Project Details
Description
Project Summary
Heterotopic ossification (HO) is the pathologic formation of extra-skeletal bone that occurs in ~20% of
patients after hip arthroplasty, musculoskeletal trauma or burns, whereas this incidence increases to over 80%
in patients with high energy injuries implicating the role of the innate immune response. Standardized
treatment protocols to prevent HO are missing and surgical resection of HO fails to restore pre-injury functional
capacity and has a high risk of recurrence. HO, regardless of the inciting event, most commonly forms at sites
of mobility. Once HO is diagnosed, physicians restrict movement of the effected joint to limit progression,
however, the mechanism behind limiting mobility to alter inflammation and HO progression remains unknown.
Further complicating treatment is the fact that there are currently no biomarkers to guide clinicians on which
patients are at high HO risk and therefore should receive prophylaxis and when to initiate treatment. Thus,
there is a substantial clinical need to develop an effective, inflammatory targeted HO therapy and to validate a
biomarker to guide patient selection and precise therapeutic timing. This proposal will generate data sets for
those two unmet clinical needs to provide a breakthrough towards more efficient intervention for HO.
Recent novel dynamic analyses of HO injuries by our group have identified neutrophil phenotype as central
to HO. Specifically, we found that structural components released by neutrophils, known as neutrophil
extracellular traps (NETs), play a critical role in HO. This is a novel aspect how the innate immune response
contributes to HO. It is reported that tissue injury prompts formation of NETs for prevention of infections
(primary NETosis). HO is unique as it forms in sites of mobility which adds a unique force (extrinsic) placed on
NETs which has not been studied. Preliminary data demonstrates that motion of a joint disrupts primary NETs
to induce propagation of NETs (secondary NETosis), critical to develop HO. We found this HO-specific novel
mechanism is mediated by toll-like receptor 9 (TLR9), a known receptor for DNA complexes. Therefore, we
propose that TLR9 is a novel target specific to HO.
Aim 1: Evaluate the role of NETs as a biomarker to predict HO formation. We will evaluate differential NET
formation in HO compared to non-HO control in our mouse models and in a well characterized human patient
cohort at risk for HO (hip arthroplasty) to examine injury site and systemic NET levels as a HO biomarker.
Aim 2: Characterize the role and therapeutic potential specific to secondary NET formation through TLR9
signaling in HO formation and progression. We will also assess the ability of pharmacologic TLR9 inhibition
and neutrophil specific Tlr9 deletion to mitigate secondary NETosis and HO in proven mouse models.
Status | Finished |
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Effective start/end date | 1/09/23 → 31/08/24 |
Funding
- National Institute of Arthritis and Musculoskeletal and Skin Diseases: $410,000.00
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