Unravelling the mechanobiology of the craniofacial system- towards a novel therapy (CranioMech)
Lead Research Organisation:
University College London
Department Name: Mechanical Engineering
Abstract
Our skulls consist of several bones that are joined together along their edges by soft tissues called cranial joints or sutures. During infancy, our skulls grow rapidly in size and shape to accommodate our brain growth. Once the brain has reached its maximum size, soft tissues at the sutures turn into bone to protect our brain and enable us to bite harder.
Our fundamental understanding of the level of forces that our skulls and its cranial joints experience during the growth is extremely limited. This lack of knowledge has limited our ability to advance treatment of a wide range of craniofacial conditions affecting:
children e.g. craniosynostosis is a medical condition caused by early fusion of cranial joints that has very nearly doubled in incidence across Europe in the last 30 years for unknown reasons
adults e.g. large calvarial defects increasingly being used for the management of ischaemic stroke and traumatic brain injury
Thus, this is a huge engineering challenge that requires in-depth investigations using a range of advanced techniques. CranioMech aims to address these engineering challenges and critical gaps in our knowledge while focusing on developing a revolutionary therapy for craniosynostosis (CS).
CranioMech builds on my network of collaborators and strong track record in this field, significant institutional support (ca. £690k), as well as my recent work (in vivo mouse testing) that demonstrates the feasibility of a therapy that could become a reality for children of the 21st century. CranioMech aims to: (1) further expand on my therapy in mouse and unravel the fundamental underlying mechanism by which it works; (2) test its scalability in larger animal models; and (3) carry out a series of proof of concept studies in preparation for the first human trials, while unravelling the biomechanics of current treatments of CS.
This is a truly high risk, high gain multidisciplinary, multi-scale project, combining fundamental principles with significant translational potential. It will use a combination of advanced approaches e.g. computer simulation, manufacturing, imaging, sensing and in vivo experiments to transform the treatment of CS by resolving its unknown mechanics. This is a neglected area, well in line with EPSRC Healthcare Technologies themes and the UK strategy for rare diseases that can offer a beacon of equality, diversity, inclusion (EDI) & responsible research and innovation (RRI).
Our fundamental understanding of the level of forces that our skulls and its cranial joints experience during the growth is extremely limited. This lack of knowledge has limited our ability to advance treatment of a wide range of craniofacial conditions affecting:
children e.g. craniosynostosis is a medical condition caused by early fusion of cranial joints that has very nearly doubled in incidence across Europe in the last 30 years for unknown reasons
adults e.g. large calvarial defects increasingly being used for the management of ischaemic stroke and traumatic brain injury
Thus, this is a huge engineering challenge that requires in-depth investigations using a range of advanced techniques. CranioMech aims to address these engineering challenges and critical gaps in our knowledge while focusing on developing a revolutionary therapy for craniosynostosis (CS).
CranioMech builds on my network of collaborators and strong track record in this field, significant institutional support (ca. £690k), as well as my recent work (in vivo mouse testing) that demonstrates the feasibility of a therapy that could become a reality for children of the 21st century. CranioMech aims to: (1) further expand on my therapy in mouse and unravel the fundamental underlying mechanism by which it works; (2) test its scalability in larger animal models; and (3) carry out a series of proof of concept studies in preparation for the first human trials, while unravelling the biomechanics of current treatments of CS.
This is a truly high risk, high gain multidisciplinary, multi-scale project, combining fundamental principles with significant translational potential. It will use a combination of advanced approaches e.g. computer simulation, manufacturing, imaging, sensing and in vivo experiments to transform the treatment of CS by resolving its unknown mechanics. This is a neglected area, well in line with EPSRC Healthcare Technologies themes and the UK strategy for rare diseases that can offer a beacon of equality, diversity, inclusion (EDI) & responsible research and innovation (RRI).
Organisations
- University College London (Fellow, Lead Research Organisation)
- Oxford University Hospitals NHS Trust (Project Partner)
- Catholic (Radboud) University Foundation (Project Partner)
- University of Oxford (Project Partner)
- Erasmus MC (Project Partner)
- Headlines Craniofacial Support (Project Partner)
- Hôpital Necker-Enfants Malades (Project Partner)
- King's College London (Project Partner)
- University of Washington (Project Partner)
- University of Leeds (Project Partner)
People |
ORCID iD |
Mehran Moazen (Principal Investigator / Fellow) |
Publications
Moazen M
(2022)
Mechanical loading of cranial joints minimizes the craniofacial phenotype in Crouzon syndrome.
in Scientific reports
Cross C
(2022)
A preliminary analysis of replicating the biomechanics of helmet therapy for sagittal craniosynostosis
in Child's Nervous System
Hoshino Y
(2023)
Synchondrosis fusion contributes to the progression of postnatal craniofacial dysmorphology in syndromic craniosynostosis.
in Journal of anatomy
Liang C
(2023)
Normal human craniofacial growth and development from 0 to 4 years.
in Scientific reports
Buzi C
(2023)
Icex: Advances in the automatic extraction and volume calculation of cranial cavities.
in Journal of anatomy
Didziokas M
(2024)
Multiscale mechanical characterisation of the craniofacial system under external forces.
in Biomechanics and modeling in mechanobiology