Stress-driven method bio-inspired by long bone structure for mechanical part mass reduction by removing geometry at macro and cell-unit scales

Cyclic GMP (cGMP) is an important intracellular regulator of endochondral bone growth and skeletal remodeling. Tadalafil, an inhibitor of the phosphodiesterase (PDE) type 5 (PDE5) that specifically hydrolyzes cGMP, is increasingly used to treat children with pulmonary arterial hypertension (PAH), but the effect of tadalafil on bone growth and strength has not been previously investigated. In this study, we first analyzed the expression of transcripts encoding PDEs in primary cultures of chondrocytes from newborn rat epiphyses. We detected robust expression of PDE5 as the major phosphodiesterase hydrolyzing cGMP. Time-course experiments showed that C-type natriuretic peptide increased intracellular levels of cGMP in primary chondrocytes with a peak at 2 min, and in the presence of tadalafil the peak level of intracellular cGMP was 37% greater ( P < 0.01) and the decline was significantly attenuated. Next, we treated 1-mo-old Sprague Dawley rats with vehicle or tadalafil for 3 wk. Although 10 mg·kg−1·day−1 tadalafil led to a significant 52% ( P < 0.01) increase in tissue levels of cGMP and a 9% reduction ( P < 0.01) in bodyweight gain, it did not alter long bone length, cortical or trabecular bone properties, and histological features. In conclusion, our results indicate that PDE5 is highly expressed in growth plate chondrocytes, and short-term tadalafil treatment of growing rats at doses comparable to those used in children with PAH has neither obvious beneficial effect on long bone growth nor any observable adverse effect on growth plate structure and trabecular and cortical bone structure.

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Palaeobiological inferences based on long bone epiphyseal and diaphyseal structure - the forelimb of xenarthrans (Mammalia)

10.1101/318121 ◽

2018 ◽

Cited By ~ 1

Author(s):

Eli Amson ◽

John A Nyakatura

Keyword(s):

Bone Structure ◽

Phylogenetic Signal ◽

Great Accuracy ◽

Long Bone ◽

Comparative Approach ◽

High Resolution Computed Tomography ◽

3D Architecture ◽

Bone Trabeculae ◽

Close Relatives ◽

Ground Sloths

ABSTRACTTrabecular architecture (i.e., the main orientation of the bone trabeculae, their number, mean thickness, spacing, etc.) has been shown experimentally to adapt with great accuracy and sensitivity to the loadings applied to the bone during life. However, the potential of trabecular parameters used as a proxy for the mechanical environment of an organism’s organ to help reconstruct the lifestyle of extinct taxa has only recently started to be exploited. Furthermore, these parameters are rarely combined to the long-used mid-diaphyseal parameters to inform such reconstructions. Here we investigate xenarthrans, for which functional and ecological reconstructions of extinct forms are particularly important in order to improve our macroevolutionary understanding of their main constitutive clades, i.e., the Tardigrada (sloths), Vermilingua (anteaters), and Cingulata (armadillos and extinct close relatives). The lifestyles of modern xenarthrans can be classified as fully terrestrial and highly fossorial (armadillos), arboreal (partly to fully) and hook-and-pull digging (anteaters), or suspensory (fully arboreal) and non-fossorial (sloths). The degree of arboreality and fossoriality of some extinct forms, “ground sloths” in particular, is highly debated. We used high-resolution computed tomography to compare the epiphyseal 3D architecture and mid-diaphyseal structure of the forelimb bones of extant and extinct xenarthrans. The comparative approach employed aims at inferring the most probable lifestyle of extinct taxa, using phylogenetically informed discriminant analyses. Several challenges preventing the attribution of one of the extant xenarthran lifestyles to the sampled extinct sloths were identified. Differing from that of the larger “ground sloths”, the bone structure of the small-sized Hapalops (Miocene of Argentina), however, was found as significantly more similar to that of extant sloths, even when accounting for the phylogenetic signal.

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Limitations in Use of Elastic Stable Intramedullary Nailing (ESIN) in Children with Disorders of Bone Mineralization

Ortopedia Traumatologia Rehabilitacja ◽

10.5604/01.3001.0014.1154 ◽

2020 ◽

Vol 22 (2) ◽

pp. 77-83

Author(s):

Artur Oberc ◽

Jerzy Sułko

Keyword(s):

Bone Structure ◽

Bone Fractures ◽

Bone Mineralization ◽

Cartilage Damage ◽

Long Bone ◽

Mechanical Resistance ◽

Long Bone Fractures ◽

Fractures In Children ◽

Satisfactory Outcome ◽

Pin Fixation

Background. Elastic intramedullary nails (ESIN) have been the treatment of choice in many long bone fractures in children for more than 20 years. The introduction of ESIN has drastically reduced tissue traumatization during fracture fixation procedures and decreased the risk of growth cartilage damage, as well as allowing for preservation of the natural biology of closed fracture healing. The objective of the present report is to draw attention to a small group of patients with bone mineralization disorders, who consequently demonstrate decreased mechanical resistance of the skeletal system, in whom indications for using ESIN fixation are limited. Material and methods. The study group consisted of 6 patients who met the criteria for using ESIN fixation, but did not demonstrate a satisfactory outcome. The inclusion criteria included age below 18 years, appropriate ESIN nail insertion technique with correct calculation of nail diameter (2/5 of the medullary canal diameter), body mass < 50 kg and achieving appropriate prebending that is the prerequisite of three-point intramedullary support. The patients’ medical records and radiographs were analyzed and they were invited for clinical and radiological follow-up examinations. Results. All six patients demonstrated a gradually increasing bending deformity of the long bone axis. Additionally, in three patients, there was intrusion of terminal parts of the nails into the bone. In one patient with bone fibrous dysplasia, the proximal epiphysis was perforated by the flattened ends of the nails. In all patients, the removal of the ESIN fixation was followed by single or double-level corrective osteotomies and Rush pin fixation. Conclusion. In cases of long bone fractures in children with metabolic bone disorders in whom the bone structure is weakened and the bones themselves are easily deformed, more rigid intramedullary fixation with Rush or Fassier-Duval type nails as primary osteosynthesis should be considered.

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Accelerated Bone Growth Remotely Induced by Magnetic Fields and Smart Materials

ASME 2007 Summer Bioengineering Conference ◽

10.1115/sbc2007-175966 ◽

2007 ◽

Author(s):

Stephen A. Hart ◽

Marcelo J. Dapino

Keyword(s):

Smart Materials ◽

Cell Walls ◽

Bone Growth ◽

Bone Structure ◽

Bone Cells ◽

Bending Moment ◽

Bone Architecture ◽

Long Bone ◽

Fluid Shear ◽

Physical Loading

Bone structure is exquisitely matched to its physical loading environment. From the cartilaginous skeletal framework formed in the embryo to the aging skeleton, bone architecture is directly related to function. Bone is a dynamic system, constantly remodeling itself by absorbing old tissue and forming new tissue. This capability allows bone architecture to become optimized to the loading environment. Julius Wolff [1] first postulated that bone structure adapts to changing stress environments in 1892. Exact understanding of the process of mechanotransduction, however, has remained elusive. In addition to normal remodeling, bone growth has been shown to occur along the diaphysis, or shaft portion, of long bones such as the femur when placed in dynamic bending. Bone in this region is dense and is known as cortical bone. A bending moment placed on a long bone will cause the bone to curve creating a region of tension on one side and a region of compression on the opposing side. As the bending moment is cycled, fluid within the bone will flow from the region of compression to the region of tension creating fluid shear on cell walls within the bone which promotes the anabolic response of growth [2]. Growth from such stimuli is thought to be mediated by fluid flow around quiescent bone cells, osteocytes, and their canalicular process coursing through the bone structure [3]. Growth in this manner is directed in a latitudinal direction creating a thicker and stronger diaphysis.

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Stress-driven method bio-inspired by long bone structure for mechanical part mass reduction by removing geometry at macro and cell-unit scales

Fabrication of NiTi Shape Memory Alloys with Graded Porosity to Imitate Human Long-bone Structure

The evaluation of a synthetic long bone structure as a substitute for human tissue in gunshot experiments

The degree and pattern of phylogenetic signal in primate long-bone structure

Long Bone Structure and Strength Depend on BMP2 from Osteoblasts and Osteocytes, but Not Vascular Endothelial Cells

Exercise Stimulates Whole-body Growth And Skeletal Elongation Without An Effect On Long Bone Structure

Effects of Parotin on Long Bone Structure and Vascularization

Analysis of short-term treatment with the phosphodiesterase type 5 inhibitor tadalafil on long bone development in young rats

Palaeobiological inferences based on long bone epiphyseal and diaphyseal structure - the forelimb of xenarthrans (Mammalia)

Limitations in Use of Elastic Stable Intramedullary Nailing (ESIN) in Children with Disorders of Bone Mineralization

Accelerated Bone Growth Remotely Induced by Magnetic Fields and Smart Materials

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