Your search keyword '"Gerasimenko, Alexander"' showing total 19 results

1. Conductive Biocomposite Made by Two-Photon Polymerization of Hydrogels Based on BSA and Carbon Nanotubes with Eosin-Y.

Author

Savelyev, Mikhail S., Kuksin, Artem V., Murashko, Denis T., Otsupko, Ekaterina P., Kurilova, Ulyana E., Selishchev, Sergey V., and Gerasimenko, Alexander Yu.

Subjects

SINGLE walled carbon nanotubes, BRAIN-computer interfaces, STRUCTURAL engineering, ABSORPTION cross sections, CARBON nanotubes

Abstract

Currently, tissue engineering technologies are promising for the restoration of damaged organs and tissues. For regeneration of electrically conductive tissues or neural interfaces, it is necessary to provide electrical conductivity for the transmission of electrophysiological signals. The developed biocomposite structures presented in this article possess such properties. Their composition includes bovine serum albumin (BSA), gelatin, eosin-Y and single-walled carbon nanotubes (SWCNTs). For the first time, a biocomposite structure was formed from the proposed hydrogel using a nanosecond laser, and a two-photon absorption cross section value of 580 GM was achieved. Increased viscosity over 3 mPa∙s and self-focusing with a nonlinear refractive index of 42 × 10−12 cm2/W make it possible to create a biocomposite structure over the entire specified area. The obtained electrical conductivity value was 19 mS∙cm−1, due to the formation of effective electrically conductive networks. For a biocomposite with a concentration of gelatin 3 wt. %, formed by low-energy near-IR pulses, the survival of Neuro 2A nerve tissue cells was confirmed. The obtained results are important for the creation of new tissue engineering structures and neural interfaces from a biopolymer hydrogel based on the organic dye eosin-Y and carbon nanotubes by two-photon polymerization. [ABSTRACT FROM AUTHOR]

Published

2024

2. Preparation of Linear Actuators Based on Polyvinyl Alcohol Hydrogels Activated by AC Voltage.

Author

Dayyoub, Tarek, Maksimkin, Aleksey, Larionov, Dmitry I., Filippova, Olga V., Telyshev, Dmitry V., and Gerasimenko, Alexander Yu.

Subjects

POLYVINYL alcohol, GASES, ACTUATORS, HYDROGELS, CONDUCTING polymers, VOLTAGE, ARTIFICIAL muscles

Abstract

Currently, the preparation of actuators based on ionic electroactive polymers with a fast response is considered an urgent topic. In this article, a new approach to activate polyvinyl alcohol (PVA) hydrogels by applying an AC voltage is proposed. The suggested approach involves an activation mechanism in which the PVA hydrogel-based actuators undergo extension/contraction (swelling/shrinking) cycles due to the local vibration of the ions. The vibration does not cause movement towards the electrodes but results in hydrogel heating, transforming the water molecules into a gaseous state and causing the actuator to swell. Two types of linear actuators based on PVA hydrogels were prepared, using two types of reinforcement for the elastomeric shell (spiral weave and fabric woven braided mesh). The extension/contraction of the actuators, activation time, and efficiency were studied, considering the PVA content, applied voltage, frequency, and load. It was found that the overall extension of the spiral weave-reinforced actuators under a load of ~20 kPa can reach more than 60%, with an activation time of ~3 s by applying an AC voltage of 200 V and a frequency of 500 Hz. Conversely, the overall contraction of the actuators reinforced by fabric woven braided mesh under the same conditions can reach more than 20%, with an activation time of ~3 s. Moreover, the activation force (swelling load) of the PVA hydrogels can reach up to 297 kPa. The developed actuators have broad applications in medicine, soft robotics, the aerospace industry, and artificial muscles. [ABSTRACT FROM AUTHOR]

Published

2023

3. Laser-Formed Sensors with Electrically Conductive MWCNT Networks for Gesture Recognition Applications.

Author

Nikitina, Natalia A., Ryabkin, Dmitry I., Suchkova, Victoria V., Kuksin, Artem V., Pyankov, Evgeny S., Ichkitidze, Levan P., Maksimkin, Aleksey V., Kitsyuk, Evgeny P., Gerasimenko, Ekaterina A., Telyshev, Dmitry V., Bobrinetskiy, Ivan, Selishchev, Sergey V., and Gerasimenko, Alexander Yu.

Subjects

MICROCONTROLLERS, MULTIWALLED carbon nanotubes, STRAINS & stresses (Mechanics), INTELLIGENT sensors, DETECTORS, YOUNG'S modulus

Abstract

Currently, an urgent need in the field of wearable electronics is the development of flexible sensors that can be attached to the human body to monitor various physiological indicators and movements. In this work, we propose a method for forming an electrically conductive network of multi-walled carbon nanotubes (MWCNT) in a matrix of silicone elastomer to make stretchable sensors sensitive to mechanical strain. The electrical conductivity and sensitivity characteristics of the sensor were improved by using laser exposure, through the effect of forming strong carbon nanotube (CNT) networks. The initial electrical resistance of the sensors obtained using laser technology was ~3 kOhm (in the absence of deformation) at a low concentration of nanotubes of 3 wt% in composition. For comparison, in a similar manufacturing process, but without laser exposure, the active material had significantly higher values of electrical resistance, which was ~19 kOhm in this case. The laser-fabricated sensors have a high tensile sensitivity (gauge factor ~10), linearity of >0.97, a low hysteresis of 2.4%, tensile strength of 963 kPa, and a fast strain response of 1 ms. The low Young's modulus values of ~47 kPa and the high electrical and sensitivity characteristics of the sensors made it possible to fabricate a smart gesture recognition sensor system based on them, with a recognition accuracy of ~94%. Data reading and visualization were performed using the developed electronic unit based on the ATXMEGA8E5-AU microcontroller and software. The obtained results open great prospects for the application of flexible CNT sensors in intelligent wearable devices (IWDs) for medical and industrial applications. [ABSTRACT FROM AUTHOR]

Published

2023

4. Effects of Intermittent Hypoxia and Electrical Muscle Stimulation on Cognitive and Physiological Metrics.

Author

Reganova, Elizaveta, Solovyeva, Ksenia, Buyanov, Dmitriy, Gerasimenko, Alexander Yu., and Repin, Dmitry

Subjects

ELECTRIC stimulation, FUNCTIONAL connectivity, HYPOXEMIA, MIDDLE-aged men, COGNITIVE ability

Abstract

Objectives: This study describes the effects of interval hypoxic training and electrical muscle stimulation (EMS) technology on human productivity with the following metrics: biochemical indices, cognitive abilities, changes in oxygenated (HbO) and deoxygenated (Hb) hemoglobin concentrations over the prefrontal cortex, and functional connectivity via electroencephalography (EEG). Methods: All measurements according to the described technology were made before the start of training and one month later, right after it ended. The study involved middle-aged Indo-European men. Specifically, there were 14, 15, and 18 participants in the control, hypoxic, and EMS groups, respectively. Results: EMS training improved reactions and nonverbal memory but decreased attention scores. Functional connectivity decreased in the EMS group while it increased in the hypoxic group. A result of the interval normobaric hypoxic training (IHT) was significantly improved contextual memory, with a p-value = 0.08. Conclusions: It was found that EMS training is more likely to cause stress on the body than positively affect cognitive functions. At the same time, interval hypoxic training can be considered a promising direction for increasing human productivity. The data obtained during the study can also help in the timely diagnosis of insufficient or overestimated indicators of biochemistry. [ABSTRACT FROM AUTHOR]

Published

2023

5. Nonlinear Optical Response of Dispersed Medium Based on Conjugates Single-Walled Carbon Nanotubes with Phthalocyanines.

Author

Vasilevsky, Pavel N., Savelyev, Mikhail S., Tolbin, Alexander Yu., Kuksin, Artem V., Vasilevskaya, Yulia O., Orlov, Andrey P., Shaman, Yury P., Dudin, Alexander A., Pavlov, Alexander A., and Gerasimenko, Alexander Yu.

Subjects

LASER beams, LASER pulses, LIGHT absorption, ND-YAG lasers, PHTHALOCYANINES, CARBON nanotubes, DIMETHYL sulfoxide

Abstract

Nanosecond lasers have recently been widely involved in human activity. However, high-intensity laser radiation can cause severe damage to organs of vision and expensive photonic devices. Radiation in the near UV range is especially dangerous for human eyes, since it is strongly absorbed by biological media and is also invisible, i.e., the reaction time of the eye to such radiation is much lower than that of visible light. Passive limiters have high transmission (>70%) at a low light intensity and begin to "darken" only when the threshold value of the laser radiation intensity is reached. In this work, we studied liquid nanodispersed nonlinear optical limiters based on hybrids of single-walled carbon nanotubes (SWCNTs) with metal-free tetra(hydroxy)phthalocyanine (OH)4PcHH). The value of the hydrodynamic radius of separate particles after (OH)4PcHH binding increased from 288 ± 55 nm to 350 ± 60 nm, which confirms the attachment of phthalocyanine complexes to nanotubes. The third harmonic of a Nd:YAG nanosecond laser (355 nm, 20 ns) was used to study the nonlinear optical response. Based on a Z-scan with open-aperture and input-output dependence curves, third-order nonlinear optical absorption coefficients of 149, 236, and 229 cm/GW were obtained for dispersions of composites of SWCNTs and (OH)4PcHH in water, dimethylformamide (DMF), and dimethylsulfoxide (DMSO), respectively. Threshold values did not exceed 100 mJ/cm2. The Z-scan showed a gradual decrease in the duration of the laser pulse by 53%; however, near the focus, there was a sharp increase in the duration of the transmitted pulse, reaching a value of 29 ns in z = 0. This phenomenon confirms the occurrence of reverse saturable absorption in the investigated media and can be used in photonic devices to control the temporal characteristics of the signal. Thus, the possibility of protection of sensitive photonic devices and human eyes from nanosecond laser pulses in the near UV range by nanodispersed liquid media based on composites of SWCNTs with (OH)4PcHH has been discussed in this paper. [ABSTRACT FROM AUTHOR]

Published

2023

6. Stability and Thrombogenicity Analysis of Collagen/Carbon Nanotube Nanocomposite Coatings Using a Reversible Microfluidic Device.

Author

Popovich, Kristina D., Vagner, Sergey A., Murashko, Denis T., Ten, Galina N., Ryabkin, Dmitry I., Savelyev, Mikhail S., Kitsyuk, Evgeny P., Gerasimenko, Ekaterina A., Edelbekova, Polina, Konovalov, Anton N., Telyshev, Dmitry V., Selishchev, Sergey V., and Gerasimenko, Alexander Yu.

Published

2023

7. Tapered Optical Fiber Sensor Coated with Single-Walled Carbon Nanotubes for Dye Sensing Application.

Author

Polokhin, Aleksandr A., Shaman, Yuri P., Itrin, Pavel A., Panyaev, Ivan S., Sysa, Artem A., Selishchev, Sergey V., Kitsyuk, Evgeny P., Pavlov, Alexander A., and Gerasimenko, Alexander Yu.

Subjects

OPTICAL fiber detectors, CARBON nanotubes, OPTICAL fibers, RHODAMINE B, RAMAN spectroscopy, SURFACE coatings

Abstract

The present study aimed to improve the optical sensing performance of tapered optical fiber sensors toward aqueous Rhodamine B solution of different concentrations by applying single-walled carbon nanotubes (SWCNTs). The functional coating was formed on the surface of the tapered optical fiber sensor using an aerosol layer-by-layer deposition method. Before deposition, the SWCNTs were processed with multistage liquid-phase treatment in order to form a stable dispersion. The effect of SWCNT treatment was investigated through Raman spectroscopy. The deposition of 220 layers caused a reduction of up to 60% of the initial optical power of radiation propagating through the optical fiber core. The optical fiber sensor coated with SWCNTs demonstrated significantly higher sensitivity compared to a non-coated sensor in the range of 2–32 mg/L of Rhodamine B concentration in an aqueous solution. The experimental results demonstrated that the sensitivity was increased 10 times from 32 (mg/L)−1, for the non-coated sensor, up to 317 (mg/L)−1 after SWCNT coating deposition. Moreover, the SWCNT-coated sensor demonstrated high repeatability that allowed for the evaluation of the concentration regardless of the previously analyzed dye concentration. [ABSTRACT FROM AUTHOR]

Published

2023

8. Strain Sensor Based on Biological Nanomaterial

Author

Ichkitidze, Levan P., primary, Gerasimenko, Alexander Yu., additional, Telyshev, Dmitry V., additional, Kitsyuk, Eugeny P., additional, Petukhov, Vladimir A., additional, and Selishchev, Sergei V., additional

Published

2021

9. Hybrid Carbon Nanotubes–Graphene Nanostructures: Modeling, Formation, Characterization.

Author

Gerasimenko, Alexander Yu., Kuksin, Artem V., Shaman, Yury P., Kitsyuk, Evgeny P., Fedorova, Yulia O., Murashko, Denis T., Shamanaev, Artemiy A., Eganova, Elena M., Sysa, Artem V., Savelyev, Mikhail S., Telyshev, Dmitry V., Pavlov, Alexander A., and Glukhova, Olga E.

Subjects

*FIELD emission, *LASER beams, *ELECTRIC conductivity, *ELECTRON transport, *DIPOLE moments

Abstract

A technology for the formation and bonding with a substrate of hybrid carbon nanostructures from single-walled carbon nanotubes (SWCNT) and reduced graphene oxide (rGO) by laser radiation is proposed. Molecular dynamics modeling by the real-time time-dependent density functional tight-binding (TD-DFTB) method made it possible to reveal the mechanism of field emission centers formation in carbon nanostructures layers. Laser radiation stimulates the formation of graphene-nanotube covalent contacts and also induces a dipole moment of hybrid nanostructures, which ensures their orientation along the force lines of the radiation field. The main mechanical and emission characteristics of the formed hybrid nanostructures were determined. By Raman spectroscopy, the effect of laser radiation energy on the defectiveness of all types of layers formed from nanostructures was determined. Laser exposure increased the hardness of all samples more than twice. Maximum hardness was obtained for hybrid nanostructure with a buffer layer (bl) of rGO and the main layer of SWCNT—rGO(bl)-SWCNT and was 54.4 GPa. In addition, the adhesion of rGO to the substrate and electron transport between the substrate and rGO(bl)-SWCNT increased. The rGO(bl)-SWCNT cathode with an area of ~1 mm2 showed a field emission current density of 562 mA/cm2 and stability for 9 h at a current of 1 mA. The developed technology for the formation of hybrid nanostructures can be used both to create high-performance and stable field emission cathodes and in other applications where nanomaterials coating with good adhesion, strength, and electrical conductivity is required. [ABSTRACT FROM AUTHOR]

Published

2022

10. Electroactive Polymer-Based Composites for Artificial Muscle-like Actuators: A Review.

Author

Maksimkin, Aleksey V., Dayyoub, Tarek, Telyshev, Dmitry V., and Gerasimenko, Alexander Yu.

Subjects

CONDUCTING polymers, FERROELECTRIC polymers, ACTUATORS, ELECTROACTIVE substances, ROBUST control, POLYMER colloids, SHAPE memory polymers, TUNGSTEN bronze

Abstract

Unlike traditional actuators, such as piezoelectric ceramic or metallic actuators, polymer actuators are currently attracting more interest in biomedicine due to their unique properties, such as light weight, easy processing, biodegradability, fast response, large active strains, and good mechanical properties. They can be actuated under external stimuli, such as chemical (pH changes), electric, humidity, light, temperature, and magnetic field. Electroactive polymers (EAPs), called 'artificial muscles', can be activated by an electric stimulus, and fixed into a temporary shape. Restoring their permanent shape after the release of an electrical field, electroactive polymer is considered the most attractive actuator type because of its high suitability for prosthetics and soft robotics applications. However, robust control, modeling non-linear behavior, and scalable fabrication are considered the most critical challenges for applying the soft robotic systems in real conditions. Researchers from around the world investigate the scientific and engineering foundations of polymer actuators, especially the principles of their work, for the purpose of a better control of their capability and durability. The activation method of actuators and the realization of required mechanical properties are the main restrictions on using actuators in real applications. The latest highlights, operating principles, perspectives, and challenges of electroactive materials (EAPs) such as dielectric EAPs, ferroelectric polymers, electrostrictive graft elastomers, liquid crystal elastomers, ionic gels, and ionic polymer–metal composites are reviewed in this article. [ABSTRACT FROM AUTHOR]

Published

2022

11. Reconstruction of Soft Biological Tissues Using Laser Soldering Technology with Temperature Control and Biopolymer Nanocomposites.

Author

Gerasimenko, Alexander Yu., Morozova, Elena A., Ryabkin, Dmitry I., Fayzullin, Alexey, Tarasenko, Svetlana V., Molodykh, Victoria V., Pyankov, Evgeny S., Savelyev, Mikhail S., Sorokina, Elena A., Rogalsky, Alexander Y., Shekhter, Anatoly, and Telyshev, Dmitry V.

Subjects

*SEMICONDUCTOR lasers, *TEMPERATURE control, *SOLDER & soldering, *HEAT radiation & absorption, *LASER welding, *BIOPOLYMERS, *TISSUES

Abstract

Laser soldering is a current biophotonic technique for the surgical recovery of the integrity of soft tissues. This technology involves the use of a device providing laser exposure to the cut edges of the wound with a solder applied. The proposed solder consisted of an aqueous dispersion of biopolymer albumin (25 wt.%), single-walled carbon nanotubes (0.1 wt.%) and exogenous indocyanine green chromophore (0.1 wt.%). Under laser exposure, the dispersion transforms into a nanocomposite due to the absorption of radiation and its conversion into heat. The nanocomposite is a frame structure of carbon nanotubes in a biopolymer matrix, which provides adhesion of the wound edges and the formation of a strong laser weld. A new laser device based on a diode laser (808 nm) has been developed to implement the method. The device has a temperature feedback system based on a bolometric infrared matrix sensor. The system determines the hottest area of the laser weld and adjusts the current supplied to the diode laser to maintain the preset laser heating temperature. The laser soldering technology made it possible to heal linear defects (cuts) in the skin of laboratory animals (rabbits) without the formation of a fibrotic scar compared to the control (suture material). The combined use of a biopolymer nanocomposite solder and a laser device made it possible to achieve a tensile strength of the laser welds of 4 ± 0.4 MPa. The results of the experiment demonstrated that the addition of single-walled carbon nanotubes to the solder composition leads to an increase in the ultimate tensile strength of the laser welds by 80%. The analysis of regenerative and morphological features in the early stages (1–3 days) after surgery revealed small wound gaps, a decrease in inflammation, the absence of microcirculatory disorders and an earlier epithelization of laser welds compared to the control. On the 10th day after the surgical operation, the laser weld was characterized by a thin cosmetic scar and a continuous epidermis covering the defect. An immunohistochemical analysis proved the absence of myofibroblasts in the area of the laser welds. [ABSTRACT FROM AUTHOR]

Published

2022

12. Interfaces Based on Laser-Structured Arrays of Carbon Nanotubes with Albumin for Electrical Stimulation of Heart Cell Growth.

Author

Gerasimenko, Alexander Yu., Kitsyuk, Evgeny, Kurilova, Uliana E., Suetina, Irina A., Russu, Leonid, Mezentseva, Marina V., Markov, Aleksandr, Narovlyansky, Alexander N., Kravchenko, Sergei, Selishchev, Sergey V., and Glukhova, Olga E.

Subjects

*CARBON nanotubes, *ELECTRIC stimulation, *HEART cells, *MULTIWALLED carbon nanotubes, *CELL growth, *BIOELECTRONICS

Abstract

Successful formation of electronic interfaces between living cells and electronic components requires both good cell viability and performance level. This paper presents a technology for the formation of nanostructured arrays of multi-walled carbon nanotubes (MWCNT) in biopolymer (albumin) layer for higher biocompatibility. The layer of liquid albumin dispersion was sprayed on synthesized MWCNT arrays by deposition system. These nanostructures were engineered using the nanosecond pulsed laser radiation mapping in the near-IR spectral range (λ = 1064 nm). It was determined that the energy density of 0.015 J/cm2 provided a sufficient structuring of MWCNT. The structuring effect occurred during the formation of C–C bonds simultaneously with the formation of a cellular structure of nanotubes in the albumin matrix. It led to a decrease in the nanotube defectiveness, which was observed during the Raman spectroscopy. In addition, laser structuring led to a more than twofold increase in the electrical conductivity of MWCNT arrays with albumin (215.8 ± 10 S/m). Successful electric stimulation of cells on the interfaces with the system based on a culture plate was performed, resulting in the enhanced cell proliferation. Overall, the MWCNT laser-structured arrays with biopolymers might be a promising material for extended biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2022

13. Laser Technology for the Formation of Bioelectronic Nanocomposites Based on Single-Walled Carbon Nanotubes and Proteins with Different Structures, Electrical Conductivity and Biocompatibility.

Author

Gerasimenko, Alexander Yu., Kurilova, Uliana E., Suetina, Irina A., Mezentseva, Marina V., Zubko, Aleksandr V., Sekacheva, Marina I., and Glukhova, Olga E.

Subjects

PROTEIN structure, ELECTRIC conductivity, CARBON nanotubes, NANOCOMPOSITE materials, SEMICONDUCTOR lasers, FEEDBACK control systems, NANOTUBES, BIOCOMPATIBILITY

Abstract

A laser technology for creating nanocomposites from alternating layers of albumin/collagen proteins with two types of single-walled carbon nanotubes (SWCNT) at concentrations of 0.001 and 0.01 wt.% was proposed. For this purpose, a setup with a diode laser (810 nm) and feedback system for controlling the temperature of the area affected by the radiation was developed. Raman spectroscopy was used to determine a decrease in the defectiveness of SWCNT with an increase in their concentration in the nanocomposite due to the formation of branched 3D networks with covalent bonds between nanotubes. It was revealed that adhesion of proteins to branched 3D networks from SWCNT occurred. The specific electrical conductivity of nanocomposites based on large SWCNT nanotubes was 3.2 and 4.3 S/m compared to that for nanocomposites based on small SWCNT with the same concentrations—1.1 and 1.8 S/m. An increase in the concentration and size of nanotubes provides higher porosity of nanocomposites. For small SWCNT-based nanocomposites, a significant number of mesopores up to 50 nm in size and the largest specific surface area and specific pore volume were found. Nanocomposites with small SWCNT (0.001 wt.%) provided the best cardiac fibroblast viability. Such technology can be potentially used to create bioelectronic components or scaffolds for heart tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2021

14. Fontan Hemodynamics Investigation via Modeling and Experimental Characterization of Idealized Pediatric Total Cavopulmonary Connection.

Author

Porfiryev, Andrey, Markov, Aleksandr, Galyastov, Andrey, Denisov, Maxim, Burdukova, Olga, Gerasimenko, Alexander Yu., and Telyshev, Dmitry

Subjects

FLOW velocity, HEART transplant recipients, HEART transplantation, HUMAN body, PALLIATIVE treatment

Abstract

Simulation of the human body normal operating conditions is the important issue in the engineering process of designing biomedical devices intended for implantation. As an example of such process the Fontan procedure aims to support the human body function. It is a standard palliative treatment method for patients with a functionally univentricular heart. Nevertheless, this procedure has significant drawbacks. For instance, overload of the only functional ventricle leads to the inevitability of the heart transplantation. Herein, we perform simulation and experimental characteristics of the pediatric total cavopulmonary connection (TCPC) influence on the blood flow. We investigate and design three different types of pediatric TCPC configurations; we detect fluorescent particles via a high-speed camera in order to analyze distribution of the blood flow velocity modulus in different types of TCPCs. Finally, we evaluate hydraulic power losses for various cases. This work is particularly relevant for the improvement of existing TCPCs quality that can extend the life of Fontan patients. Moreover, it also applies to the reduction of morbidity and mortality of the patients waiting for a heart transplantation. [ABSTRACT FROM AUTHOR]

Published

2020

15. Flexible Strain-Sensitive Silicone-CNT Sensor for Human Motion Detection.

Author

Demidenko, Natalia A., Kuksin, Artem V., Molodykh, Victoria V., Pyankov, Evgeny S., Ichkitidze, Levan P., Zaborova, Victoria A., Tsymbal, Alexandr A., Tkachenko, Svetlana A., Shafaei, Hassan, Diachkova, Ekaterina, and Gerasimenko, Alexander Yu.

Subjects

TEMPERATURE coefficient of electric resistance, MULTIWALLED carbon nanotubes, LASER beams, SIGNAL processing, STRENGTH of materials, MOTION detectors

Abstract

This article describes the manufacturing technology of biocompatible flexible strain-sensitive sensor based on Ecoflex silicone and multi-walled carbon nanotubes (MWCNT). The sensor demonstrates resistive behavior. Structural, electrical, and mechanical characteristics are compared. It is shown that laser radiation significantly reduces the resistance of the material. Through laser radiation, electrically conductive networks of MWCNT are formed in a silicone matrix. The developed sensor demonstrates highly sensitive characteristics: gauge factor at 100% elongation −4.9, gauge factor at 90° bending −0.9%/deg, stretchability up to 725%, tensile strength 0.7 MPa, modulus of elasticity at 100% 46 kPa, and the temperature coefficient of resistance in the range of 30–40 °C is −2 × 10−3. There is a linear sensor response (with 1 ms response time) with a low hysteresis of ≤3%. An electronic unit for reading and processing sensor signals based on the ATXMEGA8E5-AU microcontroller has been developed. The unit was set to operate the sensor in the range of electrical resistance 5–150 kOhm. The Bluetooth module made it possible to transfer the received data to a personal computer. Currently, in the field of wearable technologies and health monitoring, a vital need is the development of flexible sensors attached to the human body to track various indicators. By integrating the sensor with the joints of the human hand, effective movement sensing has been demonstrated. [ABSTRACT FROM AUTHOR]

Published

2022

16. Electrically Conductive Networks from Hybrids of Carbon Nanotubes and Graphene Created by Laser Radiation.

Author

Gerasimenko, Alexander Yu., Kuksin, Artem V., Shaman, Yury P., Kitsyuk, Evgeny P., Fedorova, Yulia O., Sysa, Artem V., Pavlov, Alexander A., and Glukhova, Olga E.

Subjects

*LASER beams, *CARBON nanotubes, *MULTIWALLED carbon nanotubes, *ELECTROMAGNETIC wave absorption, *FLEXIBLE electronics, *ELECTRIC conductivity

Abstract

A technology for the formation of electrically conductive nanostructures from single-walled carbon nanotubes (SWCNT), multi-walled carbon nanotubes (MWCNT), and their hybrids with reduced graphene oxide (rGO) on Si substrate has been developed. Under the action of single pulses of laser irradiation, nanowelding of SWCNT and MWCNT nanotubes with graphene sheets was obtained. Dependences of electromagnetic wave absorption by films of short and long nanotubes with subnanometer and nanometer diameters on wavelength are calculated. It was determined from dependences that absorption maxima of various types of nanotubes are in the wavelength region of about 266 nm. It was found that contact between nanotube and graphene was formed in time up to 400 fs. Formation of networks of SWCNT/MWCNT and their hybrids with rGO at threshold energy densities of 0.3/0.5 J/cm2 is shown. With an increase in energy density above the threshold value, formation of amorphous carbon nanoinclusions on the surface of nanotubes was demonstrated. For all films, except the MWCNT film, an increase in defectiveness after laser irradiation was obtained, which is associated with appearance of C–C bonds with neighboring nanotubes or graphene sheets. CNTs played the role of bridges connecting graphene sheets. Laser-synthesized hybrid nanostructures demonstrated the highest hardness compared to pure nanotubes. Maximum hardness (52.7 GPa) was obtained for MWCNT/rGO topology. Regularity of an increase in electrical conductivity of nanostructures after laser irradiation has been established for films made of all nanomaterials. Hybrid structures of nanotubes and graphene sheets have the highest electrical conductivity compared to networks of pure nanotubes. Maximum electrical conductivity was obtained for MWCNT/rGO hybrid structure (~22.6 kS/m). Networks of nanotubes and CNT/rGO hybrids can be used to form strong electrically conductive interconnections in nanoelectronics, as well as to create components for flexible electronics and bioelectronics, including intelligent wearable devices (IWDs). [ABSTRACT FROM AUTHOR]

Published

2021

17. Biocompatible SWCNT Conductive Composites for Biomedical Applications.

Author

Markov, Aleksandr, Wördenweber, Roger, Ichkitidze, Levan, Gerasimenko, Alexander, Kurilova, Ulyana, Suetina, Irina, Mezentseva, Marina, Offenhäusser, Andreas, and Telyshev, Dmitry

Subjects

BIOMECHANICS, BIOELECTRONICS, BIOCOMPATIBILITY, BIOLOGICAL systems, SERUM albumin, BIOMEDICAL materials, ELECTRIC conductivity

Abstract

The efficiency of devices for biomedical applications, including tissue engineering and neuronal stimulation, heavily depends on their biocompatibility and performance level. Therefore, it is important to find adequate materials that meet the necessary requirements such as (i) being intrinsically compatible with biological systems, (ii) providing a sufficient electronic conductivity that promotes efficient signal transduction, (iii) having "soft" mechanical properties comparable to biological structures, and (iv) being degradable in physiological solution. We have developed organic conducting biocompatible single-walled carbon nanotubes (SWCNT) composites based on bovine serum albumin, carboxymethylcellulose, and acrylic polymer and investigated their properties, which are relevant for biomedical applications. This includes ζ-potential measurements, conductivity analyses, and SEM micrographs, the latter providing a local analysis of SWCNT distribution in the base material. We observed the development of the electrical conductivity of the SWCNT composites exposed to 1 mM KCl electrolyte for 40 days, representing a high stability of the samples. The conductivity of samples reaches 1300 S/m for 0.45 wt.% nanotubes. Moreover, we demonstrated the biocompatibility of the composites via cultivating fibroblast cell culture. Finally, we showed that composite coating results in the longer lifespan of cells on the surface. Overall, the SWCNT-based conductive composites might be a promising material for extended biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2020

18. Frame Coating of Single-Walled Carbon Nanotubes in Collagen on PET Fibers for Artificial Joint Ligaments.

Author

Gerasimenko, Alexander Yu., Zhurbina, Natalia N., Cherepanova, Nadezhda G., Semak, Anna E., Zar, Vadim V., Fedorova, Yulia O., Eganova, Elena M., Pavlov, Alexander A., Telyshev, Dmitry V., Selishchev, Sergey V., and Glukhova, Olga E.

Subjects

*SYNTHETIC fibers, *ARTIFICIAL joints, *ADHESIVE tape, *SINGLE walled carbon nanotubes, *CARBON nanotubes, *COLLAGEN, *ARTIFICIAL knees

Abstract

The coating formation technique for artificial knee ligaments was proposed, which provided tight fixation of ligaments of polyethylene terephthalate (PET) fibers as a result of the healing of the bone channel in the short-term period after implantation. The coating is a frame structure of single-walled carbon nanotubes (SWCNT) in a collagen matrix, which is formed by layer-by-layer solidification of an aqueous dispersion of SWCNT with collagen during spin coating and controlled irradiation with IR radiation. Quantum mechanical method SCC DFTB, with a self-consistent charge, was used. It is based on the density functional theory and the tight-binding approximation. The method established the optimal temperature and time for the formation of the equilibrium configurations of the SWCNT/collagen type II complexes to ensure maximum binding energies between the nanotube and the collagen. The highest binding energies were observed in complexes with SWCNT nanometer diameter in comparison with subnanometer SWCNT. The coating had a porous structure—pore size was 0.5—6 μm. The process of reducing the mass and volume of the coating with the initial biodegradation of collagen after contact with blood plasma was demonstrated. This is proved by exceeding the intensity of the SWCNT peaks G and D after contact with the blood serum in the Raman spectrum and by decreasing the intensity of the main collagen bands in the SWCNT/collagen complex frame coating. The number of pores and their size increased to 20 μm. The modification of the PET tape with the SWCNT/collagen coating allowed to increase its hydrophilicity by 1.7 times compared to the original PET fibers and by 1.3 times compared to the collagen coating. A reduced hemolysis level of the PET tape coated with SWCNT/collagen was achieved. The SWCNT/collagen coating provided 2.2 times less hemolysis than an uncoated PET implant. MicroCT showed the effective formation of new bone and dense connective tissue around the implant. A decrease in channel diameter from 2.5 to 1.7 mm was detected at three and, especially, six months after implantation of a PET tape with SWCNT/collagen coating. MicroCT allowed us to identify areas for histological sections, which demonstrated the favorable interaction of the PET tape with the surrounding tissues. In the case of using the PET tape coated with SWCNT/collagen, more active growth of connective tissue with mature collagen fibers in the area of implantation was observed than in the case of only collagen coating. The stimulating effect of SWCNT/collagen on the formation of bone trabeculae around and inside the PET tape was evident in three and six months after implantation. Thus, a PET tape with SWCNT/collagen coating has osteoconductivity as well as a high level of hydrophilicity and hemocompatibility. [ABSTRACT FROM AUTHOR]

Published

2020

19. Protein-Polymer Matrices with Embedded Carbon Nanotubes for Tissue Engineering: Regularities of Formation and Features of Interaction with Cell Membranes.

Author

Slepchenkov, Michael M., Gerasimenko, Alexander Yu., Telyshev, Dmitry V., and Glukhova, Olga E.

Subjects

*CARBON nanotubes, *CELL membranes, *LASER beams, *RADIATION absorption, *POINT defects, *TISSUE engineering, *MULTIWALLED carbon nanotubes

Abstract

This paper reveals the mechanism of nanowelding a branched network of single-walled carbon nanotubes (SWCNTs) used as a framework for the formation of protein–polymer matrices with albumin, collagen, and chitosan. It is shown that the introduction of certain point defects into the structure of SWCNTs (single vacancy, double vacancy, Stone–Wales defect, and a mixed defect) allows us to obtain strong heating in defective regions as compared to ideal SWCNTs. The wavelengths at which absorption reaches 50% are determined. Non-uniform absorption of laser radiation along with inefficient heat removal in defective regions determines the formation of hot spots, in which nanowelding of SWCNTs is observed even at 0.36 nm between contacting surfaces. The regularities of formation of layered protein–polymer matrices and the features of their interaction with cell membrane are revealed. All studies are carried out in silico using high-precision quantum approaches. [ABSTRACT FROM AUTHOR]

Published

2019