GET IN TOUCH

Technology

At the heart of our work at CompagOs, our core technology features Bon3OID™ in vitro models.

By combining 3D bioprinting, biomechanical stimulation, and micro-CT in a reproducible manner, we have developed a robust and scalable framework for drug development. In the future, we envision utilizing this framework not only to personalize treatments in fields with high unmet needs, such as bone metastasis and osteoporosis, but also to advance regenerative medicine by recreating bone tissue for patients with severe cancerous and traumatic conditions.

How We Create Bon3OID™ Models

We use 3D bioprinting to create human mesenchymal stem cell-laden hydrogel scaffolds, either from diseased or healthy donors.​

These scaffolds are subjected to cyclic mechanical loading, stimulating cell-mediated mineralization and effectively mimicking human biology. Our bioreactors provide precise stimulation, similar to the mechanical load exerted to cells in bones during everyday activities like walking.

Our basic organotypic bone models consist of osteoblasts and osteocytes. Depending on specific research and clinical needs, we can introduce other types of cells, including osteoclasts and cancer cells.

How We Make a Difference

Value Across Stakeholders

At CompagOs, our technology is more than just a tool. It's a revolution in the field of bone health, creating a ripple effect of benefits across the healthcare spectrum. Our technology has the potential to bring value to stakeholders at all stages, from research to clinical applications.

Researchers

can gain early insights into the likely effectiveness of drugs in humans, thereby derisking the development pipeline.

Doctors

could use Bon3OID™ models as functional in vitro diagnostic tools to assess patient-specific disease properties at an early stage, leading to informed treatment decisions. Additionally, these models could advance regenerative medicine, allowing them to treat critical bone defects.

Patients

could receive more effective treatments at earlier stages, specifically tailored to them, and recover faster, leading to better outcomes and an improved quality of life.

Payers

could benefit from cost savings through fewer complications, unnecessary treatments, and shorter healing periods.

Related Resources

Deepen your understanding of our solutions and their applications. find out more in our Resource Center featuring publications, brochures, and more.

February 18, 2024

Physiological Cell Bioprinting Density in Human Bone-Derived Cell-Laden Scaffolds Enhances Matrix Mineralization Rate and Stiffness Under Dynamic Loading

Publication

Read More

June 30, 2022

Long-Term Mechanical Loading Is Required for the Formation of 3D Bioprinted Functional Osteocyte Bone Organoids

Publication

Read More

January 2, 2021

Time-Lapsed Imaging of Nanocomposite Scaffolds Reveals Increased Bone Formation in Dynamic Compression Bioreactors

Publication

Read More
VIEW ALL RESOURCES

Blog I Resources I News

CompagOs AG, Rigistrasse 15c, c/o MAS Solutions GmbH, 6331 Hünenberg, Switzerland​​

© 2024 CompagOs. All rights reserved.

Blog I Resources I News

CompagOs AG
Rigistrasse 15c
c/o MAS Solutions GmbH
6331 Hünenberg
Switzerland​​

© 2024 CompagOs. All rights reserved.