Find your life's calling
Arguably, your most important task at hand is to figure out how to best spend the years available to you. Every course you take is an opportunity to go a step further, tasting some new field of endeavor and adding or subtracting it from your list of candidates. This is possible only if you get close enough to see clearly the actual activity typical of the field.
A major goal of this course is to put you in a position where you can participate in a research project, enabling you to grasp what it is about, and to tell whether this is something for you.
Make progress towards independence
Arguably, the most important function of a college education isn't to get a degree, nor to get job next year, but to help prepare yourself for the rest of your life. Just as learning to read and do arithmetic many years ago made
you a more capable person in all aspects of your life, so can many higher order skills that few already possess upon entering college.
- Define problems rather than have them handed to you
If you ever find yourself working a job where all the decisions are made for you, then it's probably a short term job.
Prepare for automation to eventually push you to the unemployment line. Machines beat humans in well-defined
repetitive tasks, while humans beat machines in fuzzy problems, where insight is required to figure out what the
problem actually is. Like any other skill, finding sense in ill-defined problems takes practice. You will have it.
- Gain comfort in reading research articles
The primary literature, for example research articles, is where you can read for yourself what is known and make your own judgement what is true. But research articles are difficult to read. It's much easier to have someone else read them and tell you what is true. Textbooks do this. So do most web pages. Then why do you need to read research articles?
If you value your lives, you need to be able to feel comfortable reading the primary literature! Why? I could write for hours on this... In fact, I have.
- Take control of your education
Leave school, and you'll find nary a syllabus, nary a multiple choice exam, nary even a grade except in the most basic
sense. Whatever you learn will be your choice (learning nothing is also a choice). Can you build your own syllabus? Compose your own exams? Grade yourself? If not, it's time to learn how.
Understand how bioinformatics lets us see biology in a new light
"Introduction to Bioinformatics"...
You've no doubt taken many courses called Introduction to X where you've learned the basic concepts of X, enabling you to move on to Advanced X. You have a pretty good idea what X is going into the course, perhaps through colleagues who are X majors or a high school X course or perhaps even a hard-hitting TV show with a dashing Xologist as the main character.
That's fine when X is a mature field with a well-defined body of knowledge.
X is not bioinformatics.
Some courses focus on how to use state-of-the-art (also known as soon-to-be-extinct) tools.
Not this one.
Some focus on the timeless precepts behind bioinformatic tools.
That's a different course.
We will focus instead on something you can take away and use now and twenty years from now: the viewpoint of bioinformatics. The only way I know to help you grasp that viewpoint is to put you in a situation where you're using that viewpoint through problem-solving and within an actual scientific project. So that's what we'll do.
Much of the first half of the course will be devoted to getting you to a position where you can work productively on the Project, which will occupy most of your time the second half of the course.
Realize that the tools of bioinformatics are within your grasp
- Quantitative thinking
Nature sets traps for the unwary, and in bioinformatics, she sets BIG traps. Quantitative
thinking is our best defence. I'm not talking about fancy math. I've probably had fewer classes
and know less higher math than most of you in this class. I mean simple high school math, applied
daily to the world around you. Probability (i.e., creative counting) will pop up time and again
through our bioinformatic travels.
I don't count statistics as simple math, but they can be understood intuitively, and they can
protect us from idiocy. Unfortunately, without an intuitive understanding of them, they often
produce idiocy themselves. Periodically we'll examine common statistics to try to understand what
they really mean, then we'll use them to our advantage.
- Creative computation
Without understanding how the psychologist's contraption works, a dog paws the lever (or maybe
paws the air), hoping for a reward. Without understanding how computer programming works, biologists
paw glitzy applications, hoping for results. Without the ability to program the computer to do what
you want it to do (rather than allow it to program you), you're pretty much stuck on
the sidelines to cheer.
Those of you who have become comfortable in programming a computer will find it as difficult to
imagine not being able to do so as to imagine not being able to do long division.
Those of you who have never programmed will be delighted to discover that learning long division is
the more difficult task. You who do not know a programming language will know one
(BioBIKE) by the end of the course.
The combination of a digital computer and a creative human can do amazing things that neither
can do alone. In particular, it makes possible the exploration of massive amounts of information,
which is at the heart of bioinformatics and increasingly at the heart of biology.
However, this is not a course in computer programming. To learn how to make a computer work
reliably, efficiently, and beyond reach of the idiocies of foolish humans is the subject of long
study, a study few want to undertake. But just as you all learned how to write (but not necessarily
write great poetry), in this course you will all learn how to create for yourself basic but extremely
useful shopping-list computer programs.
Want more arguments as to why people interested in biology need to be able to use simple math?
Cohen JE (2006). Mathematics is biology's next microscope, only better; biology is mathematics' next physics, only better. PLoS Biology 2:e439.
Want more arguments as to why people interested in biology need to be able to program a computer?
Elhai J (2010). Humans, computers, and the route to biological insights: Retaining our capacity for surprise. Journal of Computational Biology (in press).