High performance electronic device for the measurement of the inverse spin Hall effect.

We have developed a high performance analog electronic device that can be used for the measurement of the inverse spin Hall effect (ISHE) as a function of the applied magnetic field. The electronic circuit is based on the synchronous detection technique with a careful selection of the active components in order to optimize the response in this application. The electronic accessory was adapted for the simultaneous measurement of the ISHE signal and the microwave absorption in an electron spin resonance spectrometer and tested with a bilayer sample of 5 nm of permalloy (Ni80Fe20) and 5 nm of tantalum. The response of the electronic device was characterized as a function of the microwave power, the amplitude and frequency of the modulation signal, and the relative phase between signal and reference. This last characterization reveals a simple method to put in phase the signal with the reference. The maximum signal to noise ratio was achieved for a modulation frequency between 6 and 12 kHz, for the largest possible values of field modulation amplitude and microwave power.

Alteraciones de la morfología dendrítica neuronal en la corteza cerebral de ratones infectados con rabia: un estudio con la técnica de Golgi / Neuronal dentritic morphology alterations in the cerebral cortex of rabies-infected mice: a Golgi study

Introducción. Los signos neurológicos de la rabia son impresionantes; no obstante, el cerebro infectado sufre apenas cambios histológicos muy sutiles. Objetivo. Estudiar la morfología neuronal mediante la técnica de Golgi, en la corteza cerebral de ratones infectados con el virus de la rabia. Materiales y métodos. Se inocularon ratones con virus silvestre de la rabia (virus ‘calle’) de origen canino o con virus adaptado (virus ‘fijo’) de la cepa CVS (challenge virus standard). Los animales se sacrificaron en la fase terminal de la enfermedad y se fijaron por perfusión con paraformaldehído. Los cerebros se procesaron con la técnica de Golgi, se obtuvieron cortes coronales de la corteza, se contaron las neuronas impregnadas en un área de 1 mm2, se midió el tamaño de sus cuerpos celulares y se tomaron fotografías en diferentes planos de profundidad. Resultados. Se observaron alteraciones morfológicas notables en el soma y las dendritas de neuronas piramidales, con pérdida acentuada de espinas, en 12,9 por ciento de neuronas corticales de animales infectados con virus ‘calle’ por vía intracerebral; en 8,2 por ciento de neuronas de ratones inoculados con este mismo virus por la ruta intramuscular y en 31,8 por ciento de neuronas en los animales inoculados con virus ‘fijo’ por vía intramuscular. Además, en las muestras de material infectado el número de neuronas impregnadas por la técnica de Golgi fue considerablemente menor al observado en las muestras no infectadas. Conclusiones. Estos resultados son evidencia de que el virus de la rabia sí puede inducir daño neuronal estructural. Además, esta infección aparentemente interfiere con los mecanismos de impregnación argéntica del método de Golgi.

Introduction. The neurological signs of rabies are very dramatic. Nevertheless, the infected brain manifests only very subtle histological changes. Objective. The neuronal morphology in the cerebral cortex of rabies-infected mice was examined by means the Golgi technique for detection of neuropathy. Materials and methods. Two groups of mice were inoculated with rabies—one with street virus isolated from an infected dog and the second with fixed CVS (challenge virus standard) virus. At the terminal phase of illness, the animals were sacrificed and fixed for histological staining by perfusion with paraformaldehyde. Next, the brains were treated by the Golgi technique and coronal sections were obtained. Neurons enclosed within 1 mm2 frames of the frontal cortex sections were counted and the sizes of the cellular bodies were measured. Photographs of several depth levels from the sections were obtained. Results. Cortical pyramidal neurons showed distinctive morphological alterations in the soma and dendrites (including loss of dendritic spines) in 12.9% of cells from intracerebral infectedmice with street virus; in 8.2% of neurons from intramuscular infected-mice with street virus, and in 31.8% of neurons from mice injected intramusculary with fixed virus. In addition, the number of neurons impregnated by the Golgi technique in infected brains was considerably lower than in the non-infected samples. Conclusions. Rabies virus can induce structural neuron damage. The infection also appears to induce tissue changes that interfere with the chemical mechanisms of the Golgi silver impregnation method.

[Neuronal dentritic morphology alterations in the cerebral cortex of rabies-infected mice: a Golgi study]. / Alteraciones de la morfología dendrítica neuronal en la corteza cerebral de ratones infectados con rabia: un estudio con la técnica de Golgi.

INTRODUCTION: The neurological signs of rabies are very dramatic. Nevertheless, the infected brain manifests only very subtle histological changes. OBJECTIVE: The neuronal morphology in the cerebral cortex of rabies-infected mice was examined by means the Golgi technique for detection of neuropathy. MATERIALS AND METHODS: Two groups of mice were inoculated with rabies-one with street virus isolated from an infected dog and the second with fixed CVS (challenge virus standard) virus. At the terminal phase of illness, the animals were sacrificed and fixed for histological staining by perfusion with paraformaldehyde. Next, the brains were treated by the Golgi technique and coronal sections were obtained. Neurons enclosed within 1 mm2 frames of the frontal cortex sections were counted and the sizes of the cellular bodies were measured. Photographs of several depth levels from the sections were obtained. RESULTS: Cortical pyramidal neurons showed distinctive morphological alterations in the soma and dendrites (including loss of dendritic spines) in 12.9% of cells from intracerebral infected-mice with street virus; in 8.2% of neurons from intramuscular infected-mice with street virus, and in 31.8% of neurons from mice injected intramusculary with fixed virus. In addition, the number of neurons impregnated by the Golgi technique in infected brains was considerably lower than in the non-infected samples. CONCLUSIONS: Rabies virus can induce structural neuron damage. The infection also appears to induce tissue changes that interfere with the chemical mechanisms of the Golgi silver impregnation method.

Calbindin distribution in cortical and subcortical brain structures of normal and rabies-infected mice.

Rabies has been an enigmatic disease of the nervous system because microscopic findings in the brain tissue are not paralleled by the severity of the clinical illness. The calcium binding protein calbindin (CB) is a neuronal marker of great interest in neuroanatomy and neuropathology. CB-ir neurons in the striatum and cerebral cortex are gabaergic cells. In the present work CB-immunoreactivity was evaluated in brains of normal and rabies-infected mice. Rabies infection caused loss of CB-immunostaining in the cortical supragranular layers as well as in the striatum. Loss of CB in the brains of mice infected with rabies virus can produce impairment in Ca++ homeostasis and in the gabaergic neurotransmission.

[Effect of rabies virus infection on the expression of parvalbumin, calbindin and calretinin in mouse cerebral cortex]. / Efecto de la infección por el virus de la rabia sobre la expresión de parvoalbúmina, calbindina y calretinina en la corteza cerebral de ratones.

Some clinical features of rabies and experimental evidence from cell culture and laboratory animals suggest impairment of gabaergic neurotransmission. Several types of gabaergic neurons occur in the cerebral cortex. They can be identified by three neuronal markers: the calcium binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR). Rabies virus spreads throughout the cerebral cortex; however, rabies cytopathic effects on gabaergic neurons are unknown. The expression of calcium-binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR) was studied in the frontal cortex of mice. The effect of gabaergic neurons was evaluated immunohistochemically. The distribution patterns of CaBPs in normal mice and in mice infected with 'fixed' or 'street' rabies virus were compared. PV was found in multipolar neurons located in all cortical layers except layer I, and in pericellular clusters of terminal knobs surrounding the soma of pyramidal neurons. CB-immunoreactivity was distributed in two cortical bands. One was composed of round neurons enclosed by a heavily labeled neuropil; this band corresponds to supragranular layers II and III. The other was a weakly stained band of neuropil which contained scattered multipolar CB-ir neurons; this corresponds to infragranular layers V and VI. The CR-ir neurons were bipolar fusiform cells located in all layers of cortex, but concentrated in layers II and III. A feature common to samples infected with both types of viruses was a more intense immunoreactivity to PV in contrast to normal samples. The infection with 'street' virus did not cause additional changes in the expression of CaBPs. However, the infection with 'fixed' virus produced a remarkable reduction of CB-immunoreactivity demonstrated by the loss of CB-ir neurons and low neuropil stain in the frontal cortex. In addition, the size of CR-ir neurons in the cingulate cortex was decreased.

Efecto de la infección por el virus de la rabia sobre la expresión de parvoalbúmina, calbindina y calretinina en la corteza cerebral de ratones / Effect of rabies virus infection on the expression of parvalbumin, calbindin and calretinin in mouse cerebral cortex

Algunas manifestaciones clínicas de la rabia, así como los resultados de experimentos con cultivos celulares y animales de laboratorio han llevado a sugerir que el virus de la rabia afecta la neurotransmisión gabaérgica. En la corteza cerebral existen diferentes tipos de neuronas que sintetizan el neurotransmisor GABA. Éstas se pueden identificar con marcadores neuronales, entre los que se destacan tres proteínas ligadoras de calcio: la parvoalbúmina (PV), la calbindina (CB) y la calretinina (CR). El virus de la rabia se disemina a través de la corteza cerebral pero se desconocen sus posibles efectos citopáticos sobre las neuronas gabaérgicas. Para evaluar el efecto de la rabia sobre estas neuronas, se estudió mediante inmunohistoquímica la expresión de PV, CB y CR en la corteza frontal de ratones normales y ratones infectados con virus 'calle' o virus 'fijo' de la rabia. La PV se expresó en neuronas multipolares dispersas regularmente entre las capas II y VI, y en botones sinápticos que bordeaban el soma de las neuronas piramidales. La inmunorreactividad a CB se manifestó en dos franjas corticales: la primera, en las capas supragranulares II y III en neuronas con somas redondeados e inmersos en un neuropilo intensamente marcado; la segunda, en las capas infragranulares V y VI en neuronas multipolares dispersas y rodeadas por un neuropilo menos reactivo. La CR se expresó en neuronas bipolares con somas fusiformes distribuidas en las seis capas corticales, pero concentradas principalmente en las capas II y III. Hubo una característica común en las muestras infectadas con los dos tipos de virus: la inmunotinción a PV fue más intensa que en las muestras normales. La infección derivada del virus 'calle' no causó alteraciones adicionales en la expresión de las tres proteínas. En contraste, la infección con virus 'fijo' produjo una reducción notable del número de neuronas CB+, así como de la inmunorreactividad a CB en el neuropilo de la corteza frontal. Además, provocó una disminución significativa del tamaño de las neuronas CR+ en la corteza del cíngulo. Estos resultados aportan evidencia histológica en apoyo de la hipótesis según la cual las neuronas gabaérgicas son afectadas por el virus de la rabia.

Some clinical features of rabies and experimental evidence from cell culture and laboratory animals suggest impairment of gabaergic neurotransmission. Several types of gabaergic neurons occur in the cerebral cortex. They can be identified by three neuronal markers: the calcium binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR). Rabies virus spreads throughout the cerebral cortex; however, rabies cytopathic effects on gabaergic neurons are unknown. The expression of calcium-binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR) was studied in the frontal cortex of mice. The effect of gabaergic neurons was evaluated immunohistochemically. The distribution patterns of CaBPs in normal mice and in mice infected with 'fixed' or 'street' rabies virus were compared. PV was found in multipolar neurons located in all cortical layers except layer I, and in pericellular clusters of terminal knobs surrounding the soma of pyramidal neurons. CB-immunoreactivity was distributed in two cortical bands. One was composed of round neurons enclosed by a heavily labeled neuropil; this band corresponds to supragranular layers II and III. The other was a weakly stained band of neuropil which contained scattered multipolar CB-ir neurons; this corresponds to infragranular layers V and VI. The CR-ir neurons were bipolar fusiform cells located in all layers of cortex, but concentrated in layers II and III. A feature common to samples infected with both types of viruses was a more intense immunoreactivity to PV in contrast to normal samples. The infection with 'street' virus did not cause additional changes in the expression of CaBPs. However, the infection with 'fixed' virus produced a remarkable reduction of CB-immunoreactivity demonstrated by the loss of CB-ir neurons and low neuropil stain in the frontal cortex. In addition, the size of CR-ir neurons in the cingulate cortex was decreased.