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Title: Integrating Carbon Nanomaterials with Metals for Bio-sensing Applications

Abstract

Age structure in most developed countries is changing fast as the average lifespan is increasing significantly, calling for solutions to provide improved treatments for age-related neurological diseases and disorders. In order to address these problems, a reliable way of recording information about neurotransmitters from in vitro and in vivo applications is needed to better understand neurological diseases and disorders as well as currently used treatments. Likewise, recent developments in medicine, especially with the opioid crisis, are demanding a swift move to personalized medicine to administer patient needs rather than population-wide averages. In order to enable the so-called personalized medicine, it is necessary to be able to do measurements in vivo and in real time. These actions require sensitive and selective detection of different analytes from very demanding environments. Current state-of-the-art materials are unable to provide sensitive and selective detection of neurotransmitters as well as the required time resolution needed for drug molecules at a reasonable cost. To meet these challenges, we have utilized different metals to grow carbon nanomaterials and applied them for sensing applications showing that there are clear differences in their electrochemical properties based on the selected catalyst metal. Additionally, we have combined atomistic simulations to support optimizingmore » materials for experiments and to gain further understanding of the atomistic level reactions between different analytes and the sensor surface. With carbon nanostructures grown from Ni and Al + Co + Fe hybrid, we can detect dopamine, ascorbic acid, and uric acid simultaneously. On the other hand, nanostructures grown from platinum provide a feasible platform for detection of H2O2 making them suitable candidates for enzymatic biosensors for detection of glutamate, for example. Tetrahedral amorphous carbon electrodes have an ability to detect morphine, paracetamol, tramadol, and O-desmethyltramadol. With carbon nanomaterial-based sensors, it is possible to reach metal-like properties in sensing applications using only a fraction of the metal as seed for the material growth. We have also seen that by using nanodiamonds as growth catalyst for carbon nanofibers, it is not possible to detect dopamine and ascorbic acid simultaneously, although the morphology of the resulting nanofibers is similar to the ones grown using Ni. This further indicates the importance of the metal selection for specific applications. However, Ni as a continuous layer or as separate islands does not provide adequate performance. Thus, it appears that metal nanoparticles combined with fiber-like morphology are needed for optimized sensor performance for neurotransmitter detection. This opens up a new research approach of application-specific nanomaterials, where carefully selected metals are integrated with carbon nanomaterials to match the needs of the sensing application in question.« less

Authors:
 [1];  [2];  [2];  [2];  [2];  [2];  [2];  [2];  [3];  [3];  [2];  [2]
+ Show Author Affiliations
  1. SLAC National Accelerator Lab., Menlo Park, CA (United States). Stanford Synchrotron Radiation Lightsource (SSRL); Aalto Univ., Espoo (Finland)
  2. Aalto Univ., Espoo (Finland)
  3. NASA Ames Research Center (ARC), Moffett Field, Mountain View, CA (United States)
Publication Date:
Research Org.:
SLAC National Accelerator Laboratory (SLAC), Menlo Park, CA (United States)
Sponsoring Org.:
USDOE; Instrumentarium Science Foundation
OSTI Identifier:
1617157
Grant/Contract Number:  
AC02-76SF00515
Resource Type:
Accepted Manuscript
Journal Name:
Molecular Neurobiology
Additional Journal Information:
Journal Volume: 57; Journal Issue: 1; Journal ID: ISSN 0893-7648
Publisher:
Springer Nature
Country of Publication:
United States
Language:
English
Subject:
59 BASIC BIOLOGICAL SCIENCES; Carbon; Carbon nanomaterials; Bio-sensing; Dopamine

Citation Formats

Sainio, Sami, Leppänen, Elli, Mynttinen, Elsi, Palomäki, Tommi, Wester, Niklas, Etula, Jarkko, Isoaho, Noora, Peltola, Emilia, Koehne, Jessica, Meyyappan, M., Koskinen, Jari, and Laurila, Tomi. Integrating Carbon Nanomaterials with Metals for Bio-sensing Applications. United States: N. p., 2019. Web. doi:10.1007/s12035-019-01767-7.
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Sainio, Sami, Leppänen, Elli, Mynttinen, Elsi, Palomäki, Tommi, Wester, Niklas, Etula, Jarkko, Isoaho, Noora, Peltola, Emilia, Koehne, Jessica, Meyyappan, M., Koskinen, Jari, & Laurila, Tomi. Integrating Carbon Nanomaterials with Metals for Bio-sensing Applications. United States. https://doi.org/10.1007/s12035-019-01767-7
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Sainio, Sami, Leppänen, Elli, Mynttinen, Elsi, Palomäki, Tommi, Wester, Niklas, Etula, Jarkko, Isoaho, Noora, Peltola, Emilia, Koehne, Jessica, Meyyappan, M., Koskinen, Jari, and Laurila, Tomi. Sat . "Integrating Carbon Nanomaterials with Metals for Bio-sensing Applications". United States. https://doi.org/10.1007/s12035-019-01767-7. https://www.osti.gov/servlets/purl/1617157.
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@article{osti_1617157,
title = {Integrating Carbon Nanomaterials with Metals for Bio-sensing Applications},
author = {Sainio, Sami and Leppänen, Elli and Mynttinen, Elsi and Palomäki, Tommi and Wester, Niklas and Etula, Jarkko and Isoaho, Noora and Peltola, Emilia and Koehne, Jessica and Meyyappan, M. and Koskinen, Jari and Laurila, Tomi},
abstractNote = {Age structure in most developed countries is changing fast as the average lifespan is increasing significantly, calling for solutions to provide improved treatments for age-related neurological diseases and disorders. In order to address these problems, a reliable way of recording information about neurotransmitters from in vitro and in vivo applications is needed to better understand neurological diseases and disorders as well as currently used treatments. Likewise, recent developments in medicine, especially with the opioid crisis, are demanding a swift move to personalized medicine to administer patient needs rather than population-wide averages. In order to enable the so-called personalized medicine, it is necessary to be able to do measurements in vivo and in real time. These actions require sensitive and selective detection of different analytes from very demanding environments. Current state-of-the-art materials are unable to provide sensitive and selective detection of neurotransmitters as well as the required time resolution needed for drug molecules at a reasonable cost. To meet these challenges, we have utilized different metals to grow carbon nanomaterials and applied them for sensing applications showing that there are clear differences in their electrochemical properties based on the selected catalyst metal. Additionally, we have combined atomistic simulations to support optimizing materials for experiments and to gain further understanding of the atomistic level reactions between different analytes and the sensor surface. With carbon nanostructures grown from Ni and Al + Co + Fe hybrid, we can detect dopamine, ascorbic acid, and uric acid simultaneously. On the other hand, nanostructures grown from platinum provide a feasible platform for detection of H2O2 making them suitable candidates for enzymatic biosensors for detection of glutamate, for example. Tetrahedral amorphous carbon electrodes have an ability to detect morphine, paracetamol, tramadol, and O-desmethyltramadol. With carbon nanomaterial-based sensors, it is possible to reach metal-like properties in sensing applications using only a fraction of the metal as seed for the material growth. We have also seen that by using nanodiamonds as growth catalyst for carbon nanofibers, it is not possible to detect dopamine and ascorbic acid simultaneously, although the morphology of the resulting nanofibers is similar to the ones grown using Ni. This further indicates the importance of the metal selection for specific applications. However, Ni as a continuous layer or as separate islands does not provide adequate performance. Thus, it appears that metal nanoparticles combined with fiber-like morphology are needed for optimized sensor performance for neurotransmitter detection. This opens up a new research approach of application-specific nanomaterials, where carefully selected metals are integrated with carbon nanomaterials to match the needs of the sensing application in question.},
doi = {10.1007/s12035-019-01767-7},
journal = {Molecular Neurobiology},
number = 1,
volume = 57,
place = {United States},
year = {Sat Sep 14 00:00:00 EDT 2019},
month = {Sat Sep 14 00:00:00 EDT 2019}
}
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https://doi.org/10.1007/s12035-019-01767-7
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Works referenced in this record:

Structural morphology of carbon nanofibers grown on different substrates
journal, March 2016

Partially Reduced Graphene Oxide Modified Tetrahedral Amorphous Carbon Thin-Film Electrodes as a Platform for Nanomolar Detection of Dopamine
journal, March 2017

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Reactivity of Amorphous Carbon Surfaces: Rationalizing the Role of Structural Motifs in Functionalization Using Machine Learning
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Amorphous carbon thin film electrodes with intrinsic Pt-gradient for hydrogen peroxide detection
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Reactivity of Amorphous Carbon Surfaces: Rationalizing the Role of Structural Motifs in Functionalization Using Machine Learning.
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Detecting Subsecond Dopamine Release with Fast-Scan Cyclic Voltammetry in Vivo
journal, October 2003

Growth Mechanism and Origin of High sp^{3} Content in Tetrahedral Amorphous Carbon.
text, January 2018

  • Caro, Miguel A.; Deringer, Volker; Koskinen, Jari
  • Apollo - University of Cambridge Repository
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Computational Surface Chemistry of Tetrahedral Amorphous Carbon by Combining Machine Learning and Density Functional Theory
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Simultaneous electrochemical detection of tramadol and O-desmethyltramadol with Nafion-coated tetrahedral amorphous carbon electrode
journal, February 2019

Cost of disorders of the brain in Europe 2010
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Integrated Carbon Nanostructures for Detection of Neurotransmitters
journal, June 2015

Electrochemical detection of hydrogen peroxide on platinum-containing tetrahedral amorphous carbon sensors and evaluation of their biofouling properties
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Carbon Nanostructure Based Platform for Enzymatic Glutamate Biosensors
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Computational Surface Chemistry of Tetrahedral Amorphous Carbon by Combining Machine Learning and Density Functional Theory
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Psychoanalytical Electrochemistry: Dopamine and Behavior
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What Does Nitric Acid Really Do to Carbon Nanofibers?
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Nano biosensors for neurochemical monitoring
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Selective detection of morphine in the presence of paracetamol with anodically pretreated dual layer Ti/tetrahedral amorphous carbon electrodes
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Application-Specific Catalyst Layers: Pt-Containing Carbon Nanofibers for Hydrogen Peroxide Detection
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SU-8 based pyrolytic carbon for the electrochemical detection of dopamine
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  • Journal of Materials Chemistry B, Vol. 5, Issue 45
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Growth Mechanism and Origin of High s p 3 Content in Tetrahedral Amorphous Carbon
journal, April 2018

Integrated Carbon Nanostructures for Detection of Neurotransmitters
journal, June 2015

Selective detection of morphine in the presence of paracetamol with anodically pretreated dual layer Ti/tetrahedral amorphous carbon electrodes
journal, January 2018

Amorphous carbon thin film electrodes with intrinsic Pt-gradient for hydrogen peroxide detection
journal, October 2017

Simultaneous electrochemical detection of tramadol and O-desmethyltramadol with Nafion-coated tetrahedral amorphous carbon electrode
journal, February 2019

Electrochemical detection of hydrogen peroxide on platinum-containing tetrahedral amorphous carbon sensors and evaluation of their biofouling properties
journal, October 2015

  • Tujunen, Noora; Kaivosoja, Emilia; Protopopova, Vera
  • Materials Science and Engineering: C, Vol. 55
  • DOI: 10.1016/j.msec.2015.05.060

Psychoanalytical Electrochemistry: Dopamine and Behavior
journal, October 2003

  • Venton, B. Jill; Wightman, R. Mark
  • Analytical Chemistry, Vol. 75, Issue 19
  • DOI: 10.1021/ac031421c

Computational Surface Chemistry of Tetrahedral Amorphous Carbon by Combining Machine Learning and Density Functional Theory
journal, September 2018

Reactivity of Amorphous Carbon Surfaces: Rationalizing the Role of Structural Motifs in Functionalization Using Machine Learning
journal, September 2018

Carbon Nanostructure Based Platform for Enzymatic Glutamate Biosensors
journal, February 2017

  • Isoaho, Noora; Peltola, Emilia; Sainio, Sami
  • The Journal of Physical Chemistry C, Vol. 121, Issue 8
  • DOI: 10.1021/acs.jpcc.6b10612

Pt-grown carbon nanofibers for enzymatic glutamate biosensors and assessment of their biocompatibility
journal, January 2018

  • Isoaho, Noora; Peltola, Emilia; Sainio, Sami
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Detecting Subsecond Dopamine Release with Fast-Scan Cyclic Voltammetry in Vivo
journal, October 2003

Growth Mechanism and Origin of High sp^{3} Content in Tetrahedral Amorphous Carbon.
text, January 2018

  • Caro, Miguel A.; Deringer, Volker; Koskinen, Jari
  • Apollo - University of Cambridge Repository
  • DOI: 10.17863/cam.33069
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