The choroid plexus transcriptome reveals changes in type I and II interferon responses in a mouse model of Alzheimer's disease

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by a marked decline in cognition and memory function. Increasing evidence highlights the essential role of neuroinflammatory and immune-related molecules, including those produced at the brain barriers, on brain immune surveillance, cellular dysfunction and amyloid beta (Aß) pathology in AD. Therefore, understanding the response at the brain barriers may unravel novel pathways of relevance for the pathophysiology of AD. Herein, we focused on the study of the choroid plexus (CP), which constitutes the blood-cerebrospinal fluid barrier, in aging and in AD. Specifically, we used the PDGFB-APPSwInd (J20) transgenic mouse model of AD, which presents early memory decline and progressive Aß accumulation, and littermate age-matched wild-type (WT) mice, to characterize the CP transcriptome at 3, 5-6 and 11-12months of age. The most striking observation was that the CP of J20 mice displayed an overall overexpression of type I interferon (IFN) response genes at all ages. Moreover, J20 mice presented a high expression of type II IFN genes in the CP at 3months, which became lower than WT at 5-6 and 11-12months. Importantly, along with a marked memory impairment and increased glial activation, J20 mice also presented a similar overexpression of type I IFN genes in the dorsal hippocampus at 3months. Altogether, these findings provide new insights on a possible interplay between type I and II IFN responses in AD and point to IFNs as targets for modulation in cognitive decline.

Assessing the application of polypropylene multifilament yarns in brain phantoms

The currently available clinical imaging methods do not provide highly detailed information about location and severity of axonal injury or the expected recovery time of patients with traumatic brain injury [1]. High-Definition Fiber Tractography (HDFT) is a novel imaging modality that allows visualizing and quantifying, directly, the degree of axons damage, predicting functional deficits due to traumatic axonal injury and loss of cortical projections. This imaging modality is based on diffusion technology [2]. The inexistence of a phantom able to mimic properly the human brain hinders the possibility of testing, calibrating and validating these medical imaging techniques. Most research done in this area fails in key points, such as the size limit reproduced of the brain fibers and the quick and easy reproducibility of phantoms [3]. For that reason, it is necessary to develop similar structures matching the micron scale of axon tubes. Flexible textiles can play an important role since they allow producing controlled packing densities and crossing structures that match closely the human crossing patterns of the brain. To build a brain phantom, several parameters must be taken into account in what concerns to the materials selection, like hydrophobicity, density and fiber diameter, since these factors influence directly the values of fractional anisotropy. Fiber cross-section shape is other important parameter. Earlier studies showed that synthetic fibrous materials are a good choice for building a brain phantom [4]. The present work is integrated in a broader project that aims to develop a brain phantom made by fibrous materials to validate and calibrate HDFT. Due to the similarity between thousands of hollow multifilaments in a fibrous arrangement, like a yarn, and the axons, low twist polypropylene multifilament yarns were selected for this development. In this sense, extruded hollow filaments were analysed in scanning electron microscope to characterize their main dimensions and shape. In order to approximate the dimensional scale to human axons, five types of polypropylene yarns with different linear density (denier) were used, aiming to understand the effect of linear density on the filament inner and outer areas. Moreover, in order to achieve the required dimensions, the polypropylene filaments cross-section was diminished in a drawing stage of a filament extrusion line. Subsequently, tensile tests were performed to characterize the mechanical behaviour of hollow filaments and to evaluate the differences between stretched and non-stretched filaments. In general, an increase of the linear density causes the increase in the size of the filament cross section. With the increase of structure orientation of filaments, induced by stretching, breaking tenacity increases and elongation at break decreases. The production of hollow fibers, with the required characteristics, is one of the key steps to create a brain phantom that properly mimics the human brain that may be used for the validation and calibration of HDFT, an imaging approach that is expected to contribute significantly to the areas of brain related research.

Biological markers in noninvasive brain stimulation trials in major depressive disorder: a systematic review

Objectives: The therapeutic effects of transcranial magnetic stimulation (TMS) and transcranial direct current stimulation in patients with major depression have shown promising results; however, there is a lack of mechanistic studies using biological markers (BMs) as an outcome. Therefore, our aim was to review noninvasive brain stimulation trials in depression using BMs. Methods: The following databases were used for our systematic review: MEDLINE, Web of Science, Cochrane, and SCIELO. We examined articles published before November 2012 that used TMS and transcranial direct current stimulation as an intervention for depression and had BM as an outcome measure. The search was limited to human studies written in English. Results: Of 1234 potential articles, 52 articles were included. Only studies using TMS were found. Biological markers included immune and endocrine serum markers, neuroimaging techniques, and electrophysiological outcomes. In 12 articles (21.4%), end point BM measurements were not significantly associated with clinical outcomes. All studies reached significant results in the main clinical rating scales. Biological marker outcomes were used as predictors of response, to understand mechanisms of TMS, and as a surrogate of safety. Conclusions: Functional magnetic resonance imaging, single-photon emission computed tomography, positron emission tomography, magnetic resonance spectroscopy, cortical excitability, and brain-derived neurotrophic factor consistently showed positive results. Brain-derived neurotrophic factor was the best predictor of patients’ likeliness to respond. These initial results are promising; however, all studies investigating BMs are small, used heterogeneous samples, and did not take into account confounders such as age, sex, or family history. Based on our findings, we recommend further studies to validate BMs in noninvasive brain stimulation trials in MDD.

High-aspect-ratio tridimensional electrode arrays for neural applications

Tese de Doutoramento em Engenharia Biomédica.

Stress-triggered synaptic malfunction: a gate along the path from depressionto dementia

Tese de Doutoramento em Ciências da Saúde.

The bounds of education in the human brain connectome

Inter-individual heterogeneity is evident in aging; education level is known to contribute for this heterogeneity. Using a cross-sectional study design and network inference applied to resting-state fMRI data, we show that aging was associated with decreased functional connectivity in a large cortical network. On the other hand, education level, as measured by years of formal education, produced an opposite effect on the long-term. These results demonstrate the increased brain efficiency in individuals with higher education level that may mitigate the impact of age on brain functional connectivity.

Synthesis and biological evaluation of mono and bis-naphthalimide derivatives against SH-SY5Y, human brain cancer cells

Dissertação de mestrado em Medicinal Chemistry

Acciones tróficas de GABA: implicancias en la diferenciación sexual del cerebro. Trophic actions of GABA: Implications for sexual differentiation of the brain.

En el hipotálamo en desarrollo, el ácido gamma-amino butírico (GABA) produce depolarización neuronal, pudiendo incluso disparar potenciales de acción y causar la apertura de canales de calcio dependientes de voltaje. Esto se debe a que la concentración intracelular de Cl- es alta respecto al medio extracelular, por lo que en reposo el potencial de equilibrio de GABA es más positivo que el potencial de membrana. A medida que el desarrollo transcurre, la concentración intracelular de Cl- disminuye y se produce un cambio en la respuesta de depolarizante (etapa excitatoria) a hiperpolarizante (etapa inhibitoria). Se ha demostrado que este cambio ocurre también en neuronas hipotalámicas in vitro. El dimorfismo sexual del cerebro de los vertebrados es consecuencia de la acción del estrógeno aromatizado a partir de andrógenos segregados por el testículo durante el "periodo crítico" del desarrollo cerebral. Evidencias previas de nuestro y otros laboratorios pusieron de manifiesto diferencias en el crecimiento y diferenciación de neuronas que no podían atribuirse a la acción hormonal, ya que ocurren antes que se inicie el brusco aumento de la secreción gonadal, alrededor del día 18 de desarrollo embrionario en la rata (E18). Además de las diferencias morfológicas, encontramos diferencias sexuales en la forma que las neuronas hipotalámicas responden a muscimol, un agonista específico del receptor GABAA. A los 9 días in vitro (9 DIV) la respuesta a muscimol fue hiperpolarizante (etapa inhibitoria) y además fue de mayor amplitud, área y duración en machos respecto a hembras. Esto nos indica que las neuronas provenientes de embriones machos son intrínsecamente diferentes a las de embriones hembra aún antes de la acción organizadora de los esteroides sexuales. En base a estas evidencias nos propusimos continuar nuestros estudios sobre la participación de GABA en la determinación de diferencias sexuales en el cerebro antes de la acción organizadora de los esteroides gonadales. Para ello, en cultivos de neuronas hipotalámicas de E16 separados por sexos, estudiaremos:- la respuesta a muscimol de las neuronas, en la etapa excitatoria (2 DIV) de la acción de GABA.- las composición de subunidades de los receptores GABAA en la etapa excitatoria/inhibitoria de la acción de GABA.- la participación de los receptores GABAA sobre el crecimiento neurítico.- la activación de la vía de las MAP quinasas por muscimol.- la participación de los receptores GABAA sobre el crecimiento axonal inducido por estradiol in vitro.Toda la metodología propuesta es de uso habitual en nuestro laboratorio e involucra herramientas de la electrofisiología y la biología celular-molecular; como patch-clamp, cultivo de neuronas hipotalámicas, Western blot, RT-PCR, entre otras. Esperamos encontrar diferencias sexuales en la amplitud, área y duración de la respuesta de las neuronas hipotalámicas al muscimol a los 2 DIV, y que éstas se deban a una diferente composición de subunidades del receptor GABAA. En cuanto a la participación del receptor GABAA en la neuritogenesis, esperamos encontrar mayor longitud neurítica en neuronas macho como así también una activación sexualmente dimórfica de la vía de las MAP quinasas. Además esperamosque la acción de un antagonista del receptor GABAA interfiera con la axogénesis inducida por estradiol in vitro, característica que muestra diferencia sexual también a favor de los machos, lo que reforzaría nuestra hipótesis. La importancia y originalidad de este proyecto reside en la evaluación de la participación del sistema GABAérgico en la determinación de características que durante el desarrollo, podrían estar involucradas en la determinación de diferencias sexuales permanentes en el cerebro adulto independientemente de la acción de los esteroides sexuales. Hasta la fecha, no ha sido evaluada la influencia de los receptores GABAA en la diferenciación sexual del cerebro antes de la acción organizadora de los esteroides gonadales.

The Word Brain - A Short Guide to Fast Language Learning

How long does it take to learn another language? How many words do you need to learn? Are languages within the reach of everybody? Which teachers would you choose and which teachers should you avoid? These are some of the questions you ask yourself when you start learning a new language.The Word Brain provides the answers. If you have learned foreign languages in the past, consider reading it. If you or your children need to learn languages in the future, you must read it. What you will discover in two hours will change for ever the way you see languages and language learning. The principles of The Word Brain are timeless. Our children’s grandchildren will follow them when they discover the people of our planet.

Role of mitochondria in ischemia/reperfusion mediated brain injury : mechanisms and pharmacology interventions

Magdeburg, Univ., Fak. für Naturwiss., Diss., 2004

"Differential metabolic recruitment of cognitive, emotional and modulatory brain regions in infant and adolescent rats undergoing two-way active avoidance training"

Magdeburg, Univ., Fak. für Naturwiss., Diss., 2011