Doxorubicin-Loaded Multivesicular Liposomes (DepoFoam) as a Sustained Release Carrier Intended for Locoregional Delivery in Cancer Treatment: Development, Characterization, and Cytotoxicity Evaluation.

IF 1.8 4区医学 Q3 PHARMACOLOGY & PHARMACY

Iranian Journal of Pharmaceutical Research Pub Date : 2022-12-01 DOI:10.5812/ijpr-134190

Mohammad Ali Mahjoub, Simin Dadashzadeh, Azadeh Haeri, Soraya Shahhosseini, Zahra Abbasian, Fatemeh Nowroozi

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引用次数: 1

Abstract

Background: Despite the advantages of direct intratumoral (IT) injection, the relatively rapid withdrawal of most anti-cancer drugs from the tumor due to their small molecular size limits the effectiveness of this method of administration. To address these limitations, recently, increasing attention has been directed to using slow-release biodegradable delivery systems for IT injection.

Objectives: This study aimed to develop and characterize a doxorubicin-loaded DepoFoam system as an efficient controlled-release carrier to be employed for locoregional drug delivery in cancer treatment.

Methods: Major formulation parameters, including the molar ratio of cholesterol to the main lipid [Chol/egg phosphatidylcholine (EPC)], triolein (TO) content, and lipid-to-drug molar ratio (L/D), were optimized using a two-level factorial design approach. The prepared batches were evaluated for encapsulation efficiency (EE) and percentage of drug release (DR) after 6 and 72 hours as dependent variables. The optimum formulation (named DepoDOX) was further evaluated in terms of particle size, morphology, zeta potential, stability, Fourier-transform infrared spectroscopy, in vitro cytotoxicity, and hemolysis.

Results: The analysis of factorial design indicated that TO content and L/D ratio had a negative effect on EE; between these two, TO content had the greatest effect. The TO content was also the most significant component, with a negative effect on the release rate. The ratio of Chol/EPC showed a dual effect on the DR rate. Using a higher percentage of Chol slowed down the initial release phase of the drug; nevertheless, it accelerated the DR rate in the later slow phase. DepoDOX were spherical and honeycomb-like structures (≈ 9.81 μm) with a desired sustained release profile, as DR lasted 11 days. Its biocompatibility was confirmed by the results of cytotoxicity and hemolysis assays.

Conclusions: The in vitro characterization of optimized DepoFoam formulation demonstrated its suitability for direct locoregional delivery. DepoDOX, as a biocompatible lipid-based formulation, showed appropriate particle size, high capability for encapsulating doxorubicin, superior physical stability, and a markedly prolonged DR rate. Therefore, this formulation could be considered a promising candidate for locoregional drug delivery in cancer treatment.

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负载阿霉素的多泡脂质体(DepoFoam)作为一种缓释载体，用于癌症治疗的局部递送:发展、表征和细胞毒性评估。

背景:尽管肿瘤内直接注射(IT)具有优势，但大多数抗癌药物由于其小分子大小而相对快速地从肿瘤中撤出，限制了这种给药方法的有效性。为了解决这些限制，最近，人们越来越关注使用缓释可生物降解的给药系统进行IT注射。目的:本研究旨在开发和表征一种负载多柔比星的DepoFoam系统，作为一种高效的控释载体，用于癌症治疗的局部药物递送。方法:采用双水平析因设计方法，优化主要处方参数，包括胆固醇与主要脂质[胆固醇/鸡蛋磷脂酰胆碱(EPC)]的摩尔比、三油酸(to)含量、脂药摩尔比(L/D)。以6 h和72 h后的包封率(EE)和释药率(DR)为因变量进行评价。最佳配方(命名为DepoDOX)在粒径、形态、ζ电位、稳定性、傅里叶变换红外光谱、体外细胞毒性和溶血等方面进行了进一步评价。结果:析因设计分析表明，TO含量和L/D比对EE有负向影响;两者之间，TO含量的影响最大。TO含量也是最显著的组成部分，对释放率有负向影响。Chol/EPC的比值对DR率有双重影响。使用较高百分比的Chol减慢了药物的初始释放阶段;然而，它加速了后期慢速阶段的DR速率。DepoDOX为球形和蜂窝状结构(≈9.81 μm)，具有理想的缓释轮廓，DR持续11天。细胞毒性和溶血试验证实了其生物相容性。结论:优化后的DepoFoam配方的体外表征表明其适合局部直接给药。DepoDOX是一种生物相容性脂基制剂，具有粒径适宜、包封能力强、物理稳定性好、DR率明显延长等特点。因此，该制剂可被认为是癌症治疗中局部给药的有希望的候选者。

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来源期刊

Iranian Journal of Pharmaceutical Research 医学-药学

CiteScore

3.40

自引率

6.20%

发文量

审稿时长

2 months

期刊介绍： The Iranian Journal of Pharmaceutical Research (IJPR) is a peer-reviewed multi-disciplinary pharmaceutical publication, scheduled to appear quarterly and serve as a means for scientific information exchange in the international pharmaceutical forum. Specific scientific topics of interest to the journal include, but are not limited to: pharmaceutics, industrial pharmacy, pharmacognosy, toxicology, medicinal chemistry, novel analytical methods for drug characterization, computational and modeling approaches to drug design, bio-medical experience, clinical investigation, rational drug prescribing, pharmacoeconomics, biotechnology, nanotechnology, biopharmaceutics and physical pharmacy.