School of Pharmacy, Queen's University Belfast, Medical Biology Centre, 97 Lisburn Road, Belfast, UK
J Control Release. 2012 Apr 10;159(1):52-9. doi: 10.1016/j.jconrel.2012.01.003. Epub 2012 Jan 12.
It has recently been proposed that the combination of skin barrier impairment using microneedles (MNs) coupled with iontophoresis (ITP) may broaden the range of drugs suitable for transdermal delivery, as well as enabling the rate of delivery to be achieved with precise electronic control. However, no reports exist on the combination of ITP with in situ drug loaded polymeric MN delivery systems. Furthermore, although a number of studies have highlighted the importance of MN design for transdermal drug delivery enhancement, to date, there has been no systematic investigation of the influence of MN geometry on the performance of polymeric MN arrays which are designed to remain in contact with the skin during the period of drug delivery. As such, for the first time, this study reports on the effect of MN heigth and MN density upon the transdermal delivery of small hydrophilic compounds (theophylline, methylene blue, and fluorescein sodium) across neonatal porcine skin in vitro, with the optimised MN array design evaluated for its potential in the electrically faciliatated delivery of peptide (bovine insulin) and protein (fluorescein isothiocyanate-labelled bovine serum albumin (FTIC-BSA)) macromolecules. The results of the in vitro drug release investigations revealed that the extent of transdermal delivery was dependent upon the design of the MN array employed, whereby an increase in MN height and an increase in MN density led to an increase in the extent of transdermal drug delivery achieved 6h after MN application. Overall, the in vitro permeation studies revealed that the MN design containing 361 MNs/cm(2) of 600 μm height resulted in the greatest extent of transdermal drug delivery. As such, this design was evaluated for its potential in the MN mediated iontophoretic transdermal delivery. Whilst the combination of MN and ITP did not further enhance the extent of small molecular weight solute delivery, the extent of peptide/protein release was significantly enhanced when ITP was used in combination of the soluble PMVE/MA MN arrays. For example, the cumulative amount of insulin permeated across neonatal porcine skin at 6h was found to be approximately 150 μg (3.25%), 227 μg (4.85%) and 462 μg (9.87%) for ITP, MN, and MN/ITP delivery strategies, respectively. Similarly, the cumulative amount of FTIC-BSA delivered across neonatal porcine skin after a 6h period was found to be approximately 110 μg (4.53%) for MN alone and 326 μg (13.40%) for MN in combination with anodal ITP (p<0.001). As such, drug loaded soluble PMVE/MA MN arrays show promise for the electrically controlled transdermal delivery of biomacromolecules in a simple, one-step approach.
最近有人提出,联合使用微针(MNs)破坏皮肤屏障和离子电渗(ITP)可能会扩大适合透皮给药的药物范围,并能够通过精确的电子控制实现给药速度。然而,目前尚无关于 ITP 与原位载药聚合物 MN 传递系统联合应用的报道。此外,尽管许多研究强调了 MN 设计对经皮药物传递增强的重要性,但迄今为止,还没有系统地研究 MN 几何形状对设计用于在药物传递期间与皮肤保持接触的聚合物 MN 阵列性能的影响。因此,本研究首次报道了 MN 高度和 MN 密度对小亲水性化合物(茶碱、亚甲蓝和荧光素钠)经新生儿猪皮体外透皮传递的影响,优化后的 MN 阵列设计评估了其在电促进多肽(牛胰岛素)和蛋白质(异硫氰酸荧光素标记牛血清白蛋白(FTIC-BSA))大分子输送中的潜力。体外药物释放研究的结果表明,透皮传递的程度取决于所使用的 MN 阵列设计,其中 MN 高度的增加和 MN 密度的增加导致 MN 应用 6 小时后透皮药物传递的程度增加。总体而言,体外渗透研究表明,含有 361 个 MN/cm2、高度为 600 μm 的 MN 设计导致最大程度的透皮药物传递。因此,评估了这种设计在 MN 介导的离子电渗透皮给药中的潜力。虽然 MN 和 ITP 的联合应用并没有进一步增强小分子溶质输送的程度,但当可溶性 PMVE/MA MN 阵列与 ITP 联合使用时,肽/蛋白质的释放程度显著增强。例如,在 6 小时时,胰岛素经新生儿猪皮渗透的累积量分别为 ITP、MN 和 MN/ITP 给药策略的约 150μg(3.25%)、227μg(4.85%)和 462μg(9.87%)。同样,在 6 小时后,FTIC-BSA 经新生儿猪皮传递的累积量约为 MN 单独使用时的 110μg(4.53%)和 MN 与阳极 ITP 联合使用时的 326μg(13.40%)(p<0.001)。因此,载药可溶性 PMVE/MA MN 阵列有望以简单的一步法实现生物大分子的电控制透皮输送。
