3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications

Mohammad Rizwan; Konrad Rudnicki; Christopher Gwenin; Lukasz Poltorak

doi:10.1039/9781837673216-00233

3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications

Mohammad Rizwan, Konrad Rudnicki, Christopher Gwenin, Lukasz Poltorak

Department of Built Environment and Life Sciences

Research output: Chapter in Book/Report/Conference proceeding › Chapter (peer-reviewed) › peer-review

Abstract

Recently, 3D-printing technology has emerged as an unconventional, cost-effective, and user-friendly method for prototyping, developing, and fabricating objects, which can be directly used for scientific applications, as well as for developing prototypes and final products. The increasing number of applications includes energy storage devices, biomedical equipment, analytical platforms, and low-cost diagnostic devices. Notable examples of 3D-printed objects for electroanalytical diagnostics include electrochemical cells, electrodes, and microfluidic devices. In this chapter, we will focus on the basic aspects of 3D-printing technology, the materials used for fabricating electrochemical low-cost diagnostic devices, and their development and performance.

Original language	English
Title of host publication	Low-cost diagnostics
Subtitle of host publication	fabrication, materials, and applications
Editors	Mohammad Rizwan, Minhaz Uddin Ahmed, Guobao Xu
Place of Publication	London
Publisher	Royal Society of Chemistry
Chapter	10
Pages	233-261
Number of pages	29
ISBN (Electronic)	9781837673216, 9781837673223
ISBN (Print)	9781837672387
DOIs	https://doi.org/10.1039/9781837673216-00233
Publication status	Published - 11 Dec 2024

Publication series

Name	Detection science series
Publisher	Royal Society of Chemistry
Number	26
ISSN (Print)	2052-3068
ISSN (Electronic)	2052-3076

Access to Document

10.1039/9781837673216-00233

Cite this

Rizwan, M., Rudnicki, K., Gwenin, C., & Poltorak, L. (2024). 3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications. In M. Rizwan, M. U. Ahmed, & G. Xu (Eds.), Low-cost diagnostics: fabrication, materials, and applications (pp. 233-261). (Detection science series; No. 26). Royal Society of Chemistry. https://doi.org/10.1039/9781837673216-00233

Rizwan, Mohammad ; Rudnicki, Konrad ; Gwenin, Christopher et al. / 3D-printed low-cost electroanalytical diagnostic platforms : basics, materials, fabrication, and applications. Low-cost diagnostics: fabrication, materials, and applications. editor / Mohammad Rizwan ; Minhaz Uddin Ahmed ; Guobao Xu. London : Royal Society of Chemistry, 2024. pp. 233-261 (Detection science series; 26).

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abstract = "Recently, 3D-printing technology has emerged as an unconventional, cost-effective, and user-friendly method for prototyping, developing, and fabricating objects, which can be directly used for scientific applications, as well as for developing prototypes and final products. The increasing number of applications includes energy storage devices, biomedical equipment, analytical platforms, and low-cost diagnostic devices. Notable examples of 3D-printed objects for electroanalytical diagnostics include electrochemical cells, electrodes, and microfluidic devices. In this chapter, we will focus on the basic aspects of 3D-printing technology, the materials used for fabricating electrochemical low-cost diagnostic devices, and their development and performance.",

author = "Mohammad Rizwan and Konrad Rudnicki and Christopher Gwenin and Lukasz Poltorak",

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Rizwan, M, Rudnicki, K, Gwenin, C & Poltorak, L 2024, 3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications. in M Rizwan, MU Ahmed & G Xu (eds), Low-cost diagnostics: fabrication, materials, and applications. Detection science series, no. 26, Royal Society of Chemistry, London, pp. 233-261. https://doi.org/10.1039/9781837673216-00233

3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications. / Rizwan, Mohammad; Rudnicki, Konrad; Gwenin, Christopher et al.
Low-cost diagnostics: fabrication, materials, and applications. ed. / Mohammad Rizwan; Minhaz Uddin Ahmed; Guobao Xu. London: Royal Society of Chemistry, 2024. p. 233-261 (Detection science series; No. 26).

Research output: Chapter in Book/Report/Conference proceeding › Chapter (peer-reviewed) › peer-review

TY - CHAP

T1 - 3D-printed low-cost electroanalytical diagnostic platforms

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AU - Rizwan, Mohammad

AU - Rudnicki, Konrad

AU - Gwenin, Christopher

AU - Poltorak, Lukasz

PY - 2024/12/11

Y1 - 2024/12/11

N2 - Recently, 3D-printing technology has emerged as an unconventional, cost-effective, and user-friendly method for prototyping, developing, and fabricating objects, which can be directly used for scientific applications, as well as for developing prototypes and final products. The increasing number of applications includes energy storage devices, biomedical equipment, analytical platforms, and low-cost diagnostic devices. Notable examples of 3D-printed objects for electroanalytical diagnostics include electrochemical cells, electrodes, and microfluidic devices. In this chapter, we will focus on the basic aspects of 3D-printing technology, the materials used for fabricating electrochemical low-cost diagnostic devices, and their development and performance.

AB - Recently, 3D-printing technology has emerged as an unconventional, cost-effective, and user-friendly method for prototyping, developing, and fabricating objects, which can be directly used for scientific applications, as well as for developing prototypes and final products. The increasing number of applications includes energy storage devices, biomedical equipment, analytical platforms, and low-cost diagnostic devices. Notable examples of 3D-printed objects for electroanalytical diagnostics include electrochemical cells, electrodes, and microfluidic devices. In this chapter, we will focus on the basic aspects of 3D-printing technology, the materials used for fabricating electrochemical low-cost diagnostic devices, and their development and performance.

U2 - 10.1039/9781837673216-00233

DO - 10.1039/9781837673216-00233

M3 - Chapter (peer-reviewed)

SN - 9781837672387

T3 - Detection science series

SP - 233

EP - 261

BT - Low-cost diagnostics

A2 - Rizwan, Mohammad

A2 - Ahmed, Minhaz Uddin

A2 - Xu, Guobao

PB - Royal Society of Chemistry

CY - London

ER -

Rizwan M, Rudnicki K, Gwenin C, Poltorak L. 3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications. In Rizwan M, Ahmed MU, Xu G, editors, Low-cost diagnostics: fabrication, materials, and applications. London: Royal Society of Chemistry. 2024. p. 233-261. (Detection science series; 26). Epub 2024 Dec 11. doi: 10.1039/9781837673216-00233

3D-printed low-cost electroanalytical diagnostic platforms: basics, materials, fabrication, and applications

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