Your search keyword '"Zheltikov AM"' showing total 4 results

1. Thermogenetic neurostimulation with single-cell resolution.

Author

Ermakova YG, Lanin AA, Fedotov IV, Roshchin M, Kelmanson IV, Kulik D, Bogdanova YA, Shokhina AG, Bilan DS, Staroverov DB, Balaban PM, Fedotov AB, Sidorov-Biryukov DA, Nikitin ES, Zheltikov AM, and Belousov VV

Subjects

Action Potentials, Animals, Cells, Cultured, Electrophysiology methods, HEK293 Cells, Hot Temperature, Humans, Ions, Lasers, Mice, Mice, Inbred C57BL, Microwaves, Snakes, Zebrafish, Calcium metabolism, Neurons metabolism, Thermogenesis, Transient Receptor Potential Channels physiology

Abstract

Thermogenetics is a promising innovative neurostimulation technique, which enables robust activation of neurons using thermosensitive transient receptor potential (TRP) cation channels. Broader application of this approach in neuroscience is, however, hindered by a limited variety of suitable ion channels, and by low spatial and temporal resolution of neuronal activation when TRP channels are activated by ambient temperature variations or chemical agonists. Here, we demonstrate rapid, robust and reproducible repeated activation of snake TRPA1 channels heterologously expressed in non-neuronal cells, mouse neurons and zebrafish neurons in vivo by infrared (IR) laser radiation. A fibre-optic probe that integrates a nitrogen-vacancy (NV) diamond quantum sensor with optical and microwave waveguide delivery enables thermometry with single-cell resolution, allowing neurons to be activated by exceptionally mild heating, thus preventing the damaging effects of excessive heat. The neuronal responses to the activation by IR laser radiation are fully characterized using Ca 2+ imaging and electrophysiology, providing, for the first time, a complete framework for a thermogenetic manipulation of individual neurons using IR light.

Published

2017

2. Multi-millijoule few-cycle mid-infrared pulses through nonlinear self-compression in bulk.

Author

Shumakova V, Malevich P, Ališauskas S, Voronin A, Zheltikov AM, Faccio D, Kartashov D, Baltuška A, and Pugžlys A

Abstract

The physics of strong-field applications requires driver laser pulses that are both energetic and extremely short. Whereas optical amplifiers, laser and parametric, boost the energy, their gain bandwidth restricts the attainable pulse duration, requiring additional nonlinear spectral broadening to enable few or even single cycle compression and a corresponding peak power increase. Here we demonstrate, in the mid-infrared wavelength range that is important for scaling the ponderomotive energy in strong-field interactions, a simple energy-efficient and scalable soliton-like pulse compression in a mm-long yttrium aluminium garnet crystal with no additional dispersion management. Sub-three-cycle pulses with >0.44 TW peak power are compressed and extracted before the onset of modulation instability and multiple filamentation as a result of a favourable interplay between strong anomalous dispersion and optical nonlinearity around the wavelength of 3.9 μm. As a manifestation of the increased peak power, we show the evidence of mid-infrared pulse filamentation in atmospheric air.

Published

2016

3. A strong-field driver in the single-cycle regime based on self-compression in a kagome fibre.

Author

Balciunas T, Fourcade-Dutin C, Fan G, Witting T, Voronin AA, Zheltikov AM, Gerome F, Paulus GG, Baltuska A, and Benabid F

Abstract

Over the past decade intense laser fields with a single-cycle duration and even shorter, subcycle multicolour field transients have been generated and applied to drive attosecond phenomena in strong-field physics. Because of their extensive bandwidth, single-cycle fields cannot be emitted or amplified by laser sources directly and, as a rule, are produced by external pulse compression-a combination of nonlinear optical spectral broadening followed up by dispersion compensation. Here we demonstrate a simple robust driver for high-field applications based on this Kagome fibre approach that ensures pulse self-compression down to the ultimate single-cycle limit and provides phase-controlled pulses with up to a 100 μJ energy level, depending on the filling gas, pressure and the waveguide length.

Published

2015

4. Optical devices: the friendly gas phase.

Author

Zheltikov AM

Subjects

Biosensing Techniques, Crystallization, Gases, Lasers, Light, Optical Devices, Optics and Photonics, Photons, Scattering, Radiation, Spectrum Analysis, Raman, Equipment Design, Physics methods, Physics trends

Published

2005