Additive Manufacturing of a Portable Electrochemical Sensor with a Recycled Conductive Filament for the Detection of Atropine in Spiked Drink Samples

Arantes, Iana V. S.; Crapnell, Robert D.; Whittingham, Matthew J.; Sigley, Evelyn; Paixão, Thiago R.L.C.; Banks, Craig E.

doi:10.1021/acsaenm.3c00345

Cited by 8 publications

(5 citation statements)

References 22 publications

(45 reference statements)

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“…1 A, which demonstrates the excellent low-temperature flexibility of this filament. Across 10 cm of this filament, an extremely low average resistance of 277 ± 9 Ω was measured, which matches the published bespoke filament range from ~ 250 to 1000 Ω [ 26 – 28 , 39 ] and represents a significant improvement on the commercially available conductive PLA which has a quoted resistance of 2–3 kΩ [ 40 , 41 ]. Importantly, this filament achieves such a level of conductivity at a low material cost of under £0.06 per gram, compared to £0.72 per gram previously reported [ 27 ] and a current purchasing cost of commercial filament of ~£1.20 per gram.…”

Section: Resultssupporting

confidence: 78%

Optimised graphite/carbon black loading of recycled PLA for the production of low-cost conductive filament and its application to the detection of β-estradiol in environmental samples

Augusto,

Crapnell,

Bernalte

et al. 2024

Microchim Acta

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The production, optimisation, physicochemical, and electroanalytical characterisation of a low-cost electrically conductive additive manufacturing filament made with recycled poly(lactic acid) (rPLA), castor oil, carbon black, and graphite (CB-G/PLA) is reported. Through optimising the carbon black and graphite loading, the best ratio for conductivity, low material cost, and printability was found to be 60% carbon black to 40% graphite. The maximum composition within the rPLA with 10 wt% castor oil was found to be an overall nanocarbon loading of 35 wt% which produced a price of less than £0.01 per electrode whilst still offering excellent low-temperature flexibility and reproducible printing. The additive manufactured electrodes produced from this filament offered excellent electrochemical performance, with a heterogeneous electron (charge) transfer rate constant, k0 calculated to be (2.6 ± 0.1) × 10−3 cm s−1 compared to (0.46 ± 0.03) × 10−3 cm s−1 for the commercial PLA benchmark. The additive manufactured electrodes were applied to the determination of β-estradiol, achieving a sensitivity of 400 nA µM−1, a limit of quantification of 70 nM, and a limit of detection of 21 nM, which compared excellently to other reports in the literature. The system was then applied to the detection of ß-estradiol within four real water samples, including tap, bottled, river, and lake water, where recoveries between 95 and 109% were obtained. Due to the ability to create high-performance filament at a low material cost (£0.06 per gram) and through the use of more sustainable materials such as recycled polymers, bio-based plasticisers, and naturally occurring graphite, additive manufacturing will have a permanent place within the electroanalysis arsenal in the future. Graphical abstract

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Section: Resultssupporting

confidence: 78%

Optimised graphite/carbon black loading of recycled PLA for the production of low-cost conductive filament and its application to the detection of β-estradiol in environmental samples

Augusto,

Crapnell,

Bernalte

et al. 2024

Microchim Acta

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“…The ability to make bespoke laments has received signicant attention, where one can vary the thermoplastic, for example into recycled versions, and one can change the conducting components and increase their amount, alongside the use of bio-based plasticizers. 11,[33][34][35]70 The approach to fabricate bespoke lament is summarized within Fig. 3, where two approaches have been developed, one that produces conductive composites using solvent-based methods, and another that employs thermal procedures.…”

Section: Additive Manufacturing Biosensors Using Bespoke Filamentsmentioning

confidence: 99%

“…These all aim to improve the electrochemical and printing performance over that achievable using commercially available laments, with many easily printable materials offering signicantly lower resistances (200-900 U over 10 cm of lament length). [32][33][34][35][36][37][38] In this minireview, we focus upon the use of FFF additive manufacturing technology along with the use of biosensors that are exclusively using antibodies, enzymes and associated biosensing materials (mediators). This minireview paper looks to provide an overview of the literature on the use of additive manufacturing for the production of electrochemical biosensors, with the focus on fused lament fabrication for the production of the electrode and offer some suggestions for how this eld can progress in the future.…”

Section: Introductionmentioning

confidence: 99%

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Electroanalysis overview: additive manufactured biosensors using fused filament fabrication

Crapnell,

Banks

2024

Anal. Methods

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“…In diverse fields, 3D printing finds applications ranging from tissue engineering and medical device fabrication to soft robotics, dentistry, and sensor development among many others. − The methods used in 3D printing are classified based on printing techniques and material utilization. Extrusion-based 3D printing, including melt material extrusion (MME) and direct ink writing (DIW), is commonly employed for the fabrication of high-performance polymer (HPP) structures from filaments or shear thinning inks. − Photocuring technologies, such as stereolithography (SLA) and digital light processing (DLP), utilize photochemical curing of liquid acrylate or cationically polymerizable resin materials to produce 3D-printed components. , Compared to extrusion-based methods, DLP 3D printing offers higher precision in manufacturing, improved mechanical toughness, and better layer unity. , Despite these advancements, a persistent challenge lies in processing high-performance polymers (HPPs) such as polyether ether ketone (PEEK) and polyimide under ambient conditions. , HPPs exhibit remarkable mechanical and thermal properties due to the concentration of aromatic rings within their polymer chains, resulting in strong bonds and interchain interactions. , PEEK, in particular, stands out for its strength and heat resistance, making it valuable in fields like the automotive industry and medical implants. − Commercial PEEK polymer has a reported tensile strength of 90–100 MPa and Young’s modulus of 4 GPa with a glass transition temperature of 143 °C and stability up to 450 °C with only 5% weight loss.…”

Section: Introductionmentioning

confidence: 99%

Room Temperature Photocurable PEEK Polymer Formulations for High-Performance 3D Printing Applications

Pal,

Gaikwad,

S. K.

2024

ACS Appl. Eng. Mater.

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Digital light processing (DLP) technology was employed to 3D print acrylate-modified poly(ether ether ketone) (PEEK). PEEK and modified PEEK (mPEEK incorporating pendant pentadecyl chain) polymers were synthesized and end-capped with urethane acrylate units. These end-modified PEEK polymers were combined with commercially available (meth)acrylic cross-linkers and photoinitiator to create photocurable resin formulations suitable for DLP 3D printing. The resulting 3Dprinted parts exhibited remarkable mechanical strength, with a Young's modulus of 2.1 GPa. This surpassed the mechanical properties of commercial acrylate resin 3D-printed parts and achieved approximately 55% of the Young's modulus of reported commercial PEEK polymer. Notably, the thermal properties of the 3D-printed materials were impressive, including a high glass transition temperature of 140 °C and stability with only around 10% weight degradation occurring at approximately 400 °C. These innovative resins demonstrated excellent printability with high resolution, enabling the fabrication of intricate shapes, including complex dental materials by DLP 3D printing. Their versatility extends to potential applications in dentistry, automobile manufacturing, and robotics.

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Additive Manufacturing of a Portable Electrochemical Sensor with a Recycled Conductive Filament for the Detection of Atropine in Spiked Drink Samples

Cited by 8 publications

References 22 publications

Optimised graphite/carbon black loading of recycled PLA for the production of low-cost conductive filament and its application to the detection of β-estradiol in environmental samples

Optimised graphite/carbon black loading of recycled PLA for the production of low-cost conductive filament and its application to the detection of β-estradiol in environmental samples

Electroanalysis overview: additive manufactured biosensors using fused filament fabrication

Room Temperature Photocurable PEEK Polymer Formulations for High-Performance 3D Printing Applications

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