Stimulation of fracture mineralization by salt-inducible kinase inhibitors

Kaveh Momenzadeh, Diana Yeritsyan, Mohammadreza Abbasian, Nadim Kheir, Philip Hanna, Jialiang Wang, Pere Dosta, Garyfallia Papaioannou, Sarah Goldfarb, Cheng Chia Tang, Eliz Amar-Lewis, Michaela Nicole Prado Larrea, Edith Martinez Lozano, Mohamed Yousef, John Wixted, Marc Wein, Natalie Artzi, Ara Nazarian

Research output: Indexed journal article Articlepeer-review

1 Citation (Web of Science)

Abstract

Introduction: Over 6.8 million fractures occur annually in the US, with 10% experiencing delayed- or non-union. Anabolic therapeutics like PTH analogs stimulate fracture repair, and small molecule salt inducible kinase (SIK) inhibitors mimic PTH action. This study tests whether the SIK inhibitor YKL-05-099 accelerates fracture callus osteogenesis. Methods: 126 female mice underwent femoral shaft pinning and midshaft fracture, receiving daily injections of PBS, YKL-05-099, or PTH. Callus tissues were analyzed via RT-qPCR, histology, single-cell RNA-seq, and μCT imaging. Biomechanical testing evaluated tissue rigidity. A hydrogel-based delivery system for PTH and siRNAs targeting SIK2/SIK3 was developed and tested. Results: YKL-05-099 and PTH-treated mice showed higher mineralized callus volume fraction and improved structural rigidity. RNA-seq indicated YKL-05-099 increased osteoblast subsets and reduced chondrocyte precursors. Hydrogel-released siRNAs maintained target knockdown, accelerating callus mineralization. Discussion: YKL-05-099 enhances fracture repair, supporting selective SIK inhibitors’ development for clinical use. Hydrogel-based siRNA delivery offers targeted localized treatment at fracture sites.

Original languageEnglish
Article number1450611
Number of pages14
JournalFrontiers in Bioengineering and Biotechnology
Volume12
DOIs
Publication statusPublished - 16 Sept 2024
Externally publishedYes

Keywords

  • bone
  • fracture repair
  • microparticle
  • nanoscale drug delivery
  • PTH
  • SIK2/SIK3 inhibitor
  • siRNA targeting

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