Faculty
-
Professor
- Physics
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
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Richard W. Kritzer Distinguished Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
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Teaching Associate Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Research in BME Education
-
- Donald Biggar Willett Professor in Engineering
- Head, Department of Bioengineering
PROF- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
- Computational and Systems Biology
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Research Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Professor of PsychologyResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
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- Grainger Distinguished Chair in Engineering
- Dean, College of Engineering
PROF- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
- Micro and Nanotechnology Laboratory
- NSF EBICS
- NSF NanoBioNode
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Research Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
- Research in BME Education
-
Associate ProfessorResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
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Founder Professor in Bioengineering and Bliss Faculty Scholar
- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Cancer Community @ Illinois
- Chemical and Biomolecular Engineering
- Chemistry
- Electrical and Computer Engineering
- Micro and Nanotechnology Laboratory
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Abel Bliss Professor of Engineering and Director of Imaging at Illinois
- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Electrical and Computer Engineering
- GSK Center for Optical Molecular Imaging
- Internal Medicine
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
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Clinical Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Research in BME Education
-
Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Research Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Research Assistant Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale
-
Hans Thurnauer Professor
- Materials Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Adjunct Professor; Charles W. Lake Jr. Professor of Engineering, Cornell UniversityResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Donald Biggar Willett Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Assistant Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
- Center for Biophysics and Quantitative Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
- Computational and Systems Biology
- Molecular, Cellular and Tissue Engineering
-
Professor
- Veterinary Biosciences
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Associate Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
- Head, Experimental Molecular Imaging Laboratory
Associate Professor- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Cancer Community @ Illinois
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor Emeritus
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Assistant Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
- Synthetic Bioengineering
-
Professor
- Cell and Developmental Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Professor
- Physics
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
TEACHING ASST PROF
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Robert W. Schaefer Professor
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
ProfessorResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
ADJ ASSOC PROFResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Donald Biggar Willett Professor in Engineering
- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Mayo-Illinois Alliance
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Founder Professor in Bioengineering
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale
- Molecular, Cellular and Tissue Engineering
-
Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Teaching Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Research in BME Education
-
Assistant Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
- Research in BME Education
- Synthetic Bioengineering
-
Assistant Professor
- Food Science / Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
ADJ PROFResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
-
Elio Eliakim Tarika Endowed Chair and Professor
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Robert W. Schaefer Professor
- Carl R. Woese Institute for Genomic Biology
- Chemical and Biomolecular Engineering
- Pathobiology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Research Assistant Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
- Research in BME Education
-
Assistant Professor
- Beckman Institute for Advanced Science and Technology
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Reid T. Milner Professor
- Bioengineering
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Adjunct Research Associate Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
- Computational and Systems Biology
-
Research AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
ProfessorResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
Associate Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
- NSF NanoBioNode
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
- Synthetic Bioengineering
-
Professor
- Chemistry
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Teaching Associate Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Research in BME Education
-
Professor and Bliss Faculty Scholar
- Bioengineering
- Brookhaven National Laboratory, Upton, NY
- Carl R. Woese Institute for Genomic Biology
- National Center for Supercomputing Applications
- Physics
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
-
Professor
- Nuclear, Plasma, and Radiological Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor
- Chemistry
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
ADJ ASSOC PROFResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
- Molecular, Cellular and Tissue Engineering
-
Grainger Distinguished Chair and Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale
-
Associate Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Assistant Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
Associate Professor Emeritus
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Associate Professor
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
ADJ ASSOC PROFResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Research AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
-
Associate Professor
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Professor
- Physics
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor
- Computer Science
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
-
Assistant Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
- Synthetic Bioengineering
-
Associate Professor
- Bioengineering
- Materials Science and Engineering
- Micro and Nanotechnology Laboratory
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale
- Molecular, Cellular and Tissue Engineering
-
Assistant Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor
- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Electrical and Computer Engineering
- Neuroscience
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
James R. Eiszner Endowed Chair and Professor
- Chemistry
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Professor
- Biochemistry
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Computational and Systems Biology
-
Research Associate Professor
- Bioengineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Computational and Systems Biology
- Molecular, Cellular and Tissue Engineering
-
Associate Professor
- Bioengineering
- Carl R. Woese Institute for Genomic Biology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Professor
- Chemistry
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
Senior Associate Consultant
- Mayo Clinic
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Founder Professor
- Beckman Institute for Advanced Science and Technology
- Bioengineering
- Electrical and Computer Engineering
- Materials Science and Engineering
- Micro and Nanotechnology Laboratory
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Chief Medical Officer
- Jump Trading Simulation & Education Center
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Associate Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Associate Professor
- Psychology
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bioimaging at Multi-Scale
-
Professor
- Mechanical Science and Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
-
Professor EmeritusResearch AreasBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
-
Professor
- Animal Sciences
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Molecular, Cellular and Tissue Engineering
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Professor
- Agricultural and Biological Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
-
Professor
- Chemical and Biomolecular Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Synthetic Bioengineering
-
Assistant Professor
- Electrical and Computer Engineering
Research AreasBioimaging at Multi-ScaleBioimaging 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 NanotechnologyBio-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 BioengineeringSynthetic 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 EngineeringMolecular, 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 BiologyComputational 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 EducationResearch in BME Education
- Bio-Micro and Nanotechnology
- Bioimaging at Multi-Scale