Administration

Mark A. Anastasio
- Donald Biggar Willett Professor in Engineering
- Head, Department of Bioengineering
Donald Biggar Willett Professor in Engineering Head, Department of Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
- Bioimaging at Multi-Scale
- Computational and Systems Biology
Flordeliza Bowman
Assistant Director, Master of Engineering Program
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Maddie Darling
Assistant Director of Undergraduate Programs
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Wawrzyniec Dobrucki
- Head, Experimental Molecular Imaging Laboratory
Director of Master of Engineering Program
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
- Bioimaging at Multi-Scale
Stacy H. Fournier
Office Support Specialist
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Autumn Elaine Goodrum
Associate Director of Operations
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Michael R. Hansen
Assistant Director of Facilities
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Reginald Earl Payne, II
Academic Hourly
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Donna Shubert
Administrative Aide/Assistant to Department Head
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Andrew M. Smith
Associate Head of Undergraduate Programs
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale
- Molecular, Cellular and Tissue Engineering
Rose Smith
Office Support Specialist
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Huan Song
Assistant Director of Marketing & Communications
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
Gregory H. Underhill
Associate Head of Graduate Programs
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education
- Molecular, Cellular and Tissue Engineering
Wendy S. Woods
Lab Coordinator
- Bioengineering
Research Areas
Bioimaging at Multi-Scale
Bioimaging at Multi-Scale

Developing technologies for quantitative imaging of the structure and function of biological systems.
- Biosensors
- Multi-Scale Tissue Engineering
- Nanomedicine
- Bio-Micro/Nanotechnology
Bio-Micro and Nanotechnology

Bio-Micro and Nanotechnology

Developing molecular scale materials to Lab-on-Chip devices to sense, manipulate, and re-engineer molecular and cellular structure and function.

Synthetic Bioengineering

Synthetic Bioengineering

Forward engineering and design using biological components at all scales, both in-vitro and in-vivo, with applications in human health, and sustainability.

Molecular, Cellular and Tissue Engineering

Molecular, Cellular and Tissue Engineering

Drug delivery, stem cell engineering, development of biomaterials, and approaches for regenerative medicine aimed at improving the understanding and treatment of diseases.

Computational and Systems Biology

Computational and Systems Biology

Computational medicine, systems biology, and computational biophysics - utilizing high-performance computation, large-scale informatics, and control systems to very large-scale complex systems of cell networks to generate a new understanding of human health.

Research and BME Education

Research in BME Education

Administration

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale

Bio-Micro and Nanotechnology

Synthetic Bioengineering

Molecular, Cellular and Tissue Engineering

Computational and Systems Biology

Research in BME Education

Bioimaging at Multi-Scale