Abstract
Children with syndromic forms of craniosynostosis undergo a plethora of surgical interventions to resolve the clinical features caused by the premature fusion of cranial sutures. While surgical correction is reliable, the need for repeated rounds of invasive treatment puts a heavy burden on the child and their family. This study explores a non-surgical alternative using mechanical loading of the cranial bones to prevent or delay craniosynostosis and its effects.
We treated Crouzon syndrome mice before the onset of craniosynostosis by mechanical loading of cranial bones.
Cranial loading applied to the frontal bone caused partial normalisation of skull shape, reducing the typical brachycephalic appearance. This is underpinned by the delayed closure of the coronal suture and of the intersphenoidal synchondrosis.
This study provides a novel treatment alternative for syndromic craniosynostosis which has the potential to be an important step towards replacing, reducing or refining the surgical treatment of craniosynostosis patients.
Highlights
Mechanical loading of calvarial bone suspends craniosynostosis.
Loading effects on cranial base reduce midfacial hypoplasia.
1. Introduction
Some of the most common birth defects affect the craniofacial development of a new-born baby. Therefore, the care of children with craniofacial birth defects is an important clinical activity. Diagnosis and treatment of the disorders typically involves a child being seen by a number of specialists in areas including clinical genetics, radiology, dentistry, maxillo-facial and neurosurgery, and anaesthesia. Craniosynostosis is a common birth defect with an estimated prevalence between 1 in 2,1001 and 1 in 4,200 incidence2. It is caused by the premature fusion of the bones that form the skull, which can have serious, possibly life-threatening results3,4. Traditional approaches to the treatment of this type of craniofacial birth defect employ complex surgical remodelling of the skull including facial deformities, aimed at protecting brain development, visual function and the restoration of a more normal craniofacial appearance. While the surgical correction of the craniofacial deformity and its secondary defects is reliable in many cases, syndromic forms of craniosynostosis are often more severe and there is a heavy burden of care and ongoing surgical intervention from birth to maturity.
The most severe forms of craniosynostosis that require the most intensive treatments are often syndromic and single-gene disorders5. While the underlying pathogenesis of syndromic cases of craniosynostosis is complex and can involve a plethora of developmental signalling pathways, the majority of cases are caused by mutations in genes directly or indirectly involved in the FGF signalling pathway6. In addition, abberant FGF signalling plays an important role in many other developmental skeletal defects, affecting endochondral as well as intramembranous ossification7. Besides abnormalities in cellular physiology, studies showing an association between intrauterine constraint and increased incidence of craniosynostosis indicate a role for external mechanical forces on the formation and/or homeostasis of cranial sutures8.
Surgical treatment of syndromic craniosynostosis can be clinically challenging because in many cases multiple sutures are affected. Also, the genetic and phenotypic variability between patients, even those within the same syndrome classification is often significant enough to require individualised treatment protocols9,10. In addition, these patients require an increased number of craniofacial procedures5. The number of post-surgical complications is higher in syndromic cases, with increased rates seen in secondary synostosis11. There is also a high number of complication associated with frontonasal distraction procedures12.
Despite the rapid evolution of human genetics, gene therapy and stem cell therapy during the last few decades, very few studies have been able to find suitable alternatives to surgery. While our understanding of the pathogenesis of syndromic craniosynostosis has increased significantly -mainly through the use of genetically manipulated mouse models-this has not resulted in any clinically applicable non-surgical treatment alternatives13. To date, some of the most promising studies have tried to identify a biological solution to the treatment or prevention of craniosynostosis using gene therapy or drug development. Using transgenically modified mouse strains, attempts have been made to use either RNA interference against a mutation causing Apert syndrome, knockout of PIN1 in an Apert model or overexpression of the FGFR2c isoform to target a mutation causing Crouzon syndrome14-16. All successfully improved the synostosis phenotype in vivo, but to date have not been translated into clinical application. Pharmacologically, a host of studies have tried to identify drug targets that can possibly delay or prevent craniosynostsis in a mouse model. A drug screen of 640 FDA approved drugs identified 14 small molecule inhibitors that affect normal craniofacial development in zebrafish and went on to show that one of these prevented craniosynostosis in a mouse model for Crouzon syndrome17. Another study was able to use viral delivery of tissue nonspecific alkaline phosphatase (TNAP) to partially rescue the craniosynostosis phenotype in a Crouzon mouse model18. Finally, the recent study by Yu et al. is the only example so far of in vivo suture regeneration using stem cells that has the potential for clinical application19.
Mechanotransduction is the process whereby cells convert mechanical stimulus into a molecular and cellular response. While there is a large body of literature on mechanical loading of endochondral bone20, only recently studies have started to explore how intramembranous, craniofacial bones and sutures respond to mechanical forces. These studies have shown that craniofacial sutures respond to cyclical, mechanical loading using both in vitro and in vivo models. Resected calvaria of wild-type rat skulls were loaded on the posterior intrafrontal suture under tension in an ex vivo model. It was reported that loaded sutures remained patent while in the control group the suture fused normally21. In vivo cyclical loading applied to the skull (i.e. maxilla) has been shown to increase the width of the premaxillomaxillary suture by approximately 30% compared to controls in rat22 and similar results have been obtained in rabbit23. Normal craniofacial sutures in a pig model have also been shown to respond to tension forces by proliferation and differentiation of suture cells, while compression forces lead to increased osteogenesis24. Therefore, the aforementioned studies suggest that cyclical, mechanical loading can keep cranial sutures patent during postnatal development and delay their natural closure.
Many mouse models have been developed that feature the craniosynostosis phenotype13. For this study we used an established model of Crouzon syndrome. Crouzon mice carry a mutation (p.C342Y) in the FGFR2 receptor, are viable and fertile and are characterised by brachycephaly caused by coronal craniosynostosis as well as midfacial hypoplasia associated with malocclusion25. Our laboratory has been studying this mouse model since 2010 and have built up considerable knowledge of the cellular and molecular events underlying the pathogenesis of the phenotypic features this animal model exhibits, including impaired mesenchymal condensation of skeletal elements due to misregulation of SOX926. A study from Hatch et al. showed that genetic background effects phenotypic severity with a more pronounced craniofacial phenotype in C57BL/6 mice compared to BALB/c27. Our mice have been backcrossed onto the CD-1 strain, which mimicks human Crouzon syndrome and on our hands displays synostosis of the coronal suture at three weeks of age (P21). We have also previously shown differences in biomechanical properties of individual calvarial bones (i.e. frontal bone vs parietal bone) in Crouzon syndrome calvarial bones and sutures28. These observations point to a fundamental difference between the architecture of normal craniofacial bone and suture tissue affected by FGFR2 mutation. These observations are supported by studies showing that the neural crest derived frontal bone is more susceptive to FGFR2 perturbation than the mesoderm derived parietal bone15,29.
This study aims to investigate the possibility that external mechanical force applied to cranial bone can delay or prevent closure of abnormal sutures prone to craniosynostosis. Previous research has shown that mechanical loading of cranial bone in can delay the normal closure of cranial sutures during postnatal development. Our hypothesis is that in vivo mechanical loading of calvarial bone can significantly delay premature, pathogenic suture closure in a mouse model for craniosynostosis.
2. Results
In vivo mechanical loading of cranial bone in a Crouzon syndrome mouse model
To test our hypothesis that mechanical loading of the skull can prevent pathogenic suture closure, we performed in vivo loading of cranial bones on pre-weaning Crouzon mice. We developed a bespoke system using a linear actuator and force sensor enabling us to carry out controlled and repeatable loading of the cranial bones (Figure 1a). The actuator moved a force sensor in the dorso-ventral direction while a probe was fixed to it, in effect loading the skull via the probe. The loading tip of the probe that came into contact with the skull had a flat circular surface with a diameter of 1mm. Based on previous work on rabbit and rat models 22,23, we decided to apply a force of 10 gram at 1Hz for all our cranial bone loading protocols. To facilitate accurate, positional loading on cranial bones of pre-weaning mice, we used general aneasthesia by Isoflurane inhalation to fix animals in position using a custom-made, 3D printed tube underneath the actuator probe for the duration of the loading procedure (Figures 1B and 1C). We loaded all animals on the left side of the cranium to allow us to compare with the right side as an unloaded control (Figure 1D). Because of the overlapping nature of the coronal suture (Figure 1E) we decided to perform loading experiments on the frontal and parietal bone seperately. This way, we were able to compare the application of tension force on the suture when loading on the frontal bone and compression force on the suture when loading on the parietal bone (Figure 1F). We used an Fgfr2-C342Y transgenic mouse line that is kept on a CD-1 background, that in our hands displays patent sutures at birth, followed by the onset of craniosynostosis which is usually complete by P21. To maximise the potential impact of our cranial bone loading treatment, we loaded animals for 10 days between P7-18. Skulls were subsequently dissected and analysed at P21 (Figure 1G). Supplementary Videos 1a and 1b show examples of the cranial bone loading procedure at P7 and P14 respectively. In all experiments, mice recovered quickly after daily cycles of aneasthesia and cranial bone loading and at P21, after 10 rounds of treatment, animals appeared healthy (Supplementary Video 2a and b).
Changes in Crouzon skull morphology after cranial bone loading
We applied cyclical, mechanical loading to the frontal bone of wild-type (WT; n=15) and FGFR2-C342Y (MUT; n=7) mice and to the parietal bone of WT (n=9) and MUT (n=8) mice for 10 days between P7 and P18. On the last day of loading, mice were injected with Alizarin complexone and on P21 mice were culled and skulls dissected. Skulls were then microCT scanned for further morphological characterisation. In all our subsequent analyses, we compared treated mice with untreated control mice, WT (n=12) and MUT (n=16), at P21. In the untreated group (Figure 2A), we could clearly see the typical phenotypic appearance of the Crouzon mouse demonstrated by a domed, brachycephalic skull vault and a shortened maxilla which in the most severe cases resulted in malocclusion of the incisors. Superfical analysis of the surface of the skull vault showed complete synostosis of the coronal suture. Analysis of the mutants loaded on the frontal bone showed a distinctive shift to a more normal skull appearance, with reduced doming of the skull and elongated maxillary area (Figure 2B). Strikingly, the coronal suture was still absent in most cases at P21. Mice loaded on the parietal bone showed no improvement of Crouzon-realted appearance (Figure 2C). No apparent effect was noted on WT loaded skulls. To quantify these gross morphological observations, we performed detailed analysis of skull morphologies (i.e. length, width and height) using the microCT images (Figures 2D-E). Untreated mutant animals showed a significant difference in the skull width (Δ4.1%, p=1.3E-07), length (Δ12.2%, p=9.2E-11), height (Δ13.4%, p=2.1E-12) when compared to the untreated WTs, represented by the phenotypic effects of midfacial hypoplasia and brachycephaly. Comparing the skull morphologies of the treated and untreated mutant mice, showed distinct differences suggesting phenotypic rescue, but only in the group treated on the frontal bone. Again, no difference was noted between treated and untreated WT skulls. The dimensions of the untreated mutant skull were used as control in all subsequent comparisons to compare the effect of the treatment. Mice treated on the frontal bone showed a statistically significant reduction of the maxillary shortening compared to untreated mutants (skull length: Δ5.9% vs Δ12.2%, p=2.9E-04). Brachycephalic appearance measured by the skull height was reduced in frontal loaded skulls (Δ10.7% vs Δ13.4%, p=0.14), but not statistically significant. Unexpectedly, skull width was significantly different in both the frontal and parietal loaded skulls (Δ7.5% vs Δ4.1%, p=4.7E-04 and Δ7.8% vs Δ4.1%, p=2.9E-04 respectively). Overall, the mutant mice loaded on the frontal bone displayed a normalised skull morphology, representing partial phenotypic rescue. In contrast, mice loaded on the parietal bone did not.
Changes in coronal suture morphology and histology following cranial bone loading
In an attempt to explain the gross phenotypic effects on skull size and shape after cranial bone loading, we analysed coronal suture morphology in more detail. Using a fluorescent Alizarin Red dye, injected in animals at the end of the loading protocol, we were able to image the calvarial bones and sutures post-treatment at P21. Untreated WT skulls showed the charatcteristic overlapping feature of the coronal suture (Figure 3A), while untreated mutants showed loss of suture patency as well as increased bone denisty around the location of the suture (Figure 3B). Skulls loaded on the frontal bone showed calvaria with patent sutures in most cases, but still with an abnormal suture morphology, including increased bone density at the edges. Parietal loaded skulls showed no difference from untreated controls. When analysing the patency of the coronal suture in this way we observed that some skulls exhibit an asymmetrical partial rescue of coronal synostosis on the treated (left) side. Other skulls show a wider effect where both sutures remained patent at P21. When using an unbiased (i.e. randomised and blinded) suture patency scoring system, loaded sutures were more likely to be patent or only partially fused then controls. This effect was larger on the treated side (X2=9.61, p=0.0019) than on the untreated side (X2=4.23, p=0.0397). Histological data confirmed the morphological observations. Untreated WT sutures displayed the typical overlapping structure, with the parietal bone on top of the frontal bone and the sutural mesenchyme in between (Figure 3F). Untreated mutant sutures had lost the normal, patent structure and instead showed scattered areas of mesenchyme surrounded by a larger amount of bone (Figure 3G). Sutures loaded under tension (frontal bone) had increased patency, but also showed increased bone mass (Figure 3H). The number of mesenchymal cells appeared to had decreased. Sutures loaded under compression (parietal bone) showed no difference compared to the untreated controls (Figure 3I). Using the same histological preparations we analysed the brain tissue underneath the location of loading to exclude any secondary effects on the underlying cortex. In none of the samples analysed, we observed any signs of abnormal cortical lamination (Supplementary Figure 1). Therefore, we can conclude that cranial loading on the frontal bone, inducing tension on the suture, causes partial rescue in the majority of cases and total rescue in a minority of cases without any damage to the underlying brain.
Changes in skull base morphology and histology following cranial bone loading
Analysis of the gross skull morphology showed that mutant mice loaded on the frontal bone display a reduced maxillary shortening (Figure 2E). While the delayed synostosis of the coronal suture may contribute to this, we explored whether the cranial base plays a role. Using the micro-CT data, we constructed 2D images of the midline through the cranial base to assess the morphology. At P21, both the sphenoidal-occipital synchondrosis (SOS) and the intersphenoidal synchondrosis (ISS) were open in WT mice, but in the untreated mutants, the ISS is partially or fully closed (Figure 4B). This contributes to the maxillary reduction and the resulting midfacial hypoplasia seen in Crouzon mice. The majority of mutant mice loaded on the frontal bone had a partially open ISS, sometimes with a bony bridge located on the caudal side of the cranial base (Figure 4C). Parietal bone loaded mutants showed no difference to untreated controls (Figure 4D). An unbiased (i.e. randomised and blinded) synchondrosis patency scoring system showed that the increased patency of the ISS in the mutant mice treated on the frontal bone was statistically significant (p<0.05; Figure 4E). Histological analysis confirmed that the ISS was abnormal in the mutant mice compared to WT while the SOS was normal in both (Figure 4G+H). The mutant ISS cartilage appears ectopic to the cranial base with a reduced number of chondrocytes and is cone-shaped rather than rectangular. Frontal loaded mutant mice show normal ISS cartilage comparable to the untreated WT mice (Figure 4I), but parietal loaded mice showed no difference to untreated controls (Figure 4J). This data supports an interpretation that cranial loading has an effect on the cranial base, which in turn, contributes to the normalised skull shape, in particular skull length.
Comparing the pattern of mechanical strain distribution across the skull between frontal and parietal loading
To understand the pattern of mechanical strain distribution across the skull due to the loading at the frontal and parietal, we used a previously validated finite element (FE) model30,31. The FE model was developed based on a P3 WT mouse skull and was used to model calvarial growth. We use this model to predict the shape and pattern of tissue differentiation at P7 and loaded the model at P7 analagous to our in vivo experiments (Figure 5A). The pattern of first princial strain highlights that frontal loading induced a lower level of strain across the coronal suture (see highlighted dash boxes in Figure 5B&C) compared to parietal loading. It also shows that the load applied to the skull roof induced a mechanical strain on the skull base. Interestingly, the level of induced strain across the intersphenoidal synchondrosis (ISS) was lower in the frontal loading compare to the parietal loading group (see highlighted dash boxes in Figure 5D&E).
3. Discussion
This study has shown that the application of external mechanical loading on the skull of a syndromic craniosynostosis mouse model can prevent the complete closure of the coronal suture and of the anterior synchondrosis, which in turn reduces the damaging effects on skull shape and size, partially restoring normal skull appearance.
Accurate loading of the individual calvarial bones was achieved using a novel set up that was developed enabling us to apply force up to a predetermined maximum of 0.1 N. No adverse effects were observed in any of our loading procedures (total of 670) so we conclude this to be a safe approach for cranial loading in mouse. While the mice were subjected to general anaesthesia, this was mainly to avoid any movement during the procedure and we don’t foresee this to be necessary when applied to patients. Further work will focus on the optimisation of the force/frequency needed to achieve the desired effect and on answering the question whether an initial loading treatment is sufficient to prevent complete synostosis or if loading needs to be applied long term to avoid the process of synostosis recommencing.
Overall we identified a significant effect on the size and shape of Crouzon skulls after frontal loading only. This can be explained by the characteristic feature of the coronal suture, where the parietal bone partially overlaps the frontal bone. Loading the frontal bone will load the soft sutural tissue under tension, that is likely to cause a certain level of shear stress. Cellular tension has been shown to activate the ROCK/TAZ pathway in vitro32, but further in vivo analysis of the mechanotransduction effects on the sutural mesenchyme can potentially unravel the precise mechanism. While we anticipated the effect to be more pronounced on the loaded side (L) compared to the unloaded side (R), analysis showed only a small number of samples that presented with an asymmetric presentation of coronal synostosis rescue. A likely explanantion for this is that the mechanical strain that has been induced as a result of the unilateral loading transfers onto the unloaded coronal suture on the opposite side. The finite element data confirm that a low level of strain was indeed induced on the unloaded coronal suture albeit higher in the parietal loaded group compare to the frontal loaded group. At the same time, our observation that cranial loading prevents complete fusion of the synchondrosis supports the theory that loading the calvarial can impact the skull base through the 3D structural framework of the cranium.
In our hands, the Crouzon Fgfr2-C342Y mouse model on a CD-1 background shows near complete fusion of the coronal suture at P21, the end point of our experiments15,26. Compared to unloaded controls, frontal loaded sutures showed a mixed histological picture with increased patency on the one hand and reduction of the sutural mesenchyme on the other hand. Disappearance of the sutural mesenchyme by premature differentiation into osteoblast and bone is typical of the pathological synostosis process caused by FGFR2 mutation33 and allows the fusion of the flanking bones. In this case however, daily application of mechanical tension prevents the fusion, while it seems unable to prevent the premature differentiation of the mesenchyme. As a result, the coronal suture retains it’s patency allowing the skull to grow normally without the compensatory growth associated with coronal synostosis34.
An additional, unexpected discovery was that apart from partially rescueing the coronal suture synostosis phenotype, we were also able to partially rescue the premature closure of the anterior synchondrosis (i.e. intersphenoidal synchondrosis (ISS)) in the skull base of the Crouzon mouse. Prevention of premature fusion of the ISS in this mouse model for syndromic craniosynostosis is likely to contribute to the normalisation of skull length that was observed in this study. Anatomically, the mouse ISS is similar to that in human and natural fusion of the human ISS occurs between 2-4 years of age35. There is no CT data available for the premature fusion of the ISS in human Crouzon syndrome patients, but in the Crouzon mouse model the ISS is fused prematurely at P21 as shown by by Liu et al.29 and this study. A significant delay in the premature fusion was identified in the frontal loaded Crouzon mice, which suggests that cranial loading transfers its effect indirectly to the synchondroses in the skull base. This was also corroborated by our finite element results that showed that calvarial loading induced mechanical strain on the skull base and ISS. Histologically, the mutant ISS displays as a cone shape cartilage, protruding rostrally from the sphenoidal flanking bones with a bony bridge forming caudally. We speculate that applying mechanical tension on the anterior side of the ISS (i.e. the presphenoidal bone) causes shear stress on the caudal side preventing the formation of the bony bridge and the subsequent protrusion of the cartilaginous synchondrosis. Alternatively, a mechanotransductional effect on the developing chondrocytes in the synchondrosis is possible, as it is known that the formation and fusion of the ISS is regulated by the Indian and Sonic Hedgehog pathways36. Clinically, skull base abnormalities are difficult to resolve surgically because of the anatomical position of the target tissue. External application of a corrective mechanical force may provide be a possible way to address this clinical challenge.
It is clear that the proposed approach in this study can be further optimised and need to undergo a feasibility study in a larger animal model in prepration for clinical translation if its efficacy is proven. At present it is seems that such an approach can only be deployed on patients that present with sutures that are not fully fused i.e. have not completed the synostosis process. The number of craniosynostosis patients that present with partially patent sutures is estimated to be 5-10% at Great Ormond Street Hospital (D Dunaway 2021, personal communiation). Another potential application of the cranial loading can be to prevent the healing of surgically seperated calvarial bones post-operatively (aka resynostosis). This is an important clinical problem causing significant morbidity leading to the need for repeated reoperations. Attempts to prevent reoperation have been made using glypican-3 containing nanotubes to inhibit cranial bone regeneration in a Crouzon mouse model and by regenerating a functional suture using Gli+ mesenchymal stem cells in a Twist1 mouse model of craniosynostosis19,37. While these potential treatments have not been applied to patients yet, they will be invasive procedures involving the introduction of pharmacological or cellular agents with potential unwanted side effects. It may be possible to achieve a similar effect using cranial loading on patients post-surgery. In summary, in vivo calvarial loading using pre-weaning Crouzon mice shows a distinct phenotypic effect indicted by a normalised skull morphology and improved patency of the coronal suture and anterior synchondrosis. Further studies into the use of mechanotransduction to delay or prevent pathogenic suture closure have the potential to be a first important step towards the development of a non-invasive, non-surgical treatment alternative for children with progressive craniosynostosis.
4. Materials and methods
4.1. Animals
Crouzon mouse model (Fgfr2tm4Lni; aka Fgfr2cC342Y; MGI:3053095)
Fgfr2cC342Y were re-derived through the European Mouse Mutant Archive (EMMA) at MRC Harwell as previously described26. All animal procedures were performed in accordance with the UK Animals (Scientific Procedures) Act 1986 (Project License number: 70/8817) and maintained by UCL Biological Services.
4.2. Mechanical loading
An experimental loading set up was developed to precisely load the cranial bones of mice in vivo. Here an actuator (T-LSR series, Zaber Technologies: res. 50 µm, max. load 200 N) and a force sensor (GSO Series, Transducer Techniques: res. 0.01 N with 1N capacity) were configured to a custom developed LabVIEW program. This portable set up enabled us to carry out precise cyclic loading of mouse skulls.
4.3. Phenotypic analysis
Animals were weighed using a fine balance. An electronic caliper (Fisher) was used to measure the crown-rump length and head length of the animal.
4.4. Micro-CT analysis
4.4.1. Micro-CT scanning
At the end of experiment, animals were killed by a schedule 1 method or a non-schedule 1 method (asphyxiated using rising concentrations of CO2). Then animals were fixed and stained with Alizarin Red to better visualise the calvarial bones and sutures. They were then micro CT scanned (X-Tek HMX 160, XTek Systems Ltd, Tring, Herts., UK).
4.4.2. Image processing
CT images were imported into an image processing software (Avizo Lite, FEI V9.2., Thermo Fisher Scientific, Mass, USA). The quality of micro-CT images, voxel sizes, were between 14-20μm. Here the bone was segmented. Before segmentation micro-CT images were aligned in a similar position in different planes. Following the alignment of the raw CT images, 3D surface volumes were reconstructed and a range of parameters were measured.
4.4.3. Quantitative analysis
In the lateral view, the differences in the length, height and the overall morphology of the calvarial were observed between the groups. The dorsal view, highlights the suture fusion across the calvaria across the groups. The skull length was measured in the sagittal plane between the most anterior-medial point of the nasal bone and the most posterior-medial point of the occipital bone. Skull width was then measured in the transverse plane between the most posterior-inferior point on the interparietal. Skull height was measured in the sagittal plane between the presphenoid and the most superior part of the skull, covering bulging area in the mutant types. In addition to the aforementioned measurements a number of other features of the skulls were measured. Landmarks were placed on the cranium on the boundaries between the bones of different regions of skull. This was to measure the dimensions of these bones individually in more details.
4.4.4. Patency scoring of synchondroses
Sagittal sections through the midline of whole skull micro-CT images were presented to at least three observers blinded for treated and untreated groups. SOS and SIS synchondroses were scored as open, partially closed (<50% of the cranial base height is filled with bone) or closed (<50% of the cranial base height is filled with bone). Scores were averaged and plotted against expected frequencies in untreated groups.
4.5. Fluorescent Alizarin Red staining
Mice were injected intraperitoneally with 5ul/gram body weight of a 5mg/ml Alizarin complexone (VWR 20118.081) made up in 2% NaHCO3 in PBS. Calvaria were dissected 24 hours after injection and imaged using a Zeiss upright fluorescent microscope with a 550nm filter.
4.6. Histological analysis
For paraffin embedding, mouse heads were skinned and fixed in 10% Formalin overnight before graded dehydration in ethanol. Embryos were cleared in analytical grade xylene (Fisher) before paraffin wax displacement in a 60°C oven. The samples were embedded and sectioned between 8-10um on the sagittal plane using a microtome (Leica). Sections were stained with Haematoxylin and Eosin.
4.7. Statistical analysis
SPSS Statistics 22 (IBM) software was used as the primary statistical package for data analysis. First, the data was tested for normality using Shapiro-Wilk test to determine the use of parametric or non-parametric tests. Independent samples T-test with Welch’s correction was used to compare the difference of averages between groups for quantification. Chi2-test was used for statistical analysis of the synchodrosis patency score. One-way ANOVA with Tukey posthoc or non-parametric Kruskal Wallis with Dunn-Bonferroni posthoc test was adopted for analysis of three or more groups. A p-value of <0.05 was considered significant.
4.8. Finite element analysis
A previously validated finite element model of mouse skull growth was used here30,31. In brief, we reconstructed micro-CT images of a P3 WT mouse (Avizo FEI Visualization Sciences Group, Merignac Cedex, France) consisted of bone, sutures, and intracranial volume (ICV) that broadly represented the brain. The whole model was then transformed into a 3D solid meshed model and imported to a finite element solver, ANSYS v.18 (ANSYS Inc., Canonsburg, PA, USA). Isotropic (linear and elastic) material properties were assigned to all sections with a thermal coefficient defined only for the ICV. Bone and suture were assumed to have an elastic modulus of 3500 MPa and 30 MPa respectively at age P328,38. The elastic modulus of the ICV was assumed to be 10 MPa. The bone and suture materials were assumed to have a Poisson’s ratio of 0.3. The ICV value was 0.48. The bone-suture interfaces and bone-suture-intracranial volume interfaces were assumed to be perfectly connected. Three nodes on the presphenoid bone were constrained in all degrees of freedom. The presphenoid bone was constrained based on our previous examination of the growth of the WT mouse skull that revealed that this bone grows centrically during development and can be considered to effectively remain at the same position during the skull development30. The P3 model was then virtually grown to P7 (as described in Marghoub et al.31) and at P7 was loaded at the fronal and parietal analogoun to our in vivo experiment. The pattern of first principal strain across the skull were then compared between the two groups.
Competing interests
The authors have no competing or financial interests to declare.
Author contributions
M.M., E.P. and A.A. conceived and designed the project; M.H., D.S., M.M., A.M., D.J. and E.P. acquired, analysed and interpreted data; E.P. and M.M. wrote the paper; all authors commented on and contributed to the paper.
Supplementary Video 1a Video footage (25s) of cranial bone loading treatment protocol. This video shows a P7 WT mouse being loaded on the frontal bone.
Supplementary Video 1b Video footage (25s) of cranial bone loading treatment protocol. This video shows a P14 WT mouse being loaded on the frontal bone.
Supplementary Video 2a Video footage (52s) showing behaviour of three WT P21 litter mates (L19, L20 and L21) after completing the two-week cranial bone loading treatment protocol.
Supplementary Video 2b Video footage showing behaviour of three MUT P21 litter mates (L18, L25 and L26) after completing the two-week cranial boneloading treatment protocol.
Acknowledgements
The Fgfr2cC342Y mouse colony was derived from the EMMA Consortium. This work was supported by Newlife, the charity for disabled children (award 17-18/18), the Royal Academy of Engineering (10216/119); and the Engineering and Physical Science Research Council (EP/R513143/1-176497) and University College London. EP is a GOSHCC Principal Investigator. This research was supported by the NIHR Great Ormond Street Hospital Biomedical Research Centre. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR or the Department of Health. We are grateful to Michael Fagan for micro-CT scanning support and to Susan Herring for advice and support throughout this study.
Footnotes
Minor edits only.