Medical & Biomedical Devices

Medical & Biomedical Devices Artificial Intelligence Analysis FEA|CFD & AI Integration

Simulation Dynamics has expertise in finite element (FE) analysis of biomaterials, containers and closures, drug delivery systems including injectors, implantable and patch pumps, medical device components. We specialize in developing and validating detailed computational models for due diligence, ideation, concept selection, requirements identification and generation, design evaluation and optimization, generating design output elements for verification.

Ocular modeling is another area where FEA is used, particularly in designing contact lenses and intraocular lenses. Soft tissue simulation is also important in the design of surgical tools and techniques, as it can help predict how tissues will react to different surgical approaches.

Finite element and CFD are also used in the packaging of medical devices, as well as in the design of electronic systems used in medical devices. They are also used in the design of knee replacements and other joint replacements, as well as in the design of hospital equipment such as patient beds and gurneys. Laser bonding and ablation catheters are other medical devices that can be designed using FEA and CFD.

Mechanical connectors, such as those used in pacemakers and defibrillators, can also be analyzed using FEA. Finite element simulation and CFD are also used in the design of vascular implants and heart valve replacements, as well as in the design of prosthetics.

Medical & Biomedical Devices, Integrated FEA|CFD with Artificial Intelligence

Cardiovascular Implants

Our biomedical engineers utilize Finite Element modeling to evaluate the design, manufacturing, delivery procedures, and clinical performance of various cardiovascular implants. Cardiovascular and peripheral stents, both self-expanding and balloon expanding, can be modeled using FEA techniques to analyze the mechanical behavior and response of the implant in the body.

Vena cava filters, which are used to prevent blood clots from traveling from the lower extremities to the lungs, can also be modeled using Finite Element techniques to optimize their design and predict their mechanical behavior.

Abdominal aortic aneurysm (AAA) grafts, which are used to treat bulging and weakened sections of the aorta, can be modeled using FEA techniques to ensure their structural integrity and durability.

Artificial heart valves and devices, including those that are percutaneously placed (TAVI/TAVR) and surgically placed, can also be modeled using FEA techniques to evaluate their performance and durability. Ventricular reconstruction modeling can also be used to simulate and optimize the surgical repair of damaged heart tissue.

Revolutionize Fluid Dynamics with CFD Simulation.

Optimize fluid flow, heat transfer, and turbulence with advanced CFD simulation tools. Enhance engineering designs for aerospace, automotive, and energy industries. Experience precision and efficiency in fluid dynamics analysis.

Cardiovascular Implants, Ansys, Simulia, Siemens, Integrated FEA|CFD with Artificial Intelligence

Medical & Biomedical Devices: Cardiovascular Implants

Craniomaxillofacial and Plastic Surgery

Here at Simulation dynamics, our engineers can develop finite element models of both craniomaxillofacial and plastic surgery reconstructive procedures including:

Evaluation of wound closure forces and tissue strains for plastic surgery,
Finite element modeling tool development for surgical planning and preparation,
Analysis of bone stress and resorption surrounding dental implants,
Development of models to analyze fracture fixation and healing for craniomaxillofacial applications,

Engineering Reliability, One Simulation at a Time.

Finite Element Anlaysis(FEA) and Computational Fluid Dynamics(CFD) ensures your designs are built to last. From automotive to aerospace, analyze structural integrity with precision. Trust in reliable solutions. Whether predicting pressure drop, thermal shock, stress, strain, or deformation, FEA & CFD delivers the insights you need to innovate with confidence. Build products that perform under pressure.

Craniomaxillofacial and Plastic Surgery, Ansys, Simulia, Siemens, Integrated FEA|CFD with Artificial Intelligence

Medical & Biomedical Devices: Craniomaxillofacial and Plastic Surgery

Electromagnetic compatibility (EMC) for Medical Device

Finite element (FE) analysis of biomaterials, containers and closures, drug EMC simulations can be used to evaluate the electromagnetic environment of medical devices and to ensure that they meet the requirements for electrical safety and performance. ANSYS Electromagnetic solvers and Simulia CST package can be used to simulate the behavior of electromagnetic fields and waves in and around medical devices, including the effects of electrical interference and the performance of shielding systems.

Artificial Intelligence & Machine Learning Powers the Future of Simulation.

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Electromagnetic compatibility (EMC) for Medical Device, Ansys, Simulia, Siemens, Integrated FEA|CFD with Artificial Intelligence

Medical & Biomedical Devices: Electromagnetic compatibility (EMC) for Medical Device

Orthopedic and Dental Implants

Orthopedic implants are commonly used to restore function in patients suffering from bone fractures, degenerative joint diseases, and other musculoskeletal disorders. These implants can include bone plates, screws, and other fixation devices, as well as implant components used for hip and joint replacement.

FE modeling is commonly used in the design and evaluation of orthopedic implants. For example, FE models can be used to simulate the mechanical behavior of bone and implant components under various loading conditions, such as those experienced during daily activities. By analyzing stress and strain distributions within the implant and surrounding bone tissue, engineers can optimize the design of the implant to ensure optimal performance and durability.

Additionally, FE models can be used to study the effect of implant materials on the surrounding tissues and to ensure the biocompatibility of the implant. This is important to avoid any adverse reactions to the implant by the body and to ensure that the implant will be well-tolerated over the long term. Dental implants are another area where FEA is used, as it can help predict the forces that will be placed on the implant and surrounding tissue.

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Orthopedic and Dental Implants, Ansys, Simulia, Siemens, Integrated FEA|CFD with Artificial Intelligence

Medical & Biomedical Devices: Orthopedic and Dental Implants

Aerospace & Defence

Automotive Engineering

Chemical Processing

Civil Engineering

Energy & Power Industry

Industrial Equipment & Rotating Machinery

Marine & Shipbuilding