High-Resolution Graphene Films for Electrochemical Sensing <i>via</i> Inkjet Maskless Lithography

Hondred, John A.; Stromberg, Loreen R.; Mosher, Curtis; Claussen, Jonathan C.

doi:10.1021/acsnano.7b03554

Cited by 59 publications

(88 citation statements)

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“…and Materials). 37 The PGEs used herein were first fabricated through our previously reported IML technique 32 that includes inkjet printing a polymer mask, spin-coating a graphene flake solution, thermal postbaking the printed graphene, and finally performing an acetone rinse lift-off to form well-defined electrode patterns with a 5 mm diameter disk-shaped working electrode (Figure 1a). After the graphene patterning process, a laser diode engraver was used to anneal the graphene and remove nonconductive ink surfactants (Figure 1b).…”

Section: Pte Ink Preparation and Depositionmentioning

confidence: 99%

“…40 Additionally, this laser annealing process, performed in ambient air, increases the number of superficial defects while adding oxygenated species (COOH, −CO, and −OH) to the said defects as previously reported. 42 The increase of graphene superficial defects has been shown to significantly increase the nucleation density of PtNPs during electrodeposition. 43 Such superficial oxygen species are well-suited for subsequent enzymatic biofunctionalization via glutaraldehyde cross-linking as hydroxyl groups on the graphene surface bind to the aldehyde groups in glutaraldehyde.…”

Section: 39mentioning

confidence: 99%

“…Graphene electrodes were printed and patterned through a recently developed thin film manufacturing technique called inkjet maskless lithography (IML). 32 Next, the printed graphene electrodes (PGEs) were laser-annealed and electrochemically deposited with platinum nanoparticles (PtNPs) to create a nano/microstructured surface that is highly conductive/electroactive with a high surface area for increased enzyme loading and heterogeneous charge transport during electrochemical sensing. The graphenebased electrode was consequently biofunctionalized with the enzyme PTE through covalent cross-linking with glutaraldehyde.…”

Section: Introductionmentioning

confidence: 99%

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Printed Graphene Electrochemical Biosensors Fabricated by Inkjet Maskless Lithography for Rapid and Sensitive Detection of Organophosphates

Hondred

Breger

Alves

et al. 2018

ACS Appl. Mater. Interfaces

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119

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Solution phase printing of graphene-based electrodes has recently become an attractive low-cost, scalable manufacturing technique to create in-field electrochemical biosensors. Here, we report a graphene-based electrode developed via inkjet maskless lithography (IML) for the direct and rapid monitoring of triple-O linked phosphonate organophosphates (OPs); these constitute the active compounds found in chemical warfare agents and pesticides that exhibit acute toxicity as well as long-term pollution to soils and waterways. The IML-printed graphene electrode is nano/microstructured with a 1000 mW benchtop laser engraver and electrochemically deposited platinum nanoparticles (dia. ∼25 nm) to improve its electrical conductivity (sheet resistance decreased from ∼10 000 to 100 Ω/sq), surface area, and electroactive nature for subsequent enzyme functionalization and biosensing. The enzyme phosphotriesterase (PTE) was conjugated to the electrode surface via glutaraldehyde cross-linking. The resulting biosensor was able to rapidly measure (5 s response time) the insecticide paraoxon (a model OP) with a low detection limit (3 nM), and high sensitivity (370 nA/μM) with negligible interference from similar nerve agents. Moreover, the biosensor exhibited high reusability (average of 0.3% decrease in sensitivity per sensing event), stability (90% anodic current signal retention over 1000 s), longevity (70% retained sensitivity after 8 weeks), and the ability to selectively sense OP in actual soil and water samples. Hence, this work presents a scalable printed graphene manufacturing technique that can be used to create OP biosensors that are suitable for in-field applications as well as, more generally, for low-cost biosensor test strips that could be incorporated into wearable or disposable sensing paradigms.

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Section: Pte Ink Preparation and Depositionmentioning

confidence: 99%

Section: 39mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Printed Graphene Electrochemical Biosensors Fabricated by Inkjet Maskless Lithography for Rapid and Sensitive Detection of Organophosphates

Hondred

Breger

Alves

et al. 2018

ACS Appl. Mater. Interfaces

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119

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“…5,27 This facile LIG manufacturing protocol also eliminates the need for ink preparation, ink printing, and post-print annealing processes associated with solution-phase printed graphene. 9,[28][29] The utility of LIG has been displayed in numerous applications including supercapacitors, 14,22,[30][31] non-biofouling surfaces, 32 transparent heaters 33 , and more recently, electrochemical sensors. [25][26][34][35] For example, a non-enzymatic amperometric glucose sensor comprised of LIG functionalized with Cu nanocubes was used to selectively measure glucose over a wide concentration range (25 µM-4 mM), which is physiologically relevant to glucose levels in saliva, tears, and blood.…”

mentioning

confidence: 99%

Flexible Laser-Induced Graphene for Nitrogen Sensing in Soil

Garland¹,

McLamore

Cavallaro

et al. 2018

ACS Appl. Mater. Interfaces

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141

107

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Flexible graphene electronics are rapidly gaining interest, but their widespread implementation has been impeded by challenges with ink preparation, ink printing, and post-print annealing processes. Laser-induced graphene (LIG) promises a facile alternative by creating flexible graphene electronics on polyimide substrates through a one-step laser writing fabrication method. Herein we demonstrate the use of LIG, created through a low-cost UV laser, for electrochemical ion selective sensing of plant-available nitrogen (i.e., both ammonium and nitrate ions: NH4+ and NO3-) in soil samples. The laser used to create the LIG was operated at distinct pulse rates (10, 20, 30, 40, and 50 ms) in order to maximize the LIG electrochemical reactivity. Results illustrated that a laser pulse rate of 20 ms led to a high percentage of sp2 carbon (77%) and optimal peak oxidation current of 120 uA during ferricyanide cyclic voltammetry. Therefore, LIG electrodes created with a 20 ms pulse rate were consequently functionalized with distinct ionophores specific to NH4+(nonactin) or NO3-(tridodecylmethylammonium nitrate) within polyvinyl chloride (PVC)-based membranes to create distinct solid contact ion selective electrodes (SC-ISEs) for NH4+ and NO3-ion sensing respectively. The LIG SC-ISEs displayed near Nernstian sensitivities of 51.7 ± 7.8 mV/decade (NH4+) and -54.8 ± 2.5 mV/ decade (NO3-), detection limits of 28.2 ± 25.0 uM (NH4+) and 20.6 ± 14.8 uM (NO3-), low long-term drift of 0.93 mV/hr (NH4+) sensors and -5.3 μV/hr (NO3-) sensors and linear sensing ranges within 10-5-10-1 M for both sensors. Moreover, soil slurry sensing was performed and recovery percentages of 96% and 95% were obtained for added NH4+and NO3-, respectively. These results, combined with a facile fabrication that does not require metallic nanoparticle decoration, make these LIG electrochemical sensors appealing for a wide range of in field or point-of-service applications for soil health management. ABSTRACTFlexible graphene electronics are rapidly gaining interest, but their widespread implementation has been impeded by challenges with ink preparation, ink printing, and postprint annealing processes. Laser-induced graphene (LIG) promises a facile alternative by creating flexible graphene electronics on polyimide substrates through a one-step laser writing fabrication method. Herein we demonstrate the use of LIG, created through a low-cost UV laser, for electrochemical ion selective sensing of plant-available nitrogen (i.e., both ammonium and nitrate ions: NH 4 + and NO 3 -metallic nanoparticle decoration, make these LIG electrochemical sensors appealing for a wide range of in-field or point-of-service applications for soil health management.

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“…Graphene electrodes can be created either by direct printing of graphene ink or by printing a sacricial polymer pattern followed by the graphene deposition. 140,141 On the other hand, graphene electrodes can be produced from carbon-based polymers (i.e., polyimide) by CO 2 laser irradiation. 142 In both cases the electrodes of relatively complex pattern (e.g., interdigitated) can be easily obtained in large quantities suitable for the creation of amperometric, impedimetric or other types of biosensors.…”

Section: Graphene and Its Derivativesmentioning

confidence: 99%

Advances in nanomaterial application in enzyme-based electrochemical biosensors: a review

et al. 2019

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Electrochemical enzyme-based biosensors are one of the largest and commercially successful groups of biosensors. Integration of nanomaterials in the biosensors results in significant improvement of biosensor sensitivity, limit of detection, stability, response rate and other analytical characteristics. Thus, new functional nanomaterials are key components of numerous biosensors. However, due to the great variety of available nanomaterials, they should be carefully selected according to the desired effects. The present review covers the recent applications of various types of nanomaterials in electrochemical enzyme-based biosensors for the detection of small biomolecules, environmental pollutants, food contaminants, and clinical biomarkers. Benefits and limitations of using nanomaterials for analytical purposes are discussed. Furthermore, we highlight specific properties of different nanomaterials, which are relevant to electrochemical biosensors. The review is structured according to the types of nanomaterials. We describe the application of inorganic nanomaterials, such as gold nanoparticles (AuNPs), platinum nanoparticles (PtNPs), silver nanoparticles (AgNPs), and palladium nanoparticles (PdNPs), zeolites, inorganic quantum dots, and organic nanomaterials, such as single-walled carbon nanotubes (SWCNTs), multi-walled carbon nanotubes (MWCNTs), carbon and graphene quantum dots, graphene, fullerenes, and calixarenes. Usage of composite nanomaterials is also presented. ). S. Dzyadevych is also working as a deputy director of the same institute since 2019. They received PhD degrees in biotechnology. They are developing electrochemical enzyme-based biosensors for medical, research, and industrial applications. The biosensors are based on amperometric, ISFET, and conductometric transducers and immobilized enzymes.a AgNPssilver nanoparticles; AuNPsgold nanoparticles; CNTscarbon nanotubes; NADHreduced nicotinamide adenine dinucleotide; PdNPs palladium nanoparticles; PtNPsplatinum nanoparticles; QDsquantum dots.This journal is Fig. 1 Ways of embedding NMs in the enzyme-based biosensors. (a) Enzyme immobilization on the NM-modified electrode. (b) Schematic of the biosensor based on phosphotriesterase (PTE) immobilized via glutaraldehyde on the graphene surface with platinum nanoparticles. Reprinted with permission from . 25 (c) Enzyme/NM co-immobilization on the electrode. (d) Schematic of the biosensor based on glucose oxidase encapsulated in a chitosan-kappa-carrageenan bionanocomposite. Reprinted from Material Science and Engineering: C, 95, I. Rassas, M. Braiek, A. Bonhomme, F. Bessueille, G. Rafin, H. Majdoub, and N. Jaffrezic-Renault, Voltammetric glucose biosensor based on glucose oxidase encapsulation in a chitosan-kappa-carrageenan polyelectrolyte complex, 152-159, Copyright (2018), with permission from Elsevier. 26 4562 | Nanoscale Adv., 2019, 1, 4560-4577 This journal is Fig. 5 Schematics of the hydrogen peroxide biosensor based on oligoaniline-cross-linked HRP/CNT composite and cyclic voltammograms of the bio...

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High-Resolution Graphene Films for Electrochemical Sensing via Inkjet Maskless Lithography

Cited by 59 publications

References 60 publications

Printed Graphene Electrochemical Biosensors Fabricated by Inkjet Maskless Lithography for Rapid and Sensitive Detection of Organophosphates

Printed Graphene Electrochemical Biosensors Fabricated by Inkjet Maskless Lithography for Rapid and Sensitive Detection of Organophosphates

Flexible Laser-Induced Graphene for Nitrogen Sensing in Soil

Advances in nanomaterial application in enzyme-based electrochemical biosensors: a review

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