Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications

A. Calmet, N. Vejar, X. Gonzalez, M. Sancy, A. Ringuedé, V. Lair, S. Griveau, J.H. Zagal, F. Bedioui, M. Cassir

Research output: Contribution to journalArticle

  • 1 Citations

Abstract

AISI 304L is used in SudoscanTM technology (Impeto Medical Inc.) for the early diagnosis of small fiber neuropathy caused by type-2 diabetes or cystic fibrosis. In a recent paper, several substitute electrodes were analyzed, among which the biocompatible nickel-free AISI 430 appeared as an interesting material. In the present work, we compare in details the electrochemical behavior of AISI 430 with respect to the reference AISI 304L, using Electrochemical Impedance Spectroscopy (EIS) in mimetic electrolytic solutions of sweat. Apart of being cheaper than AISI 304L, AISI 430 has roughly similar characteristics but is slightly more sensitive to chloride ions concentration and, according to EIS and SEM analyses, forms a thicker, more homogeneous and protective oxide layer, which makes it a convenient electrode material. © 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim
LanguageEnglish
Pages162-169
Number of pages8
JournalElectroanalysis
Volume30
Issue number1
DOIs
Publication statusPublished - 2018

Fingerprint

Stainless Steel
Electrochemical impedance spectroscopy
Stainless steel
Electrodes
Medical problems
Nickel
Oxides
Chlorides
Ions
Scanning electron microscopy
Fibers

Keywords

  • 304
  • 430
  • electrochemical impedance spectroscopy
  • stainless steels
  • sudomotor dysfunction

Cite this

Calmet, A., Vejar, N., Gonzalez, X., Sancy, M., Ringuedé, A., Lair, V., ... Cassir, M. (2018). Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications. Electroanalysis, 30(1), 162-169. https://doi.org/10.1002/elan.201700464

Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications. / Calmet, A.; Vejar, N.; Gonzalez, X.; Sancy, M.; Ringuedé, A.; Lair, V.; Griveau, S.; Zagal, J.H.; Bedioui, F.; Cassir, M.

In: Electroanalysis, Vol. 30, No. 1, 2018, p. 162-169.

Research output: Contribution to journalArticle

Calmet, A, Vejar, N, Gonzalez, X, Sancy, M, Ringuedé, A, Lair, V, Griveau, S, Zagal, JH, Bedioui, F & Cassir, M 2018, 'Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications' Electroanalysis, vol. 30, no. 1, pp. 162-169. https://doi.org/10.1002/elan.201700464
Calmet A, Vejar N, Gonzalez X, Sancy M, Ringuedé A, Lair V et al. Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications. Electroanalysis. 2018;30(1):162-169. https://doi.org/10.1002/elan.201700464
Calmet, A. ; Vejar, N. ; Gonzalez, X. ; Sancy, M. ; Ringuedé, A. ; Lair, V. ; Griveau, S. ; Zagal, J.H. ; Bedioui, F. ; Cassir, M. / Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications. In: Electroanalysis. 2018 ; Vol. 30, No. 1. pp. 162-169.
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abstract = "AISI 304L is used in SudoscanTM technology (Impeto Medical Inc.) for the early diagnosis of small fiber neuropathy caused by type-2 diabetes or cystic fibrosis. In a recent paper, several substitute electrodes were analyzed, among which the biocompatible nickel-free AISI 430 appeared as an interesting material. In the present work, we compare in details the electrochemical behavior of AISI 430 with respect to the reference AISI 304L, using Electrochemical Impedance Spectroscopy (EIS) in mimetic electrolytic solutions of sweat. Apart of being cheaper than AISI 304L, AISI 430 has roughly similar characteristics but is slightly more sensitive to chloride ions concentration and, according to EIS and SEM analyses, forms a thicker, more homogeneous and protective oxide layer, which makes it a convenient electrode material. {\circledC} 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim",
keywords = "304, 430, electrochemical impedance spectroscopy, stainless steels, sudomotor dysfunction",
author = "A. Calmet and N. Vejar and X. Gonzalez and M. Sancy and A. Ringued{\'e} and V. Lair and S. Griveau and J.H. Zagal and F. Bedioui and M. Cassir",
note = "Export Date: 6 April 2018 CODEN: ELANE Correspondence Address: Cassir, M.; PSL Research University, Chimie Paristech-CNRS, Institut de Recherche de Chimie de Paris, 11 rue Pierre et Marie Curie, France; email: michel.cassir@chimie-paristech.fr References: Tamayo, T., Rosenbauer, J., Wild, S.H., Spijkerman, A.M.W., Baan, C., Forouhi, N.G., Herder, C., Rathmann, W., (2014) Diabetes Res. Clin. Pract., 103, pp. 206-207; Gardete-Correia, L., Boavida, J.M., Raposo, J.F., Mesquita, A.C., Fona, C., Massano-Cardoso, R.C.S., (2010) Diabet. Med., 27, pp. 879-881; Metelko, Z., Pavlic-Renar, I., Poljicanin, T., Szirovitza, L., Turek, S., (2008) Diabetes Res. Clin. Pract., 81, pp. 263-267; Satman, I., Omer, B., Tutuncu, Y., Kalaca, S., Gedik, S., Dinccag, N., Genc, K.K.S., Tuomilehto, J., (2013) Eur. J. Epidemiol., 28, pp. 169-180; Soriguer, F., Goday, A., Bosch-Comas, A., Bordiu, E., Calle-Pascual, A., Carmena, R., Casamitjana, R., Vendrell, J., (2012) Diabetologia, 55, pp. 88-93; van't Riet, E., Alssema, M., Rijkelijkhuizen, J.M., Kostense, P.J., Nijpels, G., Dekker, J.M., (2010) Diabetes Care, 33, pp. 61-66; Rathman, W., Haastert, B., Icks, A., L{\"o}wel, H., Meisinger, C., Holle, R., Giani, G., (2003) Diabetologia, 46, pp. 182-189; Tesfaye, S., Chaturvedi, N., Simon, E.M., (2005) N. Engl. J. Med., pp. 341-350; Low, P.A., (2004) Clin. Neurophysiol., 115, pp. 1506-1513; Brunswick, P., Bocquet, N., ; Khalfallah, K., Ayoub, H., Calvet, J.H., Neveu, X., Brunswick, P., Griveau, S., Lair, V., Bedioui, F., (2012) IEEE Sens. J., 12, pp. 456-463; Novak, P., Clin. Auton. Res., 2017; Calmet, A., Amar, A., Griveau, S., Lair, V., Sutter, E., Recio, F., Brunswick, P., Cassir, M., (2016) Electroanalysis, 28, pp. 380-384; Mouayd, A.A., Orazem, M.E., Sutter, E.M.M., Tribollet, B., Koltsov, A., (2014) Corros. Sci., 82, pp. 362-368; Ayoub, H., Lair, V., Griveau, S., Brunswick, P., Zagal, J.H., Bedioui, F., Cassir, M., (2012) Electroanalysis, 24, pp. 386-391; Calmet, A., Khalfallah, K., Ayoub, H., Lair, V., Griveau, S., Brunswick, P., Bedioui, F., Cassir, M., (2014) Electrochim. Acta,, 140, pp. 37-41; Drogowska, M., M{\'e}nard, H., Brossard, L., (1997) J. Appl. Electrochem., 27, pp. 169-177; Lee, J.S., Kitagawa, Y., Nakanishi, T., Hasegawa, Y., Fushimi, K., (2016) Electrochimica Acta,, 220, pp. 304-311; Mouayd, A.A., Orazem, M.E., Sutter, E.M.M., Tribollet, B., Koltsov, A., (2014) Corros. Sci., 82, pp. 362-368; Hirschorn, B., Orazem, M.E., Tribollet, B., Vivier, V., Frateur, I., Musiani, M., (2010) Electrochim. Acta, 55, pp. 6218-6227; Musiani, M., Orazem, M.E., P{\'e}b{\`e}re, N., Tribollet, B., Vivier, V., (2014) Prog. Org. Coat., 77, pp. 2076-2083; Nobial, M., Devos, O., Mattos, O.R., Tribollet, B., (2007) J. Electroanal. Chem., 600; Amand, S., Musiani, M., Orazem, M.E., P{\'e}b{\`e}re, N., Tribollet, B., Vivier, V., (2013) Electrochim. Acta,, 87, pp. 693-700; Barr{\`e}s, T., Tribollet, B., Stephan, O., Montigaud, H., Cohin, Y., (2017) Electrochim. Acta, 227, pp. 1-6; Tran, T.T.M., Tribollet, B., Sutter, E.M.M., (2016) Electrochim. Acta, 216, pp. 55-67; Hirschorn, B., Orazem, M.E., Tribollet, B., Vivier, V., Frateur, I., Musiani, M., (2010) Electrochim. Acta, 55, pp. 6218-6227",
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TY - JOUR

T1 - Electrochemical Behavior of Stainless Steels for Sudomotor Dysfunction Applications

AU - Calmet, A.

AU - Vejar, N.

AU - Gonzalez, X.

AU - Sancy, M.

AU - Ringuedé, A.

AU - Lair, V.

AU - Griveau, S.

AU - Zagal, J.H.

AU - Bedioui, F.

AU - Cassir, M.

N1 - Export Date: 6 April 2018 CODEN: ELANE Correspondence Address: Cassir, M.; PSL Research University, Chimie Paristech-CNRS, Institut de Recherche de Chimie de Paris, 11 rue Pierre et Marie Curie, France; email: michel.cassir@chimie-paristech.fr References: Tamayo, T., Rosenbauer, J., Wild, S.H., Spijkerman, A.M.W., Baan, C., Forouhi, N.G., Herder, C., Rathmann, W., (2014) Diabetes Res. Clin. Pract., 103, pp. 206-207; Gardete-Correia, L., Boavida, J.M., Raposo, J.F., Mesquita, A.C., Fona, C., Massano-Cardoso, R.C.S., (2010) Diabet. Med., 27, pp. 879-881; Metelko, Z., Pavlic-Renar, I., Poljicanin, T., Szirovitza, L., Turek, S., (2008) Diabetes Res. Clin. Pract., 81, pp. 263-267; Satman, I., Omer, B., Tutuncu, Y., Kalaca, S., Gedik, S., Dinccag, N., Genc, K.K.S., Tuomilehto, J., (2013) Eur. J. Epidemiol., 28, pp. 169-180; Soriguer, F., Goday, A., Bosch-Comas, A., Bordiu, E., Calle-Pascual, A., Carmena, R., Casamitjana, R., Vendrell, J., (2012) Diabetologia, 55, pp. 88-93; van't Riet, E., Alssema, M., Rijkelijkhuizen, J.M., Kostense, P.J., Nijpels, G., Dekker, J.M., (2010) Diabetes Care, 33, pp. 61-66; Rathman, W., Haastert, B., Icks, A., Löwel, H., Meisinger, C., Holle, R., Giani, G., (2003) Diabetologia, 46, pp. 182-189; Tesfaye, S., Chaturvedi, N., Simon, E.M., (2005) N. Engl. J. Med., pp. 341-350; Low, P.A., (2004) Clin. Neurophysiol., 115, pp. 1506-1513; Brunswick, P., Bocquet, N., ; Khalfallah, K., Ayoub, H., Calvet, J.H., Neveu, X., Brunswick, P., Griveau, S., Lair, V., Bedioui, F., (2012) IEEE Sens. J., 12, pp. 456-463; Novak, P., Clin. Auton. Res., 2017; Calmet, A., Amar, A., Griveau, S., Lair, V., Sutter, E., Recio, F., Brunswick, P., Cassir, M., (2016) Electroanalysis, 28, pp. 380-384; Mouayd, A.A., Orazem, M.E., Sutter, E.M.M., Tribollet, B., Koltsov, A., (2014) Corros. Sci., 82, pp. 362-368; Ayoub, H., Lair, V., Griveau, S., Brunswick, P., Zagal, J.H., Bedioui, F., Cassir, M., (2012) Electroanalysis, 24, pp. 386-391; Calmet, A., Khalfallah, K., Ayoub, H., Lair, V., Griveau, S., Brunswick, P., Bedioui, F., Cassir, M., (2014) Electrochim. Acta,, 140, pp. 37-41; Drogowska, M., Ménard, H., Brossard, L., (1997) J. Appl. Electrochem., 27, pp. 169-177; Lee, J.S., Kitagawa, Y., Nakanishi, T., Hasegawa, Y., Fushimi, K., (2016) Electrochimica Acta,, 220, pp. 304-311; Mouayd, A.A., Orazem, M.E., Sutter, E.M.M., Tribollet, B., Koltsov, A., (2014) Corros. Sci., 82, pp. 362-368; Hirschorn, B., Orazem, M.E., Tribollet, B., Vivier, V., Frateur, I., Musiani, M., (2010) Electrochim. Acta, 55, pp. 6218-6227; Musiani, M., Orazem, M.E., Pébère, N., Tribollet, B., Vivier, V., (2014) Prog. Org. Coat., 77, pp. 2076-2083; Nobial, M., Devos, O., Mattos, O.R., Tribollet, B., (2007) J. Electroanal. Chem., 600; Amand, S., Musiani, M., Orazem, M.E., Pébère, N., Tribollet, B., Vivier, V., (2013) Electrochim. Acta,, 87, pp. 693-700; Barrès, T., Tribollet, B., Stephan, O., Montigaud, H., Cohin, Y., (2017) Electrochim. Acta, 227, pp. 1-6; Tran, T.T.M., Tribollet, B., Sutter, E.M.M., (2016) Electrochim. Acta, 216, pp. 55-67; Hirschorn, B., Orazem, M.E., Tribollet, B., Vivier, V., Frateur, I., Musiani, M., (2010) Electrochim. Acta, 55, pp. 6218-6227

PY - 2018

Y1 - 2018

N2 - AISI 304L is used in SudoscanTM technology (Impeto Medical Inc.) for the early diagnosis of small fiber neuropathy caused by type-2 diabetes or cystic fibrosis. In a recent paper, several substitute electrodes were analyzed, among which the biocompatible nickel-free AISI 430 appeared as an interesting material. In the present work, we compare in details the electrochemical behavior of AISI 430 with respect to the reference AISI 304L, using Electrochemical Impedance Spectroscopy (EIS) in mimetic electrolytic solutions of sweat. Apart of being cheaper than AISI 304L, AISI 430 has roughly similar characteristics but is slightly more sensitive to chloride ions concentration and, according to EIS and SEM analyses, forms a thicker, more homogeneous and protective oxide layer, which makes it a convenient electrode material. © 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

AB - AISI 304L is used in SudoscanTM technology (Impeto Medical Inc.) for the early diagnosis of small fiber neuropathy caused by type-2 diabetes or cystic fibrosis. In a recent paper, several substitute electrodes were analyzed, among which the biocompatible nickel-free AISI 430 appeared as an interesting material. In the present work, we compare in details the electrochemical behavior of AISI 430 with respect to the reference AISI 304L, using Electrochemical Impedance Spectroscopy (EIS) in mimetic electrolytic solutions of sweat. Apart of being cheaper than AISI 304L, AISI 430 has roughly similar characteristics but is slightly more sensitive to chloride ions concentration and, according to EIS and SEM analyses, forms a thicker, more homogeneous and protective oxide layer, which makes it a convenient electrode material. © 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

KW - 304

KW - 430

KW - electrochemical impedance spectroscopy

KW - stainless steels

KW - sudomotor dysfunction

U2 - 10.1002/elan.201700464

DO - 10.1002/elan.201700464

M3 - Article

VL - 30

SP - 162

EP - 169

JO - Electroanalysis

T2 - Electroanalysis

JF - Electroanalysis

SN - 1040-0397

IS - 1

ER -