Description

Type

Postgraduate
Location

Philadelphia (USA)

Start date

Different dates available

The Master of Biotechnology Program prepares students, both full- and part-time, for leadership in the critically important and dynamic industries of biotechnology and pharmaceuticals. Strongly interdisciplinary, this innovative professional master's program draws its faculty and courses from the School of Arts and Sciences and the School of Engineering and Applied Science. Penn's world-class biomedical research centers, renowned science departments and position at the hub of the largest pharmaceutical/biotechnology corridor in the United States, place this program at the vanguard of biotechnology education. There are three parallel curriculum tracks: molecular biotechnology, pharmaceutical engineering biotechnology, and biomedical technologies. These tracks, in combination with core courses, insure that students get a uniquely broad exposure to the entire ﬁeld of biotechnology and give students flexibility to tailor their degree to their background, interests, and current career or career goals.

Facilities

Philadelphia (USA)

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Filadelfia, Pensilvania, 19104

Start date

Different dates availableEnrolment now open

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Subjects

Probability
GCSE Mathematics
Computational
Proteomics
Biomedical
Engineering
Systems
School
Imaging
Biomedical Science
Biotechnology
Mathematics
Biology
Credit

Course programme

Bioengineering III: Biomaterials
Principles of Biological Fabrication
Translational Therapeutics
Immunobiology
Cancer Cell Biology
Molecular Genetics
Principles of Drug Action
Advanced Cell Biology
Cell Signaling
The RNA World: A functional and computational analysis
Chromosomes and the Cell Cycle
Microbial Diversity and Pathogenesis
Cell Biology
Vaccines and Immune Therapeutics
Introduction to Bioinformatics
Fundamentals of Computational Biology
Wistar Inst Cancer Biol
Principles, Methods, and Applications of Tissue Engineering
Musculoskeletal Biology and Bioengineering
Mathematical Computation Methods for Modeling Biological Systems
Neurobiology of Learning and Memory
Genome Science and Genomic Medicine
Principles of Drug Action
The Science and Art of Biotechnology
Epigenetics
Genetics for Computational Biology
Biomolecular and Cellular Engineering
Nanoscale Systems Biology
Stem Cells, Proteomics and Drug Delivery - Soft Matter Fundamentals
Molecular Basis of Disease
Cell Biology
Emerging Infectious Diseases
Genomics
Fundamentals of Pharmacology
Engineering Biotechnology
Drug Discovery and Development
Masters Biotech Lab.
Biochemistry and Molecular Genetics Superlab
Statistics for Biologists
Introduction to Probability and Statistics

The core courses represent 6 credit units and the track electives represent 5 credit units. Students must take at least 6 credit units– between the core and electives- within SEAS courses.

500+ level Engineering; most Wharton Business 500+ level including ‘STAT;’ most School of Arts & Sciences 500+ level; and most Perelman School of Medicine 500+ including ‘BIOE’ course.

The course must have a technology, science, engineering focus and must be approved by the program prior to registration.

From Biomedical Science to the Marketplace
Biomicrofluidics
Principles of Biological Fabrication
Musculoskeletal Biology and Bioengineering
Genetics for Computational Biology
Genetic Analysis
Microbial Diversity and Pathogenesis
Macromolecular Biophysics: Principles and Methods
Biology of Stem Cells
Stress Responses in Metabolism and Cancer
Principles of Genome Engineering
Biomolecular and Cellular Engineering
Engineering Biotechnology
Nanoscale Systems Biology
Stem Cells, Proteomics and Drug Delivery - Soft Matter Fundamentals
Drug Discovery and Development
Drug Delivery
Introduction to Bioinformatics
Clinical Trials
Experimental Genome Science
Cell and Gene Therapy
Biot Independent Study 2

Students will be required to take 5 credit units of electives according to the respective requirements for that track. Most 500 level courses listed under the Core Curriculum (with the exception of the free elective classes) that are not used to ﬁll that core requirement, can fulﬁll an advanced elective requirement.

This may be done during one semester, or two semesters (consecutive or non-consecutive).

Biomechanics and Biotransport
Optical Microscopy
Biomicrofluidics
Principles, Methods, and Applications of Tissue Engineering
Network Neuroscience
Mathematical Computation Methods for Modeling Biological Systems
Translational Therapeutics
Principles of Genome Engineering
Engineering Biotechnology
Nanoscale Systems Biology
Stem Cells, Proteomics and Drug Delivery - Soft Matter Fundamentals
Drug Discovery and Development
Transport Processes I
Mathematical Foundations of Computer Science
Fundamental Concepts in Nanotechnology
Introduction to Probability and Statistics
Foundations of Engineering Mathematics - I
From Biomedical Science to the Marketplace
Musculoskeletal Biology and Bioengineering
Translational Therapeutics
Advanced Computational Biology
Macromolecular Biophysics: Principles and Methods
Genetic Principles
Drug Delivery
Programming Languages and Techniques
Engineering Entrepreneurship I
Immunopathology
Fundamentals of Pharmacology
Introduction to Drug Development
Biopharmaceutical Product Development, Manufacturing and Regulatory Affairs
New Trends in Medicine and Vaccine Discovery
Biot Independent Study

Those in this track must choose 2-3 quantitative electives and 2-3 advanced electives to make up the 5 electives. A list of suitable courses is shown, but students can request to take a different SEAS course (500+ level) as an elective that is not shown below in the area of mathematics or transport phenomena.

Biomechanics and Biotransport
Biomedical Image Analysis
Biomicrofluidics
Principles, Methods, and Applications of Tissue Engineering
Nanoscale Systems Biology
Mathematical Computation Methods for Modeling Biological Systems
Molecular Imaging
Mathematics of Medical Imaging and Measurements
Principles of Genome Engineering
Engineering Biotechnology
Drug Discovery and Development
Introduction to Bioinformatics
Fundamental Concepts in Nanotechnology
Introduction to Probability and Statistics
From Biomedical Science to the Marketplace
Bioengineering Case Studies
Fundamental Techniques of Imaging I
Musculoskeletal Biology and Bioengineering
Advanced Biomedical Imaging Applications
Genetic Principles
Drug Delivery
Programming Languages and Techniques
Engineering Entrepreneurship I
Introduction to Genetic Epidemiology
Cell and Gene Therapy
Clinical Study Management

Those in this track must choose 2-3 quantitative electives and 2-3 advanced electives to make up the 5 electives. A list of suitable courses is shown, but students can request to take a different SEAS course (500+ level) as an elective that is not shown below in the area of mathematics or transport phenomena.

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Biotechnology, MBIOT

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Biotechnology, MBIOT

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Add similar courses
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