UTS

Bioprinting the Photoreceptor Layer of the Retina

Timeline
Feb 2022 - June 2022

3D Bioprinting of Photoreceptor Layer: A Groundbreaking Project in Biomedical Engineering

In the sphere of Biomedical Engineering, the prototyping of the photoreceptor layer of the retina using 3D bioprinting and GelMA hydrogels signifies a substantial stride in the application of technology to healthcare. This project, executed during my academic tenure at the university, was a challenging yet rewarding venture that showcased the potential of biomedical engineering in transforming medical diagnostics and treatments.

Literature Review and Research

The initial phase of the project was dedicated to an extensive literature review and research to understand the intricacies of the photoreceptor layer of the retina and the potential of GelMA hydrogels in 3D bioprinting. This phase laid the groundwork for the subsequent steps, providing us with the necessary knowledge and understanding to proceed with the project.

  • The literature review and research phase was comprehensive, providing us with a deep understanding of the project's requirements.
  • The knowledge gained from this phase laid the groundwork for the subsequent steps of the project.

Embedding Cells into GelMA Hydrogels

Following the research phase, we moved to the practical application of our knowledge by embedding cells into GelMA hydrogels. This phase provided us with invaluable hands-on experience with the fabrication of biomedical devices. Each component was created with utmost care, ensuring that the final product was robust and reliable.

  • The construction phase was carried out meticulously, providing hands-on experience.
  • Each component was created with utmost care, ensuring a robust and reliable final product.
  • The construction phase provided invaluable experience with the fabrication of biomedical devices.

Cell Viability Analysis Using Microscopes and ImageJ

The system was designed to analyze cell viability using microscopes and ImageJ software. This integration of cell imaging and biomedical engineering allowed us to create a system that was not only capable of detecting live and dead cells but also demonstrated cell viability as cells were still alive and showed differentiation.

Teamwork and Recognition: A Testament to Excellence

Our system was capable of detecting live and dead cells, demonstrating its potential for clinical applications. This level of functionality was a testament to the effectiveness of our research and the skills of our team. Our project was recognized as one of the best in the subject, earning us a distinction for our work.

  • The system could detect live and dead cells, demonstrating its potential for clinical applications.
  • Our team's skills and the effectiveness of our research were recognized, earning us a distinction.
  • The project showcased the potential of biomedical engineering in revolutionizing medical diagnostics.

Reflection and Future Prospects

This project was a significant milestone in my journey as a Biomedical Engineer. It honed my skills in research, cell imaging, and cell viability analysis. The hands-on experience of creating a patient-specific system from scratch, coupled with the recognition we received, underscores my potential in this field.

The project showcased my proficiency in using tools like microscopes and ImageJ software and my ability to work effectively with cell imaging and viability analysis. These skills, along with my problem-solving abilities and innovative thinking, make me a strong candidate for a position in Biomedical Engineering. I am eager to leverage these skills to create impactful solutions in the field and improve people's lives.