Trials / Not Yet Recruiting

Not Yet RecruitingNCT07535372

ASO Treatment for Syndromic Craniosynostoses

Nano-ink Based Antisense oligonUcleoTIde deLivery for Ultra-personaIized Treatment of Syndromic Craniosynostoses

Status: Not Yet Recruiting
Phase: —
Study type: Observational
Enrollment: 12 (estimated)

Sponsor: Fondazione Policlinico Universitario Agostino Gemelli IRCCS · Academic / Other
Sex: All
Age: 5 Years
Healthy volunteers: Not accepted

Summary

Syndromic craniosynostoses (SCS) are rare genetic disorders defined by premature cranial suture fusion, resulting in abnormal craniofacial development and constrained brain growth. These conditions, including Muenke, Saethre-Chotzen, Crouzon, Apert, Pfeiffer and craniofrontonasal syndromes, are typically caused by gain- or loss-of-function variants in key regulators of suture biology such as FGFR1/2/3, TWIST1 and TCF12. Current management is exclusively surgical, relying on early cranial vault remodelling and subsequent reconstructive procedures, which carry substantial risks (e.g. blood loss, infection, re-synostosis) and do not address the underlying molecular etiology. Recent advances in RNA-based therapeutics have demonstrated the potential of mutation-specific approaches to normalize aberrant osteogenic differentiation in patient-derived cells. However, clinical translation remains limited by inefficient delivery and lack of sustained therapeutic activity. The NAUTILUS project aims to overcome these barriers by developing a non-invasive, ultra-personalized therapeutic platform based on mutation-specific antisense oligonucleotides (ASOs) delivered via a nano-engineered system. The project will design and validate patient-tailored ASOs targeting the molecular drivers of SCS, with the goal of either silencing pathogenic gain-of-function alleles or restoring physiological expression in loss-of-function contexts. Functional efficacy will be assessed in patient-derived cellular models by evaluating transcript modulation and rescue of protein function. In parallel, NAUTILUS will optimize a nano-ink delivery platform combining PLGA-PEG-bis-sulfone nanoparticles with a GelMA-based hydrogel scaffold, enabling localized, controlled, and sustained ASO release within the cranial suture niche. Preclinical validation in relevant mouse models will assess the capacity of this platform to delay or prevent pathological suture ossification, ultimately reducing the need for repeated surgical interventions. By directly targeting the genetic basis of disease, NAUTILUS proposes a transformative approach to SCS management. This strategy has the potential to decrease treatment invasiveness, improve clinical outcomes, and enhance quality of life, establishing a precision medicine paradigm for rare craniofacial disorders.

Conditions

Interventions

Type	Name	Description
GENETIC	Design of patient specific ASO	For each patient enrolled cranial suture tissue waste and peripheral blood sample will be collected for cell isolation and ASO in vitro testing

Timeline

Start date: 2026-04-20
Primary completion: 2027-04-20
Completion: 2028-04-20
First posted: 2026-04-17
Last updated: 2026-04-17

Locations

1 site across 1 country: France

Source: ClinicalTrials.gov record NCT07535372. Inclusion in this directory is not an endorsement.