Role of neuronal cell adhesion molecules and N-cadherin in passive avoidance training of rats

A comparative study of the role of specific adhesion proteins, NCAM (neuronal cell adhesion molecules) and N-cadherin, was carried out on rats subjected to passive avoidance training procedure. It was shown that antibodies against the Ca2+-dependent adhesion protein N-cadherin injected into the rat somatosensory cortical zone 6 h after passive avoidance training had been completed did not evoke a loss of the habit by experimental animals. At the same time, an absolute amnestic effect with respect to this reflex developed after injection of antibodies against NCAM. After injection of antibodies against the above-mentioned proteins into the dorsal part of the hippocampus, the avoidance habit also disappeared in the case of treat-ment with antibodies against NCAM and was kept under the influence of antibodies against N-cadherin. The data obtained testify that NCAM and N-cadherin play dissimilar roles in the formation of a memory trace in the course of training

Kinetic modelling of quantum effects in laser-beam interaction

We present the results of kinetic modelling of quantum effects in laser-beam interaction. In the developed numerical model, electron-positron pair production by hard photons, hard photon emission and the electromagnetic fields generated by the created charged particles are taken into account. Interaction of a relativistic electron beam with a strong laser pulse is analyzed. It is shown that the quantum effects can be important even for moderately intense laser pulses when the number of emitted photons by single electron is not large. Electron-positron pair plasma production in extremely-intense laser field via development of electromagnetic cascades is also studied. The simulation results confirm the prediction of strong laser field absorption in the self-generated electron-positron plasma. It is shown that the self-generated electron-positron plasma can be an efficient source of energetic gamma-quanta.Comment: Submitted to Nuclear Instruments and Methods in Physics Research

Radiation Emission by Extreme Relativistic Electrons and Pair Production by Hard Photons in a Strong Plasma Wakefield

Radiation spectrum of extreme relativistic electrons and a probability of electron-positron pair production by energetic photons in a strong plasma wakefield are derived in the framework of a semiclassical approach. It is shown that that the radiation losses of the relativistic electron in the plasma wakefield scale as $\propto \epsilon ^{2 / 3}$ in the quantum limit when the energy of the radiated photon becomes close to the electron energy, $\epsilon$. The quantum effects will play a key role in future plasma-based accelerators operating at ultrahigh energy of the electrons.Comment: 10 pages, 2 figure