Effects of Different Types of Mechanical Loading on Trabecular Bone Microarchitecture in Rats

Mechanical loading is generally considered to have a positive impact on the skeleton; however, not all types of mechanical loading have the same beneficial effect. Many researchers have investigated which types of mechanical loading are more effective for improving bone mass and strength. Among the various mechanical loads, high-impact loading, such as jumping, appears to be more beneficial for bones than low-impact loadings such as walking, running, or swimming. Therefore, the different forms of mechanical loading exerted by running, swimming, and jumping exercises may have different effects on bone adaptations. However, little is known about the relationships between the types of mechanical loading and their effects on trabecular bone structure. The purpose of this article is to review the recent reports on the effects of treadmill running, jumping, and swimming on the trabecular bone microarchitecture in small animals. The effects of loading on trabecular bone architecture appear to differ among these different exercises, as several reports have shown that jumping increases the trabecular bone mass by thickening the trabeculae, whereas treadmill running and swimming add to the trabecular bone mass by increasing the trabecular number, rather than the thickness. This suggests that different types of exercise promote gains in trabecular bone mass through different architectural patterns in small animals.

Dental Cone Beam Computed Tomography for Trabecular Bone Quality Analysis in Maxilla and Mandible

The stability of a dental implant is one of the most important aspects that decide the success rate of implant treatment. The stability is considerably affected by the strength of trabecular bone present in maxilla and mandible. Thus, finding of trabecular bone strength is a key component for the success of dental implants. The trabecular bone strength is usually assessed by quantity of bone in terms of bone mineral density (BMD). Recently, it has been revealed that along with quantity of bone, strength of the bone also depends on quality features commonly referred as trabecular bone microarchitecture. Since the quality of the trabecular bone is varying across the maxilla and mandible, preoperative assessment of trabecular bone microarchitecture at sub-region of maxilla and mandible are essential for stable implant treatment. Thus, in this chapter, the authors inscribe the quantitative analysis of trabecular bone quality in maxilla and mandible using CBCT images by employing contourlet transform.

Mimicking high strength lightweight novel structures inspired from the trabecular bone microarchitecture

Nature's evolution of a billion years has advanced flawless functionality in limitless optimized structures like bone structural adaptation in various physiological behaviours. In this study, porous structures are designed and fabricated from the nature-inspired trabecular bone microarchitecture. A three-dimensional (3D) model of the porous trabecular architecture from the compressive proximal zone of the femoral head was constructed using the micro-computed tomography scanning tool. The model was modified to get porous structures of different volume fractions varying from 20 to 40% with an increment of 10%. The obtained porous structures were 3D printed and analysed for deformation-resistant behaviour. Quasi-static compressive loading was performed at different strain rates (0.001–1 s −1 ) to get an insight into lightweight, high strength structural behaviour. Mechanical parameters, such as specific modulus, specific strength and specific energy absorption, were analysed for the optimal volume fraction. The original volume fraction (30%) of the trabecular bone shows the highest value of mechanical parameters. This study can help engineers to select and design lightweight porous structures with high energy-absorbing capacity, mimicking the desired architecture and porosity available in nature. This article is part of the theme issue ‘Bioinspired materials and surfaces for green science and technology (part 3)’.