Functionalized microneedles for continuous glucose monitoring

Takeuchi, Kai; Kim, Beomjoon

doi:10.1186/s40580-018-0161-2

Cited by 33 publications

(45 citation statements)

References 119 publications

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“…It is not known whether the concentration of biomarkers in ISF compared to blood plasma is consistently high enough and an accurate representation for analysis, but reports claim ISF is fairly representative of true biomarker concentrations. This finding indicates that ISF is a potential alternative for some (but currently not all) biomarkers, such as glucose, [ 80 ] for monitoring, compared to the use of blood plasma, which can be invasive to extract. Samant and Prausnitz [ 13 ] used crosslinked PVA HFMs to extract ISF, showing that the use of HFMs is more effective than other methods, such as hollow MNs and osmotically driven flow for ISF extraction.…”

Section: Applications Of Hydrogel‐forming Microneedlesmentioning

confidence: 99%

Hydrogel‐Forming Microneedles: Current Advancements and Future Trends

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Estrela

et al. 2020

Macromolecular Bioscience

204

111

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In this focused progress review, the recent developments and trends of hydrogel‐forming microneedles (HFMs) and potential future directions are presented. Previously, microneedles (solid, hollow, coated, and dissolving microneedles) have primarily been used to enhance the effectiveness of transdermal drug delivery to facilitate a wide range of applications such as vaccinations and antibiotic delivery. However, the recent trend in microneedle development has resulted in microneedles formed from hydrogels which have the ability to offer transdermal drug delivery and, due to the hydrogel swelling nature, passively extract interstitial fluid from the skin, meaning they have the potential to be used for biocompatible minimally invasive monitoring devices. Thus, in this review, these recent trends are highlighted, which consolidate microneedle design considerations, hydrogel formulations, fabrication processes, applications of HFMs and the potential future opportunities for utilizing HFMs for personalized healthcare monitoring and treatment.

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Section: Applications Of Hydrogel‐forming Microneedlesmentioning

confidence: 99%

Hydrogel‐Forming Microneedles: Current Advancements and Future Trends

Turner

White

Estrela

et al. 2020

Macromolecular Bioscience

204

111

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“…Clinically ideal MNs with good biocompatibility, strong mechanical strength, and cargos (such as proteins, peptides and vaccines) are highly desirable to achieve sensing or drug release in the skin. By rational design (including shape, aspect ratio, tip radius and length, and base width), MNs with excellent physical, chemical, and biological properties have been fabricated and utilized for applications of transdermal sensing, extraction of biofluids for diagnostics, and transdermal delivery [27,29,31].…”

Section: Application Of Microneedlesmentioning

confidence: 99%

“…Many reviews on microneedle technology have been published in recent years. However, many of them typically focus on a specific aspect, such as materials science and manufacture [26], glucose monitoring [27], polymeric MNs' application [14], diagnostics [28,29], and drug delivery [30,31]. The systematical review, which elaborates on the basic knowledge and main points of MNs, and covers the latest application of diagnosis and therapy, is still in its infancy [32].…”

Section: Introductionmentioning

confidence: 99%

Engineering Microneedles for Therapy and Diagnosis: A Survey

et al. 2020

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Microneedle (MN) technology is a rising star in the point-of-care (POC) field, which has gained increasing attention from scientists and clinics. MN-based POC devices show great potential for detecting various analytes of clinical interests and transdermal drug delivery in a minimally invasive manner owing to MNs’ micro-size sharp tips and ease of use. This review aims to go through the recent achievements in MN-based devices by investigating the selection of materials, fabrication techniques, classification, and application, respectively. We further highlight critical aspects of MN platforms for transdermal biofluids extraction, diagnosis, and drug delivery assisted disease therapy. Moreover, multifunctional MNs for stimulus-responsive drug delivery systems were discussed, which show incredible potential for accurate and efficient disease treatment in dynamic environments for a long period of time. In addition, we also discuss the remaining challenges and emerging trend of MN-based POC devices from the bench to the bedside.

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“…After publication of this article [1], the author noticed there are some conversion errors with the below characters and units in the article body text. The corrections are detailed below:‘pTAS’ should be ‘µTAS’‘pm’ should be ‘µm’…”

Section: Correction To: Nano Convergence (2018) 5:28 101186/s40580-0mentioning

confidence: 99%