For more than 25 years, Altair OptiStruct™ has been the industry leader in developing and applying optimization technology for strong, lightweight designs. Developed to mimic how mechanical stresses influence optimal bone growth, it is now used to model complex biological structures and design optimized orthopedic structures. This includes lattice-designed, 3D printed components, ideal for osseointegration and promoting vascularization.

Patients with specific maladies can now be treated with custom-design implantable structures. Optimized using Altair technology, such replacement devices can be manufactured using 3D-printed resorbable biomaterials and serve as a temporary solution until the body grows its own tissue in replacement.

Whether it’s importing external or internal patient scan data, HyperMesh® has been a critical tool used by clinicians and engineers to accurately model the complex geometry of the human body. Once established, this model can then be exercised by a variety of Altair physics solvers and optimization methods to study bodily function and develop ways to improve patient care. For example, using shape optimization and elasto-plastic simulation, Altair can model complex biological systems such as the delicate structural behavior of intravascular stents within blood vessels. Vascular deformation and blood flow analyses can be performed to understand, predict, and prevent disorders.

Such tools are also essential to building accurate models of the 3D shape of the brain, acquired from MRI and CT data. These models help map cerebral vascular networks and diagnose and prevent brain disease. Further, Altair technology has been extensively applied to biomechanics, like studying injury thresholds for brain concussion in automotive safety and other applications within the field of sports medicine.