
Pushing the Frontiers
of Research
Exploring ultrasound, robotics, additive manufacturing, automation, waste valorization, and drug screening to develop next-generation precision medicine and sustainable technologies—bridging fundamental science with real-world applications.

Pushing the Frontiers
of Research
Exploring ultrasound, robotics, additive manufacturing, automation, waste valorization, and drug screening to develop next-generation precision medicine and sustainable technologies—bridging fundamental science with real-world applications.

Pushing the Frontiers
of Research
Exploring ultrasound, robotics, additive manufacturing, automation, waste valorization, and drug screening to develop next-generation precision medicine and sustainable technologies—bridging fundamental science with real-world applications.
Key Research Areas
Key Research Areas
Key Research Areas
Volumetric Bioprinting
Integrating ultrasound with printing modalities
01
Volumetric Bioprinting

02
In vivo Bioprinting
03
Preclinical in vitro models
01
Volumetric Bioprinting

Volumetric Bioprinting
Integrating ultrasound with printing modalities

02
In vivo Bioprinting
In vivo Bioprinting
Bioprinting for real-time bioprinting in vivo

03
Preclinical in vitro models
Preclinical in vitro models
Creating new disease models and a drug screening model for an in vitro preclinical screening model
01
Volumetric Bioprinting

Volumetric Bioprinting
Integrating ultrasound with printing modalities

02
In vivo Bioprinting
In vivo Bioprinting
Bioprinting for real-time bioprinting in vivo

03
Preclinical in vitro models
Preclinical in vitro models
Creating new disease models and a drug screening model for an in vitro preclinical screening model
Funding Partners and Research Communities
Funding Partners and Research Communities
Funding Partners and Research Communities

Innosuisse

Bridge POC

InnoBooster

Innosuisse Coaching

SNSF

ETH Zürich

Innosuisse

Bridge POC

InnoBooster

Innosuisse Coaching

SNSF

ETH Zürich
Featured
Publications
Featured
Publications

4d-printed-adaptive-hydrogel-tissue-expanders-for-ear-and-breast-reconstruction
A 4D-printed, pH-responsive polyelectrolyte hydrogel tissue expander that swells 10 to 30 times its volume without external triggers, enabling complex, mechanically robust shapes for minimally invasive ear and breast reconstruction.
A 4D-printed, pH-responsive polyelectrolyte hydrogel tissue expander that swells 10 to 30 times its volume without external triggers, enabling complex, mechanically robust shapes for minimally invasive ear and breast reconstruction.

An acoustically assisted volumetric 3D printer
Advances in additive manufacturing in composites have transformed aerospace, medical devices, tissue engineering, and electronics. A key aspect of enhancing properties of 3D-printed objects…
Advances in additive manufacturing in composites have transformed aerospace, medical devices, tissue engineering, and electronics. A key aspect of enhancing properties of 3D-printed objects…

SonoPrint: An acoustically assisted volumetric 3D printer
A novel 3D printing method that combines sound energy with volumetric printing to create structures with aligned reinforcement patterns.
A novel 3D printing method that combines sound energy with volumetric printing to create structures with aligned reinforcement patterns.