Proof-of-concept preparation and characterization of dual-drug amorphous nanoparticle complex as fixed-dose combination of poorly soluble drugs

Abstract

Objectives: To carry out a proof-of-concept study on the development of dual-drug amorphous nanoparticle complex (nanoplex in short) as a potential formulation platform for fixed-dose combination (FDC) of poorly-soluble drugs.

Significance: FDC has been proven effective in improving patient compliance for treatment that requires complex multidrug regimen. Currently, there is growing interest to develop FDC of poorly-soluble drugs due to the increased number of drugs exhibiting poor solubility thus low bioavailability.

Methods: The dual-drug nanoplex was prepared by electrostatically-driven co-complexation of drug molecules with oppositely charged dextran sulfate, using ciprofloxacin (CIP) and itraconazole (ITZ) as the model poorly-soluble drugs.

Results: We first verified that the co-complexation products were dual-drug CIP-ITZ nanoplex, and not binary mixtures of the single-drug CIP and ITZ nanoplexes, by demonstrating their distinct thermal behaviors and dissolution characteristics. Depending on the preparation condition, the dual-drug nanoplex exhibited size and zeta potential of 160–410 nm and −35–50 mV, respectively. The individual drug payloads were readily manipulated by varying the CIP/ITZ mass ratio in the feed, resulting in CIP and ITZ payloads in the range of 60-30% and 15-45%, respectively. The CIP-ITZ nanoplex, however, exhibited diminished CIP supersaturation generation, thus lower CIP solubility enhancement, compared to the single-drug CIP nanoplex. The CIP-ITZ nanoplex, nonetheless, remained capable of generating high ITZ supersaturation level.

Conclusion: Dual-drug nanoplex was successfully prepared with a high degree of control over its physical characteristics. Nevertheless, whether dual-drug nanoplex always exhibits diminished solubility enhancement compared to its single-drug counterparts needs to be investigated using different poorly-soluble drugs.

Keywords:

• Nanoparticles
• amorphization
• fixed-dose combination
• poorly soluble drugs
• complexation

Disclosure statement

No potential conflict of interest was reported by the authors.

Additional information

Funding

The authors would like to acknowledge the funding from GlaxoSmithKline (GSK) Singapore under their Green and Sustainable Manufacturing Trust Fund 2013 (PI: Kunn Hadinoto Ong).