Posterior fossa tumors in children: An update and new concepts.

Background: Posterior fossa tumors account for approximately half of the central nervous system tumors in children. Major technological advances, mainly in the fields of molecular biology and neuroimaging, have modified their classification, leading to a more detailed description of these entities. Into the classic taxonomy, used for many years, new concepts have been incorporated at times eliminating or modifying former ones. Methods: A literature search was conducted in PubMed using the medical subject headings involving the five most common pediatric posterior fossa tumors: diffuse midline glioma, medulloblastoma, ependymoma, atypical teratoid/rhabdoid tumor, and pilocytic astrocytoma. Only English published articles in the past 11 years that provided technological, neuroimaging, and molecular biology insight into posterior fossa tumors in children were considered. Results: Substantial changes have been introduced in the nomenclature of pediatric posterior fossa tumors. Diffuse midline gliomas are named based on alterations in histone H3. Molecular rearrangements of medulloblastomas are more important in defining the prognosis than histological variants; therefore, these tumors are currently named based on their molecular subgroups. Posterior fossa ependymomas and atypical teratoid rhabdoid tumor classification have incorporated new groups based on different genetic profiles. Pilocytic astrocytoma has been placed in a new category that distinguishes circumscribed from diffuse entities. Conclusion: Advances in molecular biology and neuroimaging have substantially changed the way pediatric neoplasms are studied. The classical taxonomy has been modified leading to more accurate classifications that are based on the genetic alterations.

Abdominal complications in patients with a ventriculoperitoneal shunt: proposal for management recommendations from a single pediatric tertiary center.

PURPOSE: The aim of this study was to describe our experience in the management of patients with ventriculoperitoneal shunt-related complications (abdominal pseudocyst, bowel-related complications, and ascites) and to propose treatment recommendations. MATERIAL AND METHODS: A retrospective descriptive study was conducted in patients with ventriculoperitoneal shunt-related abdominal complications seen between 2009 and 2019 at a tertiary-care pediatric center. Patients were classified according to their diagnosis into the following: group A (abdominal pseudocyst), group B (bowel-related complications), and group C (ascites). The following variables were studied in all three groups: age, sex, etiology of hydrocephalus, history of pyogenic ventriculitis, history of abdominal surgery, clinical presentation, presence of ventricular enlargement on computed tomography scan, abdominal ultrasonography, shunt series X-ray, cerebrospinal fluid cultures, urgent as well as elective surgical interventions, antibiotic treatment, length of hospital stay, follow-up, and outcome. RESULTS: Overall, 48 patients were analyzed: group A, n=29; group B, n=15; and group C, n=4. In all cases, surgical decision-making was based on symptom severity at the time of diagnosis, presence of ventricular enlargement on computed tomography scan, and cerebrospinal fluid culture results. In patients with positive cultures, the shunt system was removed, and an external ventricular drain was placed. In oligosymptomatic patients, cerebrospinal fluid culture results were awaited to define long-term treatment and in patients with ventricular enlargement or clinically difficult-to-treat symptoms, the distal catheter was exteriorized at the thoracic level. CONCLUSION: In patients with shunt-related abdominal complications, surgical management depends on symptom severity and/or whether infection is present at the time of diagnosis.

Neurocirugía transicional: ¿una nueva subespecialidad? / Transitional neurosurgery: a new subspecialty?

Introducción: El proceso de transición de un paciente de la etapa pediátrica a la adulta es un proceso dinámico, complejo y planificado, que incluye la transferencia propiamente dicha de una institución pediátrica a una adulta. El aumento de la sobrevida de niños y adolescentes con patologías crónicas, la falta de acuerdos formales entre instituciones de salud y la falta de enfoque multidisciplinario de estos casos son los principales problemas a tener en cuenta. El objetivo del presente trabajo es describir y proponer una respuesta a las situaciones y dificultades que se encuentran en la actualidad en la salud pública durante el proceso de transición de pacientes pediátricos con patología neuroquirúrgica crónica y de pacientes adultos con patología congénita. Para tal fin se deben considerar factores sociales, económicos y comunicacionales. Material y Método: Estudio observacional, transversal y retrospectivo de pacientes con patología neuroquirúrgica transicional desde el 01 de enero de 2017 al 31 de diciembre de 2018. En total se revisaron las historias clínicas de 47 pacientes del Hospital "El Cruce". Resultados: De los 47 pacientes observados, con un rango etario entre 17 y 42 años, realizamos una división de éstos en 2 grupos: GRUPO 1: pacientes adultos operados en la edad pediátrica que requieren un seguimiento crónico de su patología de origen; y GRUPO 2: pacientes adultos con patología congénita. En el GRUPO 1, observamos 38 pacientes (24 masculinos y 14 femeninos) de los cuales 24 fueron operados y 14 no operados (solo seguimiento clínico). Dentro de este grupo, el 63% de los pacientes (n=29) presentó como su patología de base para su seguimiento la hidrocefalia. En el GRUPO 2, observamos a 9 pacientes (2 masculinos y 7 femeninos) de los cuales 7 fueron operados y 2 no operados. Todos los pacientes de este último grupo presentaron como diagnóstico de base un disrafismo espinal. Conclusión: Se debe lograr una transición planificada para el bienestar de los jóvenes con necesidades especiales de atención de salud. Actualmente no hay acuerdos interinstitucionales formales para el seguimiento y atención de estos pacientes.Consideramos que existe un grupo de pacientes que se beneficiarían con la creación de una nueva subespecialidad neuroquirúrgica: la neurocirugía transicional. La misma debería desarrollarse en hospitales generales, de alta complejidad, donde coincidan en el servicio de neurocirugía de adultos, neurocirujanos con formación pediátrica

Introduction: The transition process of a patient from pediatric to adult stage is a dynamic, complex, and planned process which, strictly speaking, includes the transfer from a pediatric to an adult institution. The increased rate of survival of children and adolescents with chronic pathologies, lack of formal agreements between health institutions and lack of multidisciplinary approach to these cases are the main issues to consider. The purpose of this paper is to describe and provide a response to situations and difficulties that currently exist in the public health during the transition process of pediatric patients with chronic neurosurgical pathology and adult patients with congenital pathology. For this purpose, communication, social, and economic factors must be considered. Methods: Observational, cross-sectional, and retrospective study of patients with transitional neurosurgical pathology from January 1, 2017, to December 31, 2018. In total, 47 patient's medical records were reviewed from "El Cruce" Hospital. Results: A total of 47 patients, with an age range between 17 and 42 years, were observed. We divided our study population into 2 groups: GROUP 1: adult patients who have been operated in pediatric age and require chronic follow-up of their origin pathology; and GROUP 2: adult patients with congenital pathology. In GROUP 1, we observed 38 patients (24 male and 14 female) of whom 24 were performed neurosurgery, and 14 were not. Within this group, 63% of the patients (n = 29) presented hydrocephalus as their basic pathology for monitoring. In GROUP 2, we observed 9 patients (2 male and 7 female) of whom 7 were operated and 2 were not. All patients in this last group presented spinal dysraphism as their basic diagnosis. Conclusion: A planned transition for the well-being of young patients with special health care needs must be achieved. Currently, there are no formal institutional agreements for the monitoring and care of these patients. We believe that there is a group of patients who would benefit from the creation of a new neurosurgical sub-specialty: transitional neurosurgery. It should be developed in high complexity general hospitals, where neurosurgeons with pediatric training could be part of a general neurosurgery department.

Nuevo modelo de simulador para neuroendoscopía / New simulator model for neuroendoscopy

Introducción: El entrenamiento en simuladores es considerado una herramienta fundamental en las especialidades quirúrgicas, contribuyendo en el aprendizaje de una determinada técnica quirúrgica.Existen modelos de simulación sintéticos que replican la anatomía ventricular con alta fidelidad sin embargo tienen un costo elevado. Algunos centros describieron el uso de cadáveres humanos pero la disponibilidad del material suele ser limitada y la adquisición dificultosa. Otros autores utilizan entrenamiento en modelos biológicos vivos (roedores de laboratorio) que presentan la ventaja de tener alta fidelidad en cuanto a la consistencia de tejidos, sin embargo, la utilización de estos modelos se encuentra cuestionados desde el aspecto ético. Material y Métodos: Se presenta un modelo de simulación que utiliza unidades de cerebro bovino y membrana amniótica. Colocamos el cerebro bovino y las unidades de membrana amniótica dentro de un recipiente esférico de poliestireno expandido. Una vez que se forma la esfera, insertamos dos trocares que nos permitirán insertar el neuroendoscopio y llenarlo con agua. Resultado: Presentamos un nuevo modelo accesible y realista para la simulación neuroendoscópica que reproduce ejercicios de biopsia, coagulación de tejidos, fenestración y dilatación de membrana. Conclusión: Los simuladores para neuroendoscopía descritos hasta ahora son confiables, pero conllevan un alto costo. Los modelos con animales vivos, aunque con menor costo, son cuestionados desde un punto de vista ético.En el trabajo actual, describimos un modelo de simulador neuroendoscópico ventricular de alta fidelidad que, debido a su bajo costo, permite ser replicado en cualquier centro de entrenamiento que tenga un neuroendoscopio.

Objectives: Ventricular endoscopy is considered an excellent technique. However, without an optimal learning curve, it could lead to deadly complications.There are synthetic simulation models that replicate the ventricular anatomy with high fidelity but high costs. Some low-cost models have been published using human corpses for endoscopic training; however, materials' acquisition is difficult. A different option is live biological models (laboratory rodents), although cost is lower, they are questioned from an ethical point of view.The ideal simulator, in addition to aspiring maximum fidelity, must be accessible, affordable and easy to replicate to facilitate repetitive training. Methods: A simulation model using bovine brain and membrane units made by a soda cup covered by an amniotic membrane. We placed the bovine brain and the amniotic membrane units inside an expanded polystyrene spherical container; once the sphere is formed, we inserted two trocars, which will enabled us to insert the neuroendoscope and fill it with water. Result: We introduced an attainable and realistic new model for neuroendoscopic simulation, which replicates biopsy, tissue coagulation, fenestration, and membrane dilatation exercises. Conclusion: Simulators for neuroendoscopy described so far are reliable, but they entail a high cost. Models with live animals, although with lower cost, are questioned from an ethical point of view.In the current work, we describe a high fidelity ventricular neuroendoscopic simulator model that, due to its low cost, allows to be replicated in any training center that has a neuroendoscope

Low-Cost Stereotactic Brain Biopsy Simulation Model.

OBJECTIVE: Simulation training improves technical skills in a safe environment. Stereotactic techniques are widely used in neurosurgery for different kinds of procedures. The objective of the study was to describe a combined cadaveric and synthetic low-cost stereotactic simulation model and its validation by neurosurgeons. METHODS: The brain was made using self-supporting gel with solid and cystic lesions. We used imaging scans to calculate x, y, and z target coordinates. A standard frame needle biopsy was performed. We calculated the number of mistakes and time needed to accomplish the task, and we evaluated the frame assembly and biopsy performance. Wilcoxon signed rank was used to analyzed the data; we considered a P value <0.05 as statistically significant. RESULTS: The median initial number of mistakes was 32 (interquartile range [IQR]: 27.5-37) and after repeated training and feedback the final median number was 3.5 (IQR: 2-6) (P < 0.001). The median time needed to finish the exercises before training was 1020.5 seconds (IQR: 908-1125.5) and after using the model the final median time was 479 seconds (IQR: 423-503) (P < 0.0001). CONCLUSIONS: We presented a stereotactic simulation model with immediate haptic feedback. The model can be easily handmade in any neurosurgical laboratory. This model allows neurosurgeons in training to acquire and improve stereotactic techniques, reducing the number of surgical mistakes and time needed to finish the task.

The Impact of Rehabilitation-oriented Virtual Reality Device in Patients With Ischemic Stroke in the Early Subacute Recovery Phase: Study Protocol for a Phase III, Single-Blinded, Randomized, Controlled Clinical Trial.

BACKGROUND AND RATIONALE: Stroke is considered the most common cause of adult disability. Intensive rehabilitation protocols outperform nonintensive counterparts. The subacute stroke phase represents a potential window to recovery. Virtual reality (VR) has been shown to provide a more stimulating environment, allowing for increased patient compliance. However, the quality of current literature comparing VR with standard therapies is limited. Our aim is to measure the impact of VR versus standard therapy on the recovery of the upper limb motor function in patients with stroke in the early subacute recovery phase. METHOD: This is a randomized, controlled trial that will assign 262 patients to tailor-made standard rehabilitation (TMSR) or TMSR plus immersive VR device. The trial will be conducted in an urban rehabilitation clinic in the United States with expertise in the management of poststroke patients. Patients will be 18 to 70 years of age and in the early subacute period (30-90 days post ischemic stroke). The primary outcome will be the change of Fugl-Meyer Assessment-Upper Extremity (FMA-UE) score, measured at baseline and 13 weeks after randomization. The secondary outcome will be the change in the UK Functional Independence Measure and Functional Assessment Measure (UK FIM-FAM) score at the same time points. DISCUSSION: If the use of VR in the rehabilitation of patients with stroke proves to have a significant impact on their motor recovery, it will constitute an extremely important step into decreasing the functional impairment associated with stroke and the related health care expense burden.

New Simulator for Neuroendoscopy: A Realistic and Attainable Model.

OBJECTIVE: To present an attainable and realistic model for neuroendoscopic simulation which replicates exercises of tissue biopsy and coagulation and membrane fenestration. METHODS: We presented a stepwise method to create a neuroendoscopic simulation model using bovine brain and membrane units made by a soda cup covered by an amniotic membrane inside an expanded polystyrene spherical container. We used face validation for preliminary evaluation. We also rated the students before and after training with the NEVAT global rating scale (GRS) and recorded the time required to complete all 3 procedures (third ventriculostomy, tissue biopsy, and coagulation). The total cost of the model was $5. RESULTS: The experts consider this new model as capable of reproducing real surgical situations with great similarity to the human brain. We tested the model in 20 trainees. The median GRS score before the training was 9 (range, 7-12). After repeated training and performance feedback, the final median GRS score was 41 (range, 37.5-45; P < 0.0001). The time needed to finish the exercises before training was 33 minutes (range, 30.5-42.5 minutes), and after using the model the final median time was 20 minutes (range, 17.5-22 minutes; P < 0.0001). CONCLUSIONS: Simulators for neuroendoscopy described so far are reliable, but they entail a high cost. Models with live animals, although of lower cost, are questioned from an ethical point of view. In the current work, we describe a high fidelity ventricular neuroendoscopic simulator model that, because of its low cost, can be replicated in any training center that has a neuroendoscope.

Modelo de neuroendoscopia ventricular "INARUS" / Ventricular neuroendoscopy model "INARUS"

Introducción: La simulación es una herramienta de educación indispensable para un entrenamiento progresivo en un ámbito seguro, no solo para el paciente sino para el educando. La misma fue incorporada en la curricula de nuestras especialidades quirúrgicas a partir del 2013. Las habilidades neuroquirúrgicas requieren de un experticio que implica un periodo prolongado de tiempo de práctica. En la actualidad, dicho periodo, se tiende a disminuir con la enseñanza de ensayo y error, repetición de los procedimientos y automatización de maniobras que la simulación facilita con el agregado de la posibilidad de un feedback de retroalimentación entre el profesional en formación y el educador en un ambiente seguro. Objetivo: Describir un modelo de simulador físico sintético de bajo costo como herramienta inicial para mejorar la curva de aprendizaje de las técnicas de neuroendoscopia intraventricular. Descripción del simulador: es un modelo físico sintético realizado a través de técnicas de mordería con gel autoportante. El simulador ofrece la posibilidad de practicar técnicas básicas neuroendoscópicas intraventriculares, ofreciendo la particularidad de poder repetir las maniobras y gestos quirúrgicas con un coste beneficio muy elevado debido al muy bajo precio de realización del simulador. A su vez, se trata de un modelo de simulación que se puede fabricar de forma casera en cualquier centro de simulación. Discusión: Presentamos un modelo inédito de bajo costo y alta fidelidad para simulación neuroendoscópica. Consta de un cerebro sintético físico que permite replicar ejercicios de navegación intraventricular con maniobras endoscópicas, toma de biopsia de lesiones quísticas o sólidas, sección de tabiques, lavado ventricular y desobstrucción de catéteres intraventriculares. Lo consideramos una herramienta básica y de amplia ayuda para profesionales que decidan iniciar su curva de aprendizaje en la neuroendoscopia intraventricular. Planeamos su validación en futuros congresos de neurocirugía.

Introduction: Simulation is an indispensable educational tool for progressive training in a safe environment, for both patients and learning neurosurgeons. It was incorporated into the curricula of our surgical specialties as of 2013. Neurosurgical skills require an expertise that involves a prolonged period of practice time. Currently, this period tends to decrease with the teaching of trial and error, repetition of procedures and automation of maneuvers that the simulation facilitates with the addition of the possibility of feedback between the professional in training and the educator, all doing in a safe environment. Objective: To describe a low cost synthetic physical simulator model as an initial tool to improve the learning curve of intraventricular neuroendoscopy techniques. Description of the simulator: it is a synthetic physical model realized through self-supporting gel biting techniques. The simulator offers the possibility of practicing intraventricular neuroendoscopic basic techniques, offering the peculiarity of being able to repeat maneuvers and surgical gestures with a very high benefit-cost due to a very low price of its creation. At the same time, it is a simulation model that can be manufactured at home in any simulation center. Discussion: We present an unprecedented model of low cost and high fidelity for neuroendoscopic simulation. It consists of a physical synthetic brain that allows the replication of intraventricular navigation exercises with endoscopic maneuvers, a biopsy of solid or cystic lesions, the section of the ventricular septum, ventricular lavage and unblocking of intraventricular catheters. We consider this simulator as a basic tool of wide assistance for professionals who decide to start their learning curve in intraventricular neuroendoscopy. We're planning its validation in a future neurosurgery congress.

Guía de práctica clínica cirugía periapical, indicaciones y técnica quirúrgica / Periapical surgery clinical practice guide, indications and surgical technique

Esta GPC en Cirugía periapical tiene como objetivos proporcionar recomendaciones basadas en la evidencia científica, con la finalidad de mejorar la calidad asistencial y unificar los criterios de actuación en relación a las indicaciones y técnicas de aplicación en Cirugía Periapical de los profesionales sanitarios en el ámbito de la Odontología.