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迈向针对儿科应用的定制口服药物疗法:通过基于自动挤出的材料沉积方法印制的可咀嚼普萘洛尔凝胶片。

Towards a Customized Oral Drug Therapy for Pediatric Applications: Chewable Propranolol Gel Tablets Printed by an Automated Extrusion-Based Material Deposition Method.

作者信息

Roostar Kristiine, Meos Andres, Laidmäe Ivo, Aruväli Jaan, Räikkönen Heikki, Peltonen Leena, Airaksinen Sari, Topelius Niklas Sandler, Heinämäki Jyrki, Paaver Urve

机构信息

Institute of Pharmacy, Faculty of Medicine, University of Tartu, Nooruse 1, 50411 Tartu, Estonia.

Department of Geology, Institute of Ecology and Earth Sciences, University of Tartu, Ravila 14a, 50411 Tartu, Estonia.

出版信息

Pharmaceutics. 2025 Jul 4;17(7):881. doi: 10.3390/pharmaceutics17070881.

DOI:10.3390/pharmaceutics17070881
PMID:40733091
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12299291/
Abstract

Automated semi-solid extrusion (SSE) material deposition is a promising new technology for preparing personalized medicines for different patient groups and veterinary applications. The technology enables the preparation of custom-made oral elastic gel tablets of active pharmaceutical ingredient (API) by using a semi-solid polymeric printing ink. : An automated SSE material deposition method was used for generating chewable gel tablets loaded with propranolol hydrochloride (-HCl) at three different API content levels (3.0 mg, 4.0 mg, 5.0 mg). The physical appearance, surface morphology, dimensions, mass and mass variation, process-derived solid-state changes, mechanical properties, and in-vitro drug release of the gel tablets were studied. : The inclusion of API (1% /) in the semi-solid CuraBlend printing mixture decreased viscosity and increased fluidity, thus promoting the spreading of the mixture on the printed (material deposition) bed and the printing performance of the gel tablets. The printed gel tablets were elastic, soft, jelly-like, chewable preparations. The mechanical properties of the gel tablets were dependent on the printing ink composition (i.e., with or without propranolol HCl). The maximum load for the final deformation of the CuraBlend™-API (3.0 mg) gel tablets was very uniform, ranging from 73 N to 80 N. The in-vitro dissolution test showed that more than 85% of the drug load was released within 15-20 min, thus verifying the immediate-release behavior of these drug preparations. : Automated SSE material deposition as a modified 3D printing method is a feasible technology for preparing customized oral chewable gel tablets of propranolol HCl.

摘要

自动化半固体挤出(SSE)材料沉积是一种很有前景的新技术,可用于为不同患者群体制备个性化药物以及兽医应用。该技术能够通过使用半固体聚合物印刷油墨来制备活性药物成分(API)的定制口服弹性凝胶片。:采用自动化SSE材料沉积方法,以三种不同的API含量水平(3.0毫克、4.0毫克、5.0毫克)制备了载有盐酸普萘洛尔(-HCl)的可咀嚼凝胶片。对凝胶片的外观、表面形态、尺寸、质量和质量变化、过程中产生的固态变化、机械性能以及体外药物释放进行了研究。:在半固体CuraBlend印刷混合物中加入API(1% /)可降低粘度并增加流动性,从而促进混合物在印刷(材料沉积)床上的铺展以及凝胶片的印刷性能。印刷的凝胶片是有弹性的、柔软的、果冻状的、可咀嚼的制剂。凝胶片的机械性能取决于印刷油墨的组成(即有无盐酸普萘洛尔)。CuraBlend™-API(3.0毫克)凝胶片最终变形的最大负荷非常均匀,范围为73牛至80牛。体外溶出试验表明,超过85%的药物负荷在15 - 20分钟内释放,从而证实了这些药物制剂的速释行为。:自动化SSE材料沉积作为一种改进的3D打印方法,是制备定制的盐酸普萘洛尔口服可咀嚼凝胶片的可行技术。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/660a/12299291/50af8e656dbc/pharmaceutics-17-00881-g011.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/660a/12299291/6ce2aeba4e3b/pharmaceutics-17-00881-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/660a/12299291/50af8e656dbc/pharmaceutics-17-00881-g011.jpg

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本文引用的文献

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