3D-printed and In-situ prepared hydrogel anti-bacterial wound patch with silver nanoparticle embedded matrix

Hanin Amara; Fahad Alam; Said El Turk; Haider Butt

doi:10.1016/j.heliyon.2025.e42186

3D-printed and In-situ prepared hydrogel anti-bacterial wound patch with silver nanoparticle embedded matrix

Hanin Amara, Fahad Alam, Said El Turk, Haider Butt^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

The application of wearable hydrogel wound patches has great potential in advancing the field of medicine. However, for high reach and large-scale utilization, the fabrication process of wearable hydrogel wound patches needs to be low-cost, reliable, and have high throughput. Therefore, the incorporation of 3D-printing technology helps in providing a starting point for flexible, high throughput, mechanically enhanced, low-cost, and reliable antibacterial wound patches. 3D-printed patches can perform antibacterial behavior while exhibiting a fast fabrication process in a time range of less than 3 h. The fabricated patch exhibited good water retention, water vapor transmission rates a porosity values indicating that it has a promising potential to be commercialized as a wound patch.

Original language	English
Article number	e42186
Journal	Heliyon
Volume	11
Issue number	4
DOIs	https://doi.org/10.1016/j.heliyon.2025.e42186
State	Published - 28 Feb 2025

Bibliographical note

Publisher Copyright:
© 2025 The Authors

Keywords

3D-printed
Anti-bacterial
Hydrogel
Wearable
Wound patch

ASJC Scopus subject areas

General

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10.1016/j.heliyon.2025.e42186

Cite this

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title = "3D-printed and In-situ prepared hydrogel anti-bacterial wound patch with silver nanoparticle embedded matrix",

abstract = "The application of wearable hydrogel wound patches has great potential in advancing the field of medicine. However, for high reach and large-scale utilization, the fabrication process of wearable hydrogel wound patches needs to be low-cost, reliable, and have high throughput. Therefore, the incorporation of 3D-printing technology helps in providing a starting point for flexible, high throughput, mechanically enhanced, low-cost, and reliable antibacterial wound patches. 3D-printed patches can perform antibacterial behavior while exhibiting a fast fabrication process in a time range of less than 3 h. The fabricated patch exhibited good water retention, water vapor transmission rates a porosity values indicating that it has a promising potential to be commercialized as a wound patch.",

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author = "Hanin Amara and Fahad Alam and \{El Turk\}, Said and Haider Butt",

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AU - Amara, Hanin

AU - Alam, Fahad

AU - El Turk, Said

AU - Butt, Haider

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Y1 - 2025/2/28

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AB - The application of wearable hydrogel wound patches has great potential in advancing the field of medicine. However, for high reach and large-scale utilization, the fabrication process of wearable hydrogel wound patches needs to be low-cost, reliable, and have high throughput. Therefore, the incorporation of 3D-printing technology helps in providing a starting point for flexible, high throughput, mechanically enhanced, low-cost, and reliable antibacterial wound patches. 3D-printed patches can perform antibacterial behavior while exhibiting a fast fabrication process in a time range of less than 3 h. The fabricated patch exhibited good water retention, water vapor transmission rates a porosity values indicating that it has a promising potential to be commercialized as a wound patch.

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KW - Anti-bacterial

KW - Hydrogel

KW - Wearable

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VL - 11

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3D-printed and In-situ prepared hydrogel anti-bacterial wound patch with silver nanoparticle embedded matrix

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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