DAAD-GSSP Scholarships for international PhD students

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DAAD-GSSP Scholarships for international PhD students 

Unlock Your Research Potential: Join the Graduate School LSE! 

Embark on an exciting journey at the interface between engineering and life sciences with TU Darmstadt's Graduate School LSE. We are thrilled to announce a unique opportunity for international PhD students under the prestigious Graduate School Scholarship Programme (GSSP) of the German Academic Exchange Service (DAAD).

What We Offer:

  • Interdisciplinary Research: Explore cutting-edge projects at the intersection of engineering and life sciences
  • Global Network: Join a vibrant community of scientists and experts from diverse backgrounds.
  • Excellence in Supervision: Conduct your doctoral studies under the supervision of renowned scientists and benefit from the accompanying PhD programme of the Graduate School LSE 

For 2025, there are two scholarships available for doctoral studies to begin April – December 2025 (starting dates are dependent on the application and visa process) in one of the following research group:

Prof. Torsten Frosch - Biophototonics: We work at the interface between physics, chemistry, engineering and life sciences. We research novel optical spectroscopic techniques for highly relevant biomedical and life science application. The offered PhD project focuses on innovative Raman-spectroscopic techniques for rapid and label-free monitoring of biomolecules, such as disease biomarkers, drugs, and biogenic gases. One focus is on research into signal amplification techniques for highly selective and sensitive Raman-spectroscopy. Our goals involve the monitoring of drugs in body fluids, the analysis of biomarkers in exhaled gas, and biomedical imaging to provide insights into molecular mechanisms of disease. Raman-spectroscopy is a non-invasive, non-contact, label-free and quantitative method that can be used in physiological environments and is excellently suited for biomedical applications.

Your knowledge and interests:

  • Knowledge in optics and analytical spectroscopy 
  • Experimental skills and interest in the development of novel optical setups 
  • Interest in Raman spectroscopy, fiber sensing, and data analysis 
  • Interest in interdisciplinary research
  • Highly motivated 
  • Very good English written and spoken communication skills 

We offer an attractive research environment with a very friendly and active team, excellent instrumentation, and diverse interdisciplinary cooperation opportunities.

Dr. Andrea Belluati - Biohybrid Systems for cellular engineering: We seek a motivated PhD candidate to contribute to our research on the development and organisation of artificial cells into complex metastructures that mimic biological systems. The project focuses on enzymatically-synthesized hybrid polymer-lipid systems and dynamic transitions between membranised and coacervate-based architectures to create versatile synthetic cells. These constructs will be organised into higher-order tissue-like structures using assembly techniques, including microfluidics and stimuli-responsive elements, to enable adaptability and controlled interactions. The research further explores artificial symbiosis, integrating synthetic and natural cells for applications in tissue regeneration, drug delivery, and biomanufacturing. This interdisciplinary work bridges synthetic biology, polymer chemistry, and bioengineering to advance the design of adaptive, life-like materials.

Prof. Dr. Beatrix Suess - Synthetic RNA biology: In response to the worldwide antibiotics crisis, our lab is presently developing RNA-based antibiotics. Based on our expertise in targeted in vitro selection (SELEX), we are developing RNA aptamers to efficiently kill pathogenic bacteria. These RNA aptamers are obtained by a selection process from large combinatorial libraries, bind their target molecule with high affinity and specificity and inhibit their activity. Targets of interest are proteins that lead to multidrug-resistance in germs of concern, for example the penicillin-binding protein 2a from Staphylococcus aureus. Ultimately, the aim is to establish a proof of concept for a new type of RNA therapeutics.

Prof. Dr. Viktor Stein - Protein engineering: The Stein lab can host research projects in the field of protein engineering and synthetic biology. A particular emphasis is on engineering protein sensors, switches as well as diffusion and transport processes across cellular and biomimetic membranes while focussing on metabolites, drugs and other small molecules.

Applications for the envisaged protein technologies are diverse. For instance, protein sensors can be used for the real-time analysis of metabolites and drugs in both live cells and complex diagnostic samples. Similarly, protein switches can be applied to control molecular functions with exquisite specificity and temporal resolution. Further, sensors and switches can be used to build sense-and-respond circuits operating autonomously in live cells and intelligent (bio)materials. Finally, tailor-engineered transport processes across biological and biomimetic membranes can form part of sophisticated sensing and separation technologies.

Molecular Engineering endeavours are generally complemented by the development of dedicated enabling technologies (e.g. combinatorial DNA assembly methods, high-throughput screening systems and robotic automation) that are combined with high-resolution analytical methods (e.g. electrophysiological measurements in lipid bilayers and live cell fluorescence microscopy in microfluidics) to gain fundamental insight how artificially engineered proteins functions and ultimately facilitate the underlying construction process.


Prof. Dr. Felix Hausch, Structure-based drug research: The project, titled Functional and structural characterization of FKBP-Hsp90-steroid hormone receptor complexes by large-scale, site-specific, in-cell photo-crosslinking aims to uncover key states and interaction partners of FKBP51, a significant target for conditions such as depression, obesity-induced diabetes, and pain.

The position is tailored for PhD candidates with an interest in biochemistry, molecular and chemical biology, especially those eager to apply their knowledge to drug discovery. Ideal candidates will hold a Master’s degree in life sciences or (bio)chemistry, with a strong background in molecular biology and protein biochemistry techniques.

Participants in this project will receive training in advanced molecular biology methods and benefit from dedicated mentorship within an interdisciplinary and international research group. The project is planned for a duration of 3+ years, with compensation aligned to E13/65%.

For further background, candidates are encouraged to review Baischew, Engel et al. or visit the group’s webpage.

Prof. Dr. Ulrike Nuber - Stem cell and developmental biology: Three-dimensional (3D) human tissue models generated in the laboratory represent versatile in vitro models for human disease studies, drug development and toxicology assessment. They have the potential to reduce animal testing and hold great promise for regenerative medicine. However, their routine application is hindered by several limitations of the current models. One critical limitation is the lack of control over the precise spatial arrangement of cell types. Another limitation of human tissue models with diameters of more than several hundred µm is the lack of a vascular system that transports oxygen, nutrients, and metabolic waste products to and from cells. 

In natural human tissues, morphogen gradients steer the spatial development and maintenance of cell types. We have developed diffusion-based devices beyond the scale of microfluidic ones to regionalize human multicellular assemblies through concentration gradients of small bioactive molecules. Moreover, we harness the intrinsic morphogenetic capacity of vascular cells to generate a microvasculature in multicellular 3D human cell models. This process is supported by the integration of biomaterials into 3D cell cultures. To monitor cellular stages and positions in human tissue models, we have generated hiPSC fluorescent reporter lines by the CRISPR-Cas9 system.  


Please carefully review the application requirements and admission process BEFORE submitting your application here.

Application deadline: February 28, 2025

Applications are exclusively accepted via the online application form.

Contact: julia.detzer@tu-darmstadt.de

Join us in pushing the boundaries of knowledge and fostering groundbreaking discoveries. Your journey to academic excellence starts here! 

 

15602




TU Darmstadt



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Deadline: 2025-02-28
Location: Germany, Darmstadt, Hessen
Categories: Biochemistry, Biology, Biomedical Sciences, Cell Biology, Chemistry, Developmental Biology, LifeScience, Molecular Biology, pathology, PhD, Photonics, Physics, protein structure and function, spectroscopy,

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