Conor O’Mahony scite author profile

Methods-In this study we determined, for the first time, the ability of microorganisms to traverse microneedle-induced holes using two different in vitro models.Results-When employing Silescol® membranes, the numbers of Candida albicans, Pseudomonas aeruginosa and Staphylococcus epidermidis crossing the membranes were an order of magnitude lower when the membranes were punctured by microneedles rather than a 21G hypodermic needle. Apart from the movement of C. albicans across hypodermic needle-punctured membranes, where 40.2% of the microbial load on control membranes permeated the barrier over 24 h, the numbers of permeating microorganisms was less than 5% of the original microbial load on control membranes. Experiments employing excised porcine skin and radiolabelled microorganisms showed that the numbers of microorganisms penetrating skin beyond the stratum corneum were approximately an order of magnitude greater than the numbers crossing Silescol® membranes in the corresponding experiments. Approximately 10 3 cfu of each microorganism adhered to hypodermic needles during insertion. The numbers of microorganisms adhering to MN arrays were an order of magnitude higher in each case. Conclusion-We have shown here that microneedle puncture resulted in significantly less microbial penetration than did hypodermic needle puncture and that no microorganisms crossed the viable epidermis in microneedle-punctured skin, in contrast to needle-punctured skin. Given the antimicrobial properties of skin, it is, therefore, likely that application of microneedle arrays to skin in an appropriate manner would not cause either local or systemic infection in normal circumstances in immune-competent patients. In supporting widespread clinical use of microneedle-based delivery systems, appropriate animal studies are now needed to conclusively demonstrate this in vivo. Safety in patients will be enhanced by aseptic or sterile manufacture and by fabricating microneedles from self-disabling materials (e.g. dissolving or biodegradable polymers) to prevent inappropriate or accidental reuse.

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Biosensing in dermal interstitial fluid using microneedle based electrochemical devices

Madden¹,

O’Mahony²,

Thompson

et al. 2020

Sensing and Bio-Sensing Research

112

102

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Coated microneedle arrays for transcutaneous delivery of live virus vaccines

Vrdoljak

McGrath

Carey

et al. 2012

Journal of Controlled Release

147

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Vaccines are sensitive biologics that require continuous refrigerated storage to maintain their viability. The vast majority of vaccines are also administered using needles and syringes. The need for cold chain storage and the significant logistics surrounding needle-and-syringe vaccination is constraining the success of immunization programs. Recombinant live viral vectors are a promising platform for the development of vaccines against a number of infectious diseases, however these viruses must retain infectivity to be effective. Microneedles offer an effective and painless method for delivery of vaccines directly into skin that in the future could provide solutions to current vaccination issues. Here we investigated methods of coating live recombinant adenovirus and modified vaccinia virus Ankara (MVA) vectors onto solid microneedle arrays. An effective spray-coating method, using conventional pharmaceutical processes, was developed, in tandem with suitable sugar-based formulations, which produces arrays with a unique coating of viable virus in a dry form around the shaft of each microneedle on the array. Administration of live virus-coated microneedle arrays successfully resulted in virus delivery, transcutaneous infection and induced an antibody or CD8 + T cell response in mice that was comparable to that obtained by needle-and-syringe intradermal immunization. To our knowledge, this is the first report of successful vaccination with recombinant live viral vectored vaccines coated on microneedle delivery devices.

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Processing difficulties and instability of carbohydrate microneedle arrays

Donnelly¹,

Morrow²,

Singh³

et al. 2009

Drug Development and Industrial Pharmacy

137

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The processing difficulties and instability encountered in this study are likely to preclude successful clinical application of carbohydrate MNs. The findings of this study are of particular importance to those in the pharmaceutical industry involved in the design and formulation of transdermal drug delivery systems based on dissolving MN arrays. It is hoped that we have illustrated conclusively the difficulties inherent in the processing and storage of carbohydrate-based dissolving MNs and that those in the industry will now follow alternative approaches.

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Production of dissolvable microneedles using an atomised spray process: Effect of microneedle composition on skin penetration

McGrath

Vučen

Vrdoljak

et al. 2014

European Journal of Pharmaceutics and Biopharmaceutics

124

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Conor O’Mahony

Microneedle Arrays Allow Lower Microbial Penetration Than Hypodermic Needles In Vitro

Biosensing in dermal interstitial fluid using microneedle based electrochemical devices

Coated microneedle arrays for transcutaneous delivery of live virus vaccines

Processing difficulties and instability of carbohydrate microneedle arrays

Production of dissolvable microneedles using an atomised spray process: Effect of microneedle composition on skin penetration

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