Biomechanical behavior of an alveolar graft under maxillary therapies.

Cleft lip and palate is a congenital defect that affects the oral cavity. Depending on its severity, alveolar graft surgery and maxillary orthopedic therapies must be carried out as a part of the treatment. It is widely accepted that the therapies should be performed before grafting. Nevertheless, some authors have suggested that mechanical stimuli such as those from the maxillary therapies could improve the success rate of the graft. The aim of this study is to computationally determine the effect of maxillary therapies loads on the biomechanical response of an alveolar graft with different degrees of ossification. We also explore how the transverse width of the cleft affects the graft behavior and compare results with a non-cleft skull. Results suggest that stresses increase within the graft as it ossifies and are greater if maxillary expansion therapy is applied. This has consequences in the bone remodeling processes that are necessary for the graft osseointegration. Maxillary orthopedic therapies after graft surgery could be considered as a part of the treatment since they seem to act as a positive extra stimulus that can benefit the graft.

Parametric analysis of the influence of texture on human dental surface hardness.

Tooth wear is one of the dental abnormalities commonly found in different populations. The objective of this work is to conduct a parametric analysis to evaluate the texture influence on the human dental surface hardness, considered here as the ratio between contact force and contact area, obtained through homogenization procedure. A code was implemented using the statistical package R for parametric analysis. The computational approach consists of three routines: numerical generation of surfaces, based on Pearson system; the second, a script coupled to the Finite Element program Abaqus, for the modelling of the micro-contacts; the third for homogenization and statistical analysis of results. The average curvature of the roughness exerts the greatest influence on the surface hardness. The parameters that most influence the development of contact forces are kurtosis followed by skewness.

Influence of interdigitation and expander type in the mechanical response of the midpalatal suture during maxillary expansion.

BACKGROUND AND OBJECTIVE: The orthopedic Maxillary Expansion (ME) procedure is used for treating the transverse maxillary deficiency. This pathology consists in a smaller transverse dimension in the maxilla and leads to malocclusion. The treatment takes advantage of the existence of the midpalatal suture (MPS), which corresponds to the junction at the palatine bones of its horizontal portions. The technique employs a device, conventionally a palatal expander attached to the posterior teeth, to separate the two maxillary bones in the MPS. The objective of this study was to analyze, using the Finite Element Method, the biomechanical behavior of the MPS when an expansion is applied. METHODS: A Computer Tomography image of the maxilla was reconstructed, the suture geometry was modeled with different interdigitation levels and types of hyrax devices. A total of 12 geometric models (three levels for interdigitation and four types of hyrax devices) were prepared and analyzed taking into account the chewing forces and the expansion displacement. For each case, maximum principal stresses on the maxilla (bone), and equivalent stresses on the expander device (stainless steel) were observed. In the MPS, maximum principal stresses and directional displacement were evaluated. RESULTS: The results showed that the interdigitation does not have an important influence on the deformation behavior of the maxilla but it affects the stress distribution. In addition, the type of expander device and anchorage have a direct relationship with the treatment effectiveness; larger deformation in the expansion direction was obtained with skeletal when compared to dental anchorage. CONCLUSIONS: A study that allows a better understanding of the oral biomechanics during the application of ME was presented. To our knowledge, it is the first study based on computational simulations that takes into account bone structures, like maxilla and part of the skull, to analyze the interdigitation influence on the MPS behavior when exposed to a ME.

Numerical analysis of the biomechanical behaviour of a weakened root after adhesive reconstruction and post-core rehabilitation.

OBJECTIVES: The purpose of this study was to perform a finite element analysis to determine whether adhesive reconstruction is able to restore the original biomechanical behaviour of weakened roots, in terms of fracture resistance, when compared with post/crown-restored teeth with intact roots. METHODS: A three-dimensional model of a maxillary central incisor was created. The model simulated an endodontically treated tooth restored with a glass-fibre post, a composite-resin core and a metal crown (Model 1). Based on Model 1, a new volume was created in the root cervical third that represented the area where the dentine structure was lost, resulting in a structurally damaged root (Model 2). A 100N load was applied to the palatal surface at 130° from the long axis of the tooth. After processing (Ansys(®) 10.0 - Canonsburg, PA, USA), the principal normal stress data were analyzed (S1, tensile; S3, compressive). RESULTS: The models demonstrated a similar S1 distribution concentrated in the lingual cervical region but different S1 levels (Model 1: 28.7MPa; Model 2: 35.3MPa). The S3 distribution indicated differences in behaviour between the models (Model 1: -18 to -27MPa along the buccal root surface; Model 2: -25 to -32MPa on the post buccal surface and along the buccal root wall). CONCLUSIONS: Although the stress distribution within the root walls remained below the ultimate stress limit of the root dentine, the adhesive reconstruction of the weakened roots did not recover the load resistance of structurally intact roots. CLINICAL SIGNIFICANCE: The decision of when to prosthetically rehabilitate weakened roots with cervical dentine structural tissue loss is a challenge for clinicians. A 'monoblock' adhesive reconstruction has been proposed for root reinforcement. During treatment planning, the possibility of restoring the mechanical resistance of the root must be evaluated if successful long-term results are to be achieved.

Análise biomecânica ex vivo de um modelo de haste intramedular de polipropileno para osteossíntese em úmeros de bezerros / Ex vivo biomechanics assay of a model of polypropylene intramedullary nail for calf humeral osteosynthesis

Foram utilizados 12 pares de úmeros obtidos de bezerros machos da raça Holandesa, com idades entre 15 e 30 dias. Os úmeros esquerdos foram mantidos íntegros, e os direitos foram fraturados de forma oblíqua em sua diáfise, na transição entre os terços médio e proximal. A redução da fratura foi feita pela aplicação intramedular de haste de polipropileno, bloqueada por dois parafusos corticais de aço inoxidável, dispostos transversalmente em cada fragmento ósseo. Seis pares de ossos foram submetidos ao teste de compressão, e seis ao teste de flexão, utilizando-se uma máquina universal de ensaios. Nos testes de compressão, as cargas médias de ruptura foram 738,3N e 473,3N, e nos testes de flexão 322,4N e 117,9N, para os ossos íntegros e fraturados, respectivamente. Comparando-se o grupo de ossos fraturados com o grupo de ossos íntegros, verificou-se que o sistema proposto foi capaz de resistir a 66,4 por cento das cargas médias quando submetido à compressão, e a 36,6 por cento quando submetido à flexão. Úmeros fraturados e tratados com haste intramedular de polipropileno apresentaram resistência limitada se comparados aos ossos íntegros.

A total of 12 pairs of humeri from male calves 15 to 30 days old were used. The left humeri remained unchanged and the right ones were fractured in the diaphysis between proximal and middle thirds. The fracture was fixed with a polypropylene intramedullary nail interlocked with two steel bone screws crossed along each segment. Six pairs of bones were subjected to a compression test and the others to a flexural test using a universal testing machine. In the compression tests, the mean rupture loads were 738,3N and 473,3N, and in the flexural tests they were 322,4N and 117,9N for the intact and fractured bones respectively. Fractured bones fixed with the proposed model were able to resist 66.4 percent of the load during compression and 36.6 percent during bending when in comparison to intact bones. Fractured humeri treated with polypropylene intramedullary nail showed limited resistance compared to intact ones.

Bone remodelling analysis of a bovine femur for a veterinary implant design.

The response of bovine bone to the presence of an implant is analysed with the aim of simulating bone remodelling in a developing model of a polymeric intramedullary interlocking nail for veterinary use. A 3-D finite element model of the femur diaphysis is built based on computed tomography images and using a CAD-based modelling pipeline. The bone remodelling process after the surgery is analysed and compared with the healthy bone. The remodelling law assumes that bone adapts to the mechanical environment. For the analyses a consistent set of loads is determined for the bovine walk cycle. The remodelling results reproduce the morphologic features of bone and provide evidence of the difference on the bone behaviour when comparing metallic and polymeric nails. Our findings indicate that an intramedullary polymeric nail has the advantage over the metallic one of improving long-term bone healing and possibly avoiding the need of the implant removal.