Primaquine-loaded transdermal patch for treating malaria: design, development, and characterization

IF 3.4 Q2 PHARMACOLOGY & PHARMACY Future Journal of Pharmaceutical Sciences Pub Date : 2022-10-27 DOI:10.1186/s43094-022-00433-5
Pankaj Sharma, Mukul Tailang
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引用次数: 1

Abstract

Background

The goal of the current study was to create, improve, and test a transdermal patch loaded with primaquine for the treatment of malaria. Several ingredients were used to create the transdermal patch. For the choosing of polymers, placebo patches were created. The optimization of polymer ratios for patch development and testing their impact on tensile strength, in vitro drug release, in vitro drug permeation, and ex vivo drug permeation employed response surface methods. The F5 formulation was chosen as the optimal formulation based on these answers to the data. The stability of the F5 formulation was examined. According to the findings of trials on acute skin irritation, no place where transdermal patches were given showed any signs of clinical abnormalities or a change in body weight. No erythema or edema of the skin was seen in the rabbit’s skin.

Results

It was observed that tensile strength of the transdermal films formulated with Eudragit RL100 and hydroxypropyl methylcellulose (Pmix) was found between 0.32 ± 0.017 and 0.59 ± 0.013 kg/cm2, which were 0.32 ± 0.017 (F1), 0.36 ± 0.012 (F2), 0.35 ± 0.015 (F3) for Pmix ratio 1:1, 0.42 ± 0.011 (F4), 0.49 ± 0.010 (F5), 0.55 ± 0.016 (F6) for Pmix ratio 1:2 and 0.56 ± 0.014 (F7), 0.57 ± 0.010 (F8), 0.59 ± 0.013 (F9) for Pmix ratio 1:3. Data fitting to the Peppas, Hixon–Crowell, Higuchi, and Zero-order models was used to examine the optimized transdermal patch (F5) release kinetic mechanism. Data comparison was done using the correlation coefficient (R2). Zero-order had an observed correlation coefficient (R2) of 0.9988, which was greater than that for other models. Therefore, it was clear that the medication was released from the formulation after the Zero-order release.

Conclusion

The ideal thickness, percent elongation, and tensile strength of the primaquine therapeutic transdermal patches were prepared for transdermal delivery. The therapeutic transdermal patch was prepared by using Eudragit RL100: HPMC K15M (1:2) into the patch because this combination was responsible for the significant delivery of the drug into the bloodstream. The therapeutic transdermal patch has a notable penetration rate. Dimethyl sulfoxide was used as a permeation enhancer, which helped to obtain a high penetration rate. The statistical analysis was used to support the improved formulation. The therapeutic transdermal patch is a potential vehicle for the administration of primaquine, according to stability studies.

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Primaquine经皮贴剂治疗疟疾:设计、开发和表征
本研究的目的是创建、改进和测试一种装有伯氨喹的透皮贴片,用于治疗疟疾。使用了几种成分来制造透皮贴片。对于聚合物的选择,创造了安慰剂贴片。采用响应面法优化贴片开发的聚合物配比,并测试其对抗拉强度、体外药物释放、体外药物渗透和体外药物渗透的影响。根据对这些数据的回答,选择F5配方作为最优配方。考察了F5配方的稳定性。根据对急性皮肤刺激的试验结果,在给予透皮贴片的地方,没有任何临床异常或体重变化的迹象。兔皮肤未见红斑、水肿。淬硬被观察到抗拉强度的经皮的电影制定Eudragit RL100和羟丙甲纤维素(Pmix)被发现在0.32±0.017,0.59±0.013公斤/平方厘米,0.32±0.017 (F1), 0.36±0.012 (F2), 0.35±0.015 (F3) Pmix比例1:1,0.42±0.011 (F4), 0.49±0.010 (F5), 0.55±0.016 (F6) Pmix比1:2和0.56±0.014 (F7), 0.57±0.010 (F8), 0.59±0.013 (F9) Pmix比例1:3。采用Peppas、Hixon-Crowell、Higuchi和零阶模型拟合数据,考察优化后的透皮贴剂(F5)释放动力学机制。采用相关系数(R2)进行数据比较。零阶模型的相关系数(R2)为0.9988,高于其他模型。因此,很明显药物是在零级释放后从制剂中释放出来的。结论制备了理想的伯氨喹治疗性透皮贴片厚度、伸长率和抗拉强度,适合经皮给药。治疗性透皮贴片是通过在贴片中加入Eudragit RL100: HPMC K15M(1:2)来制备的,因为这种组合负责将药物显著地输送到血液中。治疗性透皮贴片具有显著的穿透率。采用二甲亚砜作为渗透增强剂,提高了渗透速率。统计分析支持改进后的配方。根据稳定性研究,治疗性透皮贴片是伯氨喹给药的潜在载体。
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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来源期刊
自引率
0.00%
发文量
44
审稿时长
23 weeks
期刊介绍: Future Journal of Pharmaceutical Sciences (FJPS) is the official journal of the Future University in Egypt. It is a peer-reviewed, open access journal which publishes original research articles, review articles and case studies on all aspects of pharmaceutical sciences and technologies, pharmacy practice and related clinical aspects, and pharmacy education. The journal publishes articles covering developments in drug absorption and metabolism, pharmacokinetics and dynamics, drug delivery systems, drug targeting and nano-technology. It also covers development of new systems, methods and techniques in pharmacy education and practice. The scope of the journal also extends to cover advancements in toxicology, cell and molecular biology, biomedical research, clinical and pharmaceutical microbiology, pharmaceutical biotechnology, medicinal chemistry, phytochemistry and nutraceuticals.
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