Access to our extensive library of design templates and simulation models accelerates development and introduces proven methodologies. This repository of customizable designs and simulation parameters, coupled with resources and guidelines, enables rapid adaptation to new challenges. It's ideal for leveraging established designs to reduce time-to-market and for incorporating tested elements into new microfluidic device configurations.

Key Benefits:

• Streamlines the design process by providing ready-to-use, adaptable templates.

• Enhances creative possibilities with access to a broad array of design options.

Micro- and nano-scale design is essential for precise fluid management in applications like lab-on-a-chip devices and biosensors. We use advanced modeling tools and detailed principles of microscale fluid physics to ensure accurate manipulation and interaction, enhancing functionality and precision in critical microfluidic technologies.

Key Benefits:

• Ensures high fidelity between simulated models and real-world behavior.

• Allows for the exploration of innovative applications in pharmaceuticals, diagnostics, and more.

Computational Fluid Dynamics (CFD) is essential for predicting complex fluid behaviors on micro- and nano-scales where traditional testing may fall short. CFD is particularly valuable during the early development stages of microfluidic devices, where it helps predict how the device will perform under various conditions. Complex flow behavior in combination with heat transfer, particle or beads flow, diffusion driven process and acoustic behavior can be modelled to accelrate development and understanding oft he system.

Key Benefits:

• Reduces the reliance on physical prototypes, saving both time and resources.

• Enhances understanding of fluid dynamics within devices, leading to more efficient designs.

• Complex multiphysic behavior can be simulated at once (flow, heat transfer, bead flow, difussion driven processes, acoustic behavior, ..)