Microfluidic Lab-on-a-Chip Systems

The “Microfluidic Lab-on-a-Chip Systems” course is designed to introduce the fundamentals and advanced concepts of microfluidics technology within a compact and efficient framework. Throughout this one-month program, participants will explore the principles of microscale fluid dynamics, the engineering of microfabricated devices, and the integration of analytical methods into tiny chip-based systems. The curriculum includes detailed sessions on material selection, device fabrication, system integration, and real-world applications, such as point-of-care medical devices and environmental sensors. In the latter part of the course, students will engage with complex scenarios, applying their knowledge to solve problems in healthcare diagnostics, drug development, and environmental monitoring, preparing them to lead advancements in this transformative field.

This program aims to provide an in-depth understanding of microfluidic lab-on-a-chip systems, focusing on their design, functionality, and applications across various fields. Participants will learn how to innovate and apply these systems to streamline laboratory processes, enhance diagnostic procedures, and develop new technologies for health and environmental monitoring.

1. Master the design principles of microfluidic systems.
2. Fabricate and test microfluidic devices using state-of-the-art techniques.
3. Integrate electronic and optical components to enhance device functionality.
4. Develop applications of lab-on-a-chip devices in clinical diagnostics and environmental assessments.
5. Drive innovation in microfluidic technology through project-based learning.

• Undergraduate degree in Mechanical Engineering, Biomedical Engineering, Chemical Engineering, or related fields.
• Professionals in the healthcare, environmental, or agricultural sectors.
• Individuals interested in advancing compact, scalable, and innovative technology solutions.

• Proficiency in microfluidic device design and fabrication.
• Ability to integrate and troubleshoot microfluidic systems.
• Competence in applying microfluidic technology to practical applications.
• Skills in innovative thinking and problem-solving within technology development.
• Readiness to contribute to advancements in healthcare and environmental technologies.