Hang Lu


Hang

 

Lu

Professor
Primary School/Department: 
Georgia Tech School of Chemical and Biomolecular Engineering
Title 2: 
James R. Fair Faculty Fellow
Title 3: 
Dennis Frank Faculty Fellow

Phone: 
404-894-8473
Office Location: 
EBB 3017
University: 
Georgia Institute of Technology

Research Keywords:

Microfluidics, bioMEMS, behavior neuroscience, cell biology, automation and high throughput engineering approaches to biology and biotechnology, and regenerative medicine

Research Affiliations:

Research Center Affiliations: 
Marcus Center for Therapeutic Cell Characterization and Manufacturing (MC3M)
Regenerative Engineering and Medicine (REM)
Integrated Cancer Research Center
Immunoengineering
Emergent Behavior of Integrated Cellular Systems
Center for ImmunoEngineering
Center for Neural Engineering

Research Areas:

Research Areas: 
Cancer Biology
Chemical Biology
Drug Design, Development and Delivery
Neuroscience
Regenerative Medicine
Systems Biology

Research Interests:

  • Microfluidic systems for high-throughput screens and image-based genetics and genomics
  • Systems biology: large-scale experimentation and data mining
  • Microtechnologies for optical stimulation and optical recording
  • Big data, machine vision, automation
  • Developmental neurobiology, behavioral neurobiology, systems neuroscience
  • Cancer, immunology, embryonic development, stem cells

Dr. Lu’s research lies at the interface of engineering and biology. The lab engineers microfluidic devices and BioMEMS (Bio Micro-Electro-Mechanical Systems) to study neuroscience, genetics, cancer biology, systems biology, and biotechnology. These miniaturized Lab-on-a-chip tools enable us to study biology in a unique way unavailable to conventional techniques. Applied to the study of fundamental biological questions, these new techniques allow us to gather large-scale quantitative data about complex systems. Microfluidic devices are especially suitable for solving these problems because of the many advantages associated with shrinking the devices down to a scale comparable to typical biological systems. Furthermore, unique phenomena at the micro and nano length scale, such as enhanced surface effects and transport phenomena, can be exploited in designing novel techniques and devices.

In neuroscience, we are interested in how the nervous system develops and functions, and how genes and environment influence behavior. In cancer biology, we are interested in the roll of extra cellular matrix and soluble factors in cell migrations. In cancer therapy, we are interested in signal transductions for adoptive transfer. For systems biology, we are interested in large-scale experimentation and automation, and applications in neuroscience and cell biology. In general, we bring together molecular and genetic techniques and the micro devices to further our understanding of the complex biological systems. We make micro devices to investigate molecular events and signaling networks, cellular behavior, connectivity and activities of populations of cells, and the resulting complex behaviors of the animals. The ultimate goal is to bring new technologies to understand natural and dysfunctional states of biological systems and ultimately bring cures to diseases.