Exploiting response surface D-optimal design study for preparation and optimization of spanlastics loaded with miconazole nitrate as a model antifungal drug for topical application

IF 2.7 4区医学 Q2 PHARMACOLOGY & PHARMACY Journal of Pharmaceutical Innovation Pub Date : 2023-11-30 DOI:10.1007/s12247-023-09800-y

Mervat Shafik Ibrahim, Omar A. Elkady, Mai A. Amer, Shereen H. Noshi

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Abstract

Purpose

Skin fungal infections are widely spreading worldwide and are considered a main cause of skin, mucous membranes, and systemic diseases. In an approach to enhance the topical delivery of miconazole nitrate (MZN) as a poorly permeable antifungal agent, spanlastics nanocarriers as a type of elastic vesicles were adopted in the current work.

Methods

MZN spanlastics were prepared and optimized according to a D-optimal response surface design to investigate the influence of formulation variables, edge activator (EA) percentage, EA type on particle size (PS), and drug entrapment efficiency percentage (% EE) as dependent variables. The spanlastics optimized formula (F7) was further assessed for its elasticity and physico-pharmaceutical properties before being incorporated into a gel. The F7 gel formula was also examined for its physical properties, in vitro release, in vitro antifungal activity against Candida albicans (ATCC® 10231), and ex vivo skin deposition studies. The results of the F7 gel formula were compared to the F7 aqueous dispersion.

Results

The D-optimal design revealed that F7, developed using Tween 60 as EA and Span 60 at a weight ratio 2:8, is the optimized formula. F7 was an elastic, spherical, non-aggregated vesicle with an average PS of 210 nm and a drug entrapment efficiency of 90%. The drug was present in an amorphous form within the vesicles. The gel form of F7 showed a prolonged drug release behavior relative to the solution form, where 75% of the drug was released over 10 h for the former and 5 h for the latter. The antifungal study revealed a significant (p < 0.05) increase in the zone of inhibition of Candida albicans (ATCC® 10231) demonstrated by spanlastics compared to MZN suspension at the same concentration level. MZN suspension showed cytotoxic activity at a concentration of 20 μg/mL and above; the incorporation of the drug in spanlastics dispersion or gel form increased the cell viability percentage. The skin deposition studies showed that F7 deposition in the dermal layer, where deep skin infections occur, is 164-folds that of the plain drug.

Conclusions

The results confirm the potential application of MZN-spanlastics to treat deeply seated skin fungal infections.

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利用响应面d -优化设计研究负载硝酸咪康唑作为外用抗真菌药物模型的塑料材料的制备与优化

皮肤真菌感染在世界范围内广泛传播，被认为是皮肤、粘膜和全身性疾病的主要原因。作为一种渗透性较差的抗真菌药物，为了提高咪康唑(MZN)的局部递送能力，本研究采用了一种弹性囊泡的弹性塑料纳米载体。方法采用d -最优响应面设计对smzn塑料进行制备和优化，考察配方变量、边缘激活剂(EA)百分比、EA类型对粒径(PS)和药物包封效率(% EE)的影响。在加入凝胶之前，进一步评估了塑性优化配方(F7)的弹性和物理药物性能。研究了F7凝胶配方的物理特性、体外释放、体外抗白色念珠菌活性(ATCC®10231)以及离体皮肤沉积研究。将F7凝胶配方的结果与F7水分散体的结果进行了比较。结果优选出以Tween 60为EA, Span 60为权重比为2:8的F7为最佳配方。F7为弹性球形非聚集囊泡，平均PS为210 nm，包封效率为90%。药物以无定形形式存在于囊泡中。凝胶形式的F7相对于溶液形式表现出较长的药物释放行为，前者在10小时内释放75%的药物，后者在5小时内释放。抗真菌研究显示显著(p <0.05)在相同浓度水平下，与MZN悬浮液相比，塑料对白色念珠菌(ATCC®10231)的抑制区增加。MZN悬浮液在浓度为20 μg/mL及以上时具有细胞毒活性;以塑料分散体或凝胶形式掺入药物可提高细胞存活率。皮肤沉积研究表明，F7在皮肤深层感染发生的真皮层沉积是普通药物的164倍。结论mzn - spanplastic在皮肤深部真菌感染治疗中的应用前景广阔。

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来源期刊

Journal of Pharmaceutical Innovation PHARMACOLOGY & PHARMACY-

CiteScore

3.70

自引率

3.80%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Pharmaceutical Innovation (JPI), is an international, multidisciplinary peer-reviewed scientific journal dedicated to publishing high quality papers emphasizing innovative research and applied technologies within the pharmaceutical and biotechnology industries. JPI''s goal is to be the premier communication vehicle for the critical body of knowledge that is needed for scientific evolution and technical innovation, from R&D to market. Topics will fall under the following categories: Materials science, Product design, Process design, optimization, automation and control, Facilities; Information management, Regulatory policy and strategy, Supply chain developments , Education and professional development, Journal of Pharmaceutical Innovation publishes four issues a year.