MEMS (micro-electromechanical systems) and microfluidics are two exciting fields of technology that have converged remarkably in recent years. MEMS devices are miniature systems made of tiny mechanical and electrical components, often using semiconductor manufacturing techniques. On the other hand, microfluidics involves the manipulation and control of small amounts of fluids in microscale channels and chambers.

The fusion of MEMS and microfluidics has given rise to a new class of devices with extraordinary capabilities. These integrated systems leverage the precision and scalability of MEMS technology to manipulate fluids at the micro scale, enabling applications in various domains such as biomedical diagnostics, drug delivery, chemical analysis, and lab-on-a-chip systems. By combining microfluidic channels and chambers with MEMS components like sensors, actuators, and valves, these devices can perform tasks like sample handling, mixing, separation, and analysis with unprecedented efficiency.

The integration of MEMS and microfluidics offers benefits such as reduced sample volumes, faster analysis times, improved sensitivity, and increased automation. The potential impact of MEMS and microfluidics fused devices is immense. They have the potential to revolutionise healthcare by enabling point-of-care diagnostics, personalised medicine, and portable lab-on-a-chip platforms. Moreover, they can find applications in environmental monitoring, food safety, and industrial processes.

Cancer diagnostics using MEMS and microfluidics

MEMS sensors have shown promise in the field of cancer detection and identification. These sensors are miniature devices that integrate mechanical and electrical components on a microscopic scale. When it comes to cancer cell identification, MEMS sensors offer several advantages such as: