Arezoo DADASHZADEH profile

I earned my Ph.D. in Pharmaceutical and Biomedical Sciences from the Université Catholique de Louvain (UCLouvain) in April 2024, where I explored groundbreaking advancements in biomaterials, tissue engineering, nanoparticles, and regenerative medicine. My academic foundation includes dual bachelor’s degrees in Biomaterials and Biomechanical Engineering and a master’s degree in Tissue Engineering. Throughout my career, I have been passionate about developing bioengineered structures that replicate the functionality of native tissues. During my Ph.D., I designed and synthesized biomaterials, including PEGylated fibrin hydrogels, to closely mimic the mechanical properties of human tissues. This work laid the groundwork for innovative approaches in ovarian tissue engineering, supporting the survival and growth of human preantral follicles in vitro. Building on these findings, my postdoctoral research focuses on in vivo studies to evaluate the safety and efficacy of PEGylated fibrin hydrogels for follicle encapsulation—critical steps toward clinical applications in fertility preservation. Beyond my primary research, I have contributed to multidisciplinary projects, including photodynamic therapy for cancer cell eradication, essential oil-loaded nanoparticles, silk-based hydrogels, and 3D tumor model fabrication. These experiences have enriched my expertise across tissue engineering, biomaterials, and cancer therapy. Looking ahead, I aim to continue bridging biomaterials and regenerative medicine, focusing on designing advanced scaffolds and therapeutic platforms that address pressing clinical needs. My journey is driven by a desire to translate innovative research into tangible solutions that improve human health and quality of life.

Throughout my academic journey, I have cultivated expertise in ovary tissue engineering, oxygen-releasing biomaterials, biocompatible hydrogels, nanoparticles, wound healing, and mathematical modeling. My skill set includes a broad array of advanced characterization techniques, such as cellular and molecular evaluations, electron microscopy (SEM and TEM), histochemical and immunohistochemical analysis, dynamic light scattering, atomic force microscopy, confocal and light-sheet microscopy, and fluorescence-activated cell sorting. During my undergraduate and graduate studies, I explored innovative solutions including optimizing nozzle designs, and developed a novel wound dressing by incorporating niosomal aloe vera within a hybrid hydrogel structure. During my Ph.D., I had the privilege of working with Prof. Christiani Amorim’s group, where I applied mathematical modeling to replicate the mechanical properties of the human ovarian cortex, creating a supportive environment for isolated ovarian follicles and stromal cells. I also utilized a microfluidic bioprinter to fabricate a 3D oxygen-releasing scaffold for ovary tissue engineering. In addition to my core research, I have collaborated on multidisciplinary projects, broadening my expertise and contributing to advancements in biomaterials and regenerative medicine. My work reflects a commitment to addressing complex challenges with innovative and practical solutions.

https://scholar.google.com/citations?user=_HOlizIAAAAJ&hl=en&oi=ao