Nanostructured Lipid Carrier-Mediated Transdermal Delivery System of Glibenclamide for Gestational Diabetes: Pharmacokinetic and Pharmacodynamic Evaluation.

M Ashwini, Preethi Sudheer, Bharani S Sogali
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Abstract

Background: Gestational diabetes mellitus (GDM) poses significant risks during pregnancy for both mother and fetus. Adherence to oral antidiabetic medications, like glibenclamide (GB), can be challenging, necessitating novel drug delivery methods. Nanostructured lipid carriers (NLC) offer a promising approach by efficiently permeating the skin due to their small size and lipid-based composition.

Objective: This study aimed to develop and evaluate transdermal patches loaded with glibenclamide NLCs to treat GDM.

Methods: Glibenclamide NLCs were prepared using hot homogenization with ultrasonication and melt dispersion method. A central composite design was utilized to optimize the formulations. Transdermal patches containing optimized NLCs were developed using HPMC K 100 and Eudragit L polymers. The patches were evaluated for various parameters, and their pharmacokinetic and pharmacodynamic studies were carried out to assess their safety and efficacy.

Results: Optimized NLCs efficiently permeated rat skin. Cell viability studies indicated the nontoxicity of the formulations. NLC-loaded transdermal patches (F2 and F7) showed drug release of 1098 μg/cm2 and 1001.83 μg/cm2 in 24 h, with a 2.5-fold higher flux and permeation coefficient than the GB patch. Pharmacokinetic analysis revealed Tmax of 8 and 10 h and Cmax of 7127 ng/ml and 7960 ng/ml for F2 and F7, respectively, ensuring sustained drug action. AUC0-α was 625681 ng/ml·h and 363625 ng/ml·h for F2 and F7, respectively, indicating improved bioavailability.

Conclusion: Transdermal patches incorporating NLCs hold promise for enhancing glibenclamide's therapeutic efficacy in GDM treatment. Improved skin permeation, sustained drug release, and enhanced bioavailability make NLC-based transdermal patches a potential alternative with better patient compliance.

纳米结构脂质载体介导的格列本脲透皮给药系统用于妊娠糖尿病:药代动力学和药效学评估。
背景:妊娠期糖尿病(GDM)对孕妇和胎儿都有很大风险。口服抗糖尿病药物(如格列本脲(GB))的依从性可能具有挑战性,因此需要新型给药方法。纳米结构脂质载体(NLC)因其体积小和基于脂质的成分,可有效渗透皮肤,是一种很有前景的方法:本研究旨在开发和评估装载格列本脲 NLC 的透皮贴片,以治疗 GDM:方法:采用超声热均质法和熔融分散法制备格列本脲NLCs。采用中心复合设计对制剂进行优化。使用 HPMC K 100 和 Eudragit L 聚合物开发了含有优化 NLCs 的透皮贴片。对这些贴剂进行了各种参数评估,并开展了药代动力学和药效学研究,以评估其安全性和有效性:结果:优化后的 NLC 可有效渗透大鼠皮肤。细胞存活率研究表明制剂无毒性。负载 NLC 的透皮贴片(F2 和 F7)在 24 小时内的药物释放量分别为 1098 μg/cm2 和 1001.83 μg/cm2,通量和渗透系数是 GB 贴片的 2.5 倍。药代动力学分析表明,F2 和 F7 的 Tmax 分别为 8 小时和 10 小时,Cmax 分别为 7127 纳克/毫升和 7960 纳克/毫升,确保了药物的持续作用。F2 和 F7 的 AUC0-α 分别为 625681 ng/ml*h 和 363625 ng/ml*h,表明生物利用度有所提高:结论:含有 NLC 的透皮贴剂有望提高格列本脲在 GDM 治疗中的疗效。皮肤渗透性的改善、药物的持续释放和生物利用度的提高使基于 NLC 的透皮贴剂成为一种潜在的替代品,病人的依从性更好。
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