Effect of excipient particle size distribution variability on compact tensile strength; and its in-line prediction by force-displacement and force-time profiling

Wee Beng Lee; Effendi Widjaja; Paul Wan Sia Heng; Lai Wah Chan

doi:10.1016/j.ejps.2021.105703

Effect of excipient particle size distribution variability on compact tensile strength; and its in-line prediction by force-displacement and force-time profiling

Eur J Pharm Sci. 2021 Apr 1:159:105703. doi: 10.1016/j.ejps.2021.105703. Epub 2021 Jan 12.

Authors

Wee Beng Lee¹, Effendi Widjaja², Paul Wan Sia Heng¹, Lai Wah Chan³

Affiliations

¹ GEA-NUS Pharmaceutical Processing Research Laboratory, Department of Pharmacy, National University of Singapore, 18 Science Drive 4, Singapore 117543, Singapore.
² MSD International GmbH, 50 Tuas West Drive, Singapore 638408, Singapore.
³ GEA-NUS Pharmaceutical Processing Research Laboratory, Department of Pharmacy, National University of Singapore, 18 Science Drive 4, Singapore 117543, Singapore. Electronic address: phaclw@nus.edu.sg.

PMID: 33444745
DOI: 10.1016/j.ejps.2021.105703

Abstract

Background: Direct compression is potentially sensitive to particle size distribution (PSD) variability in pharmaceutical grade excipients. Yet, the impact is insufficiently studied. Furthermore, the use of force sensor as a process analytical technology (PAT) platform, to monitor the effect of PSD variations on compact tensile strength, is a readily available but underutilized strategy.

Methods: To address these shortfalls, the effect of PSD variability on compaction was investigated. Low (4% w/w drug) and high (15% w/w drug) dose blends comprising chlorpheniramine, microcrystalline cellulose and spray-agglomerated lactose were tableted. The PSD of spray-agglomerated lactose was varied by adding ungranulated fines to simulate commercially-relevant variability. Tensile strength and disintegration time were determined. The use of force sensor, to generate force-displacement and force-time profiles, for in-line tensile strength prediction was evaluated.

Results: Increasing proportion of ungranulated fines (≥ 16%) reduced tensile strength by 10% and 4% in low and high dose formulations (p < 0.02). Increased friction during compaction hindered particle movement and reduced the energy available for bonding. Nevertheless, disintegration performances were equally acceptable for immediate drug release (≈ 30 s). Modelling of tensile strength with force-displacement and force-time profiles yielded ≥ 98% accuracy for in-line prediction (relative root mean square error of prediction = 3.7% and 4.8%).

Conclusion: A better understanding of the relationship between PSD variability and direct compression was attained; and force-displacement and force-time profiling are pragmatic and elegant PAT strategies. Significantly, with further refinements, the force sensor in the rotary tablet press can be repurposed for process monitoring and quality inspection. This unlocks opportunities for process understanding and control, without additional investments in PAT platforms.

Keywords: Compaction; Excipient variability; Particle size distribution; Process analytical technology; Tablet; Tensile strength.

MeSH terms

Drug Compounding
Excipients*
Particle Size
Tablets
Technology, Pharmaceutical*
Tensile Strength

Substances

Excipients
Tablets