Empower your institution with cutting-edge additive manufacturing to enable hands-on discovery, faster prototyping, and breakthrough research across disciplines.
3D printing (additive manufacturing) enables researchers to fabricate complex parts or instruments layer by layer — without long wait times or dependence on external vendors.
Students and faculty can translate digital designs into tangible models, deepening understanding and accelerating iteration in fields from engineering to materials science.
By producing in-house, institutions lower model costs and reduce procurement delays — freeing budgets and timelines for experimentation.
Additive tools allow for customized, discipline-specific research artifacts—microfluidic devices, architectural models, biomedical implants, soft robotics, and more.
3D printing (additive manufacturing) enables researchers to fabricate complex parts or instruments layer by layer — without long wait times or dependence on external vendors.
Students and faculty can translate digital designs into tangible models, deepening understanding and accelerating iteration in fields from engineering to materials science.
By producing in-house, institutions lower model costs and reduce procurement delays — freeing budgets and timelines for experimentation.
Additive tools allow for customized, discipline-specific research artifacts—microfluidic devices, architectural models, biomedical implants, soft robotics, and more.
We support a broad spectrum of 3D printing technologies suited for diverse research needs:
Fused Deposition Modeling
Affordable, versatile, and a great entry point for prototyping and custom parts development
Photopolymer Jetting
Enables multi-material, full-color, high-fidelity prints with fine detail.
Stereolithography
Ideal for parts requiring fine surface finish and intricate detail, such as fluid flow models.
Selective Absorption Fusion
Powder-based technology optimized for more advanced research and small-batch production.
Programmable Photopolymerization
An advanced open system with high precision and material flexibility
Affordable, versatile, and a great entry point for prototyping and custom parts development
Ideal for parts requiring fine surface finish and intricate detail, such as fluid flow models.
Institutions around the world are already leveraging additive manufacturing to push boundaries.
These examples show how additive manufacturing transcends traditional boundaries—melding design, engineering, biology, and more.
New Zealand
Used 3D printed internal channels to mimic plant vascular systems.
Developed multi-material fluidic devices combining liquid and solid structures.
Used PolyJet 3D printing to rapidly produce durable, high-resolution microfluidic chips with complex geometries in under 30 minutes.
Established a 3D Printing & Training Center using Stratasys technology to create lifelike anatomical models and offer specialized medical 3D printing training.
Used PolyJet 3D printing to rapidly produce durable, high-resolution microfluidic chips with complex geometries in under 30 minutes.
Established a 3D Printing & Training Center using Stratasys technology to create lifelike anatomical models and offer specialized medical 3D printing training.
