Optimisation of a Microfluidic Method for the Delivery of a Small Peptide.
Felicity Y HanWeizhi XuVinod KumarCedric S CuiXaria LiXingyu JiangTrent M WoodruffAndrew K WhittakerMaree T SmithPublished in: Pharmaceutics (2021)
Peptides hold promise as therapeutics, as they have high bioactivity and specificity, good aqueous solubility, and low toxicity. However, they typically suffer from short circulation half-lives in the body. To address this issue, here, we have developed a method for encapsulation of an innate-immune targeted hexapeptide into nanoparticles using safe non-toxic FDA-approved materials. Peptide-loaded nanoparticles were formulated using a two-stage microfluidic chip. Microfluidic-related factors (i.e., flow rate, organic solvent, theoretical drug loading, PLGA type, and concentration) that may potentially influence the nanoparticle properties were systematically investigated using dynamic light scattering and transmission electron microscopy. The pharmacokinetic (PK) profile and biodistribution of the optimised nanoparticles were assessed in mice. Peptide-loaded lipid shell-PLGA core nanoparticles with designated size (~400 nm) and a sustained in vitro release profile were further characterized in vivo. In the form of nanoparticles, the elimination half-life of the encapsulated peptide was extended significantly compared with the peptide alone and resulted in a much higher distribution into the lung. These novel nanoparticles with lipid shells have considerable potential for increasing the circulation half-life and improving the biodistribution of therapeutic peptides to improve their clinical utility, including peptides aimed at treating lung-related diseases.
Keyphrases
- drug delivery
- high throughput
- circulating tumor cells
- single cell
- cancer therapy
- innate immune
- walled carbon nanotubes
- oxidative stress
- small molecule
- photodynamic therapy
- computed tomography
- type diabetes
- ionic liquid
- big data
- insulin resistance
- artificial intelligence
- skeletal muscle
- drug release
- oxide nanoparticles