通过冲击插入法提高微针阵列在皮肤切开的人体皮肤中的刺入效果。

Improved piercing of microneedle arrays in dermatomed human skin by an impact insertion method.

作者信息

Verbaan F J, Bal S M, van den Berg D J, Dijksman J A, van Hecke M, Verpoorten H, van den Berg A, Luttge R, Bouwstra J A

机构信息

Department of Drug Delivery Technology, Leiden/Amsterdam Center for Drug Research, P.O. Box 9502, 2300 RA, Leiden, The Netherlands.

出版信息

J Control Release. 2008 May 22;128(1):80-8. doi: 10.1016/j.jconrel.2008.02.009. Epub 2008 Feb 26.

DOI:10.1016/j.jconrel.2008.02.009

PMID:18394741

Abstract

An electrical applicator was designed, which can pierce short microneedles into the skin with a predefined velocity. Three different shapes of microneedles were used, namely 300 mum assembled hollow metal microneedle arrays, 300 mum solid metal microneedle arrays and 245 mum hollow silicon microneedle arrays. The latter are available as 4x4, 6x6 and 9x9 arrays. When using a velocity of 1 or 3 m/s reproducible piercing of dermatomed and full thickness human skin was evident from the appearance of blue spots on the dermal side of the skin after Trypan Blue treatment and the presence of fluorescently labeled particles in dermatomed skin. Manual piercing did not result in the appearance of blue spots. Transport studies revealed that i) piercing of microneedles with a predefined velocity into human skin resulted in a drastic enhancement of the Cascade Blue (CB, Mw 538) transport, ii) A higher piercing velocity resulted in a higher CB transport rate, iii) The CB transport rate was also dependent on the shape of the microneedles and iv) no difference in transport rate was observed between 4x4, 6x6 and 9x9 hollow silicon microneedle arrays.

摘要

设计了一种电施药器，它能够以预定速度将短微针刺入皮肤。使用了三种不同形状的微针，即300μm组装空心金属微针阵列、300μm实心金属微针阵列和245μm空心硅微针阵列。后者有4×4、6×6和9×9阵列形式。当以1或3m/s的速度施用时，经锥虫蓝处理后皮肤真皮侧出现蓝点以及在去皮的皮肤中存在荧光标记颗粒，这表明对去皮和全层人体皮肤的穿刺具有可重复性。手动穿刺未出现蓝点。转运研究表明：i）以预定速度将微针刺入人体皮肤会显著增强级联蛋白（CB，分子量538）的转运；ii）较高的穿刺速度会导致更高的CB转运速率；iii）CB转运速率还取决于微针的形状；iv）在4×4、6×6和9×9空心硅微针阵列之间未观察到转运速率的差异。

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通过冲击插入法提高微针阵列在皮肤切开的人体皮肤中的刺入效果。

Improved piercing of microneedle arrays in dermatomed human skin by an impact insertion method.

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