Tablet fragmentation without a disintegrant: A novel design approach for accelerating disintegration and drug release from 3D printed cellulosic tablets

Arafat, Basel, Wojsz, Magdalena, Isreb, Abdullah, Forbes, Robert T., Isreb, Mohammad, Ahmed, Waqar, Arafat, Tawfiq and Alhnan, Mohamed A. (2018) Tablet fragmentation without a disintegrant: A novel design approach for accelerating disintegration and drug release from 3D printed cellulosic tablets. European Journal of Pharmaceutical Sciences, 118. pp. 191-199. ISSN 1879-0720

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Abstract

Fused deposition modelling (FDM) 3D printing has shown the most immediate potential for on-demand dose personalisation to suit particular patient's needs. However, FDM 3D printing often involves employing a relatively large molecular weight thermoplastic polymer and results in extended release pattern. It is therefore essential to fast-track drug release from the 3D printed objects. This work employed an innovative design approach of tablets with unique built-in gaps (Gaplets) with the aim of accelerating drug release. The novel tablet design is composed of 9 repeating units (blocks) connected with 3 bridges to allow the generation of 8 gaps. The impact of size of the block, the number of bridges and the spacing between different blocks was investigated. Increasing the inter-block space reduced mechanical resistance of the unit, however, tablets continued to meet pharmacopeial standards for friability. Upon introduction into gastric medium, the 1 mm spaces gaplet broke into mini-structures within 4 min and met the USP criteria of immediate release products (86.7% drug release at 30 min). Real-time ultraviolet (UV) imaging indicated that the cellulosic matrix expanded due to swelling of hydroxypropyl cellulose (HPC) upon introduction to the dissolution medium. This was followed by a steady erosion of the polymeric matrix at a rate of 8 μm/min. The design approach was more efficient than a comparison conventional formulation approach of adding disintegrants to accelerate tablet disintegration and drug release. This work provides a novel example where computer-aided design was instrumental at modifying the performance of solid dosage forms. Such an example may serve as the foundation for a new generation of dosage forms with complicated geometric structures to achieve functionality that is usually achieved by a sophisticated formulation approach.

Item Type:	Journal Article
Keywords:	Cellulose, Patient-centred, Bespoke, Personalized, Gaplet, Additive manufacturing, Complex geometry
Faculty:	ARCHIVED Faculty of Medical Science (until September 2018)
Depositing User:	Lisa Blanshard
Date Deposited:	30 Aug 2018 15:22
Last Modified:	09 Sep 2021 16:10
URI:	https://arro.anglia.ac.uk/id/eprint/703526

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