The field of orthopedic and biomedical engineering has witnessed remarkable advancements in recent years, particularly in the development of implants and complete organ replacements aimed at restoring functionality to various components of the human body. These implants can be either temporary or permanent and vary widely in terms of material qualities and design. Understanding the characteristics of newly developed materials is crucial, and this is where a multiscale modeling approach becomes invaluable.Multiscale modeling, using techniques such as finite-element analysis (FEA) or machine learning, plays a pivotal role in enhancing patient-specific implant materials and designs. As the manufacturing sector continues to grow and evolve, the need for precise and tailored implants has become increasingly important.Advancements in implant design and evaluation have revolutionized the field of orthopedics and dental, offering patients more effective and durable treatment options. This collection of research papers represents a significant contribution to the field, showcasing innovative studies that combine biomechanics, FEA, and materials science to improve the performance and longevity of orthopedic implants.The first study focuses on the treatment of distal tibial fractures using intramedullary (IM) nailing and plating. By employing FEA and a bone remodeling model, the study aims to predict the effects of these methods on bone density distribution in the tibia. The findings suggest that plating may be a better choice for distal tibial fractures from a bone remodeling perspective, highlighting the importance of understanding bone-implant interactions (Moslehi and Rouhi, 2024).Another study explores the performance of hip cement spacers, crucial in revision surgeries, through a multiscale approach. By analyzing the fracture behavior of reinforced spacers, the study reveals that reinforcing spacers with ceramic and stainless-steel full stems can significantly enhance their strength, reducing the need for early hip revisions (Saleh et al., 2024).In the realm of dental implants, a study investigates the biomechanical response of progressive thread implants using multiscale finite-element analysis. The study demonstrates that progressive thread implants may be more suitable for weaker bone conditions, offering valuable insights for dental implant design and placement (Chakraborty et al., 2024).Furthermore, a study assesses the mechanical responses between trabecular bones and porous scaffolds, crucial in tissue engineering for tissue regeneration and repair. By investigating the mechanical stimuli within a scaffold and comparing it to natural bone, the study aims to identify scaffold designs that closely mimic natural bone, offering promising solutions for tissue engineering applications (Samanta et al., 2024).Another study presents a new criterion for characterizing knee osteoarthritis using finite-element modeling, providing a methodology to quantify load applied to the knee and identify phases of cartilage wear. This...
