Energy-Based Methods and Nanocarrier-Based Approaches for Melasma Treatment.

IF 3.1 Q2 PHARMACOLOGY & PHARMACY

Advanced pharmaceutical bulletin Pub Date : 2024-12-30 Epub Date: 2024-09-15 DOI:10.34172/apb.42794

Amiremad Kheirieh, Amirhessam Kheirieh, Zahra Mahdavi, Ali Mohammad Halvani, Amir Mohammad Bagheri, Hooriyeh Nassirli, Shiva Golmohammadzadeh, Bizhan Malaekeh-Nikouei

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Abstract

Purpose: Melasma is a persistent skin condition caused by excessive melanin production, particularly affecting women's quality of life. It can result from various factors like sun exposure, genetics, hormones, medications, or inflammation. Effective melasma treatment requires products that can deeply penetrate the skin. The outermost skin layer, known as the stratum corneum (SC), plays a crucial role in delivering topical and transdermal drugs. Researchers have developed numerous strategies to enhance skin permeability and drug efficacy.

Methods: This review delves into energy-based techniques and nanocarrier systems for treating melasma, specifically focusing on improving drug delivery to the viable epidermis (EP) while overcoming the SC barrier.

Results: Physical methods offer benefits such as enhanced skin penetration but come with drawbacks like frequent visits, high costs, and the need for specialized equipment and skilled operators. Microneedle patches are gaining attention as a convenient physical treatment option for delivering multiple medications effectively, offering targeted delivery and minimal side effects. Nanocarrier systems like transferosomes demonstrate promise in enhancing skin penetration for treating melasma and skin hyperpigmentation. While they offer advantages such as high drug entrapment and improved bioavailability, challenges like stability issues and scalability hinder their widespread adoption.

Conclusion: Energy-based techniques enhance drug penetration but can lead to scarring and burns, while dissolvable micro-needles offer a convenient and effective alternative. Nano-drug carriers, like nanostructured lipid carriers (NLCs) and transferosomes, show promise for improved skin drug delivery with their flexible structures and enhanced penetration capabilities, yet further clinical research is needed for definitive conclusions.

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基于能量的方法和基于纳米载体的方法治疗黄褐斑。

目的：黄褐斑是一种由黑色素分泌过多引起的持续性皮肤状况，尤其影响女性的生活质量。它可能由多种因素引起，如阳光照射、遗传、激素、药物或炎症。有效的黄褐斑治疗需要能够深入皮肤的产品。最外层的皮肤层，被称为角质层（SC），在局部和透皮药物的输送中起着至关重要的作用。研究人员已经开发了许多策略来提高皮肤渗透性和药物疗效。方法：本综述深入研究了能量技术和纳米载体系统治疗黄褐斑，特别关注在克服SC屏障的同时改善药物向活表皮（EP）的传递。结果：物理方法提供了诸如增强皮肤穿透性等优点，但也存在诸如频繁就诊、成本高、需要专门设备和熟练操作人员等缺点。微针贴片作为一种方便的物理治疗选择，可以有效地提供多种药物，具有靶向性和最小的副作用。纳米载体系统，如转移体，在提高皮肤渗透治疗黄褐斑和皮肤色素沉着有希望。虽然它们具有高药物捕获率和提高生物利用度等优点，但稳定性问题和可扩展性等挑战阻碍了它们的广泛采用。结论：能量针刺技术虽能增强药物穿透性，但可导致瘢痕和烧伤，而可溶微针则是一种方便有效的替代方法。纳米药物载体，如纳米结构脂质载体（nlc）和转移体，由于其灵活的结构和增强的渗透能力，显示出改善皮肤给药的希望，但需要进一步的临床研究来确定结论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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