Obviously, They Should Read 40 Pages, Right?

On November 15, 2018November 16, 2018 By teachingcyborgIn Pedagogy, STEM EducationLeave a comment

“No two persons ever read the same book.”
Edmund Wilson

The designing of a course is about more than what happens in the classroom. A course also includes homework, papers, and reading assignments to name a few. According to the Carnegie unit recommendation, all the out of class work should fit into a period equal to two hours for ever credit. Therefore a 3-credit course would have 6 hours of work outside classroom a week, how should that time be divided. A question often asked is how much reading should I assign?

What this usually means is how much reading is reasonable considering all the other learning obligations the students have. In the book, Academically Adrift: Limited Learning on College Campuses, Richard Arum, and Josipa Roksa state that students that have at least 40 pages of reading a week had more substantial gains on the College Learning Assessment. Since the information on the reading is self-reported, we don’t know what kind of reading this represents. There are multiple types of reading, as an example, there is skimming, scanning, intensive, and extensive another set of options is surveying, understanding, and engaging used by the Center for Teaching Excellence at Rice University.

When students read for the survey, they are just trying to find the main points. Reading for understanding requires the student to attempt to understand all the text down to the level of single sentences. Finally Engaging with the book requires all the skills of reading for understanding while using the book to solve problems and build connections.

A book being viewed through a magnifying glass. — Book viewed through a magnifying glass. Image by Monica Velazquilo (CC BY-SA 3.0).

One way to estimate how much time it will take students to read a specific number of pages is a course workload calculator on the Reflections on Teaching & Learning blog on the Center for Teaching Excellence site at Rice University. Using the workload calculator if the students reads 40 pages in a survey mode it takes 1.43 hours, Understanding takes 2.86 hours, while Engaging takes 5.71 hours. If a three-credit class has an out of class workload of 6 hours, reading for engagement would take up all a student’s out of class time. Therefore if the point of your reading assignments is reading for engagement either 40 pages is too heavy, or it is the only thing the students should be doing.

There are other factors beyond the type of reading that affect how long the reading takes, like the complexity of the text. The more significant the amount of new information in a book the longer it is going to take to read.

While the 40+ page suggestions from Academically Adrift is one of the few research-based examples I have seen there are additional suggestions. In one case a course that meets on Tuesdays and Thursdays the instructor suggest assigning 80 – 120 pages for the period between Thursday and Tuesday and 30 – 40 pages for the period from Tuesday to Thursday. The argument being that the weekend adds 48 hours, so the students have more time and can read more.

I don’t like this argument, the students have additional time, so they should do more reading. The main point of the reading assignments is to get ready for in-class activities or to reinforce class activities. In this example, the two class periods are the same length the amount of material used to prep for the class should be the same.

So, how many pages should be an assignment for each class period? It should be clear that this is not a simple or straightforward issue. Let’s start with a 3-credit class that meets Monday, Wednesday, and Friday, 3-credit hours times 2 hours per credit means this course has 6 hours per week for reading and assignments. So, if we assume, we are talking about an introductory course that uses a textbook, and we devote half the total students time to reading (reading for understanding) then using the Rice tool the students would reading 42 pages in 3 hours. The 42 pages suggested by the tool match the reading recommendation from Academically Adrift.

Dividing the 42 pages by the three, students should read approximately 14 pages for each class period. In a regular semester excluding exams and holidays, there are 40 class periods this gives us a maximum of 560 pages per semester.

How does 560 pages compare with what courses are doing? Looking at the reading list for some introductory science courses, the total number of pages assigned are 261, 256, 338, 463, 475, and 347. The average page number is 375 ± 87. If we divide the average by the total number of class periods (40) that would mean students would be reading about 9.4 pages for each class or 28.1 pages per week.

So, what does this mean, are introductory science courses are underperforming? I don’t think so. For instance, the estimation tool I have been using lists different word densities for different types of books. For a paperback book, it lists 450 words per page while a textbook has 750 words per page. If we went with word count, then 40 pages of a paperback equal 24 pages of a textbook.

Beyond word count, we should also ask about the number of new concepts? Additionally, is the student reading to prepare for a discussion, to get a general overview of a topic, or to gain a deeper understanding? While I would love to have a rule or a set of rules that will help us design the best learning experiences, I don’t think we are there yet.

Is course design by word count the way we should go? Again, I don’t think straight numbers whether pages or word count is the way to go. Because of variables like words per page, number of new concepts and types of reading I’m not sure we will ever have a single rule that determines the optimal number of pages to read.

Just using a number does not consider the reason for the reading assignment or the number of new topics in the text. Since new concepts and long-term learning are impacted by things like working memory, and short- and long-term memory, I think the number of new ideas and the complexity of the text may end up being the most critical aspects when determining the length of reading assignments.

To determine the amount of reading appropriate for a course we defiantly need more research. However, I’m not sure this is something that is really on the research radar. If your students are having trouble do you ever think about changing the amount of reading? How important do you think the reading assignments are to your students learning? Do you think we are too concerned with how much reading we assign to students?

Thanks for Listening to My Musings

The Teaching Cyborg

It’s All in the Primes

On October 18, 2018October 18, 2018 By teachingcyborgIn Pedagogy, STEM EducationLeave a comment

“The greatest single achievement of nature to date was surely the invention of the molecule DNA.”
Lewis Thomas

When you’re an undergraduate student, two words mean a lot to you prerequisite and corequisite. These two words let you know whether you must take courses one after the other or at the same time. Ever since my undergraduate days, I have found these terms to be fascinating. As a student, I often thought of the words differently. Prerequisite meant we believe you need this information to understand our class, while corequisite indicated this information might be useful, but we don’t care.

That may seem a bit harsh, but that is the way it seemed to me when I was an undergraduate, and to be honest, it still seems that way to me. My experience for the first couple of years as a biology major was a little different than several of my classmates. As a high school student, I had been fortunate enough to attend a school with a robust Advanced Placement (AP) and International Baccalaureate (IB) program, because of this I tested out of first-year biology and chemistry. Then in a fit of madness, I took a full years’ worth of organic chemistry with labs over the summer.

Biology students would take organic chemistry the same time the would take the second year introductory biology courses, i.e., corequisite. The first biology class I took was Molecular Biology, one day we were sitting in class, and the professor was talking about DNA replication. If you know anything about DNA you know, the terms 5’ and 3’ (also written 5 prime and 3 prime) get used a lot. DNA is composed of two directional strands if one strand is 5’ to 3’ left to right the other strand will be 3’ to 5’ left to right. DNA replication is carried out by DNA Polymerase III which synthesizes new DNA from 5’ to 3’. I could go on, but that should make the idea clear enough.

DNA replication or DNA synthesis is the process of copying a double-stranded DNA molecule. This process is paramount to all life as we know it. — DNA Replication Image by Mariana Ruiz

One day my classmate turned to me and said, “I don’t understand anything he’s talking about what the hell does all this 5’ and 3’ stuff mean.” It took me a second to figure out what my classmate was saying the terms had been obvious to me. I told him the names came from organic chemistry; they are referencing the 3rd and 5th carbon on the deoxyribose ring. Specifically, the 5’ carbon on one nucleic acid binds to the 3’ carbon on another forming the DNA backbone. Didn’t they cover numbering carbons in your organic chemistry course I asked, it turns out they had not gotten to that yet?

Many times during my undergraduate education corequisite courses did not cover material before it was needed. It was this tendency of separate classes not to line up that lead me to start thinking of corequisite courses as “we really don’t care.” As a student, I usually assumed corequisite courses would be no help in a class I was taking.

As a professional, I understand the constraints that impact educational choices. Ideally, we are trying to fit all the courses needed for a degree in four years, that is four years minus summers. I suspect if we made every corequisite a prerequisite we would not fit all the courses into a four-year program. Interestingly according to the Marian Webster’s dictionary, the first known use of corequisite as we use it in education was circa 1948. The fact that corequisite didn’t exist until 1948 suggests to me that we used to fit all the courses into a four-year degree without corequisites, I wonder what changed? I would assume this has to do with the growth in the amount of material covered in a Bachler’s program while maintaining the time to degree.

The other impact on the usability of corequisite courses is that they are taught by different faculty sometimes in other departments. We hire faculty because of their experts in a field, to take full advantage of this expertise faculty are given the freedom to design and teach subject matter in the method they determine is best. I wonder if schools are doing enough to promote communication between faculty members that teach courses related by corequisites.

Then again is a corequisite essential enough for a faculty member to change how they teach their course? When thinking about curriculum design and degrees, I often think where is the line between the needs of the degree and the design freedom of a faculty member, is there a line? With the constant changes in many if not most fields and the growing amount of knowledge we must teach, we must rely on the experts in the field to keep the content of individual courses relevant. With the continual work to keep course content relevant is it even possible to create a completely unified curriculum?

It may be that corequisite is the best we can do with respects to a degree’s curriculum. However, I do know that anytime I deal with the curriculum of either a single course or a whole degree, I always remember “about what the hell does all this 5’ and 3’ stuff mean.”

Thanks for Listing To my Musings

The Teaching Cyborg

The Gardeners Keep Changing My Tree of Life

On September 13, 2018September 16, 2018 By teachingcyborgIn STEM Education, STEM LanguageLeave a comment

“You’ll be tempted to grouse about the instability of taxonomy: but stability occurs only where people stop thinking and stop working.”

Donald P. Abbott

My Ph.D. is in biology regardless of everything else I’ve learned or what my current job is I generally think of myself as a biologist. A lot of what biologists do involve using model systems or organisms. A model organism is an organism that has some trait or benefit that makes it particularly useful to answer certain types of scientific questions. For instance, the fruit fly Drosophila melanogaster produces large numbers of offspring and can easily be stored in small spaces making it an excellent system for genetics. The Zebrafish Danio rerio is a vertebrate that develops from eggs and has transparent embryos making it an excellent model system for vertebrate organ development. The information learned from model systems improves understanding of other organisms and biology in general.

The application of knowledge from one organism to another works because of the relatedness of all living things. Taxonomies are used to understand the relatedness of organisms. Taxonomies name “scientific name,” organize, and define an organism’s relationship to everything else. The full scientific name of an organism contains 8 or 9 names depending on whether you are using a Domain (Bactria, Archaea, and Eukaryotic) hierarchy. When using taxonomies to determine relatedness the more names, two organisms share, the closer they are on the tree.

I must admit as a student I found taxonomies rather dull. I’ve never really enjoyed topics that seem to be taught exclusively by memorization and regurgitation. One of the most exciting experiences I’ve ever had with taxonomies occurred in the research lab, not in the classroom.

As an undergraduate, I researched the zebrafish, a small freshwater fish that is used extensively in developmental and toxicology research.

Zebrafish Image source Wikimedia Commons Author Azul

When I first started to start working on zebrafish their scientific name was Brachydanio rerio. Shortly after I started working with them, it was proposed and approved that the name change from Brachydanio rerio to Danio rerio, or to list their full name

Kingdom: Animalia
- Phylum: Chordata
  - Class: Actinopterygii
    - Order: Cypriniformes
      - Family: Cyprinidae
        
        Subfamily: Danioninae
        
        Genus: Danio
        
        Species: rerio

Changing things like scientific names can confuse people, how can scientific information change? There are lots of different types of scientific knowledge, and generally, only scientific facts and laws are immune to change.

In science, as we learn new information, we change our interpretations to account for that new information, just ask Pluto. One of the things that have changed a lot in Biology is the tree of life (taxonomies) or how we understand the relatedness of life. When I was in high school, we learned that all life fit into five kingdoms; monera, protista, fungi, plantae, and animalia. Then the tree of life looked like this.

Tree of life showing the 5 Kingdoms Model. Image is based on Biology The science of life volume 3.

At this time almost all the classifications were based on physical traits. By the time I was in my undergraduate education, this began to change thanks to the work done by Carl Woese, who used DNA sequences to organize life, his tree looks like this.

Tree of life based on Carl Woese's genetic Analysis. Image source Wikimedia commons By Eric Gaba — Tree of life based on Carl Woese’s genetic Analysis. Image source Wikimedia commons By Eric Gaba

This process continues to change with additional trees and models put forth regularly.

The problem I currently have is on the educational side. I was reading a current intro biology textbook, the tree used in the book looks a lot like Carl Woese’s tree. However, in the layout of their book they use a word, it’s all over the textbook. The word is prokaryote it is used to classify all single-cell organisms that don’t have membrane-bound nucleus Pro = “before” Kary = “nucleus.”

I hate the word prokaryote as a means of classification from my point of view it is less than useless. I think it can be damaging. In the current textbook, bacteria and archaea are grouped as prokaryotes, because they are both single-cell organisms that lack membrane-bound nuclei. However, that is about where the similarities end. Bacteria and archaea use different chemistries for their cell walls and plasma membranes. They package their DNA differently some archaea even having histones like eukaryotes. Currently, we believe archaea are more closely related to eukaryotes than bacteria. Categorizing bacteria and archaea together under a single term suggests an evolutionary closeness that is not there.

After all, if we look at the full names of several single-celled organisms

Table show the full scientific name of three single celled organisms.

the word prokaryote does not appear anywhere in the scientific names.

When we are teaching students, it is essential that we don’t unintentionally introduce miss-conceptions. We should be teaching bacteria and archaea as the distinct groups they are. They should have independent sections in textbooks. The terms we use in education must have real meaning, and it turns out for a process of taxonomic relatedness lacking a membrane-bound nucleus should not mean things are classified together. When we teach science, when we write about science (textbooks), we need to make sure our language has meaning. We need to stop using groupings and classifications because they are convenient, it gives false impressions about relatedness. Let’s all get together and kill the term prokaryote and make it easier for students to understand how organisms are related.

Thanks for Listening to My Musings

The Teaching Cyborg

Is It in the Syllabus?

On August 23, 2018August 23, 2018 By teachingcyborgIn STEM EducationLeave a comment

Directions are instructions given to explain how.
Direction is a vision offered to explain why.
Simon Sinek

The course syllabus is the backbone of many courses; the syllabus is the means by which the teachers deliver their expectations and policies to students. However, getting students to read the syllabus has become such a common problem that it has entered popular culture. A quick search of the international net turned up over 50 memes, mugs, T-shirts, and posters all was some variation of the phrase “it’s in the syllabus.” My favorite being “It was in the syllabus it’s still in the syllabus it’s always in the syllabus” There are a lot of web pages written about the topic of the syllabus Amy Baldwin’s website is called “it’s in the syllabus.” Austin Community College professor David Lydic has a unique approach to students asking him questions that are in the syllabus.

David Lydic using his t shirt, that reads it's in the syllabus, to answer a student question that is in the syllabus. — David Lydic showing his It’s in the syllabus t shirt. Image source Imgur

The funny thing is I had not planned on writing about the syllabus. However, I recently collected course syllabi for another project. I collected 20 syllabi for first-year majors biology courses and ten each from chemistry and physics. When I started looking at the syllabi and noticed something interesting, the only thing that was in all of them was the course name.

Five of the 40 syllabi did not list the course instructor, only 12 of them listed learning goals, ten didn’t even list course schedules. With all this emphasis on it’s in the syllabus, I was quite surprised to find that when you go and look at syllabus well, it’s not in the syllabus. Since a lot of schools or at least departments require course syllabi coupled with the fact that syllabi are generally regarded as legal contracts why is so much missing?

My guess is a lack of training and models. I’ve previously talked about out why I use models in my work and so I won’t go into it. If you want to read about it, you can review my earlier blog post here. For this blog, I’m going to use the recommended checklist from “the course syllabi: a learning-centered approach” second edition. When I used this checklist to examine all 40 syllabi, this is what I found.

Syllabi Checklist Table

		Biology (n=20)	Chemistry (n=10)	Physics (n=10)	Total (n=40)
table of contents		0	0	0	0
instructor information		17	8	10	35
student information form (not needed anymore)		0	0	0	0
letters to the student or teaching philosophy statement		0	0	0	0
purpose of the course		0	0	0	0
course description		8	8	6	22
course objectives (learning goals)		4	4	4	12
readings		17	8	5	30
resources		16	9	8	33
course calendar		17	8	5	30
course requirements		0	0	0	0
policies and expectations (Instructor/Course):
	attendance	0	0	0	0
	late papers	0	0	0	0
	missed tests	1	1	0	2
	class behaviors	1	2	2	5
	civility	0	0	0	0
policies and expectations (University/College):
	academic honesty	9	4	7	20
	disability access	7	5	7	19
	safety	0	1	0	1
evaluation		0	0	0	0
grading procedures		13	7	9	29
how to succeed in this course: tools for study and work		0	0	1	1

There are a few things on this list that are not relevant anymore; student information systems replaced student information forms. I generally include the purpose of the course with the course description. So, what do you think of this list? Is it too much, not enough, should it just be different? There are two things that each appeared only once in a syllabus that I think I would add; one is a list of FAQs and other while I don’t necessarily like what it suggests. I understand its presence, and that is an escape plan. Though in all honesty, it should be the responsibility of the school to have escape plans for all its buildings.

Course syllabi are the perfect example of where schools could and should help their teachers. With today’s learning management systems school should be able to create a page template for the syllabus. The advantages a lot of the information could be auto-populated, for example when the course is assigned the syllabus page auto-populates the course title, description, room and meeting times from the course catalog. Appointing the professor can automatically populate contact information. Additionally, programs could automatically fill school policies like; disability policy, honor code, harassment, and safety. A form that could be used to add all the additional information that faculty added themselves. Imagine having a form that auto-populates with a schedule of dates that you could add readings and assignments without figuring out the calendar. Not only would this help save time, but it would also lead to consistency and support both new and experienced faculty include all the necessary components of a syllabus. Since schools write many of these components, the school should be responsible for their upkeep and consistency among syllabi.

Is there anything else you think should be in a syllabus? Anything you would leave out? Would a syllabus creation tool be something you would like to see? What do you think about the syllabus? Whatever you think about the syllabus as a group I think we need to think a little bit before we go into “It’s in the syllabus.”

Thanks for listening to my musings

The Teaching Cyborg

Clear and Obvious Facts

On August 16, 2018August 17, 2018 By teachingcyborgIn STEM EducationLeave a comment

“There is nothing more deceptive than an obvious fact.”
Arthur Conan Doyle, The Boscombe Valley Mystery

I have watched or been a student in a lot of biology classes over the years. I sometimes think we take a lot for granted when we teach students. Not only in biology but in many of the STEM fields. We have the advantage of teaching science on the shoulders of all the greats that came before us. Sometimes I think we forget how long it took to answer questions and just how smart the people that figure them out were. Also, we forget how fast things change, in biology we have something called The Central Dogma. Simply it states that DNA goes to RNA goes to protein. It’s as simple as that; we know proteins are not made directly from DNA and RNA is not made from proteins.

The funny thing about The Central Dogma’s place in modern biology is that it’s relatively new. We’ve been studying biology for a long time; Van Leeuwenhoek discovered single-cell organisms in 1670, Hooke coined the term cell in 1665. Macromolecules came later; Proteins in 1838, DNA in 1869, and RNA between 1890 and 1950, RNA was initially thought to be the same as DNA. However, we didn’t know whether DNA or proteins were the sources of genetic inheritance until 1952. We didn’t know the structure of DNA until 1953. Meselson and Stahl published the proof of semi-conservative replication of DNA in 1958.

In 2018 most of The Central Dogma is less than 70 years old. There are a substantial number of people alive that are older than The Central Dogma. This information is only old because of the speed at which biology has been progressing over the last century.

When teaching facts In STEM education we often run into a severe problem, students can often give us the “correct” answer on a test. However, if you dig a little deeper, they don’t understand what that answer means.

I have often thought that teaching biology (or any STEM field) through an understanding of the foundational experiments would help students understand the facts. Imagine going through these experiments; What was the question?, Why did they do this?, Why didn’t they do that?, What do the results show?, and What do they do next?. Teaching these experiments to students would explain not only what we know but why we know it.

Let’s look at a couple of examples. We know that DNA is the molecule responsible for genetic inheritance. How do we know? For many years scientists thought proteins had to be the source of genetic inheritance because DNA was just too simple. In 1952 Alfred Hershey and Martha Chase conducted an experiment that provided some of the most persuasive evidence that DNA was the source of genetic inheritance.

Hershey and Chase use T2 bacteriophage for their experiment, T2 phage reproduced by infecting a bacterial cell. The bacterial cell produces new phage that would be released when the cell lysed. While the mechanism of T2 phage reproductions was not known, the process required the transfer of “genetic material” from the phage to the bacteria. The T2 phage is composed of two components a protein shell and DNA core. The researchers needed to determine what part of the T2 phage entered the bacterial cell.

The researchers needed a way to label proteins and DNA independently of each other. Two atoms helped sulfur and phosphorus. Proteins use sulfur while DNA does not. DNA uses phosphorus while proteins do not. They grew phage with radioactive sulfur or radioactive phosphorus. These radioactive phages infected cells, after infection, the phage and cells were separated, and the location of the radioactivity was determined.

They found the radioactive DNA was always with the bacteria (Figure 1B) while none of the radioactive protein was with the bacteria (Figure 1A). They also showed that radioactive DNA could get incorporated into the bacterial DNA. While other scientists conducted additional experiments, this experiment showed it was the DNA, which carried the genetic information.

Cartoon depiction of the Hershey Chase Experiment — Hershey Chase Experiment, Derived from Hershey Chase experiment.png by Thomasione from Wikimedia Commons

Your students can probably (we hope) tell you that DNA replicates semiconservatively. However, if you asked them to prove semiconservative replication of DNA, could they do it? Without looking up the Meselson and Stahl experiment. In the late 1950s when Matthew Meselson and Franklin Stahl conducted their research, we already knew the structure of DNA. It was immediately clear from the structure that DNA could serve as a template for its replication.

Early on there were three competing models for DNA replication; conservative replication (Figure 2A), semiconservative replication (Figure 2B), and dispersive replication (Figure 2C). The differences in these models can be described based on where the new and old DNA strands are after replication. In conservative replication after one round, you end up with one DNA molecule composed entirely of new DNA and one molecule composed entirely of old DNA. After two rounds of replication, you now have three new DNA molecules and one old DNA molecule. In semiconservative replication after the first round, you get two molecules that both contain one new and one old strand of DNA. After two rounds you get two molecules composed entirely of new DNA and two molecules composed of one new and one old strand. In disrupted replication, the DNA molecule was cut every ten base pairs on alternating strands, and then new DNA would fill in the gaps. After one round you get molecules that are 50-50 old versus new DNA. After two rounds of replication, you get four strands that would have somewhere between 50-50 and 75-25 new versus old DNA.

Cartoon representation of 3 different modes of DNA replication tested in the Meselson and Stahl Experiment. — 3 different modes of DNA replication, Dertived from DNAreplicationModes.png by Adenosine from Wikimedia Commons.

The beauty of these models is that if you can follow the new and the old DNA you can distinguish between all models. Meselson and Stahl marked new and old DNA with nitrogen isotopes specifically N¹⁴ and N¹⁵ these isotopes differ by one neutron. Which turns out is enough to separate DNA by density in a cesium chloride gradient.

They grew bacteria on media which contained N¹⁵ then allowed the cells to grow on media containing N¹⁴ for 0, 1, or 2 cycles of replication. The DNA was then isolated from the cells and density was used to separate the DNA molecules. After zero rounds of replication, there was a single band lower than cells grown only on N¹⁴ (Figure 3 N¹⁵ 0). After one round of DNA replication, there was a single band between the N¹⁵ and N¹⁴ bands (Figure 3 N¹⁵ 1). This result ruled out conservative replication since conservative replication should have produced one heavy (N¹⁵) and one light (N¹⁴) band. However, both semiconservative and disrupted replication should produce 50-50 molecules at round one. After two rounds of replication, we get two band’s one at the 50-50 spot the second at the light (N¹⁴) position (Figure 3 N¹⁵ 3). This position of bands is what you’d expect from semiconservative replication but not dispersive replication. Dispersive replication would have produced a band between the 50-50 and the N¹⁴band. Therefore, DNA replicated semiconservative.

Cartoon representation of the Results from the Meselson Stahl Experiment. — Meselson Stahl Experiment, Derived from Meselson-stahl_experiment_diagram_en.svg: LadyofHats, Wikimedia Commons

Even if you don’t need this experiment to teach your students how semiconservative replication works, the Meselson and Stahl experiment is often referred to as one of the most elegant experiments ever conducted in biology and is worth studying to learning experimental design.

Up until these experiments were conducted the information that we teach as clear and obvious facts was up for debate. While we probably can’t go over every single fundamental experiment in enough details, so our students understand them, because of the total amount of material we need to cover, foundational experiments can be useful. If there’s a topic that your students are having trouble grasping maybe take the students through the experiments that demonstrated the facts. Perhaps the solution is a one-credit recitation that covers the experiments in conjunction with the lector. That might solve all our problems (shakes head ruefully). One last thought, if students are having trouble grasping that clear and obvious fact maybe stop and ask if it is clear and obvious?

Thanks for listening to my musings

The teaching cyborg

Biology (n=20)

Chemistry (n=10)

Physics (n=10)

Total (n=40)

Total
(n=40)