Student Projects

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Data-driven/Machine Learning polymer formulation for drug development

This project aims to leverage machine learning to accelerate the design of polymer-based drug delivery systems with tailored release kinetics. Using a curated dataset of polymer formulations and their drug release profiles, predictive models will be developed, validated, and applied to optimize future formulations. By combining computational tools with explainable AI techniques, the project seeks to uncover key design principles and reduce experimental workloads. The outcome will enable smarter, data-driven reformulation processes, advancing personalized medicine and next-generation drug delivery technologies.

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Data-driven, machine learning, polymer formulation, drug

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Semester Project , Internship

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**Introduction:** Polymer-based drug delivery systems are pivotal in modern medicine, enabling controlled release kinetics that enhance therapeutic efficacy while minimizing side effects. However, traditional formulation development relies heavily on trial-and-error experimentation, which is resource-intensive, time-consuming, and often fails to account for complex interactions between polymer composition, processing parameters, and drug release behavior. This project addresses these limitations by leveraging machine learning, ML, to accelerate the rational design of polymer formulations tailored to specific release profiles. By training predictive models on a curated dataset linking spatial composition, material properties, and kinetic outcomes, this work aims to replace empirical guesswork with data-driven insights. Successful implementation could reduce reformulation timelines for existing drugs by 40–60%, enabling rapid adaptation of therapies for personalized dosing or novel delivery routes. Furthermore, the integration of interpretable ML algorithms, such as Random Forest for feature importance analysis or neural networks for capturing non-linear relationships, promises to uncover previously hidden design rules governing polymer-drug interactions. This approach not only streamlines pharmaceutical development but also advances sustainable practices by minimizing material waste, positioning data-driven formulation as a cornerstone of next-generation smart therapeutics. **Details** In this project, the student will harness the power of machine learning to revolutionize polymer-based drug delivery systems. Using a curated dataset of polymer formulations and their drug release kinetics, they will train predictive models to identify optimal formulations for tailored release profiles. The student will explore cutting-edge algorithms, validate their performance, and use them to design new formulations that minimize experimental guesswork. By combining computational tools with real-world data, the student will accelerate drug reformulation, uncover hidden design principles, and contribute to the future of personalized medicine and smart therapeutics. **Skills and Background Required** We are looking for motivated and independent candidates with a background in data science, chemistry, pharmaceutical sciences, biomedical engineering, bioengineering, or related fields. Previous experience with Data science and machine learning is a plus, a general understanding of polymer chemistry is highly recommended. Familiarity with software like python, R, and ML libraries is needed for model development and optimization. **Join the Project:** This project offers an exciting opportunity to work at the interface of biotechnology, pharmaceutical sciences, and Data-science/machine-learning. Candidates with an interest in translational research and drug development are encouraged to apply.

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Published since: 2025-04-04 , Earliest start: 2025-04-07 , Latest end: 2025-11-30

Organization Macromolecular Engineering Laboratory

Hosts Guzzi Elia

Topics Medical and Health Sciences , Engineering and Technology , Chemistry

How Mechanical Forces Shape Cell Fate – and the Future of Regenerative Medicine

Project Summary We’re developing a powerful new in vitro model to untangle the complex mechanical cues—osmotic pressure and substrate stiffness—that skin cells experience every day. These signals are deeply intertwined in the body, but we’re building a system to decouple and precisely control them, for the first time. Why? Because understanding how cells respond to these forces is crucial for engineering functional tissues, guiding organ regeneration, and tackling mechanobiology-driven diseases like fibrosis.

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Key words: mechanical stresses, cell behavior, fibroblasts, immunostaining.

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Master Thesis

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Published since: 2025-03-26 , Earliest start: 2025-06-01 , Latest end: 2026-01-31

Organization Macromolecular Engineering Laboratory

Hosts Cuni Filippo

Topics Engineering and Technology , Biology

PDMS-Based Bioreactor Investigating Cell Behavior in Response to Hydrostatic Pressure and Substrate Stiffness

Introduction and Background Skin cells dynamically respond to mechanical and biochemical stimuli, which influence critical processes such as proliferation, differentiation, and migration. By understanding this interplay, mechanical and biochemical stimuli may be used in the future to facilitate the growth of skin patches, tissue formation, and organ regeneration, enabling new therapies and benefiting patients. The study of these responses, mechanobiology, requires advanced in-vitro systems to emulate physiological conditions. This project utilizes a device designed for controlled manipulation of hydrostatic pressure (0.1–1.5 kPa) and substrate stiffness (0.1–100 kPa). The system facilitates isolated and scalable experiments to analyze how the interplay of these mechanical parameters affects cell behavior. In this thesis, the student will use this system to investigate how different stimuli affect cell behavior.

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Bioreactor, tissue engineering, organ regeneration

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Master Thesis

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Published since: 2025-03-26 , Earliest start: 2025-05-01 , Latest end: 2025-11-30

Organization Macromolecular Engineering Laboratory

Hosts Binz Jonas

Topics Engineering and Technology , Biology

Synthesis of a novel monomer for polymeric materials with on-demand degradation and enhanced durability

Plastic waste and the resulting environmental pollution are major challenges of our time. One of the problems is the mismatch of degradability and durability in plastics. Single use plastics like packaging material should be easy to degrade to facilitate recycling after use. However, these single use plastics are often very stable and hard to recycle. Performance plastics need to last during their lifetime without significant decrease in material properties, but aging in these materials eventually leads to material failure and replacement. Both situations generate plastic waste. Therefore, we want to synthesize a material that can degrade on-demand and experiences enhanced durability on longer timescales to satisfy the needs of single use plastics and performance plastics, respectively.

Keywords

Organic and polymer chemistry, novel monomer, degradability and durability

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Semester Project , Master Thesis

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Published since: 2025-03-04 , Earliest start: 2025-04-01

Organization Macromolecular Engineering Laboratory

Hosts Söll Carolina

Topics Engineering and Technology , Chemistry

Granular Hydrogels for Chronic Wound Healing: Enhancing Stability, Transport, and Clinical Readiness

The development of biomaterials for chronic wound healing faces significant challenges in achieving shelf-stability, transportability, and compliance with clinical manufacturing standards. To address these hurdles, we aim to integrate a freeze-drying (lyophilization) step into the preparation of our granular hydrogels, facilitating storage and transport without compromising functionality. By validating the post-rehydration performance of lyophilized microgels, we aim to ensure the robustness of our product for clinical use.

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Semester Project , Bachelor Thesis , Master Thesis

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Published since: 2025-02-18 , Earliest start: 2025-04-01 , Latest end: 2025-12-31

Organization Macromolecular Engineering Laboratory

Hosts Emiroglu Börte

Topics Medical and Health Sciences , Chemistry , Biology

Ex vivo evaluation of wound healing using granular biomaterials

Chronic wound care is hindered by the complex and variable proteomic profiles of wound exudates, which limit the efficacy of existing therapies. We aim to validate the effectiveness of our granular hydrogel platform in restoring balance to the wound microenvironment. Utilizing exudates obtained from diabetic foot ulcer (DFU) patients, we will optimize our microgel library to target clinically relevant cytokine profiles.

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Semester Project , Master Thesis

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Published since: 2025-02-18 , Earliest start: 2025-03-01 , Latest end: 2025-12-31

Organization Macromolecular Engineering Laboratory

Hosts Emiroglu Börte , Singh Apoorv

Topics Medical and Health Sciences , Engineering and Technology , Chemistry , Biology

Designing photosynthetic living materials with synthetic biology

Living materials, as an emerging field that combines biology and material science, are materials composed of immobilized living organisms and a carrier matrix providing pre-determined bio-functionality. [1,2] Living materials bring about new properties that are not easily realised by conventional materials. Here, we aim to design a new type of living materials that can sequester and store atmospheric CO2 irreversibly in the form of calcium carbonate minerals.

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living materials, synthetic biology, microorganisms

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Bachelor Thesis , Master Thesis , ETH Zurich (ETHZ)

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Published since: 2025-01-27 , Earliest start: 2025-02-05 , Latest end: 2025-10-31

Organization Macromolecular Engineering Laboratory

Hosts Cui Yifan

Topics Engineering and Technology

In vitro liver tissue models for studying liver regeneration and drug delivery systems

Many organ grafts are not suitable for transplantation due to excessive ischemic injury. In an effort to save these discarded grafts, ex vivo perfusion systems have been developed to extend the time window for organ repair. The liver, in particular, has a remarkable regenerative capacity and its ex vivo perfusion provides a unique opportunity to trigger regeneration pathways. Thus far, advanced perfusion technologies have enabled the preservation of the human liver outside of the body for up to two weeks using normothermic machine perfusion. Until now, this liver perfusion machine has only been employed to treat bacterial infections, determine tumour malignancy and assess liver function, yet how to stimulate growth and repair of liver grafts ex vivo remains unexplored. In order to effectively develop regeneration strategies, in vitro liver models are necessary since ex vivo human liver experiments are low-throughput, confounded by patient to patient variability and costly. Liver tissue slices, which are directly obtained from native liver tissue, preserve the intact hepatocellular architecture and microenvironment of the liver unlike 2D cell culture and organoid models. Thus, we aim to use liver tissue slices as a screening platform to identify pro-regenerative biomolecules and drugs. In addition, we will explore mRNA lipid nanoparticles to improve the delivery and therapeutic effect of candidate biomolecules and drugs for ex vivo liver perfusion.

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in vitro liver models, regeneration, drug screening, cell culture, molecular biology, biomedical engineering

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Internship , Master Thesis

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Published since: 2024-12-10 , Earliest start: 2025-01-12 , Latest end: 2026-05-31

Organization Macromolecular Engineering Laboratory

Hosts Cunningham Leslie

Topics Engineering and Technology , Biology

Establishing a novel high throughput Drug Screening in vitro

The development of advanced drug formulations is a cornerstone of pharmaceutical innovation, directly influencing therapeutic efficacy, patient outcomes, and market success. Achieving optimal drug absorption and bioavailability remains one of the most significant challenges in formulation design, particularly for oral and parenteral delivery systems. Addressing this challenge is critical for advancing scientific understanding and also for accelerating drug discovery and reducing time-to-market for new therapies. This Master’s thesis project aims to develop an advanced cell culture assay to model drug absorption, providing a scientifically robust and commercially valuable platform for drug screening and optimizing novel drug formulations. By bridging gaps in current drug screening methodologies, this project will contribute to innovation in drug delivery technologies and enhance competitive positioning in the growing global market for pharmaceutical solutions.

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cell culture, drug screening, drug formulation, polymer,

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Master Thesis

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Published since: 2024-12-06 , Earliest start: 2024-12-09 , Latest end: 2025-12-31

Applications limited to EPFL - Ecole Polytechnique Fédérale de Lausanne , ETH Zurich , Hochschulmedizin Zürich , IBM Research Zurich Lab , Institute for Research in Biomedicine , Zurich University of Applied Sciences , Wyss Translational Center Zurich , University of Zurich , University of Berne , University of Geneva , University of Basel , University of Fribourg , Swiss National Science Foundation , Empa , CSEM - Centre Suisse d'Electronique et Microtechnique , Department of Quantitative Biomedicine , Balgrist Campus , [nothing]

Organization Macromolecular Engineering Laboratory

Hosts Guzzi Elia

Topics Medical and Health Sciences , Engineering and Technology , Chemistry , Biology