Viscoelastic properties of polymer mixtures containing micro-ribbons and microfibres for the 3D printing of pharmaceutical dosage forms by fused deposition modelling.

IF 3.2 4区医学 Q2 PHARMACOLOGY & PHARMACY

Journal of Pharmacy and Pharmacology Pub Date : 2026-05-02 DOI:10.1093/jpp/rgag044

Marwan Algellay, Satyajit D Sarker, Matthew Roberts, Lucy A Bosworth, Touraj Ehtezazi

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引用次数: 0

Abstract

Objectives: To match the disintegration time of conventional oral films with 3D printed fast-dissolving oral films (FDFs), micro-composites have been used in the formulation. However, in certain cases the 3D-printer failed to produce desired films.

Methods: The viscoelastic properties were evaluated for polyvinyl alcohol and polyvinylpyrrolidone filaments containing chitosan micro-ribbons and cellulose microfibres as micro-composites with the hypothesis that intermittent nozzle blockage was the mechanism responsible for the observed printing failures.

Key findings: Domination of loss modulus over storage modulus was observed for successful printing. Micro-composites improved the viscoelastic properties of filaments including filaments that failed to print. The novelty of this research was that poor viscoelastic properties could not be accounted for the failure of FDF 3D printing for formulations with high micro-composite contents. Filaments of these formulations exhibited rough surfaces with visible aggregates. These observations suggested intermittent nozzle blockage by aggregated micro-composites could have been the cause of 3D printing failure. This hypothesis was supported by successful printing when printer nozzle diameter increased.

Conclusions: The domination of loss modulus over storage modulus was essential for filaments to achieve successful FDF 3D printing. However, micro-composites at high concentrations in the formulation may induced nozzle blockage leading to printing failures.

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含有微带和微纤维的聚合物混合物的粘弹性特性，用于熔融沉积建模的药物剂型3D打印。

目的：采用微复合材料制备3D打印快速溶解口腔膜，以匹配常规口腔膜与3D打印快速溶解口腔膜的崩解时间。然而，在某些情况下，3d打印机无法生产出所需的胶片。方法：以含壳聚糖微带的聚乙烯醇、聚乙烯吡啶酮长丝和纤维素微纤维为微复合材料，考察其粘弹性性能，并假设间歇性喷嘴堵塞是导致打印失败的机制。主要发现：控制损失模量超过存储模量被观察到成功印刷。微复合材料改善了长丝的粘弹性，包括不能打印的长丝。该研究的新颖之处在于，对于含有高微复合材料含量的配方，较差的粘弹性不能解释FDF 3D打印失败的原因。这些配方的细丝表面粗糙，有明显的聚集体。这些观察结果表明，聚集的微复合材料间歇性堵塞喷嘴可能是3D打印失败的原因。这一假设得到了打印机喷嘴直径增大时打印成功的支持。结论：控制损耗模量大于存储模量对于长丝成功实现FDF 3D打印至关重要。然而，配方中高浓度的微复合材料可能会导致喷嘴堵塞，导致打印失败。

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

Journal of Pharmacy and Pharmacology 医学-药学

CiteScore

6.60

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： JPP keeps pace with new research on how drug action may be optimized by new technologies, and attention is given to understanding and improving drug interactions in the body. At the same time, the journal maintains its established and well-respected core strengths in areas such as pharmaceutics and drug delivery, experimental and clinical pharmacology, biopharmaceutics and drug disposition, and drugs from natural sources. JPP publishes at least one special issue on a topical theme each year.