[Neuronal ceroid lipofuscinosis. Type 6 late infantile variant in two compound heterozygous siblings with novel mutations]. / Lipofuscinosis ceroidea neuronal. Variante infantil tardía de tipo 6 en dos hermanos heterocigotos compuestos con mutaciones nuevas.

INTRODUCTION: There are 14 forms of lipofuscinosis, among them type 6 in its late childhood form is found, it starts between three and eight years with epilepsy, motor disorders, myoclonus, dysarthria, ataxia and neurological regression associated with vision loss and motor skills, and early death. It occurs from mutations in the CLN6 gene, most patients have homozygote variants associated with consanguinity, and rarely, with compound heterozygote variants. CASE REPORT: Siblings, started at 4 and 5 years each, with unstable gear, frequent falls and difficult running. Subsequently, loss of gait, myoclonus, dysphagia, and hallucinations. On physical examination, present optic nerve atrophy, Babinski and trunk ataxia. Electroencephalogram with widespread slow wave bursts during non-REM sleep, non photoparoxystic response, MRI with periventricular white substance hyperintensity, cerebellar atrophy and cortical. Panel of lipofuscinosis report two mutations, c.552del and c.244G>C, not described previously, in both patients. The mother was the carrier of the 552 deletion and the father and paternal grandmother of the G>C substitution (Gly82Arg). CONCLUSIONS: Differential diagnosis in neuroregression disorders is difficult because clinical signs are nonspecific, like many other neurodegenerative disorders with progressive myoclonic epilepsy. We report the clinical findings in two Mexican siblings with the late childhood variant of CLN6 with two new heterozygote mutations that contribute to the knowledge of mutations in the Mexican population and point out the relevance of performing next-generation genetic sequencing studies which will allow a better genetic counseling practice.

TITLE: Lipofuscinosis ceroidea neuronal. Variante infantil tardía de tipo 6 en dos hermanos heterocigotos compuestos con mutaciones nuevas.Introducción. Existen 14 formas de lipofuscinosis. La de tipo 6, en su forma infantil tardía, comienza entre los 3 y 8 años con alteraciones motoras, mioclonos, disartria, ataxia, pérdida de la visión y las habilidades motoras, y muerte temprana. Ocurre por mutaciones en el gen CLN6. La mayoría de los pacientes presenta variantes en estado homocigoto, asociadas a consanguinidad o endogamia, y son poco frecuentes las variantes en estado heterocigoto compuesto. Casos clínicos. Hermanos con síntomas desde los 4 y 5 años, con marcha inestable, caídas frecuentes, posteriormente pérdida de la marcha, mioclonías, disfagia y alucinaciones visuales. En el examen físico presentaban atrofia del nervio óptico, Babinski y ataxia del tronco. El electroencefalograma mostraba brotes de ondas lentas generalizadas, sin respuesta fotoparoxística, y la resonancia magnética de cráneo, hiperintensidad de la sustancia blanca periventricular, y atrofia cerebelosa y cortical. El panel de lipofuscinosis reveló dos mutaciones nuevas en el gen CLN6, c.552del y c.244G>C (p.Gly82Arg), no descritas previamente. La madre resultó portadora de la deleción 552, y el padre y la abuela paterna, de la sustitución G>C (Gly82Arg). Conclusiones. El diagnóstico diferencial en los trastornos con neurorregresión se dificulta debido a que los signos clínicos son inespecíficos, similares a otras epilepsias mioclónicas progresivas. Presentamos los hallazgos clínicos en dos hermanos mexicanos con la variante infantil tardía de CLN6 por dos mutaciones heterocigotas nuevas que contribuyen al conocimiento de las mutaciones en la población mexicana y señalan la relevancia de realizar estudios genéticos aplicando la secuenciación de nueva generación para permitir un adecuado asesoramiento genético.

Lipofuscinosis ceroidea neuronal. Variante infantil tardía de tipo 6 en dos hermanos heterocigotos compuestos con mutaciones nuevas / Neuronal ceroid lipofuscinosis. Type 6 late infantile variant in two compound heterozygous siblings with novel mutations

Introducción: Existen 14 formas de lipofuscinosis. La de tipo 6, en su forma infantil tardía, comienza entre los 3 y 8 años con alteraciones motoras, mioclonos, disartria, ataxia, pérdida de la visión y las habilidades motoras, y muerte temprana. Ocurre por mutaciones en el gen CLN6. La mayoría de los pacientes presenta variantes en estado homocigoto, asociadas a consanguinidad o endogamia, y son poco frecuentes las variantes en estado heterocigoto compuesto. Casos clínicos: Hermanos con síntomas desde los 4 y 5 años, con marcha inestable, caídas frecuentes, posteriormente pérdida de la marcha, mioclonías, disfagia y alucinaciones visuales. En el examen físico presentaban atrofia del nervio óptico, Babinski y ataxia del tronco. El electroencefalograma mostraba brotes de ondas lentas generalizadas, sin respuesta fotoparoxística, y la resonancia magnética de cráneo, hiperintensidad de la sustancia blanca periventricular, y atrofia cerebelosa y cortical. El panel de lipofuscinosis reveló dos mutaciones nuevas en el gen CLN6, c.552del y c.244G>C (p.Gly82Arg), no descritas previamente. La madre resultó portadora de la deleción 552, y el padre y la abuela paterna, de la sustitución G>C (Gly82Arg). Conclusiones: El diagnóstico diferencial en los trastornos con neurorregresión se dificulta debido a que los signos clínicos son inespecíficos, similares a otras epilepsias mioclónicas progresivas. Presentamos los hallazgos clínicos en dos hermanos mexicanos con la variante infantil tardía de CLN6 por dos mutaciones heterocigotas nuevas que contribuyen al conocimiento de las mutaciones en la población mexicana y señalan la relevancia de realizar estudios genéticos aplicando la secuenciación de nueva generación para permitir un adecuado asesoramiento.(AU)

Introduction: There are 14 forms of lipofuscinosis, among them type 6 in its late childhood form is found, it starts between three and eight years with epilepsy, motor disorders, myoclonus, dysarthria, ataxia and neurological regression associated with vision loss and motor skills, and early death. It occurs from mutations in the CLN6 gene, most patients have homozygote variants associated with consanguinity, and rarely, with compound heterozygote variants. Case report: Siblings, started at 4 and 5 years each, with unstable gear, frequent falls and difficult running. Subsequently, loss of gait, myoclonus, dysphagia, and hallucinations. On physical examination, present optic nerve atrophy, Babinski and trunk ataxia. Electroencephalogram with widespread slow wave bursts during non-REM sleep, non photoparoxystic response, MRI with periventricular white substance hyperintensity, cerebellar atrophy and cortical. Panel of lipofuscinosis report two mutations, c.552del and c.244G>C, not described previously, in both patients. The mother was the carrier of the 552 deletion and the father and paternal grandmother of the G>C substitution (Gly82Arg). Conclusions: Differential diagnosis in neuroregression disorders is difficult because clinical signs are nonspecific, like many other neurodegenerative disorders with progressive myoclonic epilepsy. We report the clinical findings in two Mexican siblings with the late childhood variant of CLN6 with two new heterozygote mutations that contribute to the knowledge of mutations in the Mexican population and point out the relevance of performing next-generation genetic sequencing studies which will allow a better genetic counseling practice.(AU)

Systematized water content calculation in cartilage using T1-mapping MR estimations: design and validation of a mathematical model.

BACKGROUND: Up to 80 % of cartilage is water; the rest is collagen fibers and proteoglycans. Magnetic resonance (MR) T1-weighted measurements can be employed to calculate the water content of a tissue using T1 mapping. In this study, a method that translates T1 values into water content data was tested statistically. MATERIALS AND METHODS: To develop a predictive equation, T1 values were obtained for tissue-mimicking gelatin samples. 1.5 T MRI was performed using inverse angle phase and an inverse sequence at 37 (±0.5) °C. Regions of interest were manually delineated and the mean T1 value was estimated in arbitrary units. Data were collected and modeled using linear regression. To validate the method, articular cartilage from six healthy pigs was used. The experiment was conducted in accordance with the Danish Animal Experiment Committee. Double measurements were performed for each animal. Ex vivo, all water in the tissue was extracted by lyophilization, thus allowing the volume of water to be measured. This was then compared with the predicted water content via Lin's concordance correlation coefficient at the 95 % confidence level. RESULTS: The mathematical model was highly significant when compared to a null model (p < 0.0001). 97.3 % of the variation in water content can be explained by absolute T1 values. Percentage water content could be predicted as 0.476 + (T1 value) × 0.000193 × 100 %. We found that there was 98 % concordance between the actual and predicted water contents. CONCLUSION: The results of this study demonstrate that MR data can be used to predict percentage water contents of cartilage samples. LEVEL OF EVIDENCE: 3 (case-control study).

Concomitant changes in cross-sectional area and water content in skeletal muscle after resistance exercise.

This study investigated how one bout (1EX) and three bouts (3EX) of strenuous resistance exercise affected the cross-sectional area (CSA) and water content (WC) of the quadriceps muscle and patella tendon (PT), 4 h and 52 h after the last exercise bout. Ten healthy untrained male subjects performed 1EX with one leg and 3EX with the other leg. CSA and WC were measured with magnetic resonance imaging 10, 20 and 30 cm proximal to the tibia plateau (TP) for the muscle, and at the proximal, central and distal site for the PT prior to exercise, and 4 h and 52 h after the last exercise bout. Ten centimeter above the TP, muscle CSA was significantly increased at 4 h (1EX: 13 ± 5%; 3EX: 13 ± 4%) and 52 h (1EX: 16 ± 5%; 3EX: 16 ± 5%) compared with baseline. Muscle WC was significantly increased at 4 h (1EX: 7 ± 1%; 3EX: 6 ± 2%) and 52 h (1EX: 8 ± 2%; 3EX: 8 ± 3%) compared to baseline. PT central CSA was significantly reduced at 52 h (3EX: 14 ± 2%) compared with baseline and (3EX: 13 ± 1%) compared with 4 h. Present data demonstrate that strenuous resistance exercise results in an acute increase in muscle WC and underlines the importance of ensuring sufficient time between the last exercise bout and the determination of anatomical dimensions in muscles.

Water-content calculation in growth plate and cartilage using MR T1-mapping design and validation of a new method in a porcine model.

OBJECTIVE: There is a close relation between cartilage health and its hydration state. Current magnetic resonance methods allow visualizing this tissue. However, a quantitative analysis is more useful when studying disease. The purpose of this study was to quantify water content in cartilage using magnetic resonance without contrast agents. MATERIALS AND METHODS: Water-content estimations using T1 magnetic resonance mapping were done first in eight gelatin samples where the water content was previously known. The same method was used in the physeal areas of eight skeletally immature 30-kg pigs. To calculate accuracy, T1 calculations were compared to dry-freeze, which is considered the gold standard because it can remove the total water content form a tissue. Four fresh cartilage and seven gelatin samples were dry-frozen. Water content obtained from dry-freeze was compared to the one calculated from T1 map values. A mathematical model and statistical analysis were used to calculate the predictive value of the method and its significance. RESULTS: T1-map-based magnetic resonance method can calculate water content in cartilage with an accuracy of 97.3 %. We calculated a coefficient of variance for this method against dry-frozen sample of 3.68 (SD = 1.2) in gelatin samples, and 2.73 (SD = 1.3) in in vivo samples. Between two independent observers, the coefficient of variance was 0.053, which suggests it can be easily reproduced. CONCLUSIONS: Magnetic resonance was able to calculate, with high accuracy, the cartilage water content using T1 mapping sequences.