Fix the PhD

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From Spring- Fall 2012, I spent some time working as the Neurosciences Program representative to a student advisory board, working on curriculum reform for the Stanford Biosciences umbrella program. While I’m very proud of the work our committee did, particularly with implementing a new set of two week, intensive, hands-on practical minicourses, we ran into some fundamental obstacles when we considered how best to make grad school prepare students for a wide variety of career options. These obstacles existed not in Stanford itself, but in the structure of incentives for graduate schools as a whole. When the NSF put out a call for ideas to improve graduate education, I figured it was worth putting these thoughts into writing. The piece that follows was my submission, and generally outlines my feelings on what a science PhD program ought to look like for the 21st century.

Broaden the Base of Excellence

In his 2013 State of the Union address, President Obama called for an education policy that increases “focus on science, technology, engineering and math, the skills today’s employers are looking for to fill the jobs that are there right now and will be there in the future.” Though a PhD in science or engineering can—and should—be valuable for any job that involves thinking hard about complex problems and coming up with innovative solutions, PhD programs generally do not train students with these options in mind. A substantial portion of trainees go into careers for which they have little or no training: as of 2011, the National Science Foundation reported that only half of the roughly 50,000 PhD graduates went on to academic postdocs, and that only 15% of the students that graduated five years earlier had become tenure-track faculty. If the underlying goal is innovation and economic growth, then we need to train people to thrive in non-academic-science positions where their scientific skills and expertise can help drive the economy.

PhDs could be starting companies that create jobs, communicating science to lawmakers, teaching the next generation of science students, or developing treatments in biotech and pharmaceuticals. But within the current framework of academic culture and funding incentives, most PhD training programs focus too narrowly on funneling students towards tenure-track academic science. We need to broaden the base of excellence in graduate training, maintaining high standards of quality while expanding the definition to include more careers that benefit from a scientific education.

In the long term, we need to fundamentally shift the culture of graduate school (for both faculty and students), from solely valuing the research that a student produces, to valuing the full range of meaningful contributions that they might choose to make with their training. But such a change cannot happen overnight—institutional factors, implicit biases, and the weight of tradition would not make it easy. In the short term, however, government could catalyze this transition, paving the way for scientific training programs that empower students to use their training for a variety of productive career options. If we change the way incentives are structured for the programs that train our PhDs, if we reward programs for training the best teachers and entrepreneurs alongside quality scientists, more fundamental change can follow.

Many graduate students, particularly those at top institutions, are funded by training grants. Some of these training grants are individual pre-doctoral fellowships, but some are also awarded at the level of a department or graduate program, such as the NSF IGERT program or the NIH T32. With funding for graduate students being a premium resource, the requirements for such grants, particularly institutional training grants, help to shape the structure and culture of training programs. Unfortunately, for many of these grants, the criteria by which a program or a student is judged (number of academic postdocs, number of publications in top journals) are far too narrow. Programs with institutional grants whose graduates later become leaders in industry, policy, or education are, at best, required to explain themselves, and at worst are actively discouraged. The first step in improving graduate education is for such grants to acknowledge that successful training means any career, research included, in which trainees use their skills and expertise to meaningfully contribute to society.

Some funding organizations are already getting on board with this definition. In 2011, the National Institute for General Medical Sciences put out a report calling for a comprehensive overhaul of their training grant criteria for success.  Based on conversations with stakeholders from all parts of the training process, from administrators to faculty to current trainees, the report suggests that the definition of success in scientific training needs to be broader. One version is particularly resonant: “For society, success is having a strong and diverse cadre of creative thinkers and innovative problem solvers.” To this end, the report suggests encouraging recipient programs to provide broad, flexible professional development training, and to encourage a focus on student development, rather than selection of talent alone. But why not go one step further? Funding institutions could actively encourage training programs that support any career path that thoroughly uses the skills and the training that a graduate education provides, and that make partnerships, within their universities and their communities, to offer training in the skills necessary to be competitive in today’s job market.

Institutional training grant applications currently require a description of how the program will provide professional development training to their students, usually focusing on scientific ethics and academic professional development, and individual predoctoral fellowships require statements of broader impacts. Why not also ask these institutions: how are you providing resources to students who want to acquire skills and knowledge outside the lab? How are your students exposed to a broad array of career options? Why not ask trainees on individual fellowships: how will you find the resources you need to succeed in the career of your choosing? Simply asking these kinds of questions incentivizes training institutions to experiment with how best to provide resources and encourage students to seek them out. Some programs might forge partnerships with biotechnology and pharmaceutical companies, or strengthen ties within their university to writing centers, public speaking centers, or career development centers. Others might, for example, set aside two weeks of every term as dedicated professional development time, offering courses in pedagogy, public speaking, interdisciplinary problem solving, or management. In turn, funding organizations can track which interventions get more graduates into jobs that use the skills they have acquired.

The hope, then, is that by changing the structural incentives at the highest level, we might begin the work of updating graduate school for the 21st century. So that is the dream: a culture of graduate science education that empowers students to be the best in whatever science-related career that they choose, and that arms them with tools for thinking and interacting with others that make them valuable to employers across disciplines. Such a shift, beginning with a change in incentives, is what graduate education needs to train happy, healthy, empowered students who will develop into excellent researchers, leaders, innovators, and entrepreneurs.

Right now, many science PhD programs follow a similar pattern: take courses, perhaps act as a teaching assistant, take an oral and written qualifying exam, and then tackle a mentored project to generate data until you graduate. With those initial hurdles finished, the only measurement of success that a PhD student has—and the only one that has any traction in the current graduation school culture—is progress in the lab. From the qualifying exam to the thesis defense, the most important product of graduate school is the thesis itself, despite the fact that many students who go on to postdocs are not necessarily performing the same techniques or working in the same subfield. But what if students could measure their success not only by the progress of their research, but also by their progress towards the skillset they need for a rewarding career of their choice? What if taking a professional development course on public speaking, teaching, or management felt as valuable as running another experiment?

A PhD program for the 21st century should focus on the trainee as the primary product of graduate school, and the culture of such a program should encourage a broad base of professional development and successful self-improvement to prepare trainees to meaningfully contribute to society. With such a program, a PhD could signify to any future employer that a graduate has a variety of marketable skills: critical thinking, making and evaluating evidence-based arguments, communicating complex concepts, identifying important problems from a body of background knowledge, and coming up with innovative ways to solve them. The students from such a program would benefit from a clear path to becoming leaders in whatever field they choose, from academic science, to industry, to policy, to teaching.

Admittedly, changing these incentives may require some work to measure and quantify, because the success of a program can no longer be boiled down to statistics about numbers of papers published in high-impact journals and number of students going on to academic postdocs. It will fall to the champions of 21st-century graduate training to make decisions about what is sufficient breadth of career exposure, sufficient support for professional development, and about which career options are worth investing time and energy into supporting. Simply starting the conversation about re-defining success in graduate science education could be a priceless step towards improving the process, and is essential for building momentum for cultural and institutional change. Funding institutions, by virtue of the power they hold, are in a fantastic position to start these conversations and watch as their effects propagate. By taking those first steps out of the well-trodden path of purely academic definitions of success, funding institutions could become the trailblazers for bringing graduate education in line with the myriad of ways that intelligent, well-educated science trainees can contribute to society.

Linky and the Brain: April 30, 2013

Linky and the Brain_small

Linky and the Brain_small We're doing some expanding here at the Neuroblog. In the next few months, readers will start to notice some new names at the top of posts. This expansion of our authorship is due to a newly formalized partnership with the Stanford-based science communication group NeuWrite West.

As part of this expansion, Nick Weiler and I will trade off authorship of a weekly feature, highlighting the science-related internet content that caught our eyes the previous week. I'd like to encourage folks out there to use the comments to jump in and share any items they enjoyed.

With this introduction, I'll debute entry #1 in our new link-sharing feature. 

Absolutely incredible slow-motion video of barn owl hunting

This came to my attention both via the internets and several folks who shared it with me on Facebook. A stunning video of a barn owl using an auditory cue to strike at prey. The video starts out with a side perspective, but keep watching past the first example as the video switches to showing a bottom up angle that highlights the view of the descending owl from the perspective of the prey. Looking at the focused gaze of the swooping owl, with its outstretched talons drawing inexorably closer, I realize its probably a blessing that mice can't see so well.

Interested in the neural mechanisms of how barn owls localize sound? How maps of visual and auditory space are aligned in the barn owl brain to provide a neural substrate for the terrible precision of the bird's ability to locate prey? I'll direct the curious to the work of Mark Konishi (Caltech), as well as Eric Knudsen (Stanford, my graduate advisor, former postdoc of Konishi).

The Evolution of the Country Mouse and the City Mouse

As usual, Carl Zimmer shows science writers how its done in his post highlighting research into "urban evolution". In particular the work of Jason Munshi-South (Baruch College), who studies evolutionary trajectories of white footed-mouse populations in, and around, NYC.

The art of the ambiguous conference poster abstract

In honor of the rapidly approaching SfN 2013 poster abstract deadline, Dr. Becca (@doc_becca) on writing an abstract in the absence of any data (original publication date, last year). A subject near and dear to my heart right now (damn you, preliminary data! I wish you were a fully-fleshed out scientific story already.)

U.S. Lawmaker Proposes New Criteria for Choosing NSF Grants

As a researcher personally funded by the NSF, this Science Insider news article gave me all sorts of feelings.

And some opposition to the proposed changes, from President Obama.

A Tale Of Mice And Medical Research, Wiped Out By A Superstorm

A more tragic topic - NPR covers the tragic losses suffered by Gord Fishell (and other researchers at NYU) when Superstorm Sandy caused flooding in an offsite animal facility.

Battlestar Pedagogica: Using Science Fiction to teach Science!

As an avid science fiction reader (and BSG viewer), I enjoyed reading this post on using science fiction to teach scientific concepts in the classroom. In my experiences chatting about neuroscience with non-neuroscientists (especially my computer science friends), I've found referencing sci-fi concepts to be a remarkably useful way to a) capture attention/interest and b) generate fascinating and complex discussions of current neuroscience.

Isaac Asimov Memorial Debate.

Neil deGrasse Tyson moderates the Isaac Asimov Memorial Debate. This years topic: Nothingness. The panel: Lawrence Krauss (theoretical physics, ASU), J. Richard Gott (astrophysics, Princeton), veteran science journalists Jim Holt (science journalist) and Charles Seife (science journalist), and Eve Silverstein (physics, Stanford). (via io9)

Academic Fraud, a profile of social psychologist Diederik Stapel in the NYTimes Magazine.

A long read from the NYTimes Magazine, on Dutch social psychologist Diederik Stapel who fabricated results in at least 55 of his published articles. Written by Yudhijit Bhattacharjee. (via Cori Bargmann, @betenoire1)

Ending on a Happy Note: First Steps in Border Collie Sheepdog Training.

From the twitter account of @herdyshepherd1, training a border collie to herd sheep.

And that's all the links I've got for now folks. See you round the web. -Astra