[A device for endoluminal thermal obliteration of varicose veins].

Amongst the techniques of endoluminal thermal obliteration of varicose veins, the most commonly employed treatment modalities are endovasal radiofrequency ablation and endovasal laser obliteration, both using a generating source and a special device for carrying out thermal obliteration. It has been noted that each of the methods of thermal obliteration has a number of disadvantages, irrespective of using the energy of magnetic oscillations in a radiofrequency range or laser radiation, including high cost of expendable materials and equipment. The device we worked out for endoluminal thermal obliteration of varicose veins was based on the principle of high efficacy and safety, with a significant decrease in the cost of carrying out the manipulation.

[A new-type device for endovasal laser obliteration of varicose veins].

The purpose of the study was to work out a Russian-made, simple-to-manufacture, safe, inexpensive and efficient device for performing endovasal laser obliteration (EVLO) of varicose veins, with the underlying principle of endoluminal distribution of the total laser energy into several flows. The development of this device was based on the principle of dividing the total laser radiation into two energy flows. One flow has a shape of circularly formed, continuous field of laser radiation of specified width within the angular range from 50 to 90°, which ensures the main energetic contribution to thermal impact on the vascular wall.

Effect of wettability on sessile drop freezing: when superhydrophobicity stimulates an extreme freezing delay.

An increasing number of studies directed at supercooling water droplets on surfaces with different wettabilities have appeared in recent years. This activity has been stimulated by the recognition that water supercooling phenomena can be effectively used to develop methods for protecting outdoor equipment and infrastructure elements against icing and snow accretion. In this article, we discuss the nucleation kinetics of supercooled sessile water droplets on hydrophilic, hydrophobic, and superhydrophobic surfaces under isothermal conditions at temperatures of -8, -10, and -15 °C and a saturated water vapor atmosphere.

Femtosecond laser treatment for the design of electro-insulating superhydrophobic coatings with enhanced wear resistance on glass.

Femtosecond laser treatment of a glass surface was used to fabricate a multimodal roughness having regular surface ripples with a period of a few micrometers decorated by aggregates of nearly spherical nanoparticles. UV-ozone treatment followed by chemisorption of the appropriate functional fluorosilanes onto the textured surface makes it possible to fabricate a superhydrophobic coating with a specific surface resistance on the order of petaohms on a glass surface. The main advantage of the fabricated coating under severe operating conditions with abrasion loads is the significant durability of its electro-insulating properties.

Durable icephobic coating for stainless steel.

In this work, we present a modification of a stainless steel surface to impart superhydrophobic properties to it that are robust with respect to mechanical stresses associated with cyclic icing/deicing treatment, as well as to long-term contact with aqueous media and high humidity. The durability of the superhydrophobic state is ensured by the texture with multimodal roughness stable against mechanical stresses and a 2D polymer network of fluorooxysilane chemically bound to the texture elements. The designed superhydrophobic coating is characterized by contact angles exceeding 155° and a maximum rolling angle of 42° after 100 icing/deicing cycles.