One of the many reasons I value living in other cultures, is that when I am removed from my culture, I have greater insight into my culture’s affect on who I am.

There is a fascinating radio show produced by NPR’s “This American Life” that explores the impact of testosterone on us. The first segment is a man who lost the ability to produce testosterone. In those four months he describes his loss of desire, not just the desire that we would suppose, but the desire for anything. To be sure , there was peace in not continually wanting, there was however also a sense of dismay in how much who he was dependant on testosterone.

Image from Adaptive Curriculum's "Human Body Systems"

The second segment was from a man who was born as a woman. Except for the growth of side burns and losing the ability to have a cleansing cry, this man didn’t describe how testosterone injections changed him physically. Perhaps it was assumed that almost everybody knows it can lead to secondary sexual characteristics, including bigger bones, stronger muscles, and a deeper voice. The change he described was on viewing women in a different way, and regrettably not being able to be as close to women any more.

Then in what seems like it could be fodder for afternoon TV, the folks at NPR sent in saliva samples to see who had the most testosterone. There was one group of five males and one group of four females. They all predicted relative levels first. Everybody thought that the woman in the office who made decisive decisions and spoke her mind would have the most testosterone. She even thought so, but hoped she was wrong. They were all right. There were differences in opinion for the males, as they displayed various tendencies, interests, and characteristics. The male who had the least was somewhat dismayed by the results. He said something like this, “I could have accepted this if I worked at ESPN’s Sports Center. But I work at NPR.” Then the “winner,” a balding, muscular, gay man (with almost twice as much testosterone as everybody else) wondered aloud, what is Sports Center? Which the least testosterone man took as another wound—he has more testosterone than me but doesn’t know what Sports Center is! It was a very funny radio moment.

The show ends with a mother reporting on and interviewing her very quiet 15 year-old son. In the process she presents how different her son and daughter are.

In high school biology we talk about hormones in general, and delve lightly into sex hormones. If you want a more interesting assignment (than answer Chapter 4 questions) for mature students, assign them this one-hour broadcast to listen to and ask them to write a one-page reflection. Lots of themes will emerge, and as you read your students’ work, you will have insights into who they are.

The show can be accessed or downloaded for free at: http://www.thisamericanlife.org/Radio_Episode.aspx?sched=1230. It can also be purchased at iTunes for 99 cents.

The videos on television show some of the massive destruction and the human toll of the recent earthquake in Haiti. It is difficult to imagine the suffering of the Haitian people. It is an unfortunate example of the devastation of a magnitude 7 earthquake.

It is natural to wonder why or how. When students are ready, teachers may want to discuss  earthquakes and their causes.

The folks at IRIS have a website with a PowerPoint presentation and Quicktime movie that explain a lot of details associated with this particular earthquake and earthquakes in general. The PowerPoint has excellent pictures of the destruction to buildings, without presenting images of human suffering that would be difficult for some students. The image to the right is taken from the PowerPoint.

IRIS (AKA the Incorporated Research Institutes for Seismology) has lots of resources for learning about earthquakes including SeisMac 2.0 which allows Macintosh computers to become seismographs.

In the quest for Science Literacy, we strive to give students an understanding of natural events before they happen. Adaptive Curriculum has two strong Activity Objects, one is on determining the magnitude of an earthquake and the other is determining the location of the earthquake. The image below is from “Earthquakes: Measuring Magnitude.“

When I was doing my sabbatical at the University of San Carlos (Cebu, Philippines), Ed Van den

Berg (one of the really great guys in science education), would have the undergraduate secondary education science students put on physics and chemistry demonstrations for the local school children. It was a delightful way to give them experience teaching and expose children to the interesting world of science. In the picture, two of my students demonstrate their fire tornado. (See http://www.west.asu.edu/rillero/philippines.htm for more of my photographs from the Philippines.)

In this YouTube video below, a similar program is described called “The Little Shop of Physics.”

I had the good fortune last week of being a conference presider for Irfan Kula, a talented educational designer. His session was “I Love Symbiosis.” He emailed me his PowerPoint presentation, and I am presenting this here:  i-love-symbiosis-kula.

A couple of days ago, the Wall Street Journal did an article entitled “Why We’re Failing Math and Science: A panel of experts talks about what’s wrong with our education system—and how to fix it“

One of the experts they interviewed was Joel Klein, chancellor of the New York City Department of Education. He said the following: “we’ve got to use technology differently. In any field but ours, if you fell asleep 50 years ago and woke up today, you wouldn’t recognize what’s going on. In education, if you fell asleep 50 years ago, you still have the same discussions.”

While classrooms have changed, the major change seems to be whiteboards for chalkboards and not big technology gains. The power of technology has not been used to greatly improve math and science education. Nor has technology been fully utilized to make it easier for teachers to help students learn and assess learning. Joel Klien suggests New York City schools are starting this process. As a former New York City teacher (Lehman High School in THE Bronx) I hope he is right, and that other school districts fully embrace technologies, like Adaptive Curriculum, that can help all students learn science and math.

We all want to avoid having children get hurt doing school science. We also don’t want teachers to avoid doing hands-on science because of fears related to safety issues in the science classroom. For the elementary school classroom there are a couple of valuable resources that can help teachers and administrators develop safer practices for science instruction.

These are:

Science and Safety: It’s Elementary (http://www.csss-science.org/downloads/scisaf_cal.pdf)

And

Safety in the Elementary (K-6) Science Classroom (http://membership.acs.org/c/ccs/pubs/K-6_art_2.pdf)

Many of these practices have been written with common sense in mind. And if you are safety minded, you are on the lookout for all the potential things that can go wrong and ways to prevent these accidents. Unfortunately, K-5 classrooms would not have some of this safety equipment, such as eyewash fountains, fume hoods, and safety showers, and probably most middle school science classrooms would come up short in these areas.

While going all virtual to avoid safety problems may be tempting, a more pragmatic solution is to avoid dangerous hands-on materials and be very careful to try science activities before hand, and monitor student behavior.

Technology For K-6 Science Safety

While technology is often thought of as electronic stuff, a better and wider view is that it is any human made products that make our lives better or safer. With this in mind, I present my top ten safety technologies.

1. Teacher Developed Safety Rules Contract: A teacher and students who are safety minded is probably the best defense against accidents. There should be no toleration of inappropriate behavior when doing hands-on science.

2. Goggles: Chemical splash safety goggles should be worn whenever what you are working with has the potential to hurt or damage eyes. Please don’t adopt the view, such as, “I use ammonia at home without goggles, so it is okay to use it in school without goggles.” An adult can decide not to use goggles at home and it is at their peril. If a teacher decides not to have students wear goggles with materials that could harm eyes, and eyes are damaged, the teacher will probably be held culpable, as will the administrators, the school, and the district.

3. Disposable Nitrile Gloves: From dissections to handling chemicals, these can prevent problems. And if a student is bleeding for any reason, an adult should put on gloves to help with the situation.

4. Locked Chemical Cabinet

5. Fire blanket and extinguisher

6. First aid kit

7. Proper waste containers

8. Rubber covered muslin aprons

9. Safety posters and signs

10. Non-mercury thermometers

Teachers should be urged to provide hands-on experiences for their students. But teachers are also responsible for the safety of their students.

I am at the NYSCATE Metro Conference, in Rye, NY. I grew up about 45 minutes from here but I forgot that it is still cold in mid-May. But of course, everything is relative, and relative to Arizona almost everywhere else is cooler.

This is the nyscate-critical-thinking  presentation I am  doing today. 

Angie, one of my science methods students shared this article with me. ScienceDaily (2009-03-28) — Self-led, self-structured inquiry may be the best method to train scientists at the college level and beyond, but it’s not the ideal way for all high school students to prepare for college science. That’s according to findings of a new study. See: http://www.sciencedaily.com/releases/2009/03/090326114415.htm#

“Ribosomes make protein.                                                                        A GUEST BLOG

Lysosomes keep it clean.

Endoplasmic Reticulum

transports things to and from. 

Nucleus runs the show.

Keeps control don’t you know!”

The kids wouldn’t stop rapping “Made of Cells”, an educational song I threw together to reinforce vocabulary, even a week after the exam.  It actually got to the point where I had to settle them down each time they walked into my classroom. 

Auditory comprises the “A” in Fleming’s VARK model for different styles of learning (others are Visual, Reading and Kinesthetic) and can explain why we remember things more easily if it encompasses a rhyme or a melody.   Recall when you were first introduced to the alphabet song: “a, b, c, d, eee, eff, geeee…”   It was easy to memorize 26 separate sequence specific letters as a preschooler when it took the form of music.  This technique is also implemented in learning the names of the continents (sung to the tune of “Frère Jacques” a.k.a. “Where is Thumbkin?”):

“There are se-ven, there are se-ven,

con-tin-ents, con-tin-ents:

Europe Asia Af-ri-ca

 North and South Amer-i-ca

Austral-i-a, Antarc-tic-a.

Advertisers have been using the power of jingles for decades in both private

“You deserve a-break-to-daaayy.”

and public sectors:

 “Be…All That You-Can-Be.”

Many scientists credit neuro-linguistic programming (NLP) for how the mind processes information.  The theory states that we can potentially incorporate all of our senses during cognition of a word, idea, or set of specific tasks.  The more senses bombarded through VARK when attaining that piece of information, the easier for it to “stick” in the brain and recall later.

Whether you call it an earworm, a jingle, or a catchy tune, using educational rap in the classroom is extremely effective.  This is especially true in a subject area like science where much of the terminology is derived from Greek and Latin.  So start formulating rhymes in your classroom today so your students can memorize that:

“All plants and animals are made up of cells.

Each is made up of parts called organelles.

So tiny you need a microscope to see.

About 100 trillion cells make up you and me.”   

Guest Post by Joseph Ocando, who was an 8^th grade science teacher in New York City as a member of Teach for America.  He has started a business called Rhyme ‘n Learn.  His raps can be ordered from http://cdbaby.com/cd/rhymenlearn

With a partner, my secondary science methods students selected a tree and then combined their ample knowledge, creativity, and critical thinking and came up with several methods to determine the height of the tree.

Linda Dee and Karen Schedler were helping my students learn about Project Learning Tree (PLT) and its many science activities. My students now have the assignment to develop a lesson plan using a PLT activity and then teach a high school or middle school class using this lesson plan.

This class of students has already earned my respect for their knowledge, abilities, and great attitudes, but it was still exciting to see them apply what they know with their creativity and critical thinking. Indeed the process was just as important as the result. Their tree-height-measurement methods included (a) having a partner of known height stand by the tree and estimating how many of them it would take to reach the top of the tree; (b) measuring the shadow length of the partner and the tree and using ratios; (c) holding a vertical ruler up, with the partner at the tree, and using the marking of the ruler to determine ratios for the heights, and (d) comparing the tree height to a building and then counting brick segments on the building to determine height. Of course, if a protractor was on hand we could have used the distance from the tree, angle to the top of the tree, and some trigonometry to make this estimate.

The tree height estimates were compared to a value found by using clinometers. These nifty devices, we were told, give a pretty accurate reading. You measure off 66 feet and look through the viewer with one eye and line up a horizontal line with the other eye. There were two scales for viewing the height of the tree, one in feet and the other in meters.  In many cases, my students’ estimates were pretty close to the clinometers’ readings.

I was glad to see my students using metric measurements because we had talked about this before our spring break. My advice is to have their future students do all their measurements using the metric system and NEVER convert back into the imperial system. But with the “66 feet” distance and foot scale on the clinometer, it seems like our forestry colleagues, at least in the US, are not fully metrified. Prior to this, I had thought that the only people of science who were not completely immersed in the metric system were US meteorologists. It is obvious that some science traditions don’t change easily.