Fabrication of 3D printed mutable drug delivery devices: a comparative study of volumetric and digital light processing printing.

IF 5.7 3区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Drug Delivery and Translational Research Pub Date : 2025-05-01 Epub Date: 2024-08-23 DOI:10.1007/s13346-024-01697-5

Ye Chan Oh, Jun Jie Ong, Haya Alfassam, Eduardo Díaz-Torres, Alvaro Goyanes, Gareth R Williams, Abdul W Basit

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引用次数: 0

Abstract

Mutable devices and dosage forms have the capacity to dynamically transform dimensionally, morphologically and mechanically upon exposure to non-mechanical external triggers. By leveraging these controllable transformations, these systems can be used as minimally invasive alternatives to implants and residence devices, foregoing the need for complex surgeries or endoscopies. 4D printing, the fabrication of 3D-printed structures that evolve their shape, properties, or functionality in response to stimuli over time, allows the production of such devices. This study explores the potential of volumetric printing, a novel vat photopolymerisation technology capable of ultra-rapid printing speeds, by comparing its performance against established digital light processing (DLP) printing in fabricating hydrogel-based drug-eluting devices. Six hydrogel formulations consisting of 2-(acryloyloxy)ethyl]trimethylammonium chloride solution, lithium phenyl-2,4,6-trimethylbenzoylphosphinate, varying molecular weights of the crosslinking monomer, poly(ethylene glycol) diacrylate, and paracetamol as a model drug were prepared for both vat photopolymerisation technologies. Comprehensive studies were conducted to investigate the swelling and water sorption profiles, drug release kinetics, and physicochemical properties of each formulation. Expandable drug-eluting 4D devices were successfully fabricated within 7.5 s using volumetric printing and were shown to display equivalent drug release kinetics to prints created using DLP printing, demonstrating drug release, swelling, and water sorption properties equivalent to or better than those of DLP-printed devices. The reported findings shed light on the advantages and limitations of each technology for creating these dynamic drug delivery systems and provides a direct comparison between the two technologies, while highlighting the promising potential of volumetric printing and further expanding the growing repertoire of pharmaceutical printing.

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三维打印可变型给药装置的制造：体积打印与数字光处理打印的比较研究。

可变装置和剂型在受到非机械外部触发因素的影响时，能够在尺寸、形态和机械方面发生动态变化。通过利用这些可控的变化，这些系统可用作植入物和住院设备的微创替代品，从而避免了复杂的手术或内窥镜检查。4D 打印是一种三维打印结构的制造方法，这种结构的形状、特性或功能会随着时间的推移对刺激做出反应而发生变化，因此可以制造出这种设备。本研究通过比较体积打印与现有的数字光处理（DLP）打印在制造基于水凝胶的药物洗脱装置方面的性能，探索了体积打印的潜力，体积打印是一种新型的大桶光聚合技术，能够实现超快的打印速度。针对这两种大桶光聚合技术制备了六种水凝胶配方，包括 2-(丙烯酰氧基)乙基三甲基氯化铵溶液、苯基-2,4,6-三甲基苯甲酰膦酸锂、不同分子量的交联单体聚（乙二醇）二丙烯酸酯和作为模型药物的扑热息痛。对每种制剂的溶胀和吸水曲线、药物释放动力学和理化特性进行了全面研究。使用体积印刷技术在 7.5 秒内成功制造出了可膨胀的药物洗脱 4D 装置，其药物释放动力学与使用 DLP 印刷技术制造的装置相当，药物释放、膨胀和吸水特性等同于或优于 DLP 印刷装置。报告的研究结果阐明了每种技术在创建这些动态给药系统方面的优势和局限性，并对两种技术进行了直接比较，同时强调了体积印刷的巨大潜力，并进一步扩大了不断增长的药物印刷范围。

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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.