Miopatía y polineuropatía en el paciente crítico. Estudio PEC : parálisis del enfermo crítico

Alguns pacients ingressats en la Unitat de Cures Intensives (UCI) desenvolupen una debilitat muscular en grau variable que pot arribar fins a la tetraparesia o tretraplejia. Aquesta condició és deguda a una disfunció neuromuscular perifèrica. No existeix consens internacional per al diagnòstic. En aquest treball s'estudien, de manera prospectiva, les alteracions en l'electromiograma i la seva correlació amb l'anatomia patològica del múscul com a mètode diagnòstic de miopatia i/o neuropatia del pacient crític. A més s'avaluen diversos factors predisponents i pronòstics, conseqüències d'aquesta malaltia i el seu moment d'inici.Algunos pacientes ingresados en la Unidad de Cuidados Intensivos (UCI) desarrollan una debilidad muscular en grado variable que puede llegar hasta la tetraparesia o tretraplejia. Esta condición es debida a una disfunción neuromuscular periférica. No existe consenso internacional para el diagnóstico. En este trabajo se estudian las alteraciones en el electromiograma y su correlación con la anatomía patológica del músculo como método diagnóstico de miopatía y/o nueropatía del paciente crítico. Además se evalúan diversos factores predisponentes y pronósticos, consecuencias de esta enfermedad y su momento de inicio

Three-dimensional imaging in myotonic dystrophy type 1

Altres ajuts: The research of G. Nogales-Gadea, A. Ramos-Fransi, and A. Lucia is funded by Instituto de Salud Carlos III and cofinanced by Fondos FEDER. G. Nogales-Gadea is supported by a Miguel Servet research contract and by a Trampoline Grant #21108 from AFM Telethon. A. Ballester-Lopez is funded by an FI Agaur fellowship and Generalitat de Catalunya. E. Koehorst is funded by the La Caixa Foundation (ID 100010434), fellowship code LCF/BQ/IN18/11660019, cofunded by the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement no. 713673. I. Linares-Pardo is funded by CP14/00032 and SGR 1520 (GRC) Generalitat de Catalunya. J. Núñez-Manchón was funded by AFM Telethon Trampoline Grant #21108. G. Lucente was supported by a Rio Hortega contract. J. Chojnacki is supported by European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant . The funding bodies had no role in the design of the study and collection, analysis, and interpretation of data.We aimed to determine whether 3D imaging reconstruction allows identifying molecular:clinical associations in myotonic dystrophy type 1 (DM1). We obtained myoblasts from 6 patients with DM1 and 6 controls. We measured cytosine-thymine-guanine (CTG) expansion and detected RNA foci and muscleblind like 1 (MBNL1) through 3D reconstruction. We studied dystrophia myotonica protein kinase (DMPK) expression and splicing alterations of MBNL1, insulin receptor, and sarcoplasmic reticulum Ca(2+)-ATPase 1. Three-dimensional analysis showed that RNA foci (nuclear and/or cytoplasmic) were present in 45%-100% of DM1-derived myoblasts we studied (range: 0-6 foci per cell). RNA foci represented <0.6% of the total myoblast nuclear volume. CTG expansion size was associated with the number of RNA foci per myoblast (r = 0.876 [95% confidence interval 0.222-0.986]) as well as with the number of cytoplasmic RNA foci (r = 0.943 [0.559-0.994]). Although MBNL1 colocalized with RNA foci in all DM1 myoblast cell lines, colocalization only accounted for 1% of total MBNL1 expression, with the absence of DM1 alternative splicing patterns. The number of RNA foci was associated with DMPK expression (r = 0.967 [0.079-0.999]). On the other hand, the number of cytoplasmic RNA foci was correlated with the age at disease onset (r = −0.818 [−0.979 to 0.019]). CTG expansion size modulates RNA foci number in myoblasts derived from patients with DM1. MBNL1 sequestration plays only a minor role in the pathobiology of the disease in these cells. Higher number of cytoplasmic RNA foci is related to an early onset of the disease, a finding that should be corroborated in future studies

The need for establishing a universal CTG sizing method in myotonic dystrophy type 1

The number of cytosine-thymine-guanine (CTG) repeats (‘CTG expansion size’) in the 3′untranslated region (UTR) region of the dystrophia myotonica-protein kinase (DMPK) gene is a hallmark of myotonic dystrophy type 1 (DM1), which has been related to age of disease onset and clinical severity. However, accurate determination of CTG expansion size is challenging due to its characteristic instability. We compared five different approaches (heat pulse extension polymerase chain reaction [PCR], long PCR-Southern blot [with three different primers sets—1, 2 and 3] and small pool [SP]-PCR) to estimate CTG expansion size in the progenitor allele as well as the most abundant CTG expansion size, in 15 patients with DM1. Our results indicated variability between the methods (although we found no overall differences between long PCR 1 and 2 and SP-PCR, respectively). While keeping in mind the limited sample size of our patient cohort, SP-PCR appeared as the most suitable technique, with an inverse significant correlation found between CTG expansion size of the progenitor allele, as determined by this method, and age of disease onset (r = −0.734, p = 0.016). Yet, in light of the variability of the results obtained with the different methods, we propose that an international agreement is needed to determine which is the most suitable method for assessing CTG expansion size in DM1

Preliminary findings on CTG expansion determination in different tissues from patients with myotonic dystrophy type 1

Myotonic Dystrophy type 1 (DM1) is characterized by a high genetic and clinical variability. Determination of the genetic variability in DM1 might help to determine whether there is an association between CTG (Cytosine-Thymine-Guanine) expansion and the clinical manifestations of this condition. We studied the variability of the CTG expansion (progenitor, mode, and longest allele, respectively, and genetic instability) in three tissues (blood, muscle, and tissue) from eight patients with DM1. We also studied the association of genetic data with the patients’ clinical characteristics. Although genetic instability was confirmed in all the tissues that we studied, our results suggest that CTG expansion is larger in muscle and skin cells compared with peripheral blood leukocytes. While keeping in mind that more research is needed in larger cohorts, we have provided preliminary evidence suggesting that the estimated progenitor CTG size in muscle could be potentially used as an indicator of age of disease onset and muscle function impairment

A DM1 family with interruptions associated with atypical symptoms and late onset but not with a milder phenotype

Carriage of interruptions in CTG repeats of the myotonic dystrophy protein kinase gene has been associated with a broad spectrum of myotonic dystrophy type 1 (DM1) phenotypes, mostly mild. However, the data available on interrupted DM1 patients and their phenotype are scarce. We studied 49 Spanish DM1 patients, whose clinical phenotype was evaluated in depth. Blood DNA was obtained and analyzed through triplet‐primed polymerase chain reaction (PCR), long PCR‐Southern blot, small pool PCR, AciI digestion, and sequencing. Five patients of our registry (10%), belonging to the same family, carried CCG interruptions at the 3’ end of the CTG expansion. Some of them presented atypical traits such as a very late onset of symptoms (&gt;50 years) and a severe axial and proximal weakness requiring walking assistance. They also showed classic DM1 symptoms including cardiac and respiratory dysfunction, which were severe in some of them. Sizes and interrupted allele patterns were determined, and we found a contraction and an expansion in two intergenerational transmissions. Our study contributes to the observation that DM1 patients carrying interruptions present with atypical clinical features that can make DM1 diagnosis difficult, with a later than expected age of onset and a previously unreported aging‐related severe disease manifestation

Genes and exercise intolerance: Insights from McArdle disease

McArdle disease (glycogen storage disease type V) is caused by inherited deficiency of a key enzyme in muscle metabolism, the skeletal-muscle specific isoform of glycogen phosphorylase, 'myophosphorylase', which is encoded by the PYGM gene. Here we review the main pathophysiological, genotypic and phenotypic features of McArdle disease and their interactions. To date, moderate-intensity exercise (together with pre-exercise carbohydrate ingestion) is the only treatment option that has proven useful for these patients. Further, regular physical activity attenuates the clinical severity of McArdle disease. This is quite remarkable for a monogenic disorder that consistently leads to the same metabolic defect at the muscle tissue level, that is, complete inability to use muscle glycogen stores. Further knowledge of this disorder would help patients and enhance understanding of exercise metabolism as well as exercise genomics. Indeed, McArdle disease is a paradigm of human exercise intolerance and PYGM genotyping should be included in the genetic analyses that might be applied in the coming personalized exercise medicine as well as in future research on genetics and exercise-related phenotypes.Sin financiación3.044 JCR (2016) Q2, 26/84 Physiology, 68/167 Genetics and Heredity; Q3, 104/190 Cell Biology1.448 SJR (2016) Q2, 106/351 Genetics, 47/191 PhysiologyNo data IDR 2016UE

A novel mutation in the valosin-containing-protein gene found in a Spanish family

Sin financiación2.651 JCR (2018) Q2, 99/199 Clinical Neurology; Q3, 160/267 Neurosciences0.990 SJR (2018) Q2, 70/165 Neurology, 126/378 Neurology (clinical)No data IDR 2018UE

Myotilinopathy unmasked by statin treatment: A case report

Sin financiación2.393 JCR (2018) Q3, 115/199 Clinical Neurology, 184/261 Neurosciences0.950 SJR (2018) Q2, 134/378 Neurology (clinical), 80/188 Physiology, 45/108 Physiology (medical); Q3, 59/90 Cellular and Molecular NeuroscienceNo data IDR 2018UE

The need for establishing a universal CTG sizing method in myotonic dystrophy type 1

The number of cytosine-thymine-guanine (CTG) repeats (‘CTG expansion size’) in the 3′untranslated region (UTR) region of the dystrophia myotonica-protein kinase (DMPK) gene is a hallmark of myotonic dystrophy type 1 (DM1), which has been related to age of disease onset and clinical severity. However, accurate determination of CTG expansion size is challenging due to its characteristic instability. We compared five different approaches (heat pulse extension polymerase chain reaction [PCR], long PCR-Southern blot [with three different primers sets—1, 2 and 3] and small pool [SP]-PCR) to estimate CTG expansion size in the progenitor allele as well as the most abundant CTG expansion size, in 15 patients with DM1. Our results indicated variability between the methods (although we found no overall differences between long PCR 1 and 2 and SP-PCR, respectively). While keeping in mind the limited sample size of our patient cohort, SP-PCR appeared as the most suitable technique, with an inverse significant correlation found between CTG expansion size of the progenitor allele, as determined by this method, and age of disease onset (r = −0.734, p = 0.016). Yet, in light of the variability of the results obtained with the different methods, we propose that an international agreement is needed to determine which is the most suitable method for assessing CTG expansion size in DM1. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.Sin financiación4.096 JCR (2020) Q2, 65/175 Genetics & Heredity1.337 SJR (2020) Q2, 99/340 GeneticsNo data IDR 2019UE