Discerning computational, in vitro and in vivo investigations of self-assembling empagliflozin polymeric micelles in type-2 diabetes.

IF 5.7 3区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
Drug Delivery and Translational Research Pub Date : 2024-12-01 Epub Date: 2024-08-05 DOI:10.1007/s13346-024-01658-y
Priti Wagh, Shivani Savaliya, Bhrugesh Joshi, Bhavin Vyas, Ketan Kuperkar, Manisha Lalan, Pranav Shah
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引用次数: 0

Abstract

Background: Empagliflozin (EMPA) is an SGLT2 inhibitor, a new class of anti-diabetic medication, indicated for treating type-2 diabetes. Its low permeability, poor solubility and bioavailability limits its use in management of diabetes. The study was aimed to formulate EMPA loaded polymeric micelles (PMs) to overcome these obstacles in oral absorption.

Methodology: In silico studies-molecular docking, molecular dynamic simulation (MDS), and quantum chemical calculation were employed to study the interaction of EMPA with different polymers. EMPA loaded TPGS polymeric micelles (EMPA-TPGS-PMs) were formulated by direct dissolution method and characterized in terms of surface morphology, entrapment, particle size, in vitro drug release, and in vitro cytotoxicity (HEK293 cells). In vivo pharmacokinetic and pharmacodynamic studies were also performed.

Results: The results suggested a good interaction between TPGS and EMPA with lowest binding energy compared to other polymers. Further MDS results and DFT calculations validated the stable binding of the complex hence TPGS was selected for further wet lab experiments. The EMPA-TPGS complex displayed lower value of Total energy (T.E.) than its individual components, indicating the overall stability of the complex while, the energy band gap (∆E) value lied between the two individual molecules, signifying the better electron transfer between HOMO and LUMO of the complex. Based on the solubility, entrapment and cytotoxicity studies, 5% TPGS was selected for formulating drug loaded micelles. EMPA-TPGS5-PMs presented a size of 9.008 ± 1.25 nm, Polydispersity index (PDI) of 0.254 ± 0.100, a controlled release behaviour upto 24 h. SEM and AFM images of the nanoformulation suggested spherical particles whereas, DSC, and PXRD studies confirmed the loss of crystallinity of EMPA. A 3.12-folds higher AUC and a greater reduction in blood glucose levels was exhibited by EMPA-TPGS5-PMs in comparison to EMPA-SUSP in mice model.

Conclusion: EMPA-TPGS-PMs has exhibited better bio absorption and therapeutic effectiveness in diabetes treatment. This improved performance would open the possibility of dose reduction, reduced dosing frequency & dose-related side effects, improving pharmaco-economics and thereby improved overall compliance to the patient. However, this translation from bench to bedside would necessitate studies in higher animals and human volunteers.

Abstract Image

2型糖尿病患者自组装恩格列净聚合物胶束的计算、体外和体内研究。
背景:恩格列净(Empagliflozin,EMPA)是一种SGLT2抑制剂,是一种新型抗糖尿病药物,适用于治疗2型糖尿病。其渗透性低、溶解性差、生物利用度低,限制了其在糖尿病治疗中的应用。这项研究的目的是配制负载 EMPA 的聚合物胶束(PMs),以克服口服吸收方面的这些障碍:方法:采用分子对接、分子动力学模拟(MDS)和量子化学计算等硅学研究方法研究 EMPA 与不同聚合物的相互作用。采用直接溶解法配制了EMPA负载TPGS聚合物胶束(EMPA-TPGS-PMs),并从表面形态、夹持、粒度、体外药物释放和体外细胞毒性(HEK293细胞)等方面对其进行了表征。此外,还进行了体内药代动力学和药效学研究:结果表明,与其他聚合物相比,TPGS 与 EMPA 的结合能最低,具有良好的相互作用。进一步的 MDS 结果和 DFT 计算验证了复合物的稳定结合,因此选择 TPGS 进行进一步的湿实验室实验。EMPA-TPGS 复合物的总能(T.E.)值低于其单个成分,表明复合物的整体稳定性,而能带间隙(ΔE)值介于两个单个分子之间,表明复合物的 HOMO 和 LUMO 之间的电子转移更好。根据溶解性、包埋性和细胞毒性研究,选择 5% TPGS 用于配制药物胶束。EMPA-TPGS5-PMs 的尺寸为 9.008 ± 1.25 nm,多分散指数(PDI)为 0.254 ± 0.100,控释时间长达 24 小时。在小鼠模型中,与 EMPA-SUSP 相比,EMPA-TPGS5-PMs 的 AUC 高出 3.12 倍,血糖水平降低幅度更大:结论:EMPA-TPGS-PMs 在糖尿病治疗中表现出更好的生物吸收性和治疗效果。这种性能的提高为减少剂量、降低给药频率和剂量相关副作用、改善药物经济学提供了可能,从而提高了患者的整体依从性。不过,要实现从实验室到临床的转化,还需要对高等动物和人类志愿者进行研究。
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来源期刊
Drug Delivery and Translational Research
Drug Delivery and Translational Research MEDICINE, RESEARCH & EXPERIMENTALPHARMACOL-PHARMACOLOGY & PHARMACY
CiteScore
11.70
自引率
1.90%
发文量
160
期刊介绍: The journal provides a unique forum for scientific publication of high-quality research that is exclusively focused on translational aspects of drug delivery. Rationally developed, effective delivery systems can potentially affect clinical outcome in different disease conditions. Research focused on the following areas of translational drug delivery research will be considered for publication in the journal. Designing and developing novel drug delivery systems, with a focus on their application to disease conditions; Preclinical and clinical data related to drug delivery systems; Drug distribution, pharmacokinetics, clearance, with drug delivery systems as compared to traditional dosing to demonstrate beneficial outcomes Short-term and long-term biocompatibility of drug delivery systems, host response; Biomaterials with growth factors for stem-cell differentiation in regenerative medicine and tissue engineering; Image-guided drug therapy, Nanomedicine; Devices for drug delivery and drug/device combination products. In addition to original full-length papers, communications, and reviews, the journal includes editorials, reports of future meetings, research highlights, and announcements pertaining to the activities of the Controlled Release Society.
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