A cost-effective process chain for thermoplastic microneedle manufacture combining laser micro-machining and micro-injection moulding

Mert Gulcur; Jean-Michel Romano; Pavel Penchev; Tim Gough; Elaine Brown; Stefan Dimov; Ben  Whiteside

doi:10.1016/j.cirpj.2021.01.015

A cost-effective process chain for thermoplastic microneedle manufacture combining laser micro-machining and micro-injection moulding

Mert Gulcur, Jean-Michel Romano, Pavel Penchev, Tim Gough, Elaine Brown, Stefan Dimov, Ben Whiteside

Mechanical Engineering

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

22 Citations (Scopus)

149 Downloads (Pure)

Abstract

High-throughput manufacturing of transdermal microneedle arrays poses a significant challenge due to the high precision and number of features that need to be produced and the requirement of multi-step processing methods for achieving challenging micro-features. To address this challenge, we report a flexible and cost-effective process chain for transdermal microneedle array manufacture that includes mould production using laser machining and replication of thermoplastic microneedles via micro-injection moulding (micromoulding). The process chain also incorporates an in-line manufacturing data monitoring capability where the variability in the quality of microneedle arrays can be determined in a production run using captured data. Optical imaging and machine vision technologies are also implemented to create a quality inspection system that allows rapid evaluation of key quality indicators. The work presents the capability of laser machining as a cost-effective method for making microneedle moulds and micro-injection moulding of thermoplastic microneedle arrays as a highly-suitable manufacturing technique for large-scale production with low marginal cost.

Original language	English
Pages (from-to)	311-321
Number of pages	11
Journal	CIRP Journal of Manufacturing Science and Technology
Volume	32
DOIs	https://doi.org/10.1016/j.cirpj.2021.01.015
Publication status	Published - 4 Feb 2021

Bibliographical note

Funding Information:
This research work was undertaken in the context of MICROMAN project (“Process Fingerprint for Zero-defect Net-shape MICROMANufacturing”, http://www.microman.mek.dtu.dk/). MICROMAN is a European Training Network supported by Horizon 2020, the EU Framework Programme for Research and Innovation (Project ID: 674801). This research has also received funding and support from two other Horizon 2020 projects: HIMALAIA (Grant agreement No. 766871) and Laser4Fun (GA no. 675063).

Publisher Copyright:
© 2021 CIRP

Keywords

data acquisition
laser micro-machining
micro-injection molding
microneedle arrays
polymer replication
process monitoring

ASJC Scopus subject areas

Industrial and Manufacturing Engineering

Access to Document

10.1016/j.cirpj.2021.01.015Licence: None: All rights reserved

GulcurM2021costeffectiveAccepted author manuscript, 1.04 MBLicence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

H2020_RIA_HIMALAIA
Dimov, S.
European Commission
15/09/17 → 14/03/21
Project: EU
H2020_ITN_LASER4FUN
Dimov, S.
European Commission, European Commission - Management Costs
1/09/15 → 31/08/19
Project: Research

Cite this

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abstract = "High-throughput manufacturing of transdermal microneedle arrays poses a significant challenge due to the high precision and number of features that need to be produced and the requirement of multi-step processing methods for achieving challenging micro-features. To address this challenge, we report a flexible and cost-effective process chain for transdermal microneedle array manufacture that includes mould production using laser machining and replication of thermoplastic microneedles via micro-injection moulding (micromoulding). The process chain also incorporates an in-line manufacturing data monitoring capability where the variability in the quality of microneedle arrays can be determined in a production run using captured data. Optical imaging and machine vision technologies are also implemented to create a quality inspection system that allows rapid evaluation of key quality indicators. The work presents the capability of laser machining as a cost-effective method for making microneedle moulds and micro-injection moulding of thermoplastic microneedle arrays as a highly-suitable manufacturing technique for large-scale production with low marginal cost.",

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A cost-effective process chain for thermoplastic microneedle manufacture combining laser micro-machining and micro-injection moulding

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

Fingerprint

Projects

H2020_RIA_HIMALAIA

H2020_ITN_LASER4FUN

Cite this