[Evaluation of diffuse cerebral atrophy in patients with a history of traumatic brain injury and its relation to cognitive deterioration]. / Evaluación de la atrofia cerebral difusa en pacientes con antecedentes de traumatismo craneoencefálico y su relación con el deterioro cognitivo.

INTRODUCTION: Diffuse damage secondary to traumatic brain injury (TBI) can be studied through volumetric analysis of several structures that are sensible to this kind of injury, such as corpus callosum, ventricular system, hippocampus, basal ganglia and the volume of cerebrospinal fluid spaces. OBJECTIVE: Our aim is to describe how closed head injury (CHI) occurred in early years produce diffuse damage, and how this damage affects general cognitive functioning at long term. PATIENTS AND METHODS: Initially the group of subjects was composed of 27 head injured children and adolescents following paediatric moderate to severe TBI. From this initial group we selected 15 patients without focal lesion, or in case of having suffered focal lesion, this was smaller than 2,600 mm3. These subjects were assessed by means of volumetric analysis of cerebrospinal fluid spaces, corpus callosum, hippocampus and caudate nucleus, comparing the results with a matched control group. We calculated the degree of general cognitive ability of these subjects through tests of intellectual, memory, frontal lobe and motor speed functioning. RESULTS: This study demonstrates that early CHI produce a volume decrease in all measured structures. Corpus callosum atrophy is the factor that better explains general cognitive impairment. CONCLUSIONS: Diffuse damage secondary to moderate to severe peadiatric TBI has long term effects on several cerebral structures and on cognitive performance. Corpus callosum atrophy is the best predictor for general cognitive impairment, compared with other affected structures.

Evaluación de la atrofia cerebral difusa en pacientes con antecedentes de traumatismo craneoencefálico y su relación con el deterioro cognitivo / Evaluationo of diffuse cerebral atrophy in patients with a history of traumatic brain injury and its relation to cognitive deterioration

Introducción. El daño cerebral difuso (DCD) secundario al traumatismo craneoencefálico (TCE) puede estudiarse a través de la evaluación volumétrica de diversas estructuras, entre las cuales destacan el cuerpo calloso, el hipocampo y los ganglios basales. Asimismo, el volumen de líquido cefalorraquídeo es también una buena medida de pérdida de masa encefálica. Objetivo. Evaluar el DCD producido por un TCE cerrado infantil y observar los efectos que éste tiene a largo plazo sobre el rendimiento cognitivo general. Pacientes y métodos. Se partió inicialmente de una muestra de 27 pacientes con TCE cerrado infantil, moderado o grave, de la cual se seleccionaron 15 sujetos, por carecer de lesiones focales, o en su caso, que éstas fueran inferiores a 2.600 mm3. En los 15 sujetos estudiados se realizó un análisis volumétrico del líquido cefalorraquídeo, del cuerpo calloso, del hipocampo y del núcleo caudado y se comparó con un grupo control. Además, se evaluó su deterioro cognitivo general mediante test de inteligencia, de memoria, y de la evaluación de las funciones frontales y motoras. Resultados. Los resultados mostraron que los pacientes con antecedentes de traumatismo presentaban atrofia en todas las estructuras medidas y que la atrofia del cuerpo calloso fue la variable que mejor explicaba el deterioro cognitivo general. Conclusiones. El daño difuso causado por TCE moderado-grave en la infancia persiste a largo plazo y comporta déficit cognitivos; la atrofia del cuerpo calloso es la que mejor predice el deterioro cognitivo general de los afectados, con relación a otras estructuras indicadoras de DCD (AU)

Early Experience Studying Cerebral Aneurysms with Rotational and Threedimensional Angiography and Review of CT and MR Angiography Literature.

SUMMARY: From september 2000 to september 2001, 32 consecutive patients with ruptured intracranial aneurysms were examined with rotational and 3D reconstruction angiography using an Integris V5000 Philips Medical System: 39 aneurysms were detected. After a selective cerebral artery was catheterized with a 5F or 4F-catheter, 35 ml of contrast medium was intra-arterially administered at a rate of 4 ml/s and a 180 degrees rotational angiography was performed in eight seconds. This information was transferred to a computer (Silicon Graphics Octane) with software (Integris 3DRA, Philips Integris Systems) and a three-dimensional reconstruction was made. The information provided by Angio-3D was useful for evaluating the parent artery, aneurysmal sac, aneurysmal neck and arterial branches. It was also very useful in selecting the therapeutic method. For open surgery, this technique provides preoperative images that are useful for planning microsurgical approaches, especially in cases of large aneurysm showing complex surrounding arteries. For endovascular embolization, various anatomic characteristics of the aneurysm such as neck and sac size, shape, lobularity, parent artery and arterial branches adjacent to the aneurysmal neck must be demonstrated. This is very important to determine the best projection for embolization and to avoid multiple series. This is also essential in the choice of the first coil to create a good basket producing total occlusion. Microaneurysms are demonstrated well with this technique whereas this is difficult to do with conventional arteriography. The Angio-RM and Angio-CT literature show a lower sensitivity and specificity in comparasion with our experience with 3D IA-ROT-DSA. For this reason, we believe that 3D IA-ROTDSA is now the gold standard for patients presenting intracranial aneurysms.