Lee Woan-Ruoh, Alalaiwe Ahmed, Tsai Meng-Tsan, Hu Sindy, Chang Fang-Hsin, Chien Min-Yu, Sung Hsin-Ching, Fang Jia-You
Graduate Institute of Medical Sciences, Taipei Medical University, Taipei, Taiwan.
Department of Dermatology, Taipei Medical University Shuang Ho Hospital, New Taipei City, Taiwan.
Drug Deliv Transl Res. 2025 May 29. doi: 10.1007/s13346-025-01885-x.
The use of fractional microporation to disrupt superficial skin is an effective approach to enhance drug absorption. This study analyzed and compared the effectiveness of fractional Er:YAG laser and radiofrequency microneedling (RM) in promoting skin penetration and hair follicle (HF) targeting of free or nanoencapsulated minoxidil and minocycline. Porcine skin delivery, with or without laser (3, 6, and 7 mJ) and RM (6.1, 10.2, and 20.4 mJ with a penetration depth of 0.5 or 1.0 mm), was investigated using in vitro permeation test (IVPT). The in vitro and in vivo antibacterial activity of the microporation-assisted minocycline-loaded nanocarriers was also conducted. The skin deposition and flux of free minoxidil were increased by 3- and 56-fold, respectively, with laser treatment at 7 mJ. The laser enhanced the deposition and flux of free minocycline by 25- and 40-fold compared to the untreated control, respectively. RM elevated the drug flux by 5‒18-fold compared to passive absorption. However, this enhancement effect was not observed in skin deposition. Nanostructured lipid carriers (NLC) and liposomes, with sizes of 81 and 76 nm, were produced and entrapped approximately 80% of the drugs, respectively. Microporation increased skin delivery of nanoencapsulated drugs, though this enhancement was less pronounced than that of the free drugs. Biodistribution observed through confocal microscopy showed that microporation increased the penetration depth of lipid-based nanocarriers into the dermis compared to passive diffusion. The nanocarriers were primarily distributed into the microchannels and transported into the surrounding dermal tissue. Minocycline uptake in HF increased from 0.03 to 0.16 and 0.20 nmol/cm after the nanoencapsulation with NLC and liposomes, respectively. This uptake of NLC was further increased to 1.24 and 1.51 nmol/cm by laser and RM treatment. The minocycline-loaded nanocarriers inhibited Cutibacterium acnes viability in both planktonic and biofilm forms more effectively than the free drug. The in vivo C. acnes infection model in mice exhibited an efficient bacterial eradication through microporation-mediated nanocarrier delivery. The microchannel closure in laser- and RM-treated skin occurred within 36 and 12 h, respectively, as indicated by transepidermal water loss (TEWL). These findings demonstrate that fractional laser and RM are promising strategies for improving skin- and HF-targeted absorption of nanoencapsulated drugs.
使用微针分数打孔破坏皮肤表层是增强药物吸收的有效方法。本研究分析并比较了分数倍频掺铒钇铝石榴石激光(Er:YAG激光)和射频微针(RM)在促进游离或纳米包封的米诺地尔及米诺环素的皮肤渗透和毛囊靶向方面的有效性。采用体外渗透试验(IVPT)研究了猪皮给药情况,包括有无激光(3、6和7 mJ)和RM(6.1、10.2和20.4 mJ,穿透深度为0.5或1.0 mm)。还进行了微针打孔辅助的载米诺环素纳米载体的体外和体内抗菌活性研究。7 mJ激光处理后,游离米诺地尔的皮肤沉积量和通量分别增加了3倍和56倍。与未处理的对照组相比,激光使游离米诺环素的沉积量和通量分别提高了25倍和40倍。与被动吸收相比,RM使药物通量提高了5至18倍。然而,在皮肤沉积方面未观察到这种增强作用。制备了尺寸分别为81和76 nm的纳米结构脂质载体(NLC)和脂质体,它们分别包封了约80%的药物。微针打孔增加了纳米包封药物的皮肤递送量,尽管这种增强作用不如游离药物明显。通过共聚焦显微镜观察的生物分布表明,与被动扩散相比,微针打孔增加了脂质基纳米载体在真皮中的渗透深度。纳米载体主要分布在微通道中,并转运到周围的真皮组织中。纳米包封NLC和脂质体后,毛囊中米诺环素的摄取量分别从0.03增加到0.16和0.20 nmol/cm。激光和RM处理后,NLC的摄取量进一步增加到1.24和1.51 nmol/cm。载米诺环素纳米载体比游离药物更有效地抑制了浮游和生物膜形式的痤疮丙酸杆菌的活力。小鼠体内痤疮丙酸杆菌感染模型显示,通过微针打孔介导的纳米载体递送能有效根除细菌。经表皮水分流失(TEWL)表明,激光和RM处理的皮肤中的微通道分别在36和12小时内闭合。这些发现表明,分数倍频激光和RM是改善纳米包封药物皮肤和毛囊靶向吸收的有前景的策略。
