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Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications. / Dorovskikh, Svetlana I.; Vikulova, Evgeniia S.; Kal’nyi, Danila B. et al.

In: Journal of Materials Science: Materials in Medicine, Vol. 30, No. 6, 01.06.2019, p. 69.

Research output: Contribution to journalArticlepeer-review

Harvard

Dorovskikh, SI, Vikulova, ES, Kal’nyi, DB, Shubin, YV, Asanov, IP, Maximovskiy, EA, Gutakovskii, AK, Morozova, NB & Basova, TV 2019, 'Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications', Journal of Materials Science: Materials in Medicine, vol. 30, no. 6, pp. 69. https://doi.org/10.1007/s10856-019-6275-1

APA

Dorovskikh, S. I., Vikulova, E. S., Kal’nyi, D. B., Shubin, Y. V., Asanov, I. P., Maximovskiy, E. A., Gutakovskii, A. K., Morozova, N. B., & Basova, T. V. (2019). Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications. Journal of Materials Science: Materials in Medicine, 30(6), 69. https://doi.org/10.1007/s10856-019-6275-1

Vancouver

Dorovskikh SI, Vikulova ES, Kal’nyi DB, Shubin YV, Asanov IP, Maximovskiy EA et al. Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications. Journal of Materials Science: Materials in Medicine. 2019 Jun 1;30(6):69. doi: 10.1007/s10856-019-6275-1

Author

Dorovskikh, Svetlana I. ; Vikulova, Evgeniia S. ; Kal’nyi, Danila B. et al. / Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications. In: Journal of Materials Science: Materials in Medicine. 2019 ; Vol. 30, No. 6. pp. 69.

BibTeX

@article{cca01530f40740f7b5f474a922ceed43,
title = "Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications",
abstract = "Biocompatible PtxIr(1−x) layers combining high mechanical strength of the iridium component and outstanding corrosion resistance of the platinum component providing reversible charge transfer reactions in the living tissue are one of the important materials required for implantable medical electrodes. The modern trend to complicate the shape and reduce the electrode dimensions includes the challenge to develop precise methods to obtain such bimetallic coatings with enhanced surface area and advanced electrochemical characteristics. Herein, PtxIr(1−x) coatings were firstly obtained on cathode and anode pole tips of endocardial electrodes for pacemakers using chemical vapor deposition technique. To deposit PtxIr(1−x) coatings with a wide range of metal ratios (x = 0.5–0.9) the combination of acetylacetonate-based volatile precursors with compatible thermal characteristics was used for the first time. The expected metal ratio in the coatings was regulated by a partial pressure of the precursor vapors in the reaction zone and was in the good agreement with its real value measured by various methods, including energy-dispersive and wavelength dispersive spectroscopy, X-ray photoelectron spectroscopy. According to the X-ray powder diffraction analysis, PtxIr(1−x) coatings consisted of fcc-PtxIr(1−x) solid solution phases. The microscopy data confirmed the formation of PtxIr1−x coatings with the enhanced surface areas. The effect of electrochemical activation on the surface composition and morphology of the samples was studied. The electrochemical characteristics of samples were estimated from cyclic voltammetry and electrochemical impedance spectroscopy data. The charge storage capacity (CSC) values of activated samples were in the range of 19–108 mCcm−2 (phosphate buffer saline solution, 100 mV/s).",
keywords = "Bimetallic coating, Charge storage capacity, Electrode, MOCVD, Pacemaker, CHARGE-INJECTION, ACTIVATION, CHEMICAL-VAPOR-DEPOSITION, IRIDIUM OXIDE AIROF, ELECTRODES, IR, NEURAL STIMULATION, FILMS, ELECTROCHEMICAL-BEHAVIOR, LAYER",
author = "Dorovskikh, {Svetlana I.} and Vikulova, {Evgeniia S.} and Kal{\textquoteright}nyi, {Danila B.} and Shubin, {Yury V.} and Asanov, {Igor P.} and Maximovskiy, {Evgeniy A.} and Gutakovskii, {Anton K.} and Morozova, {Natalya B.} and Basova, {Tamara V.}",
year = "2019",
month = jun,
day = "1",
doi = "10.1007/s10856-019-6275-1",
language = "English",
volume = "30",
pages = "69",
journal = "Journal of Materials Science: Materials in Medicine",
issn = "0957-4530",
publisher = "Springer Netherlands",
number = "6",

}

RIS

TY - JOUR

T1 - Bimetallic Pt,Ir-containing coatings formed by MOCVD for medical applications

AU - Dorovskikh, Svetlana I.

AU - Vikulova, Evgeniia S.

AU - Kal’nyi, Danila B.

AU - Shubin, Yury V.

AU - Asanov, Igor P.

AU - Maximovskiy, Evgeniy A.

AU - Gutakovskii, Anton K.

AU - Morozova, Natalya B.

AU - Basova, Tamara V.

PY - 2019/6/1

Y1 - 2019/6/1

N2 - Biocompatible PtxIr(1−x) layers combining high mechanical strength of the iridium component and outstanding corrosion resistance of the platinum component providing reversible charge transfer reactions in the living tissue are one of the important materials required for implantable medical electrodes. The modern trend to complicate the shape and reduce the electrode dimensions includes the challenge to develop precise methods to obtain such bimetallic coatings with enhanced surface area and advanced electrochemical characteristics. Herein, PtxIr(1−x) coatings were firstly obtained on cathode and anode pole tips of endocardial electrodes for pacemakers using chemical vapor deposition technique. To deposit PtxIr(1−x) coatings with a wide range of metal ratios (x = 0.5–0.9) the combination of acetylacetonate-based volatile precursors with compatible thermal characteristics was used for the first time. The expected metal ratio in the coatings was regulated by a partial pressure of the precursor vapors in the reaction zone and was in the good agreement with its real value measured by various methods, including energy-dispersive and wavelength dispersive spectroscopy, X-ray photoelectron spectroscopy. According to the X-ray powder diffraction analysis, PtxIr(1−x) coatings consisted of fcc-PtxIr(1−x) solid solution phases. The microscopy data confirmed the formation of PtxIr1−x coatings with the enhanced surface areas. The effect of electrochemical activation on the surface composition and morphology of the samples was studied. The electrochemical characteristics of samples were estimated from cyclic voltammetry and electrochemical impedance spectroscopy data. The charge storage capacity (CSC) values of activated samples were in the range of 19–108 mCcm−2 (phosphate buffer saline solution, 100 mV/s).

AB - Biocompatible PtxIr(1−x) layers combining high mechanical strength of the iridium component and outstanding corrosion resistance of the platinum component providing reversible charge transfer reactions in the living tissue are one of the important materials required for implantable medical electrodes. The modern trend to complicate the shape and reduce the electrode dimensions includes the challenge to develop precise methods to obtain such bimetallic coatings with enhanced surface area and advanced electrochemical characteristics. Herein, PtxIr(1−x) coatings were firstly obtained on cathode and anode pole tips of endocardial electrodes for pacemakers using chemical vapor deposition technique. To deposit PtxIr(1−x) coatings with a wide range of metal ratios (x = 0.5–0.9) the combination of acetylacetonate-based volatile precursors with compatible thermal characteristics was used for the first time. The expected metal ratio in the coatings was regulated by a partial pressure of the precursor vapors in the reaction zone and was in the good agreement with its real value measured by various methods, including energy-dispersive and wavelength dispersive spectroscopy, X-ray photoelectron spectroscopy. According to the X-ray powder diffraction analysis, PtxIr(1−x) coatings consisted of fcc-PtxIr(1−x) solid solution phases. The microscopy data confirmed the formation of PtxIr1−x coatings with the enhanced surface areas. The effect of electrochemical activation on the surface composition and morphology of the samples was studied. The electrochemical characteristics of samples were estimated from cyclic voltammetry and electrochemical impedance spectroscopy data. The charge storage capacity (CSC) values of activated samples were in the range of 19–108 mCcm−2 (phosphate buffer saline solution, 100 mV/s).

KW - Bimetallic coating

KW - Charge storage capacity

KW - Electrode

KW - MOCVD

KW - Pacemaker

KW - CHARGE-INJECTION

KW - ACTIVATION

KW - CHEMICAL-VAPOR-DEPOSITION

KW - IRIDIUM OXIDE AIROF

KW - ELECTRODES

KW - IR

KW - NEURAL STIMULATION

KW - FILMS

KW - ELECTROCHEMICAL-BEHAVIOR

KW - LAYER

UR - http://www.scopus.com/inward/record.url?scp=85066816107&partnerID=8YFLogxK

U2 - 10.1007/s10856-019-6275-1

DO - 10.1007/s10856-019-6275-1

M3 - Article

C2 - 31165268

AN - SCOPUS:85066816107

VL - 30

SP - 69

JO - Journal of Materials Science: Materials in Medicine

JF - Journal of Materials Science: Materials in Medicine

SN - 0957-4530

IS - 6

ER -

ID: 20530854