Microneedle patch capable of dual drug release for drug delivery to brain tumors.

IF 5.7 3区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Drug Delivery and Translational Research Pub Date : 2025-05-01 Epub Date: 2024-08-26 DOI:10.1007/s13346-024-01696-6

Robab Mousavi, Madjid Soltani, Mohammad Souri

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Abstract

Primary brain tumors are mostly managed using surgical resection procedures. Nevertheless, in certain cases, a thin layer of tumors may remain outside of the resection process due to the possibility of permanent injury; these residual tumors expose patients to the risk of tumor recurrence. This study has introduced the use of microneedle patches implanted after surgery with a dual-release mechanism for the administration of doxorubicin. The proposed patches possess the capability to administer drugs directly to the residual tumors and initiate chemotherapy immediately following surgical procedures. Three-dimensional simulation of drug delivery to residual tumors in the brain has been performed based on a finite element method. The impact of four important parameters on drug delivery has been investigated, involving the fraction of drug released in the burst phase, the density of microneedles on the patch, the length of microneedles, and the microvascular density of the tumor. The simulation findings indicate that lowering the fraction of drug released in the initial burst phase reduces the maximum average concentration, but the sustained release that continues for a longer period, increasing the bioavailability of free drug. However, the area under curve (AUC) for different release rates remains unchanged due to the fact that an identical dose of drug is supplied in each instance. By increasing the density of microneedles on the patch, concentration accumulation is provided over an extensive region of tumor, which in turn induces more cancer cell death. A comparative analysis of various lengths reveals that longer microneedles facilitate profound penetration into the tumor layers and present better therapeutic response due to extensive area of the tumor which is exposure to chemotherapeutic drugs. Furthermore, high microvascular density, as a characteristic of the tumor microenvironment, is shown to have a significant impact on the blood microvessels drainage of drugs and consequently lower therapeutic response outcome. Our approach offers a computational framework for creating localized drug delivery systems and addressing the challenges related to residual brain tumors.

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用于脑肿瘤给药的具有双重药物释放功能的微针贴片。

原发性脑肿瘤大多采用手术切除的方式进行治疗。然而，在某些情况下，由于可能造成永久性损伤，切除过程中可能会残留一薄层肿瘤，这些残留肿瘤使患者面临肿瘤复发的风险。本研究介绍了在手术后植入具有双重释放机制的微针贴片来给药多柔比星。这种微针贴片能够在手术后立即对残留肿瘤进行直接给药并启动化疗。基于有限元方法，对脑部残余肿瘤的给药进行了三维模拟。研究了四个重要参数对给药的影响，包括爆发期释放的药物比例、贴片上微针的密度、微针的长度和肿瘤的微血管密度。模拟结果表明，降低初始迸发阶段释放药物的比例会降低最大平均浓度，但持续释放的时间会更长，从而提高游离药物的生物利用率。不过，不同释放速率下的曲线下面积（AUC）保持不变，这是因为每次提供的药物剂量相同。通过增加贴片上微针的密度，可在肿瘤的大面积区域进行浓度累积，从而诱导更多癌细胞死亡。对不同长度的微针进行比较分析后发现，较长的微针有利于深入肿瘤层，由于肿瘤暴露于化疗药物的面积大，因此治疗效果更好。此外，高微血管密度作为肿瘤微环境的一个特征，对微血管引流药物有显著影响，从而降低了治疗效果。我们的方法提供了一个计算框架，用于创建局部给药系统，并解决与残余脑肿瘤相关的挑战。

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

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.