Welcome to my new series documenting my trials and
tribulations as I foray into academia.
I’ve recently been put in charge of creating and managing a series of
labs for a college-level course in developmental biology. The description of the course is below:
“This
is a study of the principles of development and their application to animal and
plant embryos, regeneration, metamorphosis, cancer and related processes. The
laboratory includes observation and experimentation with living animal and
plant material, plant tissue culture, and examination of prepared slides.”
I do have a colleague handling the corresponding lecture,
but ultimately the responsibility for the labs falls on me. Labs are three hours long and are held once a
week for 13 weeks total.
Designing this course has been fun, but it’s also a hell of
a challenge. The course hasn’t really
been run before and most of the labs have to either be created from scratch or
modified from protocols found within the Bio department or by searching the
internet. It's also hard to think of an
appropriate lab that’s specific to developmental biology, but doesn't overlap
with typical labs in a molecular biology, genetics, or anatomy course and also
fits within three hours. I haven't been able to find many resources online for
creating this type of course so I thought I'd post my labs on Steemit after I
make them.
The first lab is a bit unusual in
that it features a developmental organ that’s rarely used in a college-level
training lab.
From De humani corporis fabrica libri decem
Placental
Tissue Preparation and Analysis
A placenta. Source: my child :)
That’s right, I brought in a placenta. I wanted students to
gain experience with real human tissue that hadn’t been preserved in
formaldehyde. The fact that the placenta
is a keystone organ in human developmental biology was an added benefit. Pictured above is the fetal side with
attached umbilical cord.
Placentas, and unpreserved human tissue in general, can be
difficult to obtain for a training lab.
They’re either too expensive or too time sensitive to work with for
teaching purposes. Fortunately, my wife
produced a specimen just 2 weeks before the first lab. She also produced my first child, pictured
below at the ripe age of five minutes old :P
Getting this placenta was rather easy. Once I explained to the doctors and midwifes
why I wanted it, they got really excited.
Most people do weird things with the placenta like eat it so using it
for academic purposes was a nice change of pace. Once they gave it to me, they even wanted to
show me the anatomy and explain what they would look for in placentas to judge
fetal health. Once I had the thing, I
stored it in my car and it immediately froze in the hard cold of Buffalo’s
Winter. I thawed it for lab use and it
looked fine, aside from some clotting.
Still, I had to wash away a lot of excess blood to ensure everything was
easy to see.
Now showing off a fresh placenta gives this lab a nice wow
factor, but I still needed an actual experiment to go with it. I decided to have students cut off small
portions of the placenta and preserve some parts in formamide while extracting
DNA from other segments. Simple stuff,
but it lets the students get some experience handling this tissue and
understanding what might be done with it in a typical clinical lab.
Below, I’m going to provide a teacher’s guide and a protocol
handout for students. The teacher’s
guide is intended to be a resource for instructors to present this lab and the
protocol is a hand-out to give to students so they know what to do.
Teacher’s
guide
Most instructors will probably not have a fresh placenta to
work with. However, you can buy animal
reproductive organs, like this beautiful cow uterus I found online (http://biologyproducts.com/cow-uterus-pregnant/ - it has a bonus fetus inside!) and run a similar lab.
In this level course, most students should be familiar with
the placenta. The assigned readings are
actual published papers that give in-depth information on this organ. However, I did provide a brief introduction
powerpoint with some slides to explain normal placenta function. For a flashy title screen, I included a
somewhat disturbing illustration of the placenta from the 1627 medical textbook
De humani corporis fabrica libri decem (pictured at the top of this article). I also provided an image that shows placenta implantation
From The anatomy of a normal Placenta Huppertz B, J Clin Pathol. 2008, and a diagram of a
mature placenta
http://ib.bioninja.com.au/higher-level/topic-11-animal-physiology/114-sexual-reproduction/placenta.html
I used both images to give a brief recap on how the placenta forms, and what structures we'd be looking at on the real thing.
Finally, I did an anatomy lesson with the placenta
itself. The nurses, doctors, and
midwifes that delivered my baby told me what to point out, and I’ve listed
prominent features below.
Cord insertion site
– should be center, but off-center is fine
Number of vessels in cord
– Should be three, 2 has increased risk of birth defects
– Can be detected with ultrasound
Fully intact
– Pieces left behind can cause infection or hemmorage
Calcifications
– occur if baby is past due date
Signs of decay
– white/dead cells, necrotic tissue
– Often caused by smoking
Once this anatomy lesson is done, students can perform the
lab.
Assigned Reading:
The anatomy of a normal Placenta Huppertz B, J Clin Pathol. 2008.
This paper is a succinct overview of the placenta on a
macroscopic and microscopic level. It’s
a great reading to ensure all students are on the same page before starting the
lab.
Optimising sample collection for placental research, Burton
et al. Placenta, 2014 (https://www.ncbi.nlm.nih.gov/pubmed/24290528).
This 2014 paper provides an excellent explanation of what we
can learn from a placenta and the nuances involved in analyzing it. The table they provide is also an excellent
overview of the types of analysis one can perform on this organ.
Protocol
Handout
Materials Needed
Dissecting kit
Mortar and Pestle (kept in freezer at -20 oC)
Eppendorf tubes (1.5 mL) and Specimen tubes (15 mL or 50 mL)
Scale accurate to milligrams
Pipettemen (P1000 and P200)
10% formalin
5% Bleach solution (for sterilization)
Observing Placenta
Anatomy
1.)
Record approximate size and thickness. Note the color. Look for any irregularities or missing
pieces. Identify the the amnionic sac,
the maternal/fetal sides, and individual cotyledon. If possible, count the number of visible
cotyledon.
2.)
Identify the umbillical cord, record the number
of blood vessels within the cord and the length of the cord.
3.)
Take a photo for your lab notebook.
Obtaining placental
samples
1.) Using a scalpel, razor blades, or scissors, cut
off a grape-sized section of the placenta and a 2 cm section of the umbilical
cord. Make sure to record where on the
organ you removed the pieces.
2.) For each sample, remove all extraneous liquid
and any attached membrane. Record total
weight, size, and appearance.
3.) Cut each sample into 4 equal pieces. Each piece should be about 50 mg and fit
inside an Eppendorf tube. At least one
piece should be less than 3 mm in thickness.
Record the mass of each piece.
4.) Freeze 3 samples and keep the thinnest at room
temperature for formalin fixation.
Fixing Placental
tissue
1.) Add 1 mL 10% formalin to the tissue and incubate
for 5 minutes at room temperature.
2.) Calculate the volume of formalin needed to mix a
50:1 formalin:tissue ratio. Add that
volume to a Falcon tube.
3.) Transfer the tissue to the Specimen Tube. Make sure the tissue is completely
submersed. These will be incubated at
room temperature for a minimum of 72 hours to “fix” them.
Isolating Placental
DNA
1.) Ensure the mortar and pestle are below 0 oC.
2.) Remove one frozen tissue sample (the other two
samples are backups) and grind into an icy powder with the mortar and pestle.
3.) Transfer as much ground tissue to an Eppendorf
tube as possible. Use 200 uL H2O to
transfer remaining tissue. Put the
mortar and pestle in the bleach bath in the sink.
4.) Incubate the Tube for 5 minutes at 95 oC.
5.) Vortex the tube for 1 minute at high speeds,
then incubate for 5 minutes at 95 oC again.
6.) Centrifuge at max speed for 1 minute. A pellet of cell lysate should form at the
bottom and the supernatant should contain DNA (it may be viscous).
7.) Transfer the Supernatant to a sterile tube and
store in the freezer.
Cleanup
1.)
Put any equipment that’s touched organic
material into the bleach bath for at least 15 minutes. Once sterilized, they can be washed and
dried.
2.)
Excess formalin should be dumped in the liquid
waste container.
3.)
All other materials (pipette tips, tubes) need
to be disposed of in waste bins.
Final
Thoughts
All in all, there were minimal issues with this lab. It’s kind of a safe lab in that the star of
the show, the placenta, just has to sit there.
It lasted the full three hours and students were fairly intrigued to be
working with an unpreserved specimen.
However, it’s hard to conclusively determine that DNA was successfully
extracted or that the formalin fixation was successful. Future labs will continue to work with this
material and I will update on what we do with them.
One other thing I should mention is that I submitted this post on steemstem.io. I found the process a lot easier than normal posts through Steemit. My only challenge was implementing pictures, but otherwise I could copy-paste from word with most of my formatting intact. I imagine a set of references might be a bit tricky, but only if I put the links in the body of the article.
