Biodistribution Analysis of Peptide-Coated Magnetic Iron Nanoparticles: A Simple and Quantitative Method

Authors

Pavithra Natarajan, Kansas State University
Katherine Horak, USDA APHIS WS NWRC Fort Collins
Jennifer Rowe, Kansas State University
Sungmin Yoon, Kansas State University
Joshua Lingo, University of Iowa
John M. Tomich, Kansas State University
Sherry D. Fleming, Kansas State UniversityFollow

ORCID IDs

Natarajan 0000-0003-3478-2293
Fleming 0000-0001-5385-7233

Date of this Version

2024

Citation

Molecular Pharmaceutics (2024) 21: 970-981

doi: 10.1021/acs.molpharmaceut.3c01080

Comments

United States government work

Abstract

Biodistribution tracks compounds or molecules of interest in vivo to understand a compound’s anticipated efficacy and safety. Nanoparticles deliver nucleic acid and drug payloads and enhance tumor permeability due to multiple properties such as high surface area to volume ratio, surface functionalization, and modifications. Studying the in vivo biodistribution of nanoparticles documents the effectiveness and safety of nanoparticles and facilitates a more application-driven approach for nanoparticle development that allows for more successful translation into clinical use. In this study, we present a relatively simple method to determine the biodistribution of magnetic iron nanoparticles in mice. In vitro, cells take up branched amphiphilic peptide-coated magnetic nanobeads (BAPc-MNBs) like their counterparts, i.e. branched amphiphilic peptide capsules (BAPCs) with a hollow water-filled core. Both BAPc-MNBs and BAPCs have widespread applications as a nanodelivery system. We evaluated the BAPc-MNBs tissue distribution in wild-type mice injected intravenously (i.v.), intraperitoneally (i.p.), or orally gavaged to understand the biological interactions and to further the development of branched amphiphilic peptide-based nanoparticles. The magnetic nanoparticles allowed collection of the BAPc-MNBs from multiple organs by magnetic bead sorting, followed by a high-throughput screening for iron content. When injected i.v., nanoparticles were distributed widely to various organs before elimination from the system via the intestines in feces. The spleen accumulated the highest amount of BAPc-MNBs in mice administered NPs via i.v. and i.p. but not via oral gavage. Taken together, these data demonstrate that the magnetic sorting not only allowed quantification of theBAPc-MNBs but also identified the distribution of BAPc-MNBs after distinct administration methods.