Use of dairy industry side-stream lactose for tablet manufacturing - proof of concept study

Int J Pharm. 2024 Jul 20:660:124354. doi: 10.1016/j.ijpharm.2024.124354. Epub 2024 Jun 17.

Abstract

During recent years there have been shortages of certain drugs due to problems in raw material supply. These are often related to active ingredients but could also affect excipients. Lactose is one of the most used excipients in tableting and comes in two anomeric and several solid-state forms. The aim of this study was to utilize lactose from a dairy side-stream and compare it against a commercial reference in direct compression. This would be a sustainable option and would secure domestic availability during crises. Two types of lactose, spray-dried and freeze-dried, were evaluated. Lactose was mixed with microcrystalline cellulose in different ratios together with lubricant and glidant, and flowability and tabletability of the formulations was characterized. The fully amorphous and small particle-sized spray-dried lactose flowed inadequately but exhibited good tabletability. The larger particle-sized, freeze-dried lactose exhibited sufficient flow and better tabletability than the commercial reference. However, disintegration and drug release were slower when using the investigational lactose formulations. This was most likely due to remaining milk proteins, especially caseins, in the lactose. Overall, the investigational lactose provides promise for the use of such a side-stream product during crisis situations but enhancing their properties and/or purity would be needed.

Keywords: Direct compression; Lactose; Solid state; Supply chain; Sustainability.

MeSH terms

  • Cellulose* / chemistry
  • Chemistry, Pharmaceutical / methods
  • Dairying
  • Drug Compounding* / methods
  • Drug Liberation*
  • Excipients* / chemistry
  • Freeze Drying*
  • Lactose* / chemistry
  • Particle Size
  • Proof of Concept Study
  • Spray Drying
  • Tablets*

Substances

  • Lactose
  • Tablets
  • Excipients
  • Cellulose
  • microcrystalline cellulose