological symptoms mostly (n=70/103, 68%) started during the acute phase (before a negative swab for SARS-CoV-2). The most frequent acute manifestations reported, which lately became persistent, were fatigue (n=58/103, 56%), olfactory/taste dysfunction (n=58/103, 56%), headache (n=47/103, 46%), cognitive disorders (n=46/103, 45%), sleep disorders (n=30/103, 29%), sensitivity alterations (n=29/103, 28%), and dizziness (n=7/103, 7%). Tremor was also reported (n=8/103, 7%). Neuropsychological evaluation was performed in 30 patients and revealed alterations in executive functions (n=6/30, 20%), memory (n=11/30, 37%), with pathological depressive (n=9/30, 30%) and anxiety (n=8/30, 27%) scores. Brain MRIs have been performed in 41 cases, revealing nonspecific abnormal findings only in 4 cases. Thirty-six patients underwent a follow-up, where a general improvement was observed but rarely (n=2/36) a complete recovery. The majority of patients presenting persistent neurological symptoms (most frequently fatigue, cognitive disorders, and olfactory dysfunctions) developed a previous mild form of COVID-19. Further studies are required to develop therapeutic strategies.

Background/Objectives: Lafora disease is a fatal and progressive neurodegenerative disorder characterized by the accumulation of insoluble polyglucosan inclusions, known as Lafora bodies, due to impaired glycogen metabolism. Therapeutic strategies aimed at reducing intracellular glycogen accumulation represent a promising approach to mitigating disease progression. This study aimed to evaluate the feasibility of promoting Lafora body degradation by increasing the protein levels of human pancreatic amylase, a glycogen-degrading enzyme, through the SINEUP approach. Methods: Two SINEUP constructs specifically targeting human pancreatic amylase were designed and tested in continuous tumor-derived cell lines of central nervous system origin, as well as in primary fibroblasts obtained from a patient with Lafora disease. Human pancreatic amylase protein and mRNA levels were assessed to determine the specificity of SINEUP-mediated regulation. Enzymatic activity assays were performed to evaluate functional protein upregulation, and intracellular glycogen content was measured in patient-derived fibroblasts. Results: Both SINEUP constructs significantly increased human pancreatic amylase protein expression without affecting mRNA levels, confirming a post-transcriptional mechanism of action. The elevated protein levels were associated with a significant increase in enzymatic activity. In primary fibroblasts derived from a Lafora disease patient, enhanced amylase expression correlated with a marked reduction in intracellular glycogen content. Conclusions: These findings provide proof of concept that SINEUP-mediated upregulation of glycogen-degrading enzymes may represent a viable therapeutic strategy to counteract Lafora body accumulation. Further studies are warranted to assess the efficacy, safety, and translational potential of this approach, particularly in relevant animal models of Lafora disease.