Brittle Bone Brothers: Osteogenesis Imperfecta Conventional Serial Case

Osteogenesis Imperfecta is a hereditary connective tissue disorder due to COL1A1/2 mutation causing gene defect encoding proteins to metabolize collagen. The skeletal manifestation of OI causing bone incompetence, hence the name brittle bone disease. Here we report three cases of OI type IV in adults. Skeletal conventional X-rays were performed to all patients and all of them has similar results such as bowing deformities of long bones, old union and some non-union fractures with extreme angulation and severe osteoporosis. OI are classified based on skeletal structure, sclera colorization, dentinogenesis, and functional metabolic defect genetically. OI type I and IV can live until adults; also, the same type of OI can be found in siblings. Skeletal conventional X-rays can solely make the diagnosis.

The oral health status and dental treatment needs of children affected by osteogenesis imperfecta – part I

Introduction. Osteogenesis imperfecta is an inherited disorder of the connective tissue. Which in most cases, is caused by mutations in the genes encoding collagen type I. Apart from clinical features, there are characteristic dental aberrations. Aim. The purpose of this research was the assessment of the condition of teeth and therapeutic needs of children with the congenital brittle bone disease. Material and methods. The questionnaires with patient’s parents, consisting medical history and dental history were performed. The intra-oral examination included the condition of the dentition, the presence of dentinogenesis imperfecta, malocclusion, the assessment of the attrition index and dmft/DMFT index. Results. 62 patients with osteogenesis imperfecta were examined – 32 boys and 30 girls. There were normal eruption times of deciduous (48 patients – 77.42%) and permanent teeth (34 patients – 82.93%) reported in the majority of the patients with OI. In most cases bad eating and hygienic habits were observed. Dentinogenesis imperfecta in deciduous and permanent teeth was reported mostly in type III of OI. dmft/DMFT index among children with OI were low in comparison to the population studies of corresponding age groups. Conclusions. Despite bad eating and hygienic habits as well as pathological structure of dentition of patients with the congenital brittle bone disease, caries index among these children were low in comparison to the population studies of corresponding age groups.

Osteogenesis and dentinogenesis imperfecta in a four-month-old English mastiff

Osteogenesis imperfecta, also known as ‘brittle bone disease’, is an inherited connective tissue disorder caused by defects in type 1 collagen. The disease results in low bone mass and reduced bone strength, often manifesting as multiple intrauterine fractures, skeletal abnormalities and death before adulthood. A four-month-old, female entire, English mastiff was presented for multiple limb fractures. Due to a poor prognosis, euthanasia was elected. Gross examination revealed diffuse osteopenia with multiple chronic and acute skeletal fractures. All adult teeth were undersized and opalescent, and multiple deciduous incisors were retained. Histopathology of the long bones demonstrated severe, diffuse osteopenia with retention of non-ossified cartilage spicules in the secondary spongiosa. The incisor teeth had multifocal disorganisation of odontoblasts and ameloblasts that exhibited piling (dysplasia) and hypoplasia of the dentin. Diagnoses of osteogenesis imperfecta and dentinogenesis imperfecta were made. Osteogenesis imperfecta should be considered as a cause of diffuse osteopenia in young dogs.

Osteogenesis Imperfecta and Extra-/Intradural Hematomas: A Case Report and Review of the Literature

Osteogenesis imperfecta, also named as brittle bone disease, is characterized by fragile bones and short stature caused by mutations in the collagen gene. Subdural and intraparenchymal hematomas are defined and associated with trauma, vascular causes, and systemic bleeding diathesis. Skull fragility may lead to epidural hematoma, which is a life-threatening situation. Vascular fragility and intrinsic platelet defects are the causes of bleeding in patients with osteogenesis imperfecta, which is a major management challenge for neurosurgeons. Here, we reported on a 5-year-old boy with osteogenesis imperfecta with epidural hematoma and skull fracture following a trivial trauma, and made a literature review of 28 cases with extra-/intradural hematoma.

MicroCT-based phenomics in the zebrafish skeleton reveals virtues of deep phenotyping in a distributed organ system

Phenomics, which ideally involves in-depth phenotyping at the whole-organism scale, may enhance our functional understanding of genetic variation. Here, we demonstrate methods to profile hundreds of phenotypic measures comprised of morphological and densitometric traits at a large number of sites within the axial skeleton of adult zebrafish. We show the potential for vertebral patterns to confer heightened sensitivity, with similar specificity, in discriminating mutant populations compared to analyzing individual vertebrae in isolation. We identify phenotypes associated with human brittle bone disease and thyroid stimulating hormone receptor hyperactivity. Finally, we develop allometric models and show their potential to aid in the discrimination of mutant phenotypes masked by alterations in growth. Our studies demonstrate virtues of deep phenotyping in a spatially distributed organ system. Analyzing phenotypic patterns may increase productivity in genetic screens, and facilitate the study of genetic variants associated with smaller effect sizes, such as those that underlie complex diseases.

microCT-Based Phenomics in the Zebrafish Skeleton Reveals Virtues of Deep Phenotyping in a Distributed Organ System

ABSTRACTPhenomics, which ideally involves in-depth phenotyping at the whole-organism scale, may enhance our functional understanding of genetic variation. Here, we demonstrate methods to profile hundreds of measures comprised of morphological and densitometric traits from a large number sites in the axial skeleton of adult zebrafish. We show the potential for vertebral patterns to confer heightened sensitivity, with similar specificity, in discriminating mutant populations compared to analyzing individual vertebrae in isolation. We identify phenotypes associated with human brittle bone disease and thyroid stimulating hormone receptor hyperactivity. Finally, we develop allometric models and show their potential to aid in the discrimination of mutant phenotypes masked by alterations in growth. Our studies demonstrate virtues of deep phenotyping in a spatially distributed organ. Analyzing phenotypic patterns may increase productivity in genetic screens, and could facilitate the study of genetic variants associated with smaller effect sizes, such as those that underlie complex diseases.