Engineering Technologies to Interrogate and Direct Cellular Interactions for Cell-Based Therapy

Cellular interactions are central to several biological processes, and understanding and controlling how cells interact is critical for designing effective cell-based therapies. This talk will discuss how precision-engineered devices can be designed to interrogate, manipulate, and control cells in vitro and in vivo.

First, I will describe the development of a micro-engineered implant that can protect and maintain xenogeneic cells secreting therapeutic factors inside hosts without the need for immune suppression. I will show how we can use precision designs to control interactions of immune cells with the transplant to ensure long-term viability of the xenograft. I will demonstrate pre-clinical device development and testing in rodents and ongoing evaluations in non-human primates. These implants act as living drug factories inside the body, and we are exploring the potential of this platform to treat chronic diseases such as type 1 diabetes, blood disorder and liver failure.

Next, I will present our most recent work on creating platforms for sequencing non-coding RNAs in single cells. We have developed a high-throughput microfluidic device that can rapidly enrich and barcode microRNAs from single cells and process them for analysis through next-generation sequencing. I will discuss the potential of this technology as a tool for disease diagnosis and to study cell function.

Finally, I will conclude my talk with a high-level overview of problems my future lab is interested in and our interdisciplinary approach to solving them.