Manufactured Flexible Electrodes for Dopamine Detection: Integration of Conducting Polymer in 3D‐Printed Polylactic Acid

Fontana‐Escartín, Adrián; Puiggalı́-Jou, Anna; Lanzalaco, Sonia; Bertrán, Oscar; Alemán, Carlos

doi:10.1002/adem.202100002

Cited by 13 publications

(3 citation statements)

References 65 publications

(33 reference statements)

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“…30 In this regard, the use of non-conductive PLA filament has been reported for the manufacturing of a flexible biosensor for dopamine detection. 47 Although this work has demonstrated the possibility of applying nonconductive PLA filaments, most research groups have explored the advantages related to the use of PLA filament in composites with graphene (G/PLA) and CB (CB/PLA), as shown in Table 2. Abdalla and co-authors have compared 3D printed electrodes produced by both filaments by several techniques and towards the detection of different analytes.…”

Section: Biosensorsmentioning

confidence: 99%

Posttreatment of 3D‐printed surfaces for electrochemical applications: A critical review on proposed protocols

Rocha

Castro

et al. 2021

Electrochemical Science Adv

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This mini-review presents an overview of recent trends for 3D printed sensors and biosensors (with a focus on Fused Deposition Modeling (FDM) based technology), along with their posttreatment surfaces to improve electrochemical applications. The protocols described in the literature and advances in this field were covered, bringing a critical discussion about the achievements and limitations to improve the electrical properties of conducting filaments, as well as their electroanalytical performance. In addition, the pros and cons of the processes used in surface posttreatment to improve the performance of electrodes constructed by FDM are presented, comparing the time consumed during chemical and electrochemical treatments or combining the two to improve the characteristics of the sensors. Finally, the discussion about the real necessity of surface treatments of electrodes constructed by FDM technology, the techniques used for this, and some ecological protocols are discussed (surface posttreatments with and without reagents) or whether the simple optimization of printing parameters could also significantly improve the electrochemical performance of sensors built with such technologies.

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Section: Biosensorsmentioning

confidence: 99%

Posttreatment of 3D‐printed surfaces for electrochemical applications: A critical review on proposed protocols

Rocha

Castro

et al. 2021

Electrochemical Science Adv

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“…[ 156 ] Other hydrogels have been extensively used in tissue engineering. [ 156–176 ] Table 4 shows the biological properties, including cellular assay and cell type of hydrogel‐based scaffolds.…”

Section: Polymer Hydrogelsmentioning

confidence: 99%

3‐Dimensional Printing of Hydrogel‐Based Nanocomposites: A Comprehensive Review on the Technology Description, Properties, and Applications

et al. 2021

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Hydrogels are notable biomaterials in bioengineering and biotechnology due to their outstanding biocompatibility, good permeability to water-soluble metabolites, and the high swelling ratio. [1] Hydrogels are extensively used in regenerative medicine and tissue engineering, such as biomarker detection, [2] stem cell research, [3] and organ-on-a-chip (OOC) applications. Hydrogels are chemically or physically cross-linked natural or synthetic threedimensional (3D) networks that can form into various shapes and hold large amounts of water, which could be up to 4000% by dry weight, while they are hardly dissolved in water. [4] Their water retention properties are primarily because of the existence of hydrophilic groups in polymer chains such as amido, amino, carboxyl, and hydroxyl. The degree of swelling depends on the composition of the polymer, the density, and the Increasing demand for customized implants and tissue scaffolds requires advanced biomaterials and fabricating processes for fabricating three-dimensional (3D) structures that resemble the complexity of the extracellular matrix (ECM). Lately, biofabrication approaches such as cell-laden (soft) hydrogel 3D printing (3DP) have been of increasing interest in the development of 3D functional environments similar to natural tissues and organs. Hydrogels that resemble biological ECMs can provide mechanical support and signaling cues to cells to control their behavior. Although the capability of hydrogels to produce artificial ECMs can regulate cellular behavior, one of the major drawbacks of working with hydrogels is their inferior mechanical properties. Therefore, keeping and enhancing the mechanical integrity of fabricated scaffolds has become an essential matter for 3D hydrogel structures. Herein, 3D-printed hydrogel-based nanocomposites (NCs) are evaluated systematically in terms of introducing novel techniques for 3DP of hydrogel-based materials, properties, and biomedical applications.

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“…Recent advances in polymer chemistry serve as the foundations for rapid progress in novel classes of sensor technologies for medical applications. − The combination of polymers and metal coatings (and/or polymer@metal particles), together with the micro- and macro-fabrication of electrodes, provide broad capabilities in continuous biophysical and biochemical measurements of health status, in many cases with levels of precision and accuracy that can compete with clinical detection standards . One example is the recent work published by Seo et al, where they developed a gold nanonetwork (Au NN)-based microelectrode adaptable to monitor neural activities (called “electrocorticogram”, ECoG).…”

Section: Introductionmentioning

confidence: 99%

Dual-Responsive Polypropylene Meshes Actuating as Thermal and SERS Sensors

Lanzalaco

Gil

Mingot

et al. 2022

ACS Biomater. Sci. Eng.

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Polypropylene (PP) surgical meshes, with different knitted architectures, were chemically functionalized with gold nanoparticles (AuNPs) and 4-mercaptothiazole (4-MB) to transform their fibers into a surface enhanced Raman scattering (SERS) detectable plastic material. The application of a thin layer of poly[N-isopropylacrylamide-co-N,N′-methylene bis(acrylamide)] (PNIPAAm-co-MBA) graft copolymer, covalently polymerized to the mesh-gold substrate, caused the conversion of the inert plastic into a thermoresponsive material, resulting in the first PP implantable mesh with both SERS and temperature stimulus responses. AuNPs were homogeneously distributed over the PP yarns, offering a clear SERS recognition together with higher PNIPAAm lower critical solution temperature (LCST ∼ 37 °C) than without the metallic particles (LCST ∼ 32 °C). An infrared thermographic camera was used to observe the polymer-hydrogel folding-unfolding process and to identify the new value of the LCST, connected with the heat generation by plasmonic-resonance gold NPs. The development of SERS PP prosthesis will be relevant for the bioimaging and biomarker detection of the implant by using the plasmonic effect and Raman vibrational spectroscopy for minimally invasive interventions (such as laparoscopy), to prevent patient inflammatory processes. Furthermore, Raman sources have been proved to not damage the cells, like happens with near-infrared irradiation, representing another advantage of moving to SERS approaches. The findings reported here offer unprecedented application possibilities in the biomedical field by extrapolating the material functionalization to other nonabsorbable polymer made devices (e.g., surgical sutures, grapes, wound dressings, among others).

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Manufactured Flexible Electrodes for Dopamine Detection: Integration of Conducting Polymer in 3D‐Printed Polylactic Acid

Cited by 13 publications

References 65 publications

Posttreatment of 3D‐printed surfaces for electrochemical applications: A critical review on proposed protocols

Posttreatment of 3D‐printed surfaces for electrochemical applications: A critical review on proposed protocols

3‐Dimensional Printing of Hydrogel‐Based Nanocomposites: A Comprehensive Review on the Technology Description, Properties, and Applications

Dual-Responsive Polypropylene Meshes Actuating as Thermal and SERS Sensors

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