printer friendly pageAFRICAST 235: Designing Research-Based Interventions to Solve Global Health Problems (AFRICAST 135, EDUC 135, EDUC 335, EPI 235, HUMBIO 26, MED 235)
The excitement around social innovation and entrepreneurship has spawned numerous startups focused on tackling world problems, particularly in the fields of education and health. The best social ventures are launched with careful consideration paid to research, design, and efficacy. This course offers students an immersive educational experience into understanding how to effectively develop, evaluate, and scale social ventures. Students will also get a rare "behind-the-scenes" glimpse at the complex ethical dilemmas social entrepreneurs have tackled to navigate the odds. Partnered with TeachAids, a global award-winning nonprofit (scaled to 82 countries), this course introduces students to the major principles of research-based design and integrates instruction supported by several game-changing social leaders. Open to both undergraduate and graduate students, it culminates in a formal presentation to an interdisciplinary panel of diverse Silicon Valley leaders. (Cardinal Course certified by the Haas Center)
Terms: Win
| Units: 3
BIOE 273: Biodesign for Digital Health (MED 273)
Health care is facing significant cross-industry challenges and opportunities created by a number of factors, including the increasing need for improved access to affordable, high-quality care; growing demand from consumers for greater control of their health and health data; the shift in focus from sick care to prevention and health optimization; aging demographics and the increased burden of chronic conditions; and new emphasis on real-world, measurable health outcomes for individuals and populations. Moreover, the delivery of health information and services is no longer tied to traditional brick and mortar hospitals and clinics: it has increasingly become "mobile," enabled by apps, sensors, wearables. Simultaneously, it has been augmented and often revolutionized by emerging digital and information technologies, as well as by the data that these technologies generate. This multifactorial transformation presents opportunities for innovation across the entire cycle of care, from welln
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Health care is facing significant cross-industry challenges and opportunities created by a number of factors, including the increasing need for improved access to affordable, high-quality care; growing demand from consumers for greater control of their health and health data; the shift in focus from sick care to prevention and health optimization; aging demographics and the increased burden of chronic conditions; and new emphasis on real-world, measurable health outcomes for individuals and populations. Moreover, the delivery of health information and services is no longer tied to traditional brick and mortar hospitals and clinics: it has increasingly become "mobile," enabled by apps, sensors, wearables. Simultaneously, it has been augmented and often revolutionized by emerging digital and information technologies, as well as by the data that these technologies generate. This multifactorial transformation presents opportunities for innovation across the entire cycle of care, from wellness, to acute and chronic diseases, to care at the end of life. But how does one approach innovation in digital health to address these health care challenges while ensuring the greatest chance of success? At Stanford Biodesign, we believe that innovation is a process that can be learned, practiced, and perfected; and, it starts with an unmet need. In Biodesign for Digital Health, students will learn about digital health and the Biodesign needs-driven innovation process from over 50 industry experts. Over the course of 10weeks, these speakers will join the teaching team in a dynamic classroom environment that includes lectures, panel discussions, and breakout sessions. These experts represent startups, corporations, venture capital firms, accelerators, research labs, healthcare providers, and more. Student teams will take actual digital and mobile health challenges and learn how to apply Biodesign innovation principles to research and evaluate needs, ideate solutions, and objectively assess them against key criteria for satisfying the needs. Teams take a hands-on approach with the support of need coaches and other mentors. On the final day of class, teams present to a panel of digital health experts and compete for project extension funding. Friday section will be used for team projects and for scheduled workshops. Limited enrollment for this course. Students should submit their application online via:
https://stanforduniversity.qualtrics.com/jfe/form/SV_dnY6nvUXMYeILkO
Terms: Aut
| Units: 3-4
BIOE 374A: Biodesign Innovation: Needs Finding and Concept Creation (ME 368A, MED 272A)
In this two-quarter course series (
BIOE 374A/B,
MED 272A/B,
ME 368A/B,
OIT 384/5), multidisciplinary student teams identify real-world unmet healthcare needs, invent new health technologies to address them, and plan for their implementation into patient care. During the first quarter (winter), students select and characterize an important unmet healthcare problem, validate it through primary interviews and secondary research, and then brainstorm and screen initial technology-based solutions. In the second quarter (spring), teams select a lead solution and move it toward the market through prototyping, technical re-risking, strategies to address healthcare-specific requirements (regulation, reimbursement), and business planning. Final presentations in winter and spring are made to a panel of prominent health technology experts and/or investors. Class sessions include faculty-led instruction and case studies, coaching sessions by industry specialists, expert guest lecturers, and int
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In this two-quarter course series (
BIOE 374A/B,
MED 272A/B,
ME 368A/B,
OIT 384/5), multidisciplinary student teams identify real-world unmet healthcare needs, invent new health technologies to address them, and plan for their implementation into patient care. During the first quarter (winter), students select and characterize an important unmet healthcare problem, validate it through primary interviews and secondary research, and then brainstorm and screen initial technology-based solutions. In the second quarter (spring), teams select a lead solution and move it toward the market through prototyping, technical re-risking, strategies to address healthcare-specific requirements (regulation, reimbursement), and business planning. Final presentations in winter and spring are made to a panel of prominent health technology experts and/or investors. Class sessions include faculty-led instruction and case studies, coaching sessions by industry specialists, expert guest lecturers, and interactive team meetings. Enrollment is by application only, and students are required to participate in both quarters of the course. Visit
http://biodesign.stanford.edu/programs/stanford-courses/biodesign-innovation.html to access the application, examples of past projects, and student testimonials. More information about Stanford Biodesign, which has led to the creation of 50 venture-backed healthcare companies and has helped hundreds of student launch health technology careers, can be found at
http://biodesign.stanford.edu/.
Terms: Win
| Units: 4
Instructors:
Denend, L. (PI)
;
Edmonds, Z. (SI)
;
Makower, J. (SI)
...
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Instructors:
Denend, L. (PI)
;
Edmonds, Z. (SI)
;
Makower, J. (SI)
;
Venook, R. (SI)
;
Sunier, S. (TA)
BIOE 374B: Biodesign Innovation: Concept Development and Implementation (ME 368B, MED 272B)
In this two-quarter course, multidisciplinary teams identify real unmet healthcare needs, invent health technologies to address them, and plan for their implementation into patient care. In second quarter, teams select a lead solution to advance through technical prototyping, strategies to address healthcare-specific requirements (IP, regulation, reimbursement), and business planning. Class sessions include faculty-led instruction, case studies, coaching sessions by experts, guest lecturers, and interactive team meetings. Enrollment is by application. Students are required to take both quarters of the course.
Terms: Spr
| Units: 4
| Repeatable
2 times
(up to 8 units total)
BIOE 376: Startup Garage: Design (SUSTAIN 376)
Startup Garage is an intensive, hands-on, project-based course where students apply human-centric design, lean startup methodology, and the Business Model Canvas to conceive, design, and field-test new business concepts that address real world needs. Teams get out of the building and interact directly with users, industry participants, and advisors to deeply understand one or more unmet customer needs. They proceed to design, prototype, and test their proposed products or services and a business model. Teams working on impact-focused ventures will apply the same methodology to address the needs of their beneficiaries. Students develop entrepreneurial skills as they learn critical, cutting-edge techniques about launching a venture. The course is offered by the Graduate School of Business. PREREQUISITE: Team application required. See details and apply at
http://startupgarage.stanford.edu/details (login required).
Terms: Aut
| Units: 4
BIOE 377: Startup Garage: Testing and Launch (SUSTAIN 377)
In this intensive, hands-on project based course, teams continue to develop their ventures based on a user need that they validated in preparation for the course. They build out more elaborate versions of their prototypes and Business Model Canvas; test hypotheses about the product/service, business model, value proposition, customer acquisition, revenue generation, and fundraising; and deliver a seed round financing pitch to a panel of investors. Students develop entrepreneurial skills as they 1) Get out of the building and gather insights from users, investors, and advisors, 2) Make decisions about pivoting, 3) Work through their operating plans and unit economics, 4) Test go-to-market strategies, 5) Consider equity splits, 6) Learn term sheet negotiations, and 7) Practice their pitches. PREREQUISITE:
SUSTAIN 376 or a team application. See details and apply at
http://startupgarage.stanford.edu/details (login required).
Terms: Win
| Units: 4
BIOS 289: Preparation & Practice: Finance of Biotechnology
Tailored lectures and case studies lead to a practical final project. Leaders from local firms and companies will help you gain insight into the biotechnology industry, the skills and experiences necessary to succeed, and the various roles and responsibilities within the industry. Coursework is divided into 4 sections: Introductory Material: The first segment consists of two lectures and introduces the biotechnology company life cycle along with introductory concepts in finance. Venture Capital and Private Equity: The second segment consists of three lectures devoted to venture capital finance and private equity where students will learn the basic mechanics of raising capital. nPublic Finance: The third segment consists of the interpretation of financial statements, construction of company forecasts, and evaluating business value from such projections. Final Project: The final lecture will conclude with student presentations on their final projects.
Terms: Win
| Units: 1
Instructors:
Eberle, S. (PI)
BIOS 290: Preparation & Practice: Law
Through tailored lecture, case study and a practical final project, Biosciences and interdisciplinary sciences students and trainees will learn how to apply the skills they acquired in their academic training to a career in Patent Prosecution and related fields. Taught by field and faculty experts, this is your opportunity to network with IP law representatives and to gain hands-on experience in a new career of choice option. Topics include: applying for positions, the importance of IP protection, licensing, overview of the patent process, drafting applications and litigation.
Terms: Aut
| Units: 1
CEE 227: Global Project Finance
Public and private sources of finance for large, complex, capital-intensive projects in developed and developing countries. Benefits and disadvantages, major participants, risk sharing, and challenges of project finance in emerging markets. Financial, economic, political, cultural, and technological elements that affect project structures, processes, and outcomes. Case studies. Limited enrollment.
Terms: Win
| Units: 3-5
Instructors:
Bennon, M. (PI)
;
de Souza, L. (TA)
CEE 275A: California Coast: Science, Policy, and Law (CEE 175A)
This interdisciplinary course integrates the legal, scientific, and policy dimensions of how we characterize and manage resource use and allocation along the California coast. We will use this geographic setting as the vehicle for exploring more generally how agencies, legislatures, and courts resolve resource-use conflicts and the role that scientific information and uncertainty play in the process. Our focus will be on the land-sea interface as we explore contemporary coastal land-use and marine resource decision-making, including coastal pollution, public health, ecosystem management; public access; private development; local community and state infrastructure; natural systems and significant threats; resource extraction; and conservation, mitigation and restoration. Students will learn the fundamental physics, chemistry, and biology of the coastal zone, tools for exploring data collected in the coastal ocean, and the institutional framework that shapes public and private decisions
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This interdisciplinary course integrates the legal, scientific, and policy dimensions of how we characterize and manage resource use and allocation along the California coast. We will use this geographic setting as the vehicle for exploring more generally how agencies, legislatures, and courts resolve resource-use conflicts and the role that scientific information and uncertainty play in the process. Our focus will be on the land-sea interface as we explore contemporary coastal land-use and marine resource decision-making, including coastal pollution, public health, ecosystem management; public access; private development; local community and state infrastructure; natural systems and significant threats; resource extraction; and conservation, mitigation and restoration. Students will learn the fundamental physics, chemistry, and biology of the coastal zone, tools for exploring data collected in the coastal ocean, and the institutional framework that shapes public and private decisions affecting coastal resources. There will be 3 to 4 written assignments addressing policy and science issues during the quarter, as well as a take-home final assignment. Special Instructions: In-class work and discussion is often done in interdisciplinary teams of students from the School of Law, the School of Engineering, the School of Humanities and Sciences, and the Doerr School of Sustainability. Students are expected to participate in class discussion and field trips. Elements used in grading: Participation, including class session and field trip attendance, writing and quantitative assignments. Cross-listed with Civil & Environmental Engineering (
CEE 175A/275A) and Law (
LAW 2510). Open to graduate students and to advanced undergraduates with instructor permission. Enrollment limited.
Terms: Spr
| Units: 3-4
Instructors:
Boehm, A. (PI)
;
Sivas, D. (PI)
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