3D Matter Made to Order

A recent study, including Cluster Doctoral Researcher Alexander Berkes, Alumnus Pascal Kiefer and PI Martin Wegener, explores how the geometry of carrier particles affects drug delivery in dry powder inhalers. The team used multi-photon 3D laser printing to create millions of microparticles with different shapes and surface textures. The spiked Pharmacone design performed best, enabling the highest fraction of respirable drug particles. Although these particles are not intended for inhalation, this approach suggests the possibility of future biocompatible, precision-engineered carriers for more effective lung therapies.

© Wostry et al., Communications Materials 2025, CC BY 4.0

Scientists, including Cluster Alumna Tugce Nur Eren, Doctoral Researcher Jonathan L. G. Schneider, Postdoctoral Researcher Florian Feist, and PIs Martin Wegener, Jens Bauer, and Christopher Barner-Kowollik, have developed a single-component resin for 3D microprinting that enables structures with a wide range of mechanical properties in a single step. Unlike conventional resins, it does not require photoinitiators or additional crosslinkers. By adjusting laser power and scan speed, both very soft and flexible structures and very stiff and rigid structures can be produced. This breakthrough opens new opportunities in soft robotics, microfluidics and biofabrication.

© T. N. Eren, et al., Adv. Funct. Mater., 2025, e02876 (CC BY)

A new episode of our Explain Like I’m Five series is now live, exploring the fascinating world of human brain organoids. Lízia Branco, a Cluster Doctoral Researcher at the Karlsruhe Institute of Technology (KIT), demonstrates how lab-grown organoids made from stem cells can be used to study brain development and neurological disorders, eliminating the need for animal testing. Lízia combines her background in physics with neuroscience to apply imaging, data analysis, and machine learning to reveal how genetic and environmental factors influence the brain. The episode also discusses whether AI could play a role in detecting and helping to “fix” brain disorders.

The Coordinating Committee (CC) of the Cluster has been newly elected on July 31, 2025. Comprising six Principal Investigators (PIs) each from Karlsruhe Institute of Technology (KIT) and Heidelberg University, including members of the Executive Board, the CC oversees strategic decisions such as cluster membership, PI composition, fund allocation, and systematic evaluation of projects, Thrusts, PIs, and overall Cluster performance. Additionally, representatives from the KIT presidential committee and Heidelberg University’s president’s office attend to ensure seamless communication with university leadership. The newly elected CC will focus on implementing the objectives and measures outlined in the follow-up proposal.

A research team including Cluster Postdoctoral Researcher Chatrawee Scheiger and Mariana Kozlowska, and Cluster PIs Christof Wöll and Wolfgang Wenzel has demonstrated the first MOF thin film with true metallic conductivity. Using AI-guided robotic synthesis, the team fabricated highly ordered Cu₃(HHTP)₂ thin films with conductivities exceeding 200 S/m at room temperature. This metallic behavior is linked to Dirac cones in the material’s hexagonal structure, which enables highly mobile charge carriers. This breakthrough opens new possibilities for MOFs in electronics, sensing, energy storage, and quantum materials.

© Scheiger et al., Materials Horizons, 2025, CC BY 3.0

In this new publication, Cluster Doctoral Researchers Philipp Mainik and Jonathan L. G. Schneider, Principal Investigators Martin Wegener and Eva Blasco, along with Christoph A. Spiegel, present a new class of deep eutectic inks (DEIs) for multiphoton 3D laser microprinting. These inks enable the production of highly elastic and responsive microstructures with high spatial resolution and mechanical tunability. The innovative formulation combines excellent printability with minimal crosslinking, overcoming the limitations of traditional soft material inks. This advancement opens new possibilities for applications in soft robotics, bioengineering, photonics, and flexible microdevices.

© Mainik et al., Adv. Mater. 2025, CC BY 4.0