Atom probe tomography quantification of carbon in silicon.

Atom Probe Tomography (APT) was used to quantify carbon in implanted silicon at two various electric fields (~ 15 and 20 V/nm). Using equal proportions of implanted 12C and 13C, the numerous molecular ions that were observed were identified and their contribution to the carbon content statistically derived. Much more accurate carbon quantification was obtained in the lowest electric field analysis by comparing APT with Secondary Ion Mass Spectroscopy profiles. This was assigned to a lower amount of molecular ion dissociations. Furthermore, the number of self-interstitials trapped per carbon atom in clusters was derived. This value of interest for the microelectronics industry regarding dopant diffusion and implantation induced defects was estimated close to one, in agreement with the expected stoichiometry of the SiC phase present in the phase diagram. However, this was obtained only when using low electric field conditions.

The time-resolved and extreme conditions XAS (TEXAS) facility at the European Synchrotron Radiation Facility: the general-purpose EXAFS bending-magnet beamline BM23.

BM23 is the general-purpose EXAFS bending-magnet beamline at the ESRF, replacing the former BM29 beamline in the framework of the ESRF upgrade. Its mission is to serve the whole XAS user community by providing access to a basic service in addition to the many specialized instruments available at the ESRF. BM23 offers high signal-to-noise ratio EXAFS in a large energy range (5-75 keV), continuous energy scanning for quick-EXAFS on the second timescale and a micro-XAS station delivering a spot size of 4 µm × 4 µm FWHM. It is a user-friendly facility featuring a high degree of automation, online EXAFS data reduction and a flexible sample environment.

An exchangeable Bragg/Laue polychromator for energy-dispersive XAFS.

An original design for a cooled exchangeable polychromator for energy-dispersive XAFS (X-ray absorption fine structure) working either in the transmission configuration (Laue case) or in the reflection configuration (Bragg case) is presented. It enables the acquisition of X-ray absorption spectra between 5 and 25 keV with a spot size on the sample that can reach to less than 20 microm FWHM for some energies. Only 1 h is needed to exchange both benders in operative mode. Parallel transmission spectra with a bandpass between 5 and 10% can be obtained in the full energy range. The dispersive optics and mechanics of ID24 (ESRF, Grenoble, France) have been designed to obtain XAFS spectra in less than 1 s and, in some cases, in the millisecond range.

Functional recovery of forelimb response capacity after forelimb primary motor cortex damage in the rat is due to the reorganization of adjacent areas of cortex.

Functional recovery after brain damage has been described frequently and different mechanisms have been proposed to account for the observed recovery. One possible mechanism involves the capacity of one part of the brain to take over the function of another. A possible area for this to take place is in the cerebral cortex, where a variety of reorganizational processes have been described after different manipulations. We show in the present study that the forelimb force and response capacity of the rat, which becomes highly impaired after the bilateral ablation of the forelimb primary motor cortex, is recovered when the animals receive an electrical stimulation in the ventral tegmental nucleus contingent to each forelimb response in the task. Microstimulation mapping of the cortical areas adjacent to the forelimb primary motor cortex revealed the appearance of an area located caudolaterally to the forelimb primary motor cortex, where forelimb movements could be evoked in recovered animals but to a lesser extent in non-recovered animals. A positive and significant correlation was observed between the size of the reorganized forelimb area and the behavioral performance of the animals. Ablation of the forelimb reorganized area in recovered animals reinstated the forelimb behavioral impairment, while the same lesion in normal animals had no effect on the behavioral performance. The results indicate that recovery after bilateral forelimb primary motor cortex ablation may be due to the organization of specific adjacent areas in the cortex.

[Interactions between the immune system and the neuroendocrine system. Implications of the hypothalamo-hypophyseal-adrenal axis]. / Interacciones entre el sistema inmunitario y el sistema neuroendocrino. Implicaciones del eje hipotálamo-hipófisis-adrenal.

The immune and neuroendocrine systems are now recognized to be linked and involved in bidirectional communication. That interrelationship involves shared usage of common signal molecules and their receptors. The Immune System and its products can modulate neuroendocrine functions and neuroendocrine peptides and hormones can affect important immunological parameters. Specifically, this article review the evidence for immune-neuroendocrine interactions in relation to the Hypothalamic-Pituitary-Adrenocortical axis. Neuroendocrine-immune interactions appears to play an important role in psychosocial influences on immunologically resisted and mediated diseases.

PMR-relaxation and steric computations give unequivocal nucleoside conformations.

The configuration and the conformation of alpha and beta anomers of pyrazomycin, cytidine and pseudouridine in aqueous solution have been investigated by 1H-NMR at 250 MHz. T1 proton relaxation measurements are an excellent method to determine the conformation of the base around the glycosidic linkage. Frequently, steric hindrance considerations can help to decide which conformations are possible in nucleoside anomer pairs. The proton-proton coupling constants indicate that the N conformer is largely predominant in the alpha anomers while the S conformer is particularly abundant in beta-pyrazomycin. The steric hindrance is much larger for alpha than for beta-nucleosides and change of a C-C to a C-N glycosidic bond reduces considerably the rotational possibilities of the base. The relaxation data show that alpha-cytidine adopts the anti conformation with gamma = 200 degrees in good agreement with the crystal structure and with the sterical computations. In the other case, when the syn and anti conformations are sterically accessible, the orientation of the base may be completely different from one nucleoside to the other. It can be predicted neither from the crystal structure nor from comparisons with similar compounds. For alpha-pseudo-uridine the predominant orientation of the base (gamma = 120 degrees) is in the boundary of the syn-anti regions; for beta-cytidine the syn (gamma = 65 degrees) and anti (gamma = 215 degrees) conformations are equiprobable at room temperature while beta-pseudouridine shows the syn conformation with gamma = 40 degrees, the smallest angle observed until now. There is no correlation between the N/S and syn-anti ratios.