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STATE COUNCIL OF HIGHER EDUCATION FOR VIRGINIA PROGRAM PROPOSAL COVER SHEET 1. Institution George Mason University 2. Program action (Check one): New program proposal ___x__ Spin-off proposal _____ Certificate proposal _____ 3. Title of proposed program Bioengineering 5. Degree designation Doctor of Philosophy (PhD) 4. CIP code 14.0501 6. Term and year of initiation Fall 2014 7a. For a proposed spin-off, title and degree designation of existing degree program 7b. CIP code (existing program) 8. Term and year of first graduates Spring 2018 9. Date approved by Board of Visitors 10. For community colleges: date approved by local board date approved by State Board for Community Colleges 11. If collaborative or joint program, identify collaborating institution(s) and attach letter(s) of intent/support from corresponding chief academic officers(s) 12. Location of program within institution (complete for every level, as appropriate). Departments(s) or division of ____Department of Bioengineering ____________________ School(s) or college(s) of ___Volgenau School of Engineering_______________________ Campus(es) or off-campus site(s)_________________Fairfax______________________________ Distance Delivery (web-based, satellite, etc.) _____________________________________ 13. Name, title, telephone number, and e-mail address of person(s) other than the institution’s chief academic officer who may be contacted by or may be expected to contact Council staff regarding this program proposal. Joseph Pancrazio, Professor and Chair, Department of Bioengineering 703 993-1605, [email protected] TABLE OF CONTENTS PROGRAM PROPOSAL COVER SHEET .............................................................................................................1 DESCRIPTION OF THE PROPOSED PROGRAM ...............................................................................................1 OVERVIEW .................................................................................................................................................................1 CURRICULUM ............................................................................................................................................................2 COMPLIANCE WITH SACS STANDARD 3.6.2 ..............................................................................................................9 ADMISSION REQUIREMENTS .................................................................................................................................... 10 FACULTY ................................................................................................................................................................. 11 ASSESSMENT ........................................................................................................................................................... 12 BENCHMARKS OF SUCCESS ...................................................................................................................................... 14 EXPANSION OF AN EXISTING PROGRAM ................................................................................................................... 14 SPIN-OFF PROPOSAL ................................................................................................................................................ 15 COLLABORATIVE OR STANDALONE PROGRAM ........................................................................................................ 15 JUSTIFICATION FOR THE PROPOSED PROGRAM ....................................................................................... 15 RESPONSE TO CURRENT NEEDS ................................................................................................................................ 15 EMPLOYMENT DEMAND .......................................................................................................................................... 21 STUDENT DEMAND .................................................................................................................................................. 22 DUPLICATION .......................................................................................................................................................... 22 PROJECTED RESOURCE NEEDS................................................................................................................................. 25 REFERENCES ............................................................................................................................................................ 27 APPENDIX A – RESOURCES ...................................................................................................................................... 31 APPENDIX B – CATALOG DESCRIPTION OF COURSES ............................................................................................... 35 APPENDIX C – SAMPLE SCHEDULES FOR PHD IN BIOENGINEERING ......................................................................... 39 APPENDIX D- ABBREVIATED CV’S FOR THE PHD FACULTY .................................................................................... 40 APPENDIX E – DEPARTMENTAL FACULTY RESEARCH ............................................................................................. 43 i DESCRIPTION OF THE PROPOSED PROGRAM Overview George Mason University requests approval to initiate a Doctor of Philosophy (PhD) degree in Bioengineering. The proposed program will be administered by the Volgenau School of Engineering with participation from other academic units with related interests at the university. The program is to be started in the Fall of 2014. The proposed program is designed to prepare future leaders in bioengineering. The traditional definition of bioengineering, here used synonymously with biomedical engineering, is to use engineering techniques to solve problems in biology and medicine. Initially, the field concentrated in areas closely linked to traditional areas of engineering, such as designing instruments for the diagnosis of disease, building implanted devices to restore function, and developing equipment to aid individuals with disabilities. More recently, rapid advances in understanding the molecular bases of disease has led to bioengineering embracing new methodologies that combine modern biology, physics, computer science, and engineering. Bioengineers thus need to be prepared to integrate advanced tools to advance human health (1,2,3). Advancing human health, however, has resulted in societal challenges. The most widely discussed one is the cost of health care that has been increasing at an exceptionally rapid rate. Hardly a day goes by without being reminded that escalating health care costs are a burden to individuals, their employers, and the nation. Due to the power of technology, bioengineers thus must become part of making health care not only better, but to make it more efficient and affordable. The proposed program is a major step to enabling the bioengineering profession to respond to societal demands for better and more efficient health care. It is well aligned with the George Mason University’s mission statement: "Educate the new generation of leaders of the 21st century men and women capable of shaping a global community with vision, justice, and clarity." "Provide innovative and interdisciplinary undergraduate, graduate, and professional courses of study that enable students to exercise analytical and imaginative thinking and make well-founded ethical decisions." This proposed doctoral program is a follow-up to the initiation of an undergraduate program in 2010. The BS in Bioengineering program, with a current enrollment of approximately 120 undergraduates, is administered by the Volgenau School of Engineering through its new Department of Bioengineering that was established in 2011. The department has 11 full time faculty members, with 8 holding primary appointments in Bioengineering. Although the Volgenau School of Engineering is well positioned and able to plan and administer a graduate program in bioengineering, it decided to plan the proposed doctoral program in collaboration with other departments and schools at the University. This decision was made in 1 recognition of the need to integrate multiple disciplines within the curriculum and to avoid duplication and reduce overall cost of program implementation. The nature of the proposed program is in agreement with a recent report of the National Academy of Engineering: The Engineer of 2020 (4). The report forcefully advocates engineering education that is broad, interdisciplinary, and responding to societal needs. The proposed program targets the development of doctoral-level bioengineers since they are the ones who will be future leaders of the field. They are the ones who will lead research teams that generate basic knowledge for the development of appropriate technology, who will be in charge of many interdisciplinary teams in industry, who will provide intellectual leadership for setting policy for technology usage and regulation, and who will educate the rapidly increasing number of bioengineering undergraduates. The need for well-educated bioengineers is underlined by the Bureau of Labor Statistics that in 2012 projected a “much faster than average” increase in bioengineering employment between 2010 and 2020 (5). The program is designed to attract talented students with a BS degree who have already demonstrated high achievement in a relevant area of science and/or engineering. They also will be expected to have demonstrated interest in combining engineering and the natural sciences with discovery and application in the life sciences. An unique feature of the proposed program is that it expects to attract similarly motivated students with a wide variety of skills. The program is designed not only to deepen expertise and skill in a focus area of the student’s choice, but to also give them an opportunity to broaden their knowledge through meaningful interactions with their peers. They learn not only from faculty but from each other. George Mason University has demonstrated major commitment to Bioengineering, and the proposed program would further help it to further fulfill its commitment. A doctoral program would make it even more attractive to recruiting and retaining gifted and dedicated researchoriented faculty members, and it would also draw highly qualified students to its programs. It would provide an example of a forward-looking and unique program that is likely to benefit not only Mason but that would bring recognition to Virginia. It is also expected to bring public health improvements and further economic development to the Commonwealth and the nation. Curriculum Process The curriculum was designed after formulating the overall objective and the desired outcomes of the doctoral program. (These are described in the Assessment section under JUSTIFICATION OF THE PROPOSED PROGRAM.) It satisfies the university’s broad requirements for doctoral programs (6), as well as the Volgenau School’s guidelines that allow considerable flexibility for setting requirements by the individual programs (7). Consistent with the breadth of multidisciplinary science underlying bioengineering, the program was designed with input from faculty members from other academic units including but not limited to the College of Science. 2 The close interaction will continue to be reflected in the administration of the program. The Department of Bioengineering within the Volgenau School of Engineering is ultimately responsible for the proposed doctoral program. The Department will rely substantively on its Graduate Committee to provide recommendations regarding admissions, curricula, courses, and examinations. The Graduate Committee will consist of 3 faculty members from Bioengineering, and at least one from each of the cooperating Schools/Colleges. The program benefits from the contributions of colleagues from outside the Volgenau School, while the cooperating colleges benefit from access to a talented pool of graduate students and to new courses that are of interest to their own students. Faculty members in the cooperating academic units can serve as primary research advisors to Bioengineering doctoral students; they are also encouraged to serve as members of doctoral research committees. Each committee is expected to have at least two faculty members with primary appointment in Bioengineering. Following are the primary university-mandated requirements for doctoral degrees (6): Candidates must earn a minimum of 72 graduate credits, which may be reduced by a maximum of 30 credits from a completed master’s degree or other suitable, approved transfer work. Only graduate courses may apply toward the degree. More than half of all credits (minimum 72) must be taken in doctoral status, after admission to the degree program. Candidates must pass a written or oral doctoral qualifying exam and a doctoral candidacy exam. Candidates must complete a minimum of 12 credits of doctoral proposal (BENG 998) and at least 3 credits of doctoral research (BENG 999). A maximum of 24 credits of 998 and 999 may be applied to the degree. Candidates must pass a final public defense of the doctoral dissertation Candidates must have a minimum GPA of 3.0 in course work presented on the degree application, which may include no more than 6 credits of C. Core requirements The proposed doctoral program consists of a minimum of 72 credit hours, distributed among the following categories of courses: Core Science (9 credits), Core Bioengineering (6 credits), Concentration Courses (18 credits), Dissertation Research (24 credits), and Electives (12 credits). Concentrations will include: neuroengineering, biomedical imaging, data-driven biomechanical modeling, and nanoscale bioengineering. All courses that were specifically created for this new degree program are in bold, and descriptions for the core courses and required concentration courses are provided in Appendix B. 3 Core Science (9 credits): Biology Core (3 credits; select one from pool): o BIOL 682 - Advanced Eukaryotic Cell Biology (3 credits) o BMED 601 - Cell and Molecular Physiology (3 credits) o RHBS 710 - Applied Physiology I (3 credits) Computation/Mathematics Core (6 credits; select two courses of the following): o MATH 685 - Numerical Methods (3 credits) o ECE 528 - Introduction to Random Processes (3 credits) o ECE 535 - Digital Signal Processing (3 credits) Core Bioengineering (6 credits): BENG 501 - Bioengineering Research Methods (3 credits) BENG 551 - Translational Bioengineering (3 credits) Technical Electives (15 credits): These courses are intended to provide students with pre-requisites necessary to pursue upperlevel courses that support the concentrations described below. These courses can include no more than 6 credit hours outside the Engineering School and a maximum of only 6 credits can be at the 500-level. Additional Training and Education 4 Ethics Training: Collaborative Institutional Training Initiative (CITI) Responsible Conduct of Research course. CITI training modules provide students with an understanding of conflicts of interest, research misconduct, peer review, authorship, etc. Bioengineering Seminar: required attendance and participation in a minimum of 3 departmental seminars per semester. Translational Bioengineering Mentorship: Following successful completion of BENG 551, each PhD student is required to co-mentor with a Bioengineering faculty member an undergraduate Bioengineering senior design team. The PhD student will apply business, team work, and entrepreneurship concepts through biweekly meetings with the design team over two academic semesters. Competency will be demonstrated through faculty evaluation of the mentorship performance and/or satisfactory performance on senior design team student surveys. Teaching Requirement: Each PhD student is required to participate in the department's teaching activity and demonstrate competency. The requirement is typically satisfied by working as a recitation instructor for one semester or presenting several lectures within a course. Competency is demonstrated through either faculty evaluation of the teaching performance and/or satisfactory performance on student surveys of teaching performance. Concentration Courses: Students must choose one of four areas offered by the program, each of which is described below. These four concentration areas were chosen as they constitute important growth areas for the bioengineering field, reflect the expertise of the Mason faculty, and provide unique educational opportunities for bioengineering PhD students within the Commonwealth. Courses offered under each concentration are designed to provide an in-depth understanding for each area. Students must complete 18 credit hours within the concentration consisting of both required and elective courses. The elective courses within each concentration must be chosen under the guidance and approval of the students’ advisors. Concentrations Doctoral students choose an approved concentration that reflects important areas of bioengineering research. Since the field of bioengineering is very broad, we have implemented concentration areas that leverage faculty expertise to assure that students receive a first-rate educational experience both in course-work and research. The concentrations consist of a set of three required classes and three upper-level elective courses within the field of study that are selected to complement the research and educational experience of the student. All classes listed are 3 credit hours unless otherwise noted. Currently approved concentration areas and their requirements are: Neuroengineering Neuroengineering involves the use of engineering and computational techniques to understand neurological function, develop technologies to interface with the neural systems, and design engineering solutions to restore neurological function lost due disease or injury. This field of bioengineering draws on the fields of computational neuroscience, experimental neuroscience, electrical engineering and signal processing. The overall goal is to prepare students to become independent investigators who are capable of answering important and emergent questions in neuroscience through the use of engineering and computation. Required: BENG 525 – Neural Engineering NEUR 602 - Cellular Neuroscience BENG 725 - Computational Motor Control Three more upper-level courses are to be chosen under the guidance and approval of the student’s advisor. At least two of the three classes must be at the 700-800 level: BENG 636 - Advanced Biomedical Signal Processing BENG 820 – Seminar in Neuroengineering BINF 740 - Introduction to Biophysics CS 688 - Pattern Recognition ECE 738 - Advanced Digital Signal Processing NEUR 634 - Computational Modeling of Neurons and Networks NEUR 701 - Neurophysiological Laboratory 5 NEUR 734 - Computational Neurobiology NEUR 735 - Computational Neuroscience Systems NEUR 751 - Applied Dynamics in Neuroscience NEUR 752 - Modern Instrumentation in Neuroscience PSYC 701 – Cognitive Bases of Behavior PSYC 768 - Neuroimaging Biomedical Imaging Biomedical imaging involves the use of engineering techniques in order to develop medical imaging systems, including both the acquisition of medical images and their processing in order to support assisted diagnosis and monitoring techniques. This field of bioengineering draws on the fields of medical physics, signal and image processing, statistics, pattern recognition and machine intelligence. This curriculum aims to develop a knowledge base for medical imaging with an emphasis on imaging physics, image processing and machine learning techniques. The overall goal is to prepare the students to become independent investigators who are capable of answering important and emergent questions in the field of medical imaging, in terms of technology development, application, and data analysis. Required: BENG 538 - Medical Imaging Physics ECE 537 - Introduction to Digital Image Processing (DIP) BENG 738 - Advanced Medical Image Processing Three more upper-level courses are to be chosen under the guidance and approval of the student’s advisor. At least two of the three classes must be at the 700-800 level: BENG 636 - Advanced Biomedical Signal Processing BENG 830 – Seminar in Biomedical Imaging CS 659 - Theory and Applications of Data Mining CS 688 - Pattern Recognition CS 757 - Mining Massive Datasets ECE 738 - Advanced Digital Signal Processing ECE 754 - Optimum Array Processing OR 842 - Models of Probabilistic Reasoning PHYS 612 - Physics of Modern Imaging PSY 757 - Introduction to Bayesian Statistics PSY 768 - Neuroimaging STAT 760 - Advanced Biostatistical Methods SYST 842 - Models of Probabilistic Reasoning Data-Driven Biomechanical Modeling Biomechanics involves the use of engineering concepts to (1) measure and describe functions of biological structures, (2) develop computational models to simulate forces acting on and within living systems, and (3) design engineering solutions to improve human movement compromised by disease or injury. Data Driven Biomechanical Modeling leverages multivariate data acquisition to create computational models that predict biomechanical dynamics. This area in 6 Bioengineering draws on the fields of mechanical engineering, imaging, physics, rehabilitation, physiology, and medicine. The overall goal is to prepare students to not only be able to generate computational models of human dynamics, but also parameterize these models with the acquisition of experimental data. This approach enables personalized medicine through the creation of computational models tailored to individuals with disease or disability. Data sources include non-invasive bioimaging modalities such as ultrasound and MRI, electromyography, 3D motion capture and force plates. Required: BENG 538 Medical Imaging Physics BENG 650 - Advanced Biomechanics BENG 750 - Modeling and Simulation of Human Movement Three more upper-level courses are to be chosen under the guidance and approval of the student’s advisor. At least two of the three classes must be at the 700-800 level: BENG 636 - Advanced Biomedical Signal Processing BENG 738- Advanced Medical Image Processing BENG 725 - Computational Motor Control BENG 850 - Seminar in Biomechanics CS 795 - Measurement of Human Movement CSI 742 - The Mathematics of the Finite Element Method RHBS 711 - Applied Physiology II RHBS 746 - Neuromusculoskeletal Disability STAT 662 - Multivariate Statistical Methods SYST 664 - Bayesian Inference and Decision Theory Nano-Scale Bioengineering Most biological processes are transient in nature and originate at the cellular or even sub-cellular level. Nano-scale bioengineering combines interdisciplinary concepts of engineering at micro- or nano-scale to address biological problems. It offers the ability to monitor, manipulate and characterize biological systems under controlled in vitro conditions. Utilizing nanoengineered materials and devices, non-invasive techniques can be developed to understand and treat diseases in a completely novel fashion compared to the traditional biomedical approaches. Based on identification of the current leading research areas, medical and industrial needs, the curriculum involves a balanced structure of theoretical, experimental and computational components. Through the following courses, students will learn the concepts of fluid mechanics which will allow them to design and create microdevices and study biological problems at the cellular and physiological levels. Ultimately, nano-scale bioengineering will provide a solid theoretical background and practical experience in diverse areas such as tissue engineering, biopharmacy and diagnostics. 7 Required: BENG 541 - Biomaterials BENG 641 - Advanced Nanotechnology in Health BENG 745 - Biomedical Systems and Microdevices Three more upper-level courses are to be chosen under the guidance and approval of the student’s advisor. At least two of the three classes must be at the 700-800 level: BENG 840 - Seminar in Nano-scale Bioengineering BINF 740 - Introduction to Biophysics BIOL 669 - Pathogenic Microbiology CHEM 641 - Solid State Chemistry CHEM 660 - Protein Biochemistry CHEM 728 - Introduction to Solid Surfaces CHEM 733 - Polymer Physical Chemistry CHEM 814 - Advanced Bioorganic Chemistry CHEM 833 - Physical Chemistry and Biochemistry CSI 780 - Computational Physics and Applications CSI 720 - Fluid Mechanics NANO 620 - Computational Modeling in Nanoscience Dissertation Research Students are expected to complete 24 credits of BENG 998 and BENG 999 towards their degree. Students cannot enroll in BENG 999 before they have advanced to candidacy. Students advanced to candidacy after the add period for a given semester must wait until the following semester to register for BENG 999. Students cannot advance to candidacy and defend their dissertation during the same semester. Once enrolled in BENG 999, students must maintain continuous registration in BENG 999 each semester until graduation, excluding summers. Students who defend in the summer must be registered for at least 1 credit of BENG 999 during that summer term. BENG 998 - Doctoral Dissertation Proposal (Credits: 1-12; student must complete a minimum of 9 credits) BENG 999 - Doctoral Dissertation (Credits: 1-12; student must complete a minimum of 3 credits) Student Progress and Advising The typical time course of completing the program is shown in the sample schedules in Appendix C; academic and research advisors are responsible for providing students with guidance about their progress through the program. 8 After acceptance, students are assigned an academic advisor who is a member of the Bioengineering Department. As students familiarize themselves with Mason and they develop specific research interests, they need to choose a research advisor. If the research advisor is a faculty member in Bioengineering, the same person typically also becomes the student’s academic advisor. If the research advisor is not a faculty member of the Bioengineering Department, the student typically retains his or her own academic advisor, benefiting from both advisors. Qualifying Exam All students entering the Bioengineering PhD program will be required to pass a qualifying exam which consists of two phases: a Technical Qualifying Exam (TQE) and a Research Qualifying Exam (RQE). The TQE is an in-class written exam that tests knowledge of core bioengineering concepts as well as competency in mathematics and computation. A score of at least 80% is required to pass. The RQE consists of a written report and oral presentation and aims to assess the ability of the student to communicate effectively. Students will be required to define a research problem and explain the significance, critically review the literature related to the research problem, describe appropriate research methods to study the problem, and interpret and communicate their results. The RQE topic will be defined by the faculty advisor in consultation with the student. The topic may be related to the eventual thesis topic. A committee of at least three faculty members which includes the advisor will evaluate the written report and the oral presentation. During the presentation the student will be expected to answer questions about their project and about fundamental concepts related to the research. The committee will vote to determine whether or not the student has successfully passed the RQE. Students entering with an MS degree will take the TQE within their first year in the program and the RQE prior to completing 12 credits in the PhD program. Students entering with a B.S. degree will take the TQE after completing 18 credits of coursework and the RQE prior to completing 36 credits in the program. After a student has taken both the TQE and the RQE, the Bioengineering PhD Committee will review the exam results, the student's transcript, and a letter of recommendation from the student's advisor. Based on this information, the PhD Committee will determine whether or not the student is qualified for the PhD program. If the student does not qualify on their first try, the student will be allowed to repeat one or both of the exams in the following year. The TQE and RQE may be repeated once. A student who fails to qualify on their second try will be removed from the program. Compliance with SACS Standard 3.6.2 The proposed program complies with SACS standard 3.6.2: The institution structures its graduate curricula (1) to include knowledge of the literature of the discipline and (2) to ensure ongoing student engagement in research. In Table 1, relevant courses for these two standards are identified. While the proposed Bioengineering PhD program draws upon a range of existing upper-level graduate courses to provide a comprehensive educational experience for students, the table below emphasizes Bioengineering (BENG) courses. In addition to the coursework, the 9 proposed program requires students to pass a written comprehensive exam prior to advancement to candidacy. The comprehensive examination requires a thorough knowledge of the literature in Bioengineering. A Dissertation project is also a requirement of the proposed degree program. Thus, a substantial independent research project must be completed and defended. Course Knowledge of the Literature BENG 501: Bioengineering Research Methods X BENG 525: Neural Engineering X BENG 538: Medical Imaging X BENG 541: Biomaterials X BENG 551: Translational Bioengineering X BENG 641: Advanced Nanotechnology in Health X BENG 636: Advanced Biomedical Signal Processing X BENG 725: Computational Motor Control X BENG 738: Advanced Medical Image Processing X BENG 745: Biomedical Systems and Microdevices X BENG 820: Seminar in Neuroengineering X BENG 830: Seminar in Biomedical Imaging X BENG 840: Seminar in Nano-scale Bioengineering X BENG 850: Seminar in Biomechanics X BENG 998: Doctoral Dissertation Proposal X BENG 999: Dissertation Research X Table 1. Bioengineering Courses that Address SACS Comprehensive Standard 3.6.2 Research X X X X X X X Admission Requirements Applicants to the proposed program must fulfill university-specified graduate application requirements specified in detail by Mason’s catalog (6). Requirements for the Volgenau School of Engineering are flexible, allowing programs to formulate requirements in addition to those of the university (7). Accordingly, the proposed program will require submission of the following documents for considering admission: Completed Application for Graduate Study Official transcripts from all prior colleges or universities attended Goals statement Three letters of recommendation Official GRE exam scores The submitted documents are used to determine whether an applicant meets the program requirements. These requirements have been selected to assure that admitted students have a strong scientific or engineering background, have a high potential of earning a doctorate in the 10 proposed bioengineering program, and are likely to be successful as future bioengineering leaders. The required qualifications are thus as follows: BS degree in engineering or the sciences relevant to the doctoral program. A GPA of at least 3.3 is expected, which is higher than the university-mandated 3.0. Demonstrated interest in combining engineering and the natural sciences with discovery and application in the life sciences. Examples of demonstration include a degree that reflects the desired combination (such as bioengineering, biophysics); a degree in engineering or the natural sciences but also having taken courses in the life sciences; a degree in biology but also having taken courses in mathematics, physics, or engineering; having had project or research experience that combined complementary expertise. Past experience and recommendation letters indicating likely success in studies for a doctorate in bioengineering. Past experience, recommendation letters, and/or goals statement indicating genuine interest in benefiting society through leadership in research or the application of research to human health. Students will also be required to submit GRE scores. The minimum GRE scores fpr admission will be 75th percentile in the quantitative section, with 50th percentile on the verbal and quantitative sections. International students are required to also submit a TOEFL score as required by George Mason University. The minimum TOEFL score for the proposed program will be 80, which is consistent with the new requirements for the Volgenau School of Engineering. The submitted materials will be reviewed by the Graduate Committee of the Bioengineering Department which will then make a recommendation to the department chair. The Committee will also determine the number of credits the applicant is to be given if he or she applies with an MS degree or has taken previous courses in a relevant graduate program. The maximum number of credits that may be transferred is 30. As mentioned above, the Graduate Committee will consist of three full-time members of the Department, as well as at least one full-time member from each of participating School of College. Involvement of these participants is essential for assessing the applicants’ expertise and their prospects for conducting studies in areas where the primary research strength at Mason is outside the Volgenau School. Faculty The proposed program will be served by a diverse and superbly qualified faculty. As part of its initiative in bioengineering, The Volgenau School recruited 1 part time and 10 full time faculty members since 2006. The home-department of each was determined by the “best-fit” and the candidates’ preferences. The following are the home departments for the current bioengineering faculty: 11 Bioengineering: 8 full time, 1 part time Computer Science: 2 full time Electrical and Computer Engineering: 1 full time In addition, the proposed program has the participation of several other faculty members in academic units outside of the Department if Bioengineering. These faculty members have backgrounds in a variety of mathematical, physical and life sciences and will provide additional educational and research opportunities to bioengineering students. They offer courses, provide research opportunities, participate in program planning, and help make admission decisions. They have all ascertained their interest in being affiliated with the proposed program. The academic units of current affiliated faculty members are the following: Dean’s Office, Volgenau School of Engineering Department of Computer Science, Volgenau School of Engineering Department of Molecular Neuroscience, College of Science & Krasnow Institute Department of Psychology, College of Science Div. of Health and Human Performance, College of Education and Human Development School of Physics, Astronomy, and Computational Sciences, College of Science School of Systems Biology, College of Science Appendix D gives a brief description of current faculty members associated with the proposed doctoral program. This list is expected to be dynamic; it will change as new faculty members are recruited and as research interests change. Recognizing a new affiliate faculty member requires the approval of the BE faculty and current affiliate faculty. A measure of the faculty’s capacity to support doctoral-level research is external funding. The Bioengineering faculty members from within the Volgenau School of Engineering hold grants from prestigious federal agencies including the NIH, NSF, and DARPA. A detailed description of currently funded research programs is provided in Appendix E. Assessment The overall objective of the program is to educate future bioengineering leaders who will contribute substantially to improving health through research, education, business or government service. Since assessing the achievement of this overall goal would require some eight to ten years (examining education and career), desired outcomes are needed that can be assessed on a more realistic time scale. These outcomes are formulated as desired results of the educational program that can be examined as the program is being implemented. The outcomes thus can be used to serve as the basis of making continuous improvements to the program. The program expects to achieve the following outcomes that will contribute to the graduates becoming leaders in bioengineering: 12 Graduates, relying on a strong understanding of the life sciences, will demonstrate the ability to formulate and perform research that addresses significant health-related problems. Graduates will have a strong background in areas such as mathematics, physics, engineering, and computer science to allow them to perform, lead, or evaluate research that uses advanced quantitative techniques to solve health-related problems. Graduates will have had experience in making, planning and/or interpreting biomedical measurements. Graduates will understand their responsibility to publish results and share knowledge, and they will communicate effectively as speakers, writers, and educators. Graduates will understand the need for translating research results into devices or procedures that will benefit society. Thus, they will be familiar with such concepts as commercialization, entrepreneurship, intellectual property, regulation, safety, value, effectiveness, efficiency, and cost. Assessing the achievement of these outcomes is a two-stage process. The first is conducted during and after selected courses that address these outcomes. Course instructors will assess the degree of progress toward achieving relevant outcomes on a scale of 5 (excellent) to 1 (poor) for each student. These achievement scores will be given on the basis of the students’ performance on tasks specifically related to one of the outcomes, and they are assigned in addition to the regular letter grades. The second stage is aggregating the achievement scores assigned in the courses, and evaluating the overall achievement of the outcomes. This is done annually at the end of the academic year by a special joint meeting of the faculty and the Bioengineering Graduate Committee. At this meeting the faculty considers, for each doctoral student, the achievement scores in each course taken during the year. It also considers comments made by the student’s advisor(s) and any other faculty member(s). Following discussion, the faculty will determine an overall achievement score for each outcome, and determine if any action is needed that might improve the student’s achievement. Following the evaluation of individual students, the faculty will consider the effectiveness of the program itself to help students achieve the desired outcomes. This consideration will consider issues such as topics in individual courses, scheduling of courses, prerequisites, effectiveness of teaching, performance in research, and methods of determining outcomes. Based upon the discussion, ways of improving the programs will be adopted in the expectation that the changes will enhance the achievement of the desired outcomes. Evaluating the program objective will be made for the first time three years after graduating the first student. Since achieving this objective is Benchmark #7, its assessment is described in the next section. 13 Benchmarks of Success The faculty of the proposed program has adopted the following benchmarks of success: 1. At least 4 students will enroll in each of the first two years of the program. New enrollment will be at least 6 students each year in subsequent years. 2. 60% of students who enroll earn a doctorate within 5 years. 70% earn a doctorate within 6 years. 3. Each student will have achieved a score of 3 on at least four of the five outcomes during each annual evaluation. 4. On each outcome, at least 70% of students achieve a score of 3 or better. 5. At least 80% of the students will have found a job or postdoctoral position within 3 months of graduation. 6. At least 70% of the graduates will have a leadership position within five years of graduation, contributing substantially to improving health through research, education, business or government service. The achievement of these benchmarks will be assessed annually at the same faculty meeting that is used to assess the achievement of outcomes as described in the previous section. Two of these (#3 and #4) are clearly linked to the outcomes and are readily available from their assessment. The process of determining whether benchmarks #1, #2, and #5 are met will be based on readilyavailable or obtainable numeric information. Determining whether benchmark #6 is met is much more difficult. It can be performed for the first time only 5 years after the graduation of the first student, and it must depend on information received from the career path of the graduates. The information will include a then current curriculum vitae, as well as responses to a survey that deals with the graduates’ self-assessment of their careers and academic preparation. Attention will be given to maintain continuous contact with the graduates since their help and collaboration is essential for continuous program improvement. Judging whether a graduate is in a “leadership” position and whether he or she contributes “substantially” is subjective. Consequently, the faculty’s evaluation of meeting benchmarks will be shared with the Bioengineering Advisory Committee that includes representatives from the program constituents: universities, industry, and government. Final action on correcting any shortcomings an/or improving the program will be made taking into action the Committee’s feedback. Expansion of an Existing Program 14 The proposed program is new and not an extension of an existing one. Spin-off Proposal The proposed program is new and not a spin-off from an existing one. Collaborative or Standalone Program This is a standalone program developed and operated by George Mason University. No outside organization was involved in its development, and no other organization is responsible for its operation. JUSTIFICATION FOR THE PROPOSED PROGRAM Response to current needs This section first gives a brief overview of the relatively new field of bioengineering, often interchangeably referred to as biomedical engineering, and how bioengineering is changing along with engineering in general. It then describes the challenges that the nation's health care system faces and the role that bioengineers can play in meeting them. The section emphasizes the economic and social reasons why the Commonwealth of Virginia needs to play a role in educating bioengineers leaders who will advance knowledge, contribute to economic development, and help solve health care problems. The section concludes by showing why Mason is uniquely positioned to initiate a doctoral level bioengineering program of major benefit to the Commonwealth and the nation. What is bioengineering? According to the Biomedical Engineering Society, “A Biomedical Engineer uses traditional engineering expertise to analyze and solve problems in biology and medicine, providing an overall enhancement of health care" (8). Similar definitions of the field are given by numerous other sources (9,10,11). Such a definition dates back to the field’s beginning in the early 60’s when a few institutions initiated degree-granting programs in biomedical engineering or bioengineering. Typically, using techniques used by electrical or mechanical engineering, the stated purpose of the programs was to bring “engineering rigor” to biology by adding quantitative approaches to a field considered primarily descriptive. Thus, much work was done on recording and analyzing signals derived from the human body, such as the electrocardiogram, electroencephalogram, electromyogram, that give diagnostic information on the heart, brain, and muscles, respectively. The descriptions often relied on models that used mathematical approximations to characterize the living system. The rapid development of new modes of imaging, including CAT (three-dimensional X-ray), MRI, and PET, has resulted in additional ways to quantify the structure and function of the body. Devices that improve or replace 15 function, such as pacemakers, cochlear implants, and prosthetic limbs, have benefited individuals living with disability. The major role of bioengineering as a contributor to human health is reflected in the field's current definition by the National Institute of Biomedical Imaging and Bioengineering (12) of the National Institutes of Health, the nation’s premier health-related research institution with an annual budget of over $30 billion. According to this definition: "The discipline of biomedical engineering lies at the forefront of the medical revolution. Advances in biomedical engineering are accomplished through interdisciplinary activities that integrate the physical, chemical, mathematical, and computational sciences with engineering principles in order to study biology, medicine, and behavior." After giving examples of technological developments similar to those above, the definition concludes: "The goal of bioengineering is to promote biomedical advances to diagnose and treat disease and to prolong a healthy and productive life." The changing nature of engineering The societal linkages of technology and health care were mentioned among the reasons for the recommendations of an influential report by the National Academy of Engineering, The Engineer of 2020 (4). The Executive Summary of the report states that “[t]he steady integration of technology in our public infrastructures and lives will call for more involvement by engineers in the setting of public policy and participation in the civic arena.” (p 4) The report concludes that engineering must not be a narrow, strictly technology-oriented profession, but that the engineers of the future must have an exposure to a wide array of disciplines. The engineering community has endorsed the recommendations. The Harvard Crimson proudly stated (13) that the university’s “push to expand its Division of Engineering and Applied Science, begun in 2001, falls directly in line with recommendations released this past June by the National Academy of Engineering” that “called for engineering departments to widen their focus and to include more interdisciplinary work, both in research and teaching”. Since both research and teaching are performed primarily by doctoral-level graduates, the need is especially acute at this level. Likewise, a recent editorial in the Annals of Biomedical Engineering, the official journal of the Biomedical Engineering Society, stated that “[a]s biomedical engineers, we are asked to interact and work well with those in other areas. … Our graduates need to know not just the engineering aspects of a problem, but also its physiological, biological, business, regulatory, and legal facets” (3). Again, the complexity of the task requires a doctoral-level educational program with breadth that can meet the stated need. The proposed doctoral program in bioengineering is a response to the challenge raised both by the National Academy of Engineering, as well as by the Annals of Biomedical Engineering. We aim to train the next generation of bioengineering leaders. What are the current needs? 16 Although health care is improving due to advances in both biology and technology, there are major challenges. The following describes four of them. Biomedical research at multiple interfaces Basic discoveries in the life sciences are made at an unprecedented pace, increasingly aided by natural scientists, mathematicians, and engineers. Discovery of the molecular structure of the DNA, our genetic code, and the way it is translated into proteins, the building blocks of living organisms, has revolutionized our understanding of the origin of many diseases. It is now known, for example, that some abnormalities are caused by a specific single alteration in the DNA code, and some by a complex pattern of changes (14). Understanding of the underlying cause, however, does not imply easy remedy. A wrong protein that is generated by a mistake in the genetic code causes cell alterations that also alter the tissues that are formed by the aggregation of cells. Altered tissue leads to altered organs, possibly causing debilitating diseases. The complex transformation from DNA to proteins, to tissues, and then to organs is further complicated by the significant influence of the environment on the transformation. Understanding such staggering complexity and devising new therapies requires new skills for bioengineers. They may be called upon to design instruments for making measurements on cells, tissues, or organs, and to devise technologies for studying or controlling molecular to organ-level processes. As opposed to the traditional methods of studying and attacking problems at a single level, multi-level approaches are needed to derive optimum benefit (15,16,17). For example, it is no longer sufficient to study molecular-level alterations of protein structures: eventual clinical applications require that the effects of molecular alteration be followed to tissue and organ system levels where clinical abnormalities are often first identified. Bioengineers are thus needed to conduct basic research at many stages, often in collaboration with biologists and physicians, to determine the best technological approaches for experiments, find patterns in the data, and to develop and then test models. For example, silicon-based gene chips are used to identify molecular abnormalities that are associated with diseases (18), imaging and computational technologies now allow visualization of structures at molecular, cellular, and tissue levels that suggest new diagnostic and therapeutic methods (19,20), and computer-aided searches of huge amounts of data can serve as the basis for discoveries (21). The critical role of bioengineers was emphasized in a 2009 Science editorial, The Next Innovation Revolution, by Susan Hockfield, President of the Massachusetts Institute of Technology (22). She wrote: “These revolutions [convergence between engineering and the physical sciences, discovery of the structure of DNA] sowed the seeds of a third revolution that links the life sciences with engineering and the physical sciences in powerful new ways.” The proposed program will generate bioengineers who will respond to this revolution in a thoughtful, responsible, and expert manner, becoming leaders and educators of their profession. 17 Appropriate use of technology in medicine. Because of increasing knowledge, patients face a great variety of devices and procedures when they are being diagnosed or treated. Their organs are often monitored electrically, chemically, mechanically, and visually when being diagnosed. Therapy likewise includes technological interventions. Patients who are disabled by disease, accident, or war are often helped by sophisticated wheelchairs, as well as by implants designed to restore function (23,24). Pacemakers have been used for decades to initiate heartbeats, and cochlear implants are increasingly used to improve hearing (25). Deep brain stimulation has led to dramatic improvements in some patients with Parkinson's disease (26), and research is advancing to restore vision through retinal or brain implants (27), and using closed-loop control of epilepsy by transcranial electrical stimulation (28). A new approach to treating chronically elevated blood pressure that does not respond to medications is the RF ablation of the sympathetic nerve to the kidney (29). In addition to these primarily technology-based developments, biological discoveries have introduced a whole new area of diagnostic and potential therapeutic procedures that are molecular and cell-based. Genetic testing is used to identify the type of cancer that may respond to a particular class of drugs (30), and there are efforts to treat Type I diabetes by implanting properly encapsulated insulin-producing beta-cells into the diseased pancreas (31). Efforts are also underway to use stem cells implanted into the damaged myocardium in the expectation that they may be coaxed into becoming healthy muscle cells (32). While many of these devices and potential approaches are helpful or even life-saving, others may be of questionable utility. Is it beneficial, for example, to have an instrument that increases the accuracy of a measurement by 2%? Of course, it depends on many factors, including whether the improved accuracy would materially influence the choice among treatment options. If so, what is the benefit and cost to the patient of each possible treatment? If the treatment is costly, are there alternative measurements that may provide diagnostic information that do not require such a high precision? An ability to answer such questions is essential while debates about the future of the US health care system are prevalent, and when the rapid increase in health care costs, now approximately 18% of GDP is a major societal concern (33,34). Although some say that it is the cost of technology that is at least partially responsible, others argue that it is the inappropriate use of technology such as multiple and unnecessary tests, and "trial and error" approaches of therapy. Regardless, it is now imperative that improvements in health care be accompanied by recognizing their costs. It is thus no longer acceptable to develop a device or procedure that performs "better", it must perform better in a “cost-effective” way. Any analysis of cost-effectiveness must consider the question: “Cost for whom?” The answer may be different for the patient, hospital, insurance company, state, or society. While the bioengineer may not be an expert in all relevant areas, he or she must be able to ask the right questions, and evaluate the answers in a critical manner. Bioengineers of the future, especially those in leadership positions, must use their knowledge of technology, biology, and cost consciousness to bring about value, taking into account medical benefit as well as cost to patient and society (35). 18 One of the expectations is that "personalized medicine" will go a long way toward delivering more cost-effective health care (36). This approach uses genetic analysis to diagnose the patient's disease accurately and with great specificity, and then suggest the most appropriate treatment based on that analysis. The approach relies heavily on technology, involving gene or protein microarrays for data acquisition, analyzing the data by powerful computational techniques, and developing drugs, processes or devices that target the disease on a scientifically sound basis. In his book, "The Language of Life: DNA and the Revolution in Personalized Medicine”, Francis Collins, Director of the National Institutes of Health, gives an excellent description of how patient health can be improved by practicing such “personalized medicine” (14). Such therapy would avoid the usual trial and error process, speed recovery, and reduce costs by avoiding ineffective therapies. Informed decisions about appropriate technology to serve a medical need must integrate technological, biological, and societal information relevant to the question; they cannot be made on the basis of just one consideration alone. In many cases it is the modern bioengineer, having had an education that stressed the need for cross-disciplinary integration, may be the best equipped to formulate an answer. Enhancement of the economy The US biomedical industry has been one of the leaders in the world, and it is still highly competitive. For example, the US medical device market, estimated to be $106 billion, is the world’s largest (37). Seven of the world’s top ten medical device manufacturers are US companies. The industry directly employs some $400,000 Americans, and it doubled its exports to $33 billion between 1998 and 2008 (38). International competition, however, is keen, providing growing challenges. For example, imports constitute an increasing (now 32%) of the US medical market, and outsourcing of manufacturing and the emergence of major new industries in China and India are causes for economic concern (37,38) . Strict regulatory standards help ensure safety, but they also provide motivation for research and development, as well as clinical trials, to be conducted overseas. In spite of the challenges, due to the aging population and needs arising in emerging markets, the overall outlook is promising, predicting that the “medical device industry will be fueled by scientific progress in this new century of the life sciences, as fundamental discoveries and advances in computing, materials, engineering, and physics create the knowledge base for an explosive growth in the creation of new treatments and cures” (38). Integrative science, innovation, and efficiency are the keys to competitiveness, and appropriately educated bioengineers are well equipped to bring these to the biomedical industry. As discussed above, using their technical expertise, knowledge of the life sciences, as well as their recognition of the need for cost control, they are well positioned to develop innovative and cost-efficient products that will help the US biomedical industry maintain its leadership position. The Commonwealth of Virginia is well positioned to participate in the economic benefits brought about by bioengineering. As described in the Washington Business Journal, Virginia 19 plays a central role in the striving DC-area biotech industry (39). Greater Washington has the fourth largest concentration of biotechnology employment, and Virginia directly employs over 20,000 people in biotechnology organizations, with the number growing to 80,000 when counting those who are involved indirectly. Virginia’s biotech sector is said to have generated $13 billion worth of products and services in 2008. Bioscience employment in the state grew by 23% from 2008 to 2011, compared to a 6% overall growth (40). The Commonwealth has recognized that a striving economy requires excellence in research, innovation, and technology. For example, The Virginia Biotechnology Research Park in Richmond is expanding, currently having over 1.1 million square feet of research and office space in Richmond (41). The Virginia Initiative for Science Teaching and Achievement (VISTA) partnership secured a five-year $28-million grant from the US government in 2010 to improve science teaching and learning at all educational levels throughout the state (42). George Mason University plays a leadership role in this partnership. Also, in May 2012, three new STEM Academies were approved by the Virginia Board of Education, bringing the total number to 14 (43) . One of these academies is in Fairfax county, home to Mason. The summary of Virginia’s 2012-14 budget emphasizes the central role higher education plays in the state’s vision (44). The document unequivocally states that “There is no more important investment Virginians can make than in the future of those students who are currently studying to become the next leaders of this great Commonwealth”. The budget includes $100 million per year to enhance studies in science, technology, engineering, math and healthcare (STEM-H). Although the doctoral program was conceived before the publication of this budget, the program is clearly consistent with the state’s commitment to STEM-H education. Educating bioengineers of the future Although the needs above apply to all bioengineers, they are especially acute for those with a doctorate. In general, doctoral-level bioengineers are expected to achieve higher levels of professional responsibility than those with a BS or MS. Consequently, they are expected to become leaders, providing advice, guidance, and example to their more junior colleagues. Historically, a doctorate is considered to be helpful for leadership in industry and government, while essential in academia. Research universities depend on their research accomplishments, requiring highly trained faculty members who can succeed in a competitive environment. Thus, the education of the next generation of bioengineers is in the hands of those holding a doctorate, necessitating forward-looking doctoral programs in bioengineering nationally and across the Commonwealth. It has become increasingly recognized that significant opportunities exist for PhD Bioengineers in industry either as employees of large firms or as entrepreneurs seeking to turn research into marketable biomedical products (45). In spite of the extensive scientific/engineering training that PhD graduates typically attain, many businesses view graduates hesitantly because they lack core skills and knowledge such as leadership and teamwork, intellectual property, regulatory affairs, and business plans. To capitalize on opportunities in program management and emerging 20 leadership opportunities in the Washington DC metropolitan area, the proposed program requires training in translational bioengineering. Why Mason? Although the proposed program is likely to benefit the entire nation, the primary beneficiary is expected to be Virginia. Mason is located in Northern Virginia that has an entrepreneurial spirit (46) , rapidly growing and highly educated workforce, drawing highly trained engineers, scientists and physicians to state-of-the-art facilities. It has the state’s largest concentration of biotechnology companies, accounting for 34% within Virginia (40). According to figures based on 2010 and 2011 US census data, 27% of Fairfax County’s population of age 25 or over has a graduate or professional degree, and 29% at least a Bachelor's degree (47). The corresponding figures are 10% and 18%, respectively, for the US population. Such a well educated population in the university's immediate vicinity is both a major resource and potential beneficiary of the proposed program, as well as a source of students for Mason’s current and proposed bioengineering programs. There are no other doctoral programs in bioengineering in Northern Virginia, so Mason’s program is expected to fill a major void. Northern Virginia provides excellent opportunities for educating bioengineers who are aware of society's needs. The proximity of national laboratories (such as the National Institute of Standards and Technology, and Naval Research Laboratory), regulatory agencies (such as the Food and Drug Administration), and funding agencies (such as the National Institutes of Health, National Science Foundation, and the research arm of the Department of Defense) are major resources. The area also has abundant non-government research and clinical facilities, such as the Janelia Farm research laboratories of the Howard Hughes Medical Research Institute, INOVA Clinical Center, and the Children’s National Medical Center. Mason has had extensive interactions with these institutions, some of which have already provided joint research, training, and employment opportunities. Employment Demand Bioengineering is a rapidly growing profession. According to a March 29, 2012 report of the Bureau of Labor Statistics (5): “Employment of biomedical engineers is expected to grow by 62 percent from 2010 to 2020, much faster than the average for all occupations. Demand will be strong because an aging population is likely to need more medical care and because of increased public awareness of biomedical engineering advances and their benefits.” The same report states that “[b]iomedical engineers work in manufacturing, universities, hospitals, research facilities of companies and educational and medical institutions, teaching, and government regulatory agencies.” Many of these professional affiliations require a doctorate degree. 21 The rate of expected increase is especially striking when compared with those predicted for any of the other listed engineering areas (48). The next two largest increases are 22% (for Environmental Engineering) and 19% (for Chemical Engineering). Occupational projections are also available for Virginia, compiled by the Virginia Workforce Connection (49). Growth of estimated employment from 2008 to 2018 is estimated to be 88% for biomedical engineers, compared with that of 19% for all engineers. To ascertain the need for doctoral level biomedical engineers, a search has been conducted through several employment sites. Student Demand Two sources of student demand for the Ph.D. in Bioengineering are provided: 1) a survey given to undergraduate students; and 2) letters from prospective students who would want to enroll in the proposed program. STATE COUNCIL OF HIGHER EDUCATION FOR VIRGINIA SUMMARY OF PROJECTED ENROLLMENTS IN PROPOSED PROGRAM Projected enrollment: Year 1 Year 2 Year 3 Year 4 Target Year (2-year institutions) Year 5 Target Year (4-year institutions) 2014 - 2015 2015 - 2016 2016 - 2017 2017- 2018 2018 - 2019 HDCT FTES HDCT FTES HDCT FTES HDCT FTES 6 4 11 7 16 9 21 12 GRAD HDCT FTES GRAD -- 21 12 5 Duplication First and foremost, there are no other bioengineering doctoral programs available to students in Northern Virginia. Three universities in Virginia offer doctoral degrees in biomedical/medical engineering: University of Virginia (UVA), Virginia Commonwealth University (VCU), and Virginia Tech (VT). None of these programs offer any bioengineering degree programs in satellite campuses in Northern Virginia. The number of such degrees awarded by each institution in the past five, based on data published by SCHEV’s C1.2 report for CIP code 14.051 (50), is 22 listed in the Table below. The total number of annual graduates ranges from 20 in 2008-09 to 26 in 2010-11. UVA VCU VT 2007-8 15 3 5 2008-9 11 3 6 2009-10 15 4 3 2010-11 17 1 8 2011-12 8 7 6 Based on descriptions at each of the program’s website (51,52,53), emphasis areas for the programs are: UVA Cardiovascular bioengineering Biomedical and molecular engineering Cellular and molecular bioengineering Computational systems bioengineering Tissue engineering and biomaterials Musculoskeletal bioengineering VCU Biomedical imaging systems Orthopaedic biomechanics Tissue and cellular engineering Biomaterials Artificial organs Human-computer interfaces Cardiovascular devices Rehabilitation engineering VT with Wake Forest University (WFU) Tissue Engineering Biomedical Imaging Nanomedicine & Nanobioengineering Biomechanics Neuroengineering Translational Cancer Research Cardiovascular Engineering There are both similarities and differences between Mason’s initially proposed four areas and those offered by other Virginia doctoral programs. The similarities arise by the recognized importance of targeted research areas, and the emergence of new technologies that are likely to provide major advances in these areas. An example is the broad area of imaging. The differences are due to the variety of faculty and environment, enabling the use of approaches that are best suited to available resources at each of the universities. For example, the emphasis on datadriven biomechanical modeling, where students develop skills in both imaging and 23 biomechanics, is an emphasis at Mason but not at the other universities. Likewise, leveraging the strength of Mason’s Krasnow Institute in Neuroscience with key Volgenau School faculty has led to our prominent concentration in neuroengineering, a focus area somewhat shared with VT/WFU. Conversely, while tissue engineering is a major focus area at other universities, it is not at Mason. A noteworthy distinct feature of the Mason program is the requirement that students acquire understanding and appreciation of translational bioengineering. The goal with this requirement is to prepare students to be effective leaders and program managers spanning academic research laboratories, federal laboratories, and industry. Another difference between Mason’s and the approaches by the other three universities arises from differing academic/administrative arrangements. All three existing doctoral programs rely on close interaction between engineering and medical schools: UVA and VCU have their own medical schools, while the program at VT is a collaborative initiative between VT’s engineering and Wake Forest University’s medical school. Since Mason does not have a medical school, the proposed program brings about biological and medical collaborations in a different way by leveraging collaborative opportunities at Mason. The Mason collaborations depend on and benefit from the wide range of institutions both within and in the vicinity of the university. As described earlier, the proposed program aims to have the participation of multiple academic units of the university, bringing about a merging of expertise that is unusual even among bioengineering programs. It is well known that Washington, DC metropolitan area provides extraordinary educational opportunities. While research laboratories are available at most universities, the Northern Virginia and the DC area abounds in national-level government and private laboratories. The availability of policy-making and regulatory agencies is an exceptional asset for educating bioengineering leaders, an asset that the proposed program will actively utilize. Already existing collaborations with existing hospitals ensure clinical contact that introduces “reality” often missing from purely scientific and theoretical studies. Rather than being duplicative, the proposed program complements and enhances capacity for educating bioengineers in the Commonwealth to meet local and national needs. 24 Projected Resource Needs George Mason has the faculty, staff, and laboratory resources required to initiate the proposed program without compromising existing programs. The Bioengineering department already has administrative support and office resources necessary to initiate the program. Full-time Faculty The Volgenau School of Engineering, mainly through the Bioengineering Department, has committed 8 full-time faculty to the proposed program. We project that the proposed program will initially require XX FTE of full-time faculty support, rising to XX FTE by the target year of 20XX-YY. Part-time Faculty from Other Academic Units Because the majority of the new courses will derive from the Volgenau School of Engineering, we will require no part-time faculty to support the program. The marginal costs of increased enrollment in courses outside the Volgenau School of Engineering that results from enrollment in this program can be absorbed by the other colleges with minimal impact. Adjunct Faculty We project that the proposed program will not initially require any adjunct faculty. However, we anticipate utilizing 0.XX FTE of adjunct faculty by the target year 20XX-20YY. The costs of adjunct instruction will be accommodated through reallocation of internal resources. Graduate Assistantships The Office of the Provost will commit resources for one three-year Presidential Scholar’s Award for each entering class of PhD students. By the target year, these three-year awards will support three graduate research assistants for the PhD in Bioengineering. Presidential Scholars have a support level of approximately $XX,XXX, which covers stipend and tuition support. In addition, the Bioengineering Department faculty members have been routinely able to provide support to PhD students. Since Fall of 2011, XX PhD students have been supported by Bioengineering faculty through Graduate Assistantships. In the past, this support has gone to graduate students in other degree programs (i.e., Electrical and Computer Engineering and Computer Science), but if the proposed program is approved, then the support will be directed to Bioengineering PhD students. Likewise, Bioengineering PhD students would receive high priority for the three graduate teaching assistantships offered by the Bioengineering Department, support which is currently directed to PhD students in other programs. Should the proposed program be approved, the faculty plans to seek additional support for graduate students. First, Mason has created a “Provost PhD Program Award” mechanism which aims to enhance graduate educational programs at Mason by providing targeted funding for a 25 limited number of PhD students. Our faculty will apply for this competitive program as soon as we are eligible to do so. Second, Bioengineering faculty will apply for PhD student training grant programs available through the NSF and/or the NIH. Classified Positions We project that the proposed PhD will require no more than 0.25 FTE of classified support. The costs of the classified position can be accommodated through an internal reallocation of resources within the Bioengineering Department. Targeted Financial Aid As described above, since Fall 2011, the Bioengineering faculty has provided support to XX PhD students through graduate research assistantships (GRAs), all from sponsored research funding. The support for each GRA, which includes tuition, stipend, and health insurance, is approximately $XX,XXX per year. If the proposed program is approved, future funds will be directed to Bioengineering PhD students. In addition, three graduate teaching assistantships, which includes tuition, stipend, and health insurance, totaling to approximately $XX,XXX per year, will be directed to Bioengineering PhD students. Equipment Because no faculty or classified staff will be hired for support, the proposed program requires no new equipment. Library The University Libraries system routinely commits $XXX to the purchase of research journals and books. Appendix J documents the library resources available to support this program. Telecommunications No new items are required for the proposed program. Space No additional space is required to launch or sustain the proposed program. Other Resources No resources other than those described above are required to support the proposed PhD in Bioengineering. PROJECTED RESOURCE NEEDS FOR PROPOSED PROGRAM Part A, Part B, Part C, Part D, 26 References 1) Linsenmeier RA. What makes a biomedical engineer? IEEE Eng. Med. Biol. Mag. 22: 32-38, 2003. 2) Katona PG. Biomedical engineering and The Whitaker Foundation. Annals Biomed Eng. 34: 904-916, 2006. 3) Athanasiou, KA. A new form of specialization. Ann. Biomed. Eng. 40, 1627, 2012. 4) National Academy of Engineering. The Engineer of 2020: Adapting Engineering Education to the New Century, pg 2. The National Academies Press, 2005. http://www.nap.edu/books/0309096499/html 5) Bureau of Labor Statistics (for bioengineering), Mar 29, 2012 http://www.bls.gov/ooh/architecture-and-engineering/biomedical-engineers.htm 6) Mason catalog http://catalog.gmu.edu 7) Volgenau School PhD requirements volgenau.gmu.edu/PhDprogr/ 8) Biomedical Engineering Society definition http://www.bmes.org/aws/BMES/pt/sp/be_faqs 9) Biomedical engineering definition (answers.com) www.answers.com/topic/biomedical-engineering 10) Bioengineering definition (yourdictionary.com) www.yourdictionary.com/bioengineering 11) Bioengineering definition (Meriam-Webster) www.meriam-webster.com/dictionary/bioengineering 12) NIBIB/NIH definition http://www.nibib.nih.gov/HealthEdu/ScienceEdu/BioengDef 13) Guren A. Engineering to broaden focus. Harvard Crimson. July 29, 2005. 14) Collins FS. The Language of Life DNA and the Revolution in Personalized Medicine. HarperCollins, New York, 2010. 15) Maus C, Rybacki S, Uhrmacher AM. Rule-based multi-level modeling of cell biological systems. BMS Systems Biology 5:166, 2011. 27 16) Special Issue: Multiscale Systems Biology. Ann Biomed Eng 40: 2293-2500, 2012. 17) Wilson RL et al. Computational medicine: translating models to clinical care. Sci Transl Med 4: issue 158, 2012. 18) Drummond TG, Hill MG, Barton JK. Electrochemical DNA sensors. Nature Biotechnology 21:1192-1199, 2003. 19) Parekatti SP, Yeung LL, Su LM. Intraoperative tissue characterization and imaging. Urol Clinics North Amer 36: 213-221, 2009. 20) Sikdar, S. et al. Novel applications of ultrasound technology to visualize and characterize myofascial trigger points and surrounding soft tissue. Arch Phys Med Rehab 90: 18291838, 2009. 21) Payton FC. Data mining in health care applications. In: Data Mining: Opportunities and Challenges, pp 350-365. IGI Publishing, 2003. 22) Hockfield, S. The next innovation revolution. 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Genetic testing for cancer http://www.cancer.gov/cancertopics/genetics 28 31) Beck J et al. Islet encapsulation: strategies to enhance islet cell functions. Tissue Engineering 13: 589-599, 2007 32) Penn, MS et al. Stem cells for myocardial regeneration. Clinical Pharmacol Therap 90: 499-501, 2011 33) Kaiser Health News: US Health Care Costs http://www.kaiseredu.org/Issue-Modules/US-Health-Care-Costs/Background-Brief.aspx 34) Congressional Budget Office of the Congress of the United States. Technological change and the growth of health care spending. January 2008. http://www.cbo.gov/ftpdocs/89xx/doc8947/01-31-TechHealth.pdf 35) Porter ME. What is value in health care? N Engl J Med. 363: 2477-2481, 2010. 36) Weston AD, Hood L. Systems biology, proteomics, and the future of health care: toward predictive, preventative, and personalized medicine. J Proteome Res 3: 79-196, 2004. 37) Espicom Business Intelligence: The Medical Device Marker: USA; July 12, 2012 http://www.espicom.com/usa-medical-device-market 38) The U.S. Medical Device Industry in 2012: Challenges at home and abroad; July 17, 2012 www.mddionline.com/print/9436 39) Washington Business Journal; Maryland, Virginia biotech industries take center stage in D.C.; June 28, 2011. http://www.bizjournals.com/washington/blog/2011/06/md-va-biotech-industries-takecenter.html?page=all 40) Virginia Biotechnology Association: Bioscience in Virginia http://vabio.org/bioscience-in-virginia 41) Virginia BioTechnology Research Park http://vabiotech.com/about/current-development 42) Virginia Initiative for Science Teaching and Achievement (VISTA) http://vista.gmu.edu/about 43) Virginia Department of Education: News release http://www.doe.virginia.gov/news/news_releases/2012/may25.shtml 44) Fiscal years 2012-2014 Biennial Budget Summary http://www.governor.virginia.gov/utility/docs/2013-14 Budget Summary.pdf 29 45) Benderly BL. The New PhD. Prism 22 (5): 31-34, 2013. 46) Northern Virginia Technology Council: Virginia initiatives. http://www.nvtc.org/advocacy/virginia_initiatives.php 47) Fairfax County http://www.fairfaxcountyeda.org/demographics 48) Bureau of Labor Statistics (for different engineering areas), Mar 29, 2012 http://www.bls.gov/ooh/architecture-and-engineering/ 49) Virginia Workforce Commission: Occupational Employment Projections http://www.vawc.virginia.gov/analyzer/ 50) VA bioengineering/biomedical engineering http://research.schev.edu 51) UVA Biomedical Engineering graduate program www.bme.virginia.edu/graduate/index.html 52) VCU Biomedical Engineering graduate program http://biomedical.egr.vcu.edu/academics/graduate/ 53) VT/Wake Forest University Biomedical Engineering graduate program http://www.sbes.vt.edu/ 30 Appendix A – Resources Facilities: Bioengineering Department occupies a wing of the Long and Kimmy Nguyen Building of the Volgenau School of Engineering on the Fairfax campus. The department provides office space for many of the Bioengineering Department faculty, offices for administrative support, a tool/machining room, and conference room. The space is well-equipped with sufficient computers with network access and other office-related equipment. Bioengineering Department faculty members maintain laboratory space at either the Nguyen Engineering Building or at the nearby Krasnow Institute of Advanced Study on the Fairfax campus. The Blackwell laboratory encompasses 750 square feet of space, including space for electrophysiology experiments and computing equipment. The laboratory contains lab benches; desks; shelves and cabinets for storage of chemicals, and glassware; solution and tissue preparation equipment; and two electrophysiology set-ups. The set-up for whole cell patch recording has a Zeiss IR-DIC microscope, two Narishige micromanipulators, two intracellular bridge/voltage clamp amplifiers, an ITC-16 A-D board connected to a Windows computer running Pulse for computerized experiment control and data acquisition. The set-up for field recording allows collecting fields from stimulated and non-stimulated control slices simultaneously. Thus, it has two stimulators, two Warner bridge amplifiers, four mechanical manipulators, and computerized data collection employs a NIDAC board and Labview. The solution and tissue preparation equipment consists of a fume hood with sink, Leica vibratome, an analytical balance, a pH meter, heating stir plate, osmometer and a refrigerator. Computing equipment in the Blackwell laboratory includes both Windows computers and UNIX workstations with various general purpose and special purpose software, for software development, advanced data analysis and manuscript preparation. The PI as well as each student and postdoc have their own multi-processor computer workstation for code development and simulations, and we have one 16 processor workstation available for additional simulations. The workstations also have Java and C/C++ compilers, and the neural modeling software packages, GENESIS, Neuron and XPP. In addition to these computational resources in the CENlab, the Krasnow Institute has a small linux cluster available at no charge to the PI. Dr. Cebral has approximately 450 sq ft of laboratory space at the Center for Computational Fluid Dynamics (CFD), Research Hall 1, at Mason. The laboratory is equipped with advanced graphic workstations available to all researchers and students with the CFD Center. All faculty, research faculty and full time students with the CFD Center are equipped with powerful workstations for building computer models, performing medium size simulations, and visualizing results of numerical calculations. Typical workstations have 8 to 24 Intel cores, 24 to 32 GB of RAM, and NVIDIA graphic cards. In addition, Dr Cebral owns several data servers and compute engines located at the Supercomputer Facility of Research Hall 1. Data servers provide a total of approximately 40TB of redundant storage and backup. Computer servers provide approximately a total of 148 CPU cores and 1TB of RAM memory, interconnected with a local high speed Ethernet network. These servers are used for running big parallel high performance computations and archiving and mining the resulting data of large numbers of models. 31 Dr. Cortes is an active faculty of the Sports Medicine Assessment, Research and Testing (SMART) Laboratory. The SMART Lab is a brand new facility with approximately 4,000 square feet with state-of-the-art biomechanical equipment that is well suited for motion analysis capture, neuromuscular assessment, and ultrasound imaging research. In particular, the SMART Lab has 8 high-speed 3-Dimensional cameras (Vicon Motion Systems Ltd., Oxford, England) with 2 megapixels and 690 Hz with a unique combination of high speed, accuracy and resolution, 3 high-speed cameras with 1 megapixel resolution and 250 Hz capturing rate, 4 Bertec force plates (Bertec Corp, Columbus OH) to quantify ground reaction forces, a wireless 8-channel electromyography system (Delsys Trigno System) with a 2000 Hz sampling to assess muscle activation, an Ultrasonix SonixRP clinical ultrasound system, 3 load cells/dynamometers, 1 treadmill, 1 EKG system, 1 transcranial magnetic stimulation (MagStim) with multiple coils, 2 balance plates, and 1 six degree-of-freedom electromagnetic system with 3 probes. The SMART Lab has a quad-core 2.0 GHz Intel CPU with 8GB RAM, a secure internal server with 12TB of storage, five laptops, two desktops, and eight iMacs are also available. Dr. Ikonomidou’s Neuroimaging Laboratory is equipped with 5 state-of-the art Intel Xeon quadcore CPU workstations with over 10 Gb of RAM each. Two server computers are currently used to host study data. Additional computer equipment, including four high-end laptop computers, is also available. All computers are equipped with image processing software, including MATLAB and IDL, and are capable of running state-of-the-art MRI processing software such as FreeSurfer, FSL and SPM. The Neuroimaging Laboratory has access to a 3.0T Siemens MAGNETOM Allegra head-only MRI scanner, housed at the Krasnow Institute for Advanced Study in the Fairfax campus of George Mason University. Dr. Jafri has approximately 600 square feet for his computational research laboratory at the Krasnow Institute. The research laboratory houses working space for the 6 Unix workstations and 6 Windows workstations as well as offices/desks for graduate students and postdocs. The laboratory has a CPU/GPU cluster with 16 HP z800 workstations each with dual six-core Intel Xeon X5650 CPUs and 24 Gbytes of memory. The cluster contains 10 NVIDIA C2050 GPUs. Each node has 0.5 TB scratch disk space. These are connected together directly by a 40Gbps high-speed, low latency Infiniband network. The cluster is house in the 9000 sq. ft Aquia Data Center which has stabilized and emergency power and 24/7 staffing. In addition, the Jafri Lab has two HP z820 Workstations with dual quad-core Intel Xeon E5-2643 processors and 32 Gbytes of memory. One of these acts as a file server with 6 TB user disk space. The other is equipped with a NVIDIA K20 GPU. Also in the lab is a HP z800 workstation with dual quadcore Xeon Nehalem CPUs and 18 Gbytes memory, a Super Micro dual quad-core Xeon Westmere system with 24 Gbytes memory, and two dual processor dual-core AMD Opteron HP XW9300 Linux Workstations. In these are installed 3 NVIDIA C1060 GPUs, 3 NVIDIA GTX480 GPUs, and one NVIDIA GTX470 GPU. All these workstations are running the Ubuntu Linux operating system equipped with Portland Group, Inc. Fortran/CUDA FORTRAN compliers MATLAB, IDL, IMAGEJ and other essential software. There are 5 HP Elitebook Mobile Workstations and and 1 HP XW4100 workstation assigned to lab members running Microsoft Windows.These are all connected to each other and the Internet by gigabit ethernet. Files are mirrored on a 12 TB Seagate Black Armor network Raid system and backed up/archived with a HP 448 ultrium tape system. 32 Dr. Sikdar has approximately 850 sq ft of laboratory space at the Krasnow Institute for Advanced Study at Mason. The laboratory is well-equipped for ultrasound imaging research, both experimental as well as on human subjects. The laboratory maintains the following equipment: Ultrasonix SonixRP clinical ultrasound system with high frequency 5-14 MHz and real-time 3D imaging probes, Terason T3000 portable laptop-based ultrasound system with multiple transducers, Verasonics 64-channel ultrasound data acquisition system, Spencer Technologies ST3 Transcranial Doppler instrument, equipped with 2-MHz diagnostic probe and two 2-MHz bilateral monitoring probes, Interson SeeMore USB-based portable ultrasound probe for mobile applications, 3DGuidance TrakStar magnetic position sensing system with four six-degree of freedom position tracking sensors (Ascension technologies), ISS OxiplexTS near infrared spectrophotometer, a secure high-performance (quad core 2.0 GHz Intel CPU with 4GB RAM) RAID file server with 2 Terabytes of data storage capacity, a dual quad-core 2.26 GHz Intel Xeon system with 12GB 1066-MHz DDR3 RAM, and a dual 2.66 MHz hex-core MacPro server with 12 GB RAM. Dr. Shehu’s Computational Biology Lab consists of 5 workstations in the Artificial Intelligence Laboratory on the 4th floor of the Nguyen Engineering building. In addition, equipment is available from the Department of Computer Science: A departmental computing cluster is available for computational projects for undergraduates, containing 53 Intel Xeon 1U rackmount units of which half are 1-Core 2-CPU and half are 2-Core 2 2-CPU connected by 1 GB copper ethernet. Each unit has 700 GB shared storage and 1GB RAM per core. A 7.3TB XServe storage device is associated with the cluster. Drs. Peixoto and Pancrazio share Neural Engineering laboratory space on the 3rd floor of the Engineering Building. The laboratory consists of two fully outfitted wet labs comprising 700 sq feet with chemical hoods, dedicated electrophysiology, chemical solution preparation, and electrochemistry workstations. In addition, between the two laboratories is a shared 200 sq ft cell culture facility which is fully operational. Major equipment includes an Omniplex multichannel data acquisition system (Plexon Inc), Axopatch 200 patch clamp amplifier (Axon Instruments), PatchStar Micromanipulator (Scientifica), Digidata/pCLAMP data acquisition system (Axon Instruments), PC-10 pipette puller (Narishige), CPM-2 Coating and Polishing microforge (ALA Scientific Instruments), potentiostat (Gamry), two multichannel electrochemical station (CHinstruments), dual stack CO2 incubators, laminar flow biosafety cabinet, -80 C freezer, general use refrigerator, centrifuge, in vitro microelectrode array system (Multichannel Systems), three inverted microscopes equipped for fluorescence immunohistochemistry (Nikon Eclipse), phase contrast/DIC imaging for patch clamp experiments (Zeiss Axio-Observer), and a trinocular inverted microscope for cell culture use (World Precision Instruments). Dr. Salvador Morales has approximately 500 square feet of wet lab space at the Krasnow Institute for Advanced Study at Mason. The laboratory, which is dedicated to nanomedicine and nanotechnology, has the following equipment: high shear mixer, centrifuge, bench top centrifuge, analytical balance, Nanodrop UV-Vis spectrophotometer (Thermo Scientific), 3 micro-centrifuges, speed “VAC” vacuum concentrator, pH meter, freezer, hot-plates, and minirefrigerator. 33 Dr. Rangwala has access to 2000 sq. ft of laboratory space on the 4th floor of the Engineering Building with the following computer equipment: Computer Science department Beowulf cluster with 64 dual-core and quad-core Intel PCs connected via fast Ethernet switch, 5 workstations consisting of dual-core Intel Pentium at 2.6GHz, 4GB memory. All computers are running Linux and have a number of software packages installed on them including Matlab, Oracle, mySQL, and GNU development tools. Dr. Rangwala’s Data Mining Laboratory has workstation servers with 12 dual-core and quad-core Intel PCs. Two of these servers have 32 GB RAM each, and also have nVidia gifted Tesla and Quadro cards. Dr. Joiner has approximately 600 square feet of laboratory space on the second floor of the The Volgenau School of Engineering at Mason. The focus of the laboratory is studying sensorimotor integration and motor control through experimental and computational approaches. In addition to six pentium class computer workstations for analysis and computational modeling, the laboratory's main experimental equipment is a two arm robotic manipulandum (KINARM). This end-point robot is a stiff, graspable robot that can create highly complex mechanical environments. In addition, the setup has a 2D virtual reality display for natural, intuitive presentation of visual stimuli. Dr. Wei has approximately 160 square feet of lab space in the Volgenau School of Engineering at Mason. The laboratory, which is dedicated to computational biomechanics, is equipped with high performance computers as well as a binocular, infrared, head-mounted eye tracker. Dr. Agrawal maintains approximately 480 sq ft of wet laboratory space at the Krasnow Institute for Advanced Study at Mason. The laboratory is already equipped with a chemical fume hood, house vacuum and compressed air connections as well as an additional available line for supplying other gases if required. Within the laboratory, dedicated bench spaces have been assigned for device fabrication and tissue culture work. The laboratory contains the following equipment to carryout microfluidics and cell biology research: AMG EVOS FL Auto fluorescent microscope with integrated monochrome and color cameras, automated stage and LED light source for live cell imaging; AMG EVOS XL microscope with integrated LCD and time lapse imaging capability; 4 ft. Esco Labculture Class II Type A2 biological safety cabinet; cell and particle counter (Beckmen coulter counter Z2); microplate reader (Spectramax Gemini EM, Molecular Devices); a plasma system (PE-50, Plasma Etch Inc); Laurell programmable spin coater (WS-650-23); two lab ovens (Quincy labs, model 10AP); programmable syringe pump (Chemyx, Fusion 200); -86C freezer (REVCO Ultima II, 21 cu.ft.); and refrigerated centrifuge (Eppendorf 5417R); non-refrigerated microcentrifuge (Eppendorf 5415 D); Thermo IEC Centra CL3 bench top centrifuge, dual chamber water bath (Thermo Scientific Isotemp 215); two vortex mixers (Vortex Genie 2, Scientific Industries); Branson 5510 sonication bath; 25L cryotank, VWR hot plate stirrer, 21 cu.ft. top freezer refrigerator; pH/conductivity meter (Fisher Scientific Accumet AB200); and a thermal printer (Zebra TLP-2844Z). In addition, Dr. Agrawal is developing a 235 sq. ft. clean room (Class 1000) microfabrication facility within the Krasnow Institute to facilitate advanced microfluidics research at the university. 34 Appendix B – Catalog Description of Courses (* denotes new course to be developed and implemented for the proposed program) *BENG 501 - Bioengineering Research Methods Credits: 3(NR) Examines approaches for scientific research with applicability to research in bioengineering. Topics include biophysical origins of bioengineering measures, tools and technology for bioengineering data collection, basic principles of experimental design and statistical analyses, and interpretation of scientific results. Prerequisite: Graduate Standing BENG 525 - Neural Engineering Credits: 3 (NR) Provides an overview of topics in Neural Engineering. Topics covered range from sensory and motor prosthetic devices, stimulation of biological tissue, bioelectrodes and characterization techniques, brain-machine interfaces, and engineered devices to ameliorate neurological disorders. Prerequisite(s): Graduate Standing or permission of instructor. BENG 538 - Medical Imaging Credits: 3 (NR) Provides an introduction to the physical, mathematical and engineering foundations of modern medical imaging systems, medical image processing and analysis methods. In addition, this course introduces engineering students to clinical applications of medical imaging. The emphasis is on diagnostic ultrasound and magnetic resonance imaging methods, although several other modalities are covered. The course also provides an overview of recent developments and future trends in the field of medical imaging, discusses some of the challenges and controversies, and involves hands-on experience applying the methods learnt in class to real-world problems. Equivalent to ECE 538 Prerequisite(s): Graduate Standing or permission of instructor; ECE 320 or BENG 320; PHYS 262 or equivalent. *BENG 541 – Biomaterials Credits: 3(NR) This course covers the principles of biomaterials and biological interactions with materials, including an overview of biomaterials characterization, design and testing. The emphasis of this course will be on emerging strategies and design considerations of biomaterials. Specific areas of concentration will include the use of polymers, ceramics and metallics in biomaterials, drug delivery applications, tissue engineering from an orthopedic and vascular perspective, biocompatibility and acute and chronic biological response to implanted material. In vitro and in vivo testing of biomaterials will also be covered in this course. Prerequisite(s): Graduate Standing or permission of instructor. *BENG 551 - Translational Bioengineering Credits: 3(NR) Demonstrates the process for creation of both medical devices and companies in the medical device field. This course focuses on teaching students to design and build up a robust medical device prototype, write a business plan, and present a company vision. This course will 35 draw upon lectures, videos and four different guest speakers who are co-founders of successful biomedical startup companies. Prerequisite(s): Graduate Standing or permission of instructor. BENG 636 - Advanced Biomedical Signal Processing Credits: 3 (NR) Provides an overview of advanced topics in biomedical signal processing with an emphasis on practical applications. Topics include introduction to physiological origins of biomedical signals, stochastic and adaptive signal processing, spectral estimation, signal modeling and analysis of nonstationary signals. Prerequisite(s): Graduate Standing; ECE 535 or equivalent; ECE 528 or equivalent. *BENG 725 - Computational Motor Control Credits: 3(NR) This course uses approaches from robotics, control theory, and neuroscience to understand biological motor systems. The focus of the course is modeling muscles, reflexes and neural systems in order to understand how the central nervous system plans and controls movement of the eyes and limbs. Prerequisite(s): Graduate Standing; BENG 525 *BENG 738 - Advanced Medical Image Processing Credits: 3(NR) This course covers advanced processing techniques used in modern medical imaging. This course focuses primarily on neuroimaging analysis techniques, however fundamental concepts such as segmentation or registration which are applicable to imaging of other body regions are also covered. The course aims at developing an understanding of the mathematical background, principles and application of techniques such as segmentation, registration, morphometry, general linear modeling, and principal/independent component analysis. Prerequisite(s): XXXXXX *BENG 641 - Advanced Nanotechnology in Health Credits: 3(NR) This course provides interdisciplinary scientific and engineering approaches to solve relevant medical problems. The course is divided in two main sections. In the first section, students will learn polymer structure and composition, polymer material properties and different types of natural and synthetic polymers. In the second part, students will apply this knowledge to design novel nanocarriers for controlled drug release, scaffolds for tissue engineering applications and new vectors for vaccines. In addition, in this course, students will have the opportunity to discuss in depth the relevance of Nanotechnology to advance medical treatments in cancer, infectious and neurodegenerative diseases. Prerequisite(s): Graduate Standing; CHEM 441, BIOL 682, or permission of instructor *BENG 650 - Advanced Biomechanics Credits: 3(NR) Introduces the fundamental concepts of musculoskeletal biomechanics, and how to apply mechanical principles to quantitatively describe, analyze, and model movement. Topics include properties, functions, and models of the musculoskeletal structures, 3D kinematics, forward and inverse dynamics as well as instrumentation systems applied in movement analysis. Students are required to complete a project that could be either a critical review of a topic or an implementation. 36 Prerequisite(s): Graduate Standing; BENG 501, RHBS 710 *BENG 745 - Biomedical Systems and Microdevices Credits: 3(NR) Bio-micro-electro-mechanical systems (BioMEMS) provide a robust approach to mimic in vivo microenvironments within controlled in vitro settings. The goal of this course is to introduce students with the concepts of highly interdisciplinary field of Lab-on-a-Chip technologies with emphasis on its advanced applications in biological and biomedical engineering. In addition to the microfabrication processes, a variety of analytical techniques routinely used in biomedical research will also be covered. Prerequisite(s): Graduate Standing; CSI 720, or permission of instructor *BENG 750 - Modeling and Simulation of Human Movement Credits: 3(NR) Introduces the development, simulation, and characterization of data-driven 3D neuro-musculoskeletal models that can be used to quantitatively explore human movement in health and disease. Topics include reconstructing 3D geometric models of bones and muscles from medical imaging data, estimating joint kinematics from motion capture data, creating simulations of musculoskeletal motion incorporating multimodality data, and analyzing muscle and joint forces for static and dynamic activities applying computational tools. Students will learn and use open source computational biomechanics software to simulate movement. The course consists of lectures, student paper presentations, and computer laboratories. A semesterlong research project is required. Prerequisites: Graduate Standing; BENG 538, BENG 650 *BENG 820 - Seminar in Neuroengineering Credits: 3 (RD) Selective analysis and discussion of topics in neuroengineering in areas of current research interest. Topics may include brain machine interfaces, advanced materials for implantable devices, computational neuroscience, neuronal biosensors and assays, and neuroprosthetics. Prerequisite(s): Graduate Standing; BENG 525 *BENG 830 - Seminar in Biomedical Imaging Credits: 3 (RD) Selective analysis and discussion of topics in biomedical imaging in areas of current research interest. Topics may include techniques and analyses for ultrasound, magnetic resonance imaging (MRI), functional MRI, nuclear imaging, computer assisted tomography, positron emission tomography, and emergent approaches to imaging for health and disease. Prerequisite(s): Graduate Standing; BENG 538 *BENG 840 - Seminar in Nano-scale Bioengineering Credits: 3 (RD) Selective analysis and discussion of topics in nano-scale bioengineering in areas of current research interest. Topics may include nanoengineered materials, nanoscale devices and systems, and novel nano-scale fabrication and modeling approaches with application to biomedicine. Prerequisite(s): BENG XXX *BENG 850 - Seminar in Biomechanics 37 Credits: 3 (RD) Selective analysis and discussion of topics in biomechanics in areas of current research interest. Topics may include computational and physiological modeling for biomechanics, multiscale representation of biomechanical systems, data fusion techniques for biomechanics, and application of quantitative biomechanics for diagnostics or medical intervention. Prerequisite(s): BENG 650 *BENG 998 - Doctoral Dissertation Proposal Credits: 1-12 (RD) Work on research proposal that forms basis for doctoral dissertation. Notes: May be repeated. No more than 24 credits of BENG 998 and 999 may be applied to doctoral degree requirements. *BENG 999 - Doctoral Dissertation Credits: 1-12 (RD) Formal record of commitment to doctoral dissertation research under direction of BENG faculty member. Prerequisite(s): Admission to candidacy. Notes: May be repeated as needed. Students must complete minimum 12 credits of doctoral proposal (BENG 998) and doctoral dissertation research (BENG 999) Maximum of 24 credits of BENG 998 and 999 may be applied to degree. Students who choose to take less than 24 credits of BENG 998 and 999 may earn remaining credits from approved course work. Students cannot enroll in BENG 999 before research proposal accepted and approved by dissertation committee. 38 Appendix C – Sample Schedules for PhD in Bioengineering Notes: 1. For sake of simplicity, one of the four concentrations (neuroengineering) is used to illustrate the sample schedule permutations. 2. TQE indicates timing of the technical qualifying exam; RQE indicates timing of the research qualifying exam Sample Student Schedule for a Full-Time Post-Baccalaureate Student Year Fall Spring Yearly Credits Cumulative Year 1 BENG 501 (a) BENG 551 (a) 18 18 ECE 528 (b) ECE 535 (b) RHBS 710 (b) BENG 525 (c) NEUR 602 (c) BENG 725 (c) 18 36 ECE 521 (d) ECE 620 (d) CS 580 (d) ECE 621 (d) TQE RQE BENG 998 BENG 998 12 48 ECE 722 (d) ECE 738 (e) BENG 998 BENG 998 12 60 CS 688 (e) BENG 820 (e) 12 72 Year 2 Year 3 Year 4 Advance to candidacy Year 5 BENG 999 BENG 999 (a) = required bioengineering core class; (b) fulfills mathematics and bioscience requirements; (c) required concentration course; (d) = fulfills technical elective requirements in engineering; (e) fulfills concentration elective requirements. All courses are 3 credits except for BENG 999 (6 credit hrs). Sample Student Schedule for Part-Time Post-Baccalaureate Student Sample Student Schedule for Full-Time Post-Master’s Student Sample Student Schedule for Part-Time Post-Master’s Student 39 Appendix D- Abbreviated CV’s for the PhD Faculty Volgenau School of Engineering Bioengineering Graduate Program Faculty *Nitin Agrawal, Assistant Professor, Department of Bioengineering. PhD: 2006, Chemical Engineering, Texas A&M University. Postdoctoral fellow: 2006-2009, Harvard Medical School, MGH Hospital and Shriner’s Burn Hospital. Research interest: cell migration, microfluidics. Kenneth Ball, Dean, Volgenau School of Engineering. LS Randolph Professor and Head. Department of Mechanical Engineering, Virginia Polytechnic Institute and State University. PhD: 1987, Mechanical Engineering, Drexel University. Research interests: computational fluid dynamics, heat transfer in turbulent flow with applications to biomedicine. Kim “Avrama” Blackwell, Krasnow Professor of Computational Neuroscience and Neurophysiology, College of Science, The Krasnow Institute for Advanced Studies. PhD: 1988, Bioengineering, University of Pennsylvania. Research interests: biophysical and biochemical mechanisms of long term memory storage studied through computational and electrophysiological techniques. *Caitlin Burke, Assistant Professor (instructional) and Acting Associate Chair, Department of Bioengineering. PhD: 2011, Biomedical Engineering, University of Virginia. Postdoctoral fellow: 2011-2012, NIH. Interests: ultrasound, thermo-chemo-radiotherapy, bioengineering education. Juan Cebral, Professor, School of Physics, Astronomy and Computational Sciences. PhD: 1996, Computational Sciences and Informatics, George Mason University. Research interests: computational fluid dynamics, modeling of blood flow, applications to cerebral aneurysms. Nelson Cortes, Assistant Professor, Division of Health and Human Performance, College of Education and Human Development. PhD: 2010, Human Movement Sciences, Old Dominion University. Research interests: biomechanics, muscle dynamics, injury prevention. Kenneth De Jong, Professor, Department of Computer Science, Volgenau School of Engineering; Associate Director, The Krasnow Institute for Advanced Studies. PhD: 1975, Computer Science, University of Michigan. Research interests: genetic algorithms, machine learning, artificial intelligence. *Vasiliki N. Ikonomidou, Assistant Professor, Department of Bioengineering. PhD: 2002, Electrical and Computer Engineering. Visiting Fellow and then Research Fellow: 2003-2009, Neuroimmunology Branch, NINDS/NIH. Research interest: magnetic resonance imaging. M. Saleet Jafri, Professor, School of Systems Biology, College of Science; Department of Molecular Neuroscience, The Krasnow Institute for Advanced Studies. Professor and Chair: Department of Bioinformatics and Computational Biology. PhD: 1993, Biomedical Sciences, The City University of New York. Research interests: mathematical modeling of the cardiovascular system, cell signaling, cell energetics. 40 *Wilsaan Joiner, Assistant Professor of Bioengineering. PhD: 2007, Biomedical Engineering, Johns Hopkins University. Postdoctoral fellow: 2007-2012, NIH. Research interests: eye movement, perception. Peter Katona, Professor (part time, since 2006), Department of Electrical and Computer Engineering. PhD: 1965, Electrical Engineering, MIT. Assoc. Prof, Prof, Chair: Biomedical Engineering, Case Western Reserve University 1969-90. VP, President, The Whitaker Foundation 1991-2006. Dmitri Klimov, Associate Professor, School of Systems Biology, College of Science. PhD: 1992, Physics, Moscow State University. Research interests: computer simulation of biomolecules, formation of amyloid fibrils, structural transitions in proteins due to mechanical forces. *Joseph Pancrazio, Professor and Chair, Department of Bioengineering. PhD: 1990, Biomedical Engineering, University of Virginia. Research Engineer, then Head, Laboratory of Biomolecular Dynamics, Naval Research Laboratory 1998-2004. Program Director, Neural Engineering, NIH/NINDS 2004-09. Research interest: neural interfaces and next generation neuron-based assays. Nathalia Peixoto, Associate Professor, Department of Electrical and Computer Engineering. Affiliate appointment in Department of Bioengineering. PhD: 2001, Electrical Engineering. Postdoctoral Fellow: 2001-2002, Stanford; 2003-2006, Center for Neural Dynamics, George Mason University. Research interest: electrical activity of the brain. Huzefa Rangwala, Assistant Professor (since 2008), Department of Computer Science. Affiliate appointment in Department of Bioengineering. PhD: 2008, Computer Science, University of Minnesota. Research interest: bioinformatics, machine learning. *Carolina Salvador Morales, Assistant Professor, Department of Bioengineering. PhD: 2007, Chemistry, University of Oxford. Postdoctoral fellow: 2007-2011, MIT. Interests: nanoparticles, immunology, entrepreneurship. Padmanabhan Seshaiyer, Professor, Department of Mathematical Sciences, College of Science. PhD: 1998, Applied Mathematics, University of Maryland, Baltimore County. Research interests: advanced scientific and parallel computing, computational biomechanics. Amarda Shehu, Assistant Professor, Department of Computer Science. Affiliate appointment in Department of Bioengineering. PhD: 2008, Computer Science, Rice University. Research interest: protein structure. *Siddhartha Sikdar, Assistant Professor, Department of Bioengineering. Joint appointment in the Electrical and Computer Engineering Department. PhD: 2005, Electrical Engineering, University of Washington. Postdoctoral fellow: 2005-2008, Department of Bioengineering, University of Washington. Research interest: medical ultrasound. 41 James Thompson, Associate Professor, Department of Psychology, College of Science. PhD: 20??, Psychology, Swinburne University, Australia. Postdoctoral Fellow: Department of Radiology, West Virginia University, 20yy- zz. Research interests: neural basis of perception of human actions using behavior, fMRI and EEG. Iosif Vaisman, Professor and Associate Director, School of Systems Biology, College of Science. PhD: 1990, Physical Chemistry, USSR Academy of Science. Research interests: computational methods for determining protein structure and function. *Qi Wei, Assistant Professor, Department of Bioengineering. PhD: 2010, Computer Science, Rutgers University. Postdoctoral fellow: 2010-2012 Northwestern University. Research interests: computational biomechanics, neuromuscular systems, motor control. * Core Bioengineering Department Faculty 42 Appendix E – Departmental Faculty Research Active Funded Projects: COLLABORATIVE RESEARCH: Spatial and Temporal Aspects of cAMP/PKA Signaling Underlying Information Processing in Neurons Submitted to joint NIH-NSF program on Collaborative Research in Computational Neuroscience, Grant awarded by NIAAA Budget: $1,191,000 Dates: 2008-2013 Bioengineering Affiliate Faculty: Kim Blackwell (PI) From Attentive to Automatic Performance: A Multi-Scale, Multi-Species, and Multi-Modal Investigation of Spatial Learning MURI grant from ONR Budget: $7,476,164 Dates: 2009-2014 Bioengineering Affiliate Faculty: Kim Blackwell (co-PI) Computational Analysis of Cerebral Aneurysm Evolution Funding Agency: NIH Budget: $1,664,453 Dates: 09/01/2007-5/31/2013 Bioengineering Affiliate Faculty: Juan R. Cebral (PI) The goal of this project is to study the hemodynamics in unruptured cerebral aneurysms followed with non-invasive imaging to better understand the role of hemodynamics in the process of aneurysm progression, and to test whether hemodynamics can be used to improve the risk assessment of intracranial aneurysms. Computational and Biological Approach to Flow Diversion Funding Agency: NIH Budget: $895,395 Dates: 9/1/2011-8/31/2016 Bioengineering Affiliate Faculty: Juan R. Cebral (Co-I) In this project, anatomically and physiologically accurate computational models of cerebral aneurysms are constructed from multimodality images acquired in animal models treated with flow diverting stents. These models are then used to identify the hemodynamic conditions that predispose different aneurysms and different regions of the aneurysms to thrombose after implantation of flow diverting devices. This study seeks to better understand how flow diverting devices work and subsequently improve endovascular interventions. Evaluation of Flow Diversion Treatment for Cerebral Aneurysms Funding Agency: NIH 43 Budget: $80,000 Dates: 2010-2013 Bioengineering Affiliate Faculty: Juan R. Cebral (PI) This project uses patient-specific computer models of cerebral aneurysms to evaluate the prognostic value of average blood velocity changes before and after treatment with flow diverting devices. Additionally, this project seeks to develop efficient methods for modeling blood flows in stented cerebral aneurysms using a porous media approach that could be used for treatment planning in routine clinical practice. Hemodynamics in Intracranial Aneurysm Pathogenesis Funding Agency: NIH Budget: $398,709 Dates: 08/01/2011-7/31/2013 Bioengineering Affiliate Faculty: Juan R. Cebral (Co-PI) The overall goal of this project is to identify hemodynamic conditions associated to the formation of cerebral aneurysms. For this purpose patient-specific image-based computational fluid dynamics of intracranial aneurysms are used to approximate the in vivo hemodynamic conditions at known locations in cerebral arteries where aneurysms later developed. The link between hemodynamics and wall structure in cerebral aneurysms Funding Agency: NIH Budget: $423,851 Dates: 04/01/2013-3/31/2015 Bioengineering Affiliate Faculty: Juan R. Cebral (Co-PI) This project combines information from numerical simulations, multi-photon microscopy and mechanical tissue testing to determine the detail interactions between the blood flow, aneurysm wall structure and its mechanical strength. For this purpose, patient-specific computational models are constructed from medical images and used to represent the aneurysm hemodynamics. Tissue samples are harvested during neurosurgery and analyzed with multi-photon microscopy to determine the wall structure (cellular content, collagen fiber organization), and subsequently tested under loading conditions to determine the mechanical strength of the wall. This project will shed light into the mechanisms responsible for aneurysm development, progression and ultimately rupture. Functional Evaluation to Predict Lower Extremity Musculoskeletal Injury Funding Agency: National Institute of Health (NIAMS) Budget: $1,952,090 Dates: 2012-2017 Bioengineering Affiliate Faculty: Nelson Cortes (Co-I) 44 The proposed research is highly relevant to public health because the health benefits associated with physical activity for children are significant and well reported. Yet the millions of individuals of all ages who engage in recreational exercise and sport face potential short and long term limitations to their function and participation across the lifespan due to lower extremity musculoskeletal injury. Thus, the proposed research is consistent with NIH mission that pertains to the development of fundamental knowledge to extend healthy life and develop translational clinical research to help reduce the burdens of injury and disability. Calcium Entrained Arrhythmias Funding Agency: National Institutes of Health (R01HL105239-02) Budget: $1,258,236 (GMU portion of a total of $5,509,890.44 Multi-PI Project) Dates: 2011-2015 Bioengineering Affiliate Faculty: M. Saleet Jafri (PI) The project integrates experiments and multiscale modeling to gain a systems level understanding of the molecular and cellular events that lead to cardiac arrhythmias that are due to a defect in cardiac calcium dynamics. CUDA Teaching Center/CUDA Research Center Funding Agency: NVIDIA Budget: $12,000 Dates: 2011-2013 Bioengineering Affiliate Faculty: M. Saleet Jafri (PI) The teaching center award was received for efforts to instruct (mentoring and courses) students how to program in the CUDA programming language that utilized modern GPUs (graphical processing units) for computation. The research center award was received for the application of CUDA technologies for scientific research. Role of the Saccadic Eye-movement Corollary Discharge in Stable Visual Perception. Funding Agency: National Institutes of Health (R00 - NIH Pathway to Independence Award) Budget: $746,461 Dates: 2012-2015 Bioengineering Faculty: Wilsaan Joiner (PI) Stable visual perception is maintained despite the frequent saccadic eye-movements that disrupt the visual input. One hypothesis for this compensation is that advanced knowledge of the impending saccade is provided by an internal copy, a corollary discharge (CD) signal, of the motor command. This copy is utilized to distinguish self-generated sensations from environmental disturbances and reflects properties of the original motor command. Examining normal human subjects and patients with Schizophrenia, the goal of this project is to understand the role of corollary discharge in visual perception and movement control with the objective of contributing to the diagnosis and treatment of diseases that result from CD transmission deficits. The expected outcomes of the research is to provide evidence that perceptual judgments of transsaccadic changes is influenced by the variability reflected in the CD signal, and that this 45 detection ability is diminished when CD transmission is degraded in Schizophrenia. This contribution is significant because in addition to diagnostics, the majority of the internal signals in the brain that do not represent sensory or motor information are presently inaccessible, and it is likely that diseases that impair higher cognitive function affect these circuits, as in Schizophrenia. CD is one of the few internal signals that is experimentally accessible and, through its study, an enhanced understanding of these signals and their transmission can be achieved. Biocompatibility of Advanced Materials for Brain Machine Interfaces (BAMBI) Funding Agency: Defense Advanced Research Projects Agency Budget: $3,234,626 Dates 2011-2014: Bioengineering Faculty: Joseph J Pancrazio (PI) and Nathalia Peixoto (co-PI) The overall goal of this project is to establish and demonstrate a systematic process for testing novel materials for use in a new generation of reliable brain machine interfaces (BMIs). Biomaterial testing involves three fundamental phases: 1) in vitro testing of the material with cell lines; 2) material robustness and durability; and 3) in vivo testing. This project will fill a critical gap in our ability to take full advantage of emerging materials by supplying this testing capability to the material science community and working cooperatively to bring new materials forward. Our approach is novel since it will enable a translational bridge for exciting developments in material science to be rapidly considered for neural interface applications. Our group provides multidisciplinary access to expertise in electrochemistry, material science, in vitro cellular assays, and immunohistochemistry to conduct consistent, rapid, and systematic assessments of novel materials. GARDE: Equals: Enhancing Quality of Life of Students through Senior Designs Funding Agency: NSF Budget: $125,000 Dates: 2012-2016 Bioengineering Faculty: Nathalia Peixoto (PI); Vasiliki Ikonomidou (co-PI) Intellectual merit: The main intellectual merit of this project is the design of devices that enhance the quality of life of students with disabilities. So far one device has been delivered, and three other devices are currently being developed. Results from one project have been presented at the Rehabilitation Engineering and Assistive Technology Society of North America conference, and the design team was selected as one of the ten finalists. Broader impacts: we have so far trained 15 senior engineering design students. Even in this early phase, the senior design projects are attracting attention from the media, both internal and external to GMU. One of the projects involved the development of an automated camera control system. This project sparked a collaboration between the engineering students and Business School students, and a company was founded to explore potential commercialization of the system they developed. The company took part in the GMU business plan competition and their project was selected as one of the ten finalists. Pattern-Steering in Nonlinear Dynamical Networks 46 Funding Agency: NSF Budget: $300,000 Dates: 2010-2013 Bioengineering Affiliate Faculty: Nathalia Peixoto (co-PI) This project makes use of several mathematical models to understand and to explain the dynamics in two experimental models of complex networks: neuronal cell cultures and nematic liquid crystals. In this project we have worked toward steering those networks from one basin to another, associating the mathematical models to experimental patterns. Cortical Stimulation for Seizure Disruption in a Rodent Epilepsy Model Funding Agency: Mason/INOVA Life Sciences Research Grant Budget: $50,000 Dates: 2013-2014 Bioengineering Affiliate Faculty: Nathalia Peixoto (PI), James Leiphart (co-PI) Seizures may be halted through electrical stimulation of the seizure focus. This project explores sub-threshold stimulation waveforms that yield a lower seizure rate in the kainic acid model of epilepsy in rodents. VA STEM CoNNECT: Virginia Collaborative Nurturing Network to Enhance Content-Focused Teaching. Funding Agency: VA Dept of Education Budget: $100,000 Dates: 2011-2013 Bioengineering Affiliate Faculty: Nathalia Peixoto (co-PI) This grant supports the development of engineering design lectures to math and science teachers in Middle and High School in Virginia. The objective is to strengthen the connection between mathematics and engineering early on in the educational system. MRI: Acquisition of Electron Beam Evaporation System for Multidisciplinary Research and Education Funding Agency: NSF Budget: $300,000 Dates: 2011-2013 Bioengineering Affiliate Faculty: Nathalia Peixoto (co-PI) This major research instrumentation grant supports the acquisition of an evaporator that can deposit and define thin films of conductive materials. The specific research interest for the Neural Engineering Lab is to design implantable probes and fabricate them in house. Pathogenesis and Pathophysiological Mechanisms of Myofascial Trigger Points Funding Agency: National Institutes of Health (R01) Budget: $2,193,086 Dates: 2010-2014 47 Bioengineering Faculty: Siddartha Sikdar (PI) The specific aims of this project are designed to understand the relationship between MTrPs and chronic pain. Myofascial pain syndrome (MPS) is a common, soft-tissue musculoskeletal disorder, which can be characterized by MTrPs. This investigation will study two groups: (A) patients with chronic soft-tissue neck pian and palpable MTrPs (N=90) and (B) asymptomatic normal subjects (N=30). New and innovative methodology combining ultrasound, mechanical imaging, biochemical techniques and physical examination measures to quantitatively characterize MTrPs. Using ultrasound imaging and biochemical assays, information about the soft tissue and vascular environments associated with MTrPs and without MTrPs will be assessed. Subjects in group A with MTrPs will be treated by perturbing trigger points with a 3week course of dry needle therapy, and these subjects will be re-evaluated clinically and using imaging and biochemical measurements, immediately after the treatment and at 3 weeks follow up. The overall hypothesis is the pathogensis of MPS involves local trauma to the muscle fibers producing high levels of pro-inflammatory cytokines and nociceptive) pain-inducing) substances. The altered biochemical milieu causes sustained muscle contracture leading to blood vessel compression and local ischemia, resulting in the painful nodule (MTrP). Relieving the module through dry needle therapy restores blood flow and the biochemical milieu. CAREER: An Integrated Systems Approach to Understanding Complex Muscle Disorders Funding Agency: National Science Foundation Budget: $400,000 Dates: 2010-2015 Bioengineering Faculty: Siddartha Sikdar (PI) The objective of this research is to investigate complex dynamic interactions between the musculoskeletal, circulatory and nervous systems involved in common, yet poorly understood, muscle disorders. The approach is to develop novel dynamic ultrasound imaging modes for quantifying anisotropic muscle kinematics, viscoelastic tissue properties and blood flow, and integrate these novel measures with conventional measures of tissue oxygenation, electrical activation, strength, and range of motion to characterize the underlying physiological systems. Intellectual Merit: Real-time ultrasound imaging is uniquely suited for dynamic muscle function studies because it is cost-effective, portable and can be integrated with other measurements. However, the lack of quantitative dynamic measures and challenges due to anisotropy of muscle has resulted in barriers to widespread use of ultrasound. The proposed research is designed to overcome these barriers. The technical contributions are the theoretical and experimental investigation of novel ultrasound beam configurations, imaging modes and signal and image processing algorithms for quantitative imaging of anisotropic tissue motion and viscoelastic tissue properties. Broader Impacts: This research will provide enabling tools for understanding functional limitations in musculoskeletal disorders and measuring treatment efficacy, potentially leading to more effective therapies for this significant public health problem. Research and educational objectives are integrated to engage graduate, undergraduate and high school students as part of a new bioengineering curriculum. Outreach efforts include summer research programs for high school students, a bioengineering demonstration kit encouraging students to pursue careers in science and engineering, and engaging the local K-12 community by presenting stateof-the-art research on muscle disorders affecting school-age children 48 Asymptomatic Carotid Stenosis: Cognitive Function and Plaque Correlates (ACCOF) Funding Agency: Department of Veterans Affairs Budget: $247,930 Dates: 2011-2012 Bioengineering Faculty: Siddartha Sikdar (PI) Carotid artery plaques are known to cause stroke. Cognitive impairment is an insidious but poorly understood problem in patients with carotid plaques. In this study, we are uncovering the extent of cognitive impairment in veterans with carotid stenosis who are currently labeled "asymptomatic". We are using sophisticated 3D imaging techniques developed by our group to measure the structure and composition of plaques, number of particles breaking off from them, and blood flow restriction to the brain from them. This will help identify patients at risk for cognitive impairment who may benefit from preventative measures and improve selection of patients to decrease unnecessary surgical procedures. III: Medium: Collaborative Research: Computational Methods to Advance Chemical Genetics by Bridging Chemical and Biological Spaces Funding Agency: NSF Budget: $339,537 Dates: 2009-2013 Bioengineering Affiliate Faculty: Huzefa Rangwala (PI) The recent development of various government and University funded screening centers has provided the academic research community with access to state-of-the-art high-throughput and high-content screening facilities. As a result, chemical genetics, which uses small organic molecules to alter the function of proteins, has emerged as an important experimental technique for studying and understanding complex biological systems. However, the methods used to develop small-molecule modulators (chemical probes) of specific protein functions and analyze the phenotypes induced by them have not kept pace with advances in the experimental screening technologies. This project will develop novel algorithms in the areas of cheminformatics, bioinformatics, and machine learning to analyze the publicly available information associated with proteins and the molecules that modulate their functions (target-ligand activity matrix). These algorithms will be used to develop new classes of computational methods and tools to aid in the development of chemical probes and the analysis of the phenotypes elicited by small molecules. The key hypothesis underlying this research is that the target-ligand activity matrix contains a wealth of information that if properly analyzed can provide insights connecting the structure of the chemical compounds (chemical space) to the structure of the proteins and their functions (biological space). CAREER: Annotating the Microbiome using Machine Learning Methods Funding Agency: NSF Funding Agency: NSF Budget: $550,000 Dates: 2013-2018 Bioengineering Affiliate Faculty: Huzefa Rangwala (PI) 49 This project addresses an important challenge of developing sophisticated and novel machine learning techniques for complex real-world problems. New technologies allow us to determine the genomes of organisms co-existing within various ecosystems ranging from ocean, soil and human-body. Several researchers have embarked on studying the pathogenic role played by the microbiome, defined as the collection of microbial organisms within the human body, with respect to human health and disease conditions. The research activities in this CAREER project will develop approaches for the identification of taxonomy, function and metabolic potential from the collective genomes samples. A key contribution will be the development of multi-task learning approaches that combine information across multiple hierarchical databases associated with the annotation problems. During research, the PI will investigate the best ways to capture the underlying hierarchical structure, prevalent within different annotation databases. The rationale underlying this proposed research is that there is a wealth of complementary information that exists across several manually curated biological databases. Associating microbiome with phenotype requires integration of various high-throughput omic data sources (genomic, metabolic, proteomic) that may not be uniformly available across all samples. A Unified Computational Framework to Enhance the Ab-initio Sampling of Native-like Protein Conformations Funding agency: NSF Budget: $449,000 Dates: 2010-2013 Bioengineering Affiliate Faculty: Amarda Shehu (PI) The research involves the design and analysis of a framework to compute the spatial arrangements, also known as conformations, in which a protein chain of amino acids is biologically-active (in its native state). This is an important goal towards understanding protein function. While proteins are central to many biochemical processes, little is known about millions of protein sequences obtained from organismal genomes. The intellectual merit of this work lies in the development of a novel computational framework that combines probabilistic exploration with the theory of statistical mechanics to efficiently enhance the sampling of the conformational space near the native state. Low-dimensional projections guide the exploration towards low-energy and geometrically-diverse conformations. Additional intellectual merit lies in the incorporation of knowledge and observations emerging from biophysical theory and experiment, such as the use of coarse graining, relation between energy barrier height and temperature, and hierarchical organization of tertiary structure. Algorithmic components of the framework will be systematically evaluated for efficiency, accuracy, and how they enhance the sampling of the conformational space near the native state. CAREER: Probabilistic Methods for Addressing Complexity and Constraints in Protein Systems Funding agency: NSF Budget: $549,000 Dates: 2012-2017 Bioengineering Affiliate Faculty: Amarda Shehu (PI) The research addresses fundamental issues in protein modeling. Understanding proteins in silico involves searching a vast high-dimensional conformational space of inherently flexible systems 50 with numerous inter-related degrees of freedom, complex geometry, physical constraints, and continuous motion. Three core research directions are identified. (1) Geometric constraints underlying protein motion are not trivial to identify or address. The proposed research exploits mechanistic analogies between proteins and robot kinematic linkages and investigates inverse kinematics techniques to efficiently formulate and address complex geometric constraints arising in diverse protein studies. (2) The funnel-like protein energy landscape exposes physics-based energetic constraints that are often demanding to address in silico. The proposed research pursues a multiscale treatment of energetic constraints in the context of probabilistic search, supporting coarse- and fine-grained levels of protein representational detail and converting between them with information gathered during exploration. (3) The conformational ensemble view of the protein state relevant for function necessitates search algorithms capable of exploring the high-dimensional conformational space and its rugged energy landscape. A novel probabilistic search framework is proposed that gathers information about the space it explores and employs this information to advance towards promising unexplored regions of the space. Taken together, these research directions allow addressing complexity in proteins by formulating and exploiting geometric and energetic constraints, thus narrowing the search space of interest to regions where the constraints are satisfied, and by employing a novel probabilistic framework with enhanced sampling capability able to feasibly search the relevant regions of the space. 51 Letters of Support from Potential Employers 1. Dr. Joel Myklebust, Deputy Director, Office of Science and Engineering Laboratories, Center for Devices and Radiological Health, FDA 52 53 54 55