PBS Full Study Guide Josh Jones PDF

Summary

This document is a study guide for a PBS (likely a public broadcast service) biology course. It covers topics in forensic science, DNA, blood pressure, and other biomedical topics. The study guide is organized into numbered sections.

Full Transcript

1.1 One Page Wonders
Josh Jones

Proper PPE (Personal Protective Equipment)
Gloves Goggles Lab Coats

Types of Evidence
Fingerprints Footprints Hair Identification Bodily
Fluids/DNA
m M m m

Determining Time of Death- Biomedical sciences are used to determine the time
of death and how the person died
Rigor Mortis- stiffening Algor Mortis- cooling of Lividity- blood pooling in
of the muscles the body tissues and discoloration
of skin
 Glaister Equation
98.4 − 𝑚𝑒𝑎𝑠𝑢𝑟𝑒𝑑 𝑟𝑒𝑐𝑡𝑎𝑙 𝑡𝑒𝑚𝑝
= 𝑎𝑝𝑝𝑟𝑜𝑥𝑖𝑚𝑎𝑡𝑒 ℎ𝑜𝑢𝑟𝑠 𝑠𝑖𝑛𝑐𝑒 𝑑𝑒𝑎𝑡ℎ
1.5

98.4 − 92.4 6
= =4
1.5 1.5

The body was found and the temperature was 92.4 degrees Fahrenheit. This means that it was
approx. 4 hours since this person’s death. 98.4 is the average body temperature subtract 92.4,
which is the measured rectal temperature, divided by 1.5. Forensics Science is used to
determine whether civil and criminal laws are being violated. The Glaister Equation helps them
decide this problem.

Blood Pressure Experiment: How will having your hand in cold water affect your
blood pressure?
Hypothesis: If you put your hand in ice water, then your blood pressure will
increase.
Independent Variable: Hand in ice Dependent Variable:
Blood Pressure
Constant: sitting Constant: right arm being
tested
Control groups are not being Constant: Using
exposed to the independent Sphygmomanometer
variable. Constants are the
things that stay the same in an
experiment
Positive Controls is where the Negative Controls can be used to influence a negative outcome
group is expected to have a
positive result

Blood Spatter

We can learn how a person was killed, how they
died, and how high the blood was dropped, just
based on the blood spatter. You can find out if
the person was hit and at what angle they were
hit at.
 1.2 One Page Wonder - DNA Analysis
Josh Jones

What is DNA?
Deoxyribonucleic Acid (DNA) - is in the shape
of a double helix and contains genetic
information for cells and proteins. DNA is made
up of many
nucleotides,
which are
made up of a
phosphate
group,
deoxyribose sugar
and a nitrogenous base. Nucleotides form DNA.
A section of DNA is called a Gene. When many
genes buildup, they form a Chromosome. These
chromosomes code for the production of
proteins and contain genetic information. We
built a model to identify how nucleotides turn
into chromosomes
Purines- 2 carbon nitrogen rings in the nitrogenous Pyrimidines- 1 carbon nitrogen ring in the
bases (Adenine and Guanine) nitrogenous base (Thymine and Cytosine)

Purine Double Hydrogen Bond Triple Hydrogen Bond
Pyrimidine Pyrimidine
Purine

1.2.2 Strawberry DNA Lab
Step 1: Mash strawberry Step 2: Press through Step 3: Put beaker full of Step 4: Add layered
with soap cheese cloth stuff in test tube ice cold alcohol to the
solution
 Restriction Enzymes and RFLPS
HaeIII is a Restriction Enzyme. It cuts when it Restriction enzymes cut
sees GGCC and splits it into GG and CC. pieces of DNA. The
Restriction Enzymes can cut DNA in specific certain lengths of the
places. When a virus (bacteriophage) lands on DNA is called a
bacteria, it inserts its DNA code. The Restriction Fragment
restriction enzymes cut the viral DNA and Length Polymorphism
protects the bacteria’s DNA. (RFLPs). RFLPs show the
differences in a DNA
sequence and their
lengths. RFLPs can be seen
in Gel Electrophoresis and
that is where scientists
can compare the lengths
of DNA strands.

Polymerase Chain Reaction (PCR) takes out a
n

specific strand of DNA
and makes a lot of
it. This allows
scientists to
make many copies of a DNA
sequence.
Thermocycler is a device that allows DNA strands to be copied. Inside, there are thermal
blocks where the DNA samples can be placed. First, the computer raises the temperature,
which causes the DNA strands to separate. This is called Denaturation. Then, the computer
cools, giving the primers one chance to bind with the complimentary strands of DNA. This is
known as Annealing. Finally, extension is when the DNA polymerase runs through the DNA and
seals the primers together making complimentary strands of DNA.

From the gel electrophoresis DNA Analysis, we can conclude that
Anna’s DNA was found at the crime scene. Not only do her RFLPs
match up perfectly with the crime scene’s RFLPs, but her body was
even found at the crime scene. Anna’s RFLPs and the crime scene’s
RFLPs extend the same distance and are identical. Therefore,
Anna’s DNA was found at the crime scene.
 1.3 One Page Wonder – The Findings
Josh Jones

Body Systems Immune- Protects by filtering Skeletal-Supports making muscle
Urinary- Covers by keeping pathogens and makes white blood cells attachments and protecting organs
internal parts in and Joints, bones, cartilage and tendons
outside stuff out,
maintaining body
temperature, and
protecting tissues

Muscular - Moves materials around the Digestive- Nourishes by breaking down
body, makes heat, and body movement. food into nutrients and takes them to the
Heart, diaphragm, tongue, skeletal cells in the
muscles, body,
etc. removes
toxins

Cardiovascular- Delivers Endocrine- Controls by secreting Respiratory- Exchanges oxygen for
nutrients/oxygen and hormones carbon dioxide
hormones to cells

Nervous- Communicates by receiving Integumentary- Cleans by removing
signals coordinating response, and tells cellular waste, filtering blood, and
what other systems to do maintaining water balance
Autopsy- the dissection of a deceased person that will decide the cause of death. One of the
occupations that can perform this task is a medical examiner. A Y-incision is made to open up
the body and see the organs. Rokitansky’s method is that block 1 is from the trachea to the
large intestine and block 2 are the large intestine, small intestine, kidneys, appendix, and the
adrenaline glands.
External Exam Internal Exam Viewing Internal Removal of Organs
Organs

Removal of Brain Weighing of Organs Returning Organs to Sew Back Together
the Body

Health Insurance Portability and Accountability Act (HIPAA) is a set of
laws that provides clients/patients/students with confidentiality and
privacy. Health officials must protect and follow HIPAA or else they will be
fined, lose their job, be criminally prosecuted, and/or have a loss of license.
To violate HIPPA, you must share a client’s basic info, past, present, or
future conditions, bills, etc. No public records can be laying around. But,
information can be shared if: the client has an infectious disease, it
prevents an injury, it prevents neglect/abuse, it prevents public health or
safety, or worker’s compensation orders the release of records.
3 ways of violating HIPAA: 3 things that are allowed according to HIPAA:
- Leaving public records/patient records on - A doctor reporting an infectious disease to
the cafeteria table a local/state health department
- A phone call about lab results to anybody - Talking to another doctor who has the
other than the patient patient (so you both have the patient) in
- Talking to another person about a patient private
that does not have the patient - A mother asking the doctor about her
daughter’s baby and the doctor answering
all the questions
 2.1 One Page Wonder – What is Diabetes?
Josh Jones

2.1.1. Diabetes
Diabetes is a disease in which the body does not produce enough insulin or the receptors do not
recognize insulin, resulting in high blood sugar.
Risk Factors of Type 2 Diabetes: Symptoms of Diabetes:

- Being overweight/obese - Recessive thirst/urination
- Inactivity - Fatigue
- Unhealthy eating (lots of carbs - Weight loss
and sugars) - Blurred vision
- Family History (increased risk - Hunger
if parents/siblings have it) - Tingling/pain/numbness (in limbs and extremities)
- Age: >45 have an increased risk - Edema (water retention)
- Race: African- - Mood swings
Americans/Blacks, Hispanic, - Fainting
Asian Americans, American
Indians, etc.
- People with prediabetes or
gestational diabetes

Type 1 Diabetes Similarities Type 2 Diabetes
- Juvenile diabetes- symptoms - Can damage the - Adult onset diabetes- risk
start young cardiovascular system, increases when you are >45
- Your body does not produce urinary, and nervous - Cell receptors don’t recognize
enough insulin systems (often puts people insulin anymore, so the cells cannot
- Genetic- autoimmune disease, at risk for kidney failure, turn the glucose, in your blood, into
so it can’t be prevented or heart failure, blindness, ATP (energy).
reversed etc.) - Unhealthy lifestyle, can be
- Treatment: Medications for - Similar symptoms: frequent prevented/reversed
insulin and carb hunger, thirst, fatigue, - Treatment: Exercise/weight loss,
counting/diabetic diet blurred vision, etc. Diabetic diet, and medication
- More common in white people - If you have diabetes or (anticoagulants, statin, and insulin)
- Onset is sudden and suspect you have diabetes, - More common in African-Americans,
unexpected you go to an Asian Americans, Hispanics, etc.
endocrinologist - Onset is gradual

Glucose
Tolerance
Test (GTT) is
used to
determine if a
person has
diabetes
through oral
and blood
testing. In
Left- Normal GTT Results
GTT, people
are given high levels of sugar, and we see how Right-Normal vs Diabetic Results (Diabetic is green, normal is red)
their body reacts.
Insulin is a protein hormone produced to signal the cell to take in glucose and make energy (Adenosine
Triphosphate or ATP). The beta cells of the pancreas make the insulin in order to contain the amount of
glucose in the blood. Then, the insulin travels through the blood to cells all over the body. There, they fit
into the insulin receptors, like a key and a lock. This triggers the glut 4 transporter to transport glucose
through the cell membrane into the cell and out of the bloodstream. After the glut 4 transporter takes
in the glucose, it turns it into energy through glycolysis. In
type 1 diabetes, the beta cells of the pancreas do not produce
enough insulin for the amount of glucose in the blood. In type 2
diabetes, the insulin receptors have become resistant to the
insulin and refuse to allow any glucose in. Both cause
hyperglycemia because they are not taking the glucose from
the blood and turning it into energy. This is why diabetics are
often tired. Diabetics are often thirsty because your kidneys
are taking much of the water found throughout your body to
balance out the hyperglycemia. This causes some diabetics to
have edema and swell.

Negative Feedback Loop Similarities Positive Feedback Loop
- Both are secreted by
hormones and are
controlled by the
endocrine system
- Both are a reaction to a
problem in the body
- Both contain a cause,
that results in an
effect
- Both are necessary for
- A negative feedback loop stops one survival in animals, - A positive feedback loop
action and makes no action or an plant, humans, etc. continues an action until
opposite action in attempt to maintain something big happens. It keeps
homeostasis. reinforcing the first action and
- Examples: causes the reaction to increase.
- Temperature - Examples:
- Blood sugar levels - Contractions in childbirth
- Blood pressure - Orgasms
- Blood clotting

When you eat sugar, your blood When you have not eaten
glucose levels will increase. sugar in a while, your blood
This is then detected by the glucose levels will decrease.
insulin-secreting cells in the It is detected by the
pancreas and then insulin is glucagon-releasing cells in
released into the blood. The the pancreas. Glucagon is
liver takes out some of the released into the blood to
glucose in your blood and turns target the liver. Then, the
it into glycogen (stored liver detects this and
energy). But, most is absorbed glycogen breaks down and
by the cells throughout the releases glucose into the
body. The blood glucose level blood. This raises the blood
returns to normal. sugar level back to normal.
 2.2 One Page Wonder – The Science of FOOD!
Josh Jones

2.2.1 Food Testing
We used chemical indicators to test for macromolecules to better understand
what is in our foods. When chemical indicators show a positive result, generally
through coloration or bubbling, this tells us that a certain chemical reaction has
occurred. This chemical reaction happens when chemicals bonds are broken down,
and then reformed again.
Carbohydrates Protein Lipids
Starch- Lugol’s Iodine Simple Sugars- Biuret Solution Brown Paper Towel
Benedict’s Solution, m ,
Test

Positive Result- Dark Positive Result- Positive Result- Positive Result- Shiny
Blue/Black Coloration Orange/Red Coloration Purple/Blue Coloration

Carbohydrates: Both control Proteins:
Provides energy organ Structure/
(needed for activity) function in cells
and organ function. function and
and regulate
are made of tissue and
Monosaccharides are carbon, organs.
the monomer for hydrogen,
carbohydrates. Glucose and oxygen The monomers are amino acids. There are
is an example of a monomer for carbohydrates. 20 different amino acids and are made of
They are a 5 or 6 carbon ring. Disaccharides are 2
an amino group, a carboxyl group, a side
5-carbon rings that make sucrose. Polysaccharides
chain and a carbon.
are many monosaccharides.
Both provide energy and are necessary in organ and All necessary Nucleotides form DNA, which can be
system function. Without carbohydrates or lipids, for survival and
all have copied by RNA in the process of protein
humans would have no energy and would not exist
because the majority of the cell is made of lipids or monomers that synethesis. The nucleic acids code for the
buildup to production of proteins and their functions.
carbs. polymers.
Lipids: Provides Both are key Nucleic acids: Store
energy source, gives to cellular genetic information
insulation, and and transfer during
function and
structure of cells cell division.
membrane. can change
how a cell The monomer is a
Glycerol and the 3 functions. nucleotide, which is
fatty acid chains are the monomers that build composed of a
the lipid. Triglycerides store energy for later phosphate group, a
because they have 3 fatty acid chains. deoxyribose sugar,
and a nitrogenous base.
 Bonds forming- Chemical Reactions form Breaking Down Bonds and Compounds- Chemical
covalent bonds between elements or compounds. bonds are broken when a chemical reaction occurs.
They can connect elements together by bonding This can occur when you digest food. Stomach acid
them, which is considered a molecule. and the liver can break down the polymers (food)
Simultaneously, the chemical reaction generally and turn them into monomers. Breaking down food
causes a product to be made, such as energy or helps you get the right nutrients. Chemical
water. In dehydration synthesis, covalent bonds reactions happen when there is an imbalance in
are formed through a chemical reaction in order electrons. So, the electrons that move, create
to make a polymer. At the same time, the energy. The energy from the chemical reaction
chemical reaction causes 2 hydrogen and 1 causes the chemical bonds to break. In hydrolysis,
oxygen to break off forming water. This helps water is used to split the chemical bonds between
form and grow tissue throughout the body. the molecules of the polymer. The polymer is
Dehydration synthesis forms the bonds between broken into monomers. Hydrolysis breaks down the
the monomers. bonds and compounds.
Dehydration Synthesis Hydrolysis

,

Calorimetry is one way of finding out how
many calories are in a certain food. To
measure how many calories was in the food, we
burnt it under a can of water, and saw how
much the temperature increased. By knowing
how much heat was given off, we can calculate
how much energy was in a single food item. We
also measured the weight of the food and the
can of water. 50 mL of water was put into the
can before we burnt the food under it. Once
we did the lab and the results were
completed, it was time to calculate the amount
of energy gained. To find this, we used the
equation (mass of water) x (change in
temperature) x (specific heat of water).
This was to find out the amount of energy
gained by water. Then, we calculated for the
energy in the actual food. To do this, we used
the equation: Energy content of the food
sample = (energy gained by water) / change
in mass of food. After doing these 2
calculations, we still had to divide our answer
by 1,000. This would tell us the answer in
Cal/g (Calorie = energy needed to raise 1kg of
water 10C). Adenosine Triphosphate (ATP) is
stored in the body as energy. This energy is
measured in calories. It is called Adenosine
Triphosphate because it has 3 phosphates and
1 adenine.
 2.3 One Page Wonder- Life with Diabetes
Josh Jones

2.3.1 Day in a Life
It can be The most common blood sugar test
very hard is home glucose monitoring. To do
to deal with this, you prick your finger with a
diabetes. If lancet so that you are bleeding.
you have Then, place a drop of your blood on
diabetes, a test strip and insert it into the
you have to check your blood sugar meter that displays your blood
regularly and may need a help to sugar levels. It is important to track your blood sugar levels
control your insulin levels. If you have because you do not want your sugar to get too high. Testing
Type 1 diabetes, you do not have you blood sugar levels can also prevent long-term diabetic
enough insulin. This means that you complications, such as nerve damage, and organ and blood
may need a pump to give you insulin vessel damage. By making sure your blood sugar is the right
when needed. Also if you have level, you could prevent future health problems. Also, insulin
diabetes, exercising will really help pumps detect your blood sugar, and can inject insulin to lower
your cells respond to insulin better your blood sugar. The Hemoglobin A1C test can determine
and control blood sugar levels. what percent of hemoglobin is glycated (meaning covered in
sugar). It tells the average blood sugar concentrations.

2.3.2 Diabetic Emergency
High blood sugar, Hyperglycemia, is Low blood sugar,
where there is too much sugar in Hypoglycemia, is when there is
your blood. A hypertonic cell is not enough sugar in your blood.
when there is too much pressure on A hypotonic cell is where
the cell causing it to shrink. there is very little pressure on
Hyperglycemia causes your cells to the cell causing it to expand.
become hypertonic. In the egg lab that we did, In the egg lab, the egg that we placed in water
after putting an egg in vinegar to get rid of the grew because it was in water. This means more
shell, we placed the egg in a cup of corn syrup. This water could enter the egg through osmosis.
caused water to exit the cell through osmosis. In Hypoglycemia causes your cells to become
this part of the experiment, the solute was sugar, hypotonic. In this part of the experiment, there
the solution was the corn syrup and the solvent was no solute, but both the solution and the
was water. solvent was water.

Risk factors: family history and diabetes can all Risks factors: family history and people with
cause not enough insulin or insulin resistance. Not diabetes can have low blood sugar. If you have
producing insulin and insulin resistance cause high recently exercised or have skipped a meal, this
blood sugar. puts you at a greater risk of hypoglycemia.

Effects/symptoms: extreme thirst, frequent Effects/symptoms: shaking, sweating, anxious,
urination, dry skin, hunger, blurred vision, dizziness, hunger, fast heartrate, impaired
drowsiness, and nausea vision, weakness/fatigue, headache, irritable
Isotonic blood has just the right amount of sugar in it, so it puts the right
amount of pressure on the cells. Isotonic blood has the same solute
concentration as another solution. By having isotonic blood, your cells can
function and there is not too much water entering the cell or too much water
exiting the cell.
 2.3.3 Complications of Diabetes
Retinopathy Diabetic Retinopathy is a disease that
effects your vision and can come from
diabetes and high blood sugar. The high
amount of sugar in your blood weakens the
blood vessels. After months to years of
high blood sugar, blockages can buildup in
small vessels that give the retina oxygen.
When these small blood vessels can no
longer reach the retina, the retina does not
get enough oxygen. In attempt to solve the
problem, the eye and blood vessels try to
create more blood vessels. Generally, they fail to create successful blood
vessels and most leak or are not developed fully. This complication is most
related to the ocular system. Overall, it causes blurred vision and can
eventually cause you to go blind.
Neuropathy Diabetic neuropathy is caused by high glucose
levels in your blood. This can damage nerve
fibers, mainly in your hands and feet. If you have
high blood sugar for a long enough time, you may
develop neuropathy because high blood sugar can
damage nerve fibers. Also, if you have high blood
sugar, it can damage and block the capillaries
going to the nerves. This means some parts of
the nerves will not get enough oxygen and
nutrients to function. High blood sugar can
affect the way your nerves transmit signals and
interfere with your reaction time. Neuropathy
mainly affects the nervous system.

Diabetic With diabetic nephropathy, the glomeruli
Kidney Disease does not function properly and leaks an
(Diabetic unusual amount of proteins into the urine.
Glomeruli are clumps of blood vessels and
Nephropathy)
acts like a filter. In a normal kidney,
glomerulus allow waste products, water
and salt/electrolytes to pass through into
a tubule. This filter does not allow
proteins to pass. A glomerulus and tubule
make a nephron and a million nephrons are
in each kidney. But, in diabetic
nephropathy, the glomerulus get damaged
and allows proteins, mainly a protein
known as albumin, through into the urine.
The high blood sugar in your blood causes
damage to the tiny blood vessels in your kidneys, thus allowing more albumin
to enter your urine. This mainly affects your urinary system.
 3.1 One Page Wonder- The Disease
Josh Jones
Erythrocytes Leukocytes Thrombocytes

Scientific Name: Thrombocytes
Common Name: Platelets
Scientific Name: Scientific Name: Leukocytes Thrombocytes are used in the
Erythrocytes Common Name: White Blood Cells (WBC) blood to stop and prevent
Common Name: Red White blood cells fight infections and foreign bleeding. Less than 1% of the
Blood Cells (RBC) invaders (pathogens) that enter your body. blood is made of Thrombocytes.
The erythrocytes main There are 5 different types of leukocytes: When you get a cut or have an
job is to supply neutrophils, eosinophils, basophils, monocytes, open wound, platelets recognize
muscles and the brain and lymphocytes. Neutrophils, eosinophils, an injury and produce a clot to
with oxygen needed to monocytes, and lymphocytes all use stop bleeding. This helps protect
function. About 50% phagocytosis, which means that they engulf our bodies from infections, while
of your blood is made the bacteria. Basophils, as well as neutrophils keeping blood in. Platelets prevent
up of erythrocytes. and eosinophils, use degranulation to kill too much blood from being lost.
pathogens. Leukocytes make up less than 1% of They are the smallest blood cells.
the blood.
Blood Plasma
Scientific name: Plasma
Common Name: Plasma
Blood plasma’s main job is to transport nutrients and carries all the nutrients, red
blood cells, leukocytes, thrombocytes, and proteins around the body. The plasma
looks like liquid and is about 50% of the blood. About 95% of the plasma is made out
of water.

Steps of a hematocrit test: Anemia is when your blood hematocrit level gets too low. This means there
1. Collect a microtest tube of a are not as many RBC’s in your blood to carry oxygen around. It can occur
patient’s blood when you are bleeding too much and you lose too much blood, when your
2. Centrifuge the blood in a body does not make enough RBC’s, or when your body destroys/attacks
microcentrifuge for 4 minutes on RBC’s. Sickle cell disease is a disease in which the body produces
low. defective RBC’s that are in the shape of a banana. This means that your
3. Find the measurements of the blood can clot easier and not as much oxygen can be transported (anemia).
total height of the blood and the
height of the red blood cells
(mm). Calculation:
4. Calculate the height of the RBC To find hematocrit levels, you divide the height of the
over the height of the whole RBC (Cm) by the height of the blood. This should give you
blood and then multiply by 100. a decimal and you multiply that by 100 to get a percent.
This gives you a percent. 2.1 Cm
= 0.656 × 100 = 65.6%
You can use hematocrit test results 3.2 Cm
to determine whether a person has a This person has very high hematocrit level
low/normal/high hematocrit level. If because the normal hematocrit level for a male is
you have a low hematocrit level it 42%-54% and this person had 65.6%. Sickle cell
means that you are anemic and you disease causes low hematocrit levels because of
cannot carry as much oxygen to your the defective red blood cells that are carried
body. throughout the body.
 Sickle Cell Disease
Sickle Cell Disease, also known as sickle cell anemia, is an inherited
disease that is found on chromosome 11. More specifically, it is found
on the gene for hemoglobin-Beta. In this disease, the hemoglobin S
sticks to each other and form a long sickled blood cell. Sickled red
blood cells cause more blood clots and carry less blood. Although
sickle cell disease is a harmful disease, it also has some benefits. If
you receive the gene for sickle cell disease, you more immune to
malaria (malaria resistance). In a person without sickle cell disease, the hemoglobin molecule binds and
takes oxygen from the lungs and carries it to peripheral tissues.
Sickle Cell Disease is Red Blood Cells are
passed down through a directly affected
recessive gene, so you by sickle cell
can only get sickle cell disease. The
disease if both parents mutation that
are carriers or have the causes sickle cell
disease. Generally, this disease can be
mutation is found in found on the Sickled RBC
African-Americans, hemoglobin-Beta
Indians, and Mexicans. gene. This gene is located on chromosome 11 and
If your parents are both carriers for sickle cell changes the total function of the RBC. Instead of
disease (like shown in the picture), you have a 25% flowing smoothly in the arteries, veins, and
chance that you will get the disease and a 50% capillaries, the sickled RBC’s can get stuck. In a
chance that you will carry the gene. This means sickle cell, the gene tells the hemoglobin to stick
that the sickle cell gene will be passed on for together, which causes the long banana shape. If
generations. Finally, a person can never get or lose you have sickle cell disease, not all of your cells
the sickle cell disease over time, but we can treat turn sickle. Finally, sickle cells die really quickly
people with sickle cell anemia. and easily. Normal cells last approximately 120
days, but sickled RBC’s only live 10-20 days.
Symptoms of Sickle Cell Disease: Antibiotics (hydroxyurea), folic acid supplements,
- Angina or other pains (occurs when the sickled chronic blood transfusion therapy, and bone
blood forms a clot) marrow transplant are all ways to treat/cure sickle
- Swelling (due to the blockages blocking flow to cell disease. Antibiotics can help fight and prevent
hands and feet) infection for sickle cell disease. Hydroxyurea
- Infections (can damage organs such as the stimulates the production of fetal hemoglobin,
spleen) which prevents sickled cells from forming. Folic
-Delayed Growth (nutrients and oxygen cannot acid production can help with the making of new
travel the body as quickly) red blood cells. This will help to dilute the blood.
-Jaundice (the sickled Chronic blood transfusion can help increase the
RBC’s are dying faster amount of RBC’s, which ultimately helps carry more
than the liver can filter oxygen and more blood throughout the body.
them out causing Finally, bone marrow
bilirubin to build-up) helps make red blood
cells, so transplanting
bone marrow will
increase red blood
cell production.
 3.2 One Page Wonder- It’s In the Genes
Josh Jones

3.2.1 Protein Synthesis
Transcription Translation
Translation is the
process after
transcription, in
which the mRNA’s
code (copied and
opposite DNA’s
code) is
transformed into a
protein. First, the mRNA must find a ribosome.
Transcription is a process in which DNA’s code is copied onto The ribosome goes along the mRNA and finds the
a strand of RNA(ribonucleic acid). The mRNA is known as start codon (AUG). Thereafter, the ribosome
messenger RNA because it synthesizes DNA’s code to take to recognizes the letters on the base pairs. As the
the ribosomes for translation. The purpose of transcription is ribosome moves along the mRNA, tRNA (transfer
for the mRNA to copy specific genes on DNA and to be taken RNA) holding the amino acids comes and starts to
out of the nucleus, so that a protein can be produced. DNA form a peptide chain. They must match so the
cannot fit through the nuclear pores, so it must be tRNA codons will fit with the mRNA codons. The
synthesized on a strand of mRNA. This allows mRNA to take tRNA is actually using DNA’s code to produce a
the complimentary base pairs out of the nucleus for the peptide chain, which will eventually turn into a
production of proteins. This process happens inside the protein. After the tRNA has been used, it leaves.
nucleus. RNA polymerase runs down the DNA strand and Finally, once the ribosome reaches a stop codon
unwinds it so that an mRNA strand can copy the nucleotides. (UAG, UAA, and UGA), the peptide chain breaks
The mRNA copies complimentary letters (except adenine (A) away to fold and form a protein. The whole
pairs with uracil (U), instead of thymine (T)). Finally, after process, both transcription and translation, makes
the mRNA copied the DNA, it exits the nucleus through one single protein and this is when mutations
nuclear pores. often occur.
Amino Acids Codons Cytoplasm
Amino acids are Codons are 3 The cytoplasm is a
the monomers nucleotides on the cell organelle and
for proteins mRNA that attract is where
and are taken the complimentary translation occurs.
to the ribosome by the tRNA in tRNA. This helps
translation. build the peptide chain.
DNA (deoxyribonucleic acid) mRNA Nucleus
DNA is made mRNA is a copy of a The nucleus is
of genetic strand of DNA and is the control
information synthesized by RNA center of a cell
to code for polymerase. It holds and is where
all living DNA’s genetic transcription
things. It information and takes takes place.
is copied it outside the nucleus After DNA is
onto an mRNA strand so for production of synthesized, the mRNA exits the
proteins can be built. proteins. nucleus.
Ribosomes RNA Polymerase tRNA
Ribosomes RNA is tRNA transfers the
bring an amino acids to the
together the enzyme ribosome and
tRNA and that identifies the codons
mRNA and unzips so that its anticodons
move along DNA so (complimentary
an mRNA that a nucleotides of codons)
strand in order to form a peptide complimentary strand of RNA can can match up. It adds an amino
chain. be made. acid to the peptide chain.
 Van der Waals S-S Bonds Electrostatic Forces Hydrogen Bonds
The stickiness of all Cysteine amino acids Positively charged Water attracts
atoms that attracts bond because there amino acids bond to hydrophilic amino acids.
them to each other is sulfur atoms attract. negative amino acids. This affects all amino
known as Van der This only happens with acids.
Waals. hydrophilic molecules.

Hydrophilic Hydrophobic
To be hydrophilic means that you are an amino acid To be hydrophobic means that you are an amino
that is attracted to water. These amino acids are acid that is trying to move away from water. These
polar and charged. Polar means that an amino acid amino acids are nonpolar, uncharged, and neutral.
has both a positive and a negative. Hydrophobic amino acids are like oil because oil and
water separate.
Hydrophilic amino acids (Polar): Hydrophilic amino acids Hydrophobic amino acids:
(Charged):
 Glutamine- Gln  Alanine- Ala
 Asparagine- Asn  Aspartic Acid (-) –Asp  Isoleucine- Ile
 Histidine- His  Glutamic acid (-) –Glu  Leucine- Leu
 Serine- Ser  Arginine (+) –Arg  Phenylalanine- Phe
 Threonine- Thr  Lysine (+) –Lys  Valine- Val
 Tyrosine- Tyr  Proline- Pro
 Cysteine- Cys  Glycine- Gly
 Methionine- Met
 Tryptophan- Trp

The nucleotide that is changed in order for a person to
have sickle cell disease is located in the codon for the
6th amino acid. The mutation is a single nucleotide
substitution, so that means that only one letter is
changed in the whole protein. Instead of a T, people
with sickle cell have an A. This changes how the RNA is
made, resulting in an amino acid change, and eventually
the whole cell malfunctioning.
th
The amino acid changed is the 6 amino acid. In a normal red blood cell
the amino acid sequence goes: Valine – Histidine – Leucine – Threonine –
Proline – Glutamic Acid. However, in a sickled red blood, instead of the
6th amino acid being glutamic acid, it changes to valine due to the
nucleotide substitution. As a result, the hemoglobin becomes sickled. A
person could have to deal with a lifetime of pain and suffering all
because of one nucleotide base change.
Glutamic acid is hydrophilic When trying to form a cell,
and has a negative charge. So, the sickle cell hemoglobin
when it is replaced by valine, a starts to stick to each
highly hydrophobic amino acid, other causing a dense cell.
the cell and its shape has It becomes very hard for
changed. The hydrophobic the sickle cell to carry
valine wants to get away from oxygen. In a normal red
the water so it “caves” in. This blood cell hemoglobin is not
eventually causes a sickle-cell sticky, which causes it to
hemoglobin, which leads to a be able to carry more
sickled red blood cell. oxygen and flow better.
 3.3 One Page Wonder – Chromosomes
Josh Jones

3.3.1 Chromosomes
There are 23 This
pairs of karyotype
chromosomes shows the
in an average person is
human cell (46
male because
total
the genotype
chromosomes).
is XY.
Chromosome pairs 1-22 are considered A sex chromosome determines your sex. The sex
autosomes. Autosomes are chromosomes that chromosomes are on the 23rd pair of chromosomes.
do not determine a person’s sex, but code for If you are female, your genotype will be XX and if
every other protein in the body. you are male, your genotype will be XY.
This picture shows that chromosomes in the nucleus are made of coils,
which are made up of nucleosomes. A nucleosome is a strand of DNA
wrapped around histone proteins. Then, the DNA is made up of genes
and genes are made up of base pairs. DNA is made up of genes, and is
what chromosomes are made of. DNA is the genetic material for life
because it stores genetic information.
A mutation is a change in the DNA sequence that ultimately can cause a change in the production of a
protein. Mutations can be both harmful and beneficial. The change in the genetic material can allow for
genetic diversity, but can also cause genetic disorders. For example, in sickle cell disease, some red
blood cells will not be able to carry as much oxygen, but it also protects you against malaria.

Mitosis occurs in the somatic cells. This occurs only for
autosomes. Somatic cells are all the cells in your body except
sperm and egg. In interphase, the cells duplicate and pair with
their matching chromosomes. During metaphase, the
chromosomes center themselves and the spindle fibers attach.
During anaphase, the chromosomes split up and go to opposite
poles. Finally, in telophase, 2 nuclei are formed, which are then
split into 2 daughter cells. The result of mitosis is 2 daughter
cells.
Meiosis occurs in gamete, or sex, cells. More specifically,
meiosis occurs in the ovaries or the testes. The first step in
meiosis is prophase. In prophase I the chromosomes condense
and crossing over occurs. Then in metaphase I, the homologous
chromosomes move to the equator. In anaphase I, the
homologous chromosomes are pulled to opposite poles. In
telophase I, the cytoplasm divides and 2 cells are formed. The
cells are now haploid. Then in prophase II, chromosomes
condense. In metaphase II, chromosomes are pulled to the
equator and spindle fibers attach. In anaphase II, the
chromosomes are pulled apart. Finally, in telophase II, 4
haploid cells are produced. Meiosis occurs to produce sex cells.
 Homologous chromosomes are a pair of
chromosomes with a similar location, dimensions,
and structure. Homologous chromosomes
centromeres are in the same spot and their gene
loci’s are in the same position. Even though the
gene loci of the 2 chromosomes are similar, it
does not mean that the have the same alleles.
The mother may have given you the dominant
allele, but you father may have given you a
recessive allele for a certain trait, which makes
you heterozygous.

A dominant trait is a characteristic that can be A recessive trait is a characteristic that must be
passed down genetically from only one parent. If passed down genetically by both parents in order
the mother has the trait and passes it down, the for the offspring to get the trait. Both the
offspring will have the trait no matter what the mother and the father must pass on a recessive
father gives. Some examples of a dominant trait trait for the child to show the trait. Some
are: examples of a recessive trait are:

 Freckles  Attached earlobes
 Familial Hypercholesterolemia (FH)  Sickle cell disease
 Unattached Earlobes  Hemophilia
 Dwarfism  Phenylketonuria (PKU)

Homozygous dominant genotype: Homozygous recessive genotype: Heterozygous genotype: Aa
AA aa
Phenotypes:
Phenotypes: Phenotypes:
 Sickle cell disease (a
 Sickle cell disease (a  Sickle cell disease (a recessive trait): disease
recessive trait): disease recessive trait): some is not present, but the
is not present red blood cells are person is a carrier and
 Dwarfism (a dominant sickled can pass on the trait
trait): genetic disorder is  Dwarfism (a dominant  Dwarfism (a dominant
present so expresses trait): disorder is not trait): genetic disorder is
dwarfism traits present present so expresses
dwarfism traits

Pedigrees show how a disease is passed from one generation to the
next. Pedigrees are a big family tree that shows who has a specific
trait for a specific disorder/disease. Pedigrees show the heredity
of a specific trait. Sickle cell disease is a recessive trait, so both
parents must have the disease in order for their offspring to get
it. It is an autosomal disorder (occurs on chromosome 11). In the
pedigree, generation 1 mother had the disease, so her genotype
was: ss. However, the father does not have the disease, so his
genotype is SS. The father can only give an S and mother can only give an s. This means all of their
offspring must be Ss, so they all are carriers, but do not express the disease in any way. Then, for the
next generation, one of the females from generation 2 has offspring with a male that is also a carrier.
This means there is a 25% chance their children will have the disease, 25% chance their children will
not have the disease, and 50% chance their children will be carriers.
 3.4 One Page Wonder – Inheritance
Josh Jones

3.4.1 Inheritance
Genes, chromosomes, and alleles all decide most of your traits and which traits you inherit
from your parents. Genes are a specific strands of DNA that code for proteins. Each parent
gives one chromosome and chromosomes are made up of lots of genes. Alleles are specific
genes that code for proteins and determine what trait you have. Each parent can give you
either a dominant or a recessive allele on the chromosome, which determines your phenotype.

Your heredity, or inheritance, can be tracked through a
pedigree. If you have a specific disease or know you have
or are a carrier for a genetic disease (through genetic
testing), a pedigree can help determine whether your
children will have it. It can also determine whether your
relatives are carriers or have the disease. Both parents
could be carriers and not know that they could pass the
disease/trait to their children. As seen on the picture at
the right, the people who are carriers of sickle cell disease are partially shaded, those who do
not have it are not shaded, and those who do have the disease are shaded. From the
information given, you can determine and predict what other relatives might have been/will
be. For example, female 3-1 will always have children that are carriers or have the disease, no
matter who the father is. We can use pedigrees to predict the probability that your children
will have a disease or trait.

Dominant Traits Recessive Traits
A dominant trait is a trait that overrides A recessive trait is a trait that must be
other alleles. A person who have a dominant expressed by both alleles. Both parents must
trait only needs one dominant allele to contribute a recessive allele in order for the
express a certain trait because it will offspring to receive the trait.
override a recessive allele.
The only possible genotype for a recessive
Possible genotypes include: AA or Aa trait is: aa

Three examples of a dominant trait are: Three examples of a recessive trait are:
dimples, freckles, and unattached (free) hitchhikers thumb, color blindness, and
earlobes hemophilia
Trait: Hitchhikers Thumb
Possible Genotypes: aa Genotypes that will not express the trait: AA,
Aa
Phenotype: hitchhikers thumb Phenotype: no hitchhikers thumb

Punnett Squares use peoples’ genotypes to determine the probability that they’re offspring
will receive a certain trait or disease. Punnett squares can influence decisions on whether
people want to have children or not.
Tay-Sachs is a genetic disorder that destroys the brain and nerves in children. As children
should be developing, children with Tay-Sachs are going backwards. Tay Sachs expresses an
absence of the hexosaminidase A enzyme that regulates the fat in the brain. Without this
enzyme, the fat in the brain accumulates causing swelling.

Type of Trait: Autosomal Recessive

Mom: Heterozygous (Rr)

Dad: Heterozygous (Rr)

Prediction: The offspring will have a 25% chance of not producing enough of the
hexosaminidase A enzyme, 50% chance of being a carrier, and 25% they will not carry the
disease.

This map shows the
places that sickle cell
disease is the most
common.

Sickle cell disease is most common is nothern and eastern Africa, as seen on the map, but can
also be found other places around the world. Africa is one of the hottest continents with the
largest desert in the world. Not only is it hot, but it is also filled with mosquitos that carry
malaria. Sickle cell disease may be prevalent in Africa because the sickled cells prevent
malaria. It is not seen as often in other parts of the world because mosquitos carrying malaria
is most common in Africa. This is why mainly African Americans and Indians (or people that
descended from these groups) inherit the disease. Another perk of having Sickle Cell Disease
is that you will never have the plasmodium parasite, a parasite that can cause malaria. This
evolutionary genetic mutation that caused sickle cell disease may have/will save millions of
lives, but can also harm millions of lives.
 4.1 One Page Wonder – Heart Structure
Josh Jones

4.1.1. Tissues, Cells, and the Heart
Cells make up tissues, which make up organs. Cells
are the smallest units of life and a tissue is a group
of cells. Cardiac muscle tissue is the tissue that
makes up the heart. It is the strongest muscle in
the body because it has to pump blood constantly.
Heart cells make up cardiac muscle tissue. Cardiac
muscle tissue makes up the heart and the heart is
part of the cardiovascular system.

4.1.1. Heart Anatomy (Role of Structures)
Vessels Valves Chambers
There are 2 kinds of There are 2 kinds of valves: There are 2 kinds of chambers:
vessels: arteries and atrioventricular and semilunar. the ventricles and the atrium.
veins. Arteries take Atrioventricular valves are the The atrium is part of the heart
blood from the heart to valves that allows/pumps blood to where veins drop off blood and it
the body. Veins take go from the atrium to the is the entrance to the heart.
blood back to the heart. ventricle. Semilunar valves Then, the atrium pushes the
Pulmonary arteries and allow/pump blood from the blood through a valve into the
the aorta are 2 examples ventricles into the body. Examples ventricle. The heart then pumps
of arteries. 2 examples of atrioventricular valves are: the blood out of the ventricles
of veins in the heart are tricuspid valve and mitral and to the lungs or to the heart.
the superior vena cava (bicuspid) valve. Examples of The main chambers in the heart
and the inferior vena semilunar valves are: the aortic are: the right atrium, the left
cava. valve and the pulmonary valve. atrium, the left ventricle and the
right ventricle.

The right side of the heart is deoxygenated and the left
side of the heart is oxygenated. The left side pumps blood
to the body, which is when oxygen is delivered. The right
side of the heart pumps the blood, which it receives from
the superior/inferior vena cava, to the lungs so that it can
be pick up oxygen. This process continues all the time. If
the heart stops, you will die.
 4.1.1. Circuits
Pulmonary Circulation Systemic Circulation
The goal of the pulmonary The goal of the
circuit is to get oxygen systemic circuit is to
from the lungs so that it transport oxygen to
can enter the systemic the body. After it
circuit. First, the blood delivers the oxygen it
picks up oxygen molecules reports backs to the
and goes back into the left right atrium where it
atrium where it can be is pushed through the
pumped through the left ventricle and then
ventricle and out the back to the pulmonary
aorta. After pumped arteries where it
through the aorta it starts the systemic circuit. restarts the pulmonary circuit. So, the constant
The right side of your heart is smaller than the blood flow goes back and forth from the left
left side because it only has to pump to the lungs, side to the right side. This process repeats
whereas the right side pumps to your whole body. thousands of times every day.

4.1.1. Path of Blood
As a young erythrocyte, I traveled throughout the human body every single day. I still remember my first
day of circulation. It was a rough, winter morning for my beloved master when I started my circulation. I
started in the right atrium as a poor deoxygenated red blood cell. The red blood cells told me to hold on
tight because we were getting ready to pass through the tricuspid valve. Sure enough, we were all forced
through the tricuspid valve to the beat of Staying Alive by the Bee Gees. Before we knew it we were in and
out of the right ventricle and up through the pulmonary valve. "Oh oh oh oh staying alive staying alive!" sang
my fellow erythrocytes, so I joined in. Finally, we were shot through the right pulmonary artery, the
expressway to the right lung. We visited the right lung as it infused all of us with its oxygen. I left the
right lung because I had to get back to the heart. My friends nearest me followed me through the right
pulmonary vein until we reached the left atrium. There we got to stop for a split second while the Bee Gees
sang one Oh! and we soon were shoved into the left ventricle through the mitral valve. My oxygenated
friends and I were shot through the Aortic valve and then into the ascending aorta. We were really going
fast and we were shot up into the brain. There all of us gave our spare oxygen to the brain. Just as fast as
we were shot up to the brain, we were descended back down into the Superior Vena Cava. It was a long and
hard day at work. We did this all day, every day for the rest of our lives.

4.1.2 Heart Dissection
External and Internal Examination of a Sheep Heart

Photos courtesy of Anjali Patel and Lexi Mills
 4.2 One Page Wonder – The Heart at Work!
Josh Jones

4.2.1 Heart Rate
Pulse is a rhythmic beat created by the Carotid Pulse is a method of taking pulse to find
expansion and contraction of the arteries, how much blood you are pumping per minute.
which causes blood to be Your pulse can be
pumped around the body. found on your neck.
Pulse is caused by an This is where the
electrical signal that runs carotid artery is
through your heart located. Use your index
causing it to contract. finger and middle
finger to take the pulse because your thumb
has its own distinct pulse.
Radial Pulse is another way The typical heart rate is 60-80 beats per
to take your pulse. It is minute (bpm). If the pulse is too high, this
taken on your wrist. Also, means that you have tachycardia. If your pulse
take this pulse with your is lower than normal, it means that you are
index and middle finger. physically fit. This is good because it can
decrease your risk of heart disease and a heart
attack in the future.

Systole/Systolic Pressure Diastole/Diastolic Pressure
When the heart is When the
experiencing the most heart is
systolic pressure, it is experiencing
being compressed. During the most
this time the blood is being diastolic
pushed into the arteries. pressure, the
The stage in which systolic heart is
pressure is the greatest is relaxed.
known as systole. When During this
taking blood pressure, systolic pressure is the stage, the
first number and is hearts
always higher than chambers,
diastolic pressure. more
To find blood specifically the ventricles, are filling up with
pressure, you can blood. This stage is known as diastole. When
use a taking blood pressure, diastolic pressure is the
sphygmomanometer. second number and is always the lower of the 2
On a sphygmomanometer, the first time you numbers. While using the sphygmomanometer,
hear the pulse is the systolic pressure. diastolic pressure is the number at which you
hear the last pulse.
Hypertension is when you blood pressure is Causes of hypertension: Too much sodium in
too high. your diet, lack of exercise, being overweight,
stress, and smoking/alcohol consumption

Hypertension treatments: Exercise, take
medication (ACE Inhibitor), cut back on
sodium, and stress management (e.g. yoga).

The heart beats due to the electrical system that
runs through it. First, the Sinoatrial node (SA node)
sends a signal for the heart to beat. This occurs in
the right atrium and the signal continues until it
reaches the Atrioventricular node (AV node). At the
AV node, the signal pauses in order for the atria to
contract. Then, the electricity continues down into
the AV bundle or the Bundle of His. This allows the
signal to branch in two. The bundle carries the two
signals down the septum for the left and right
ventricle. Then, as the current continues, it travels to the apex and then spreads on the
ventricular walls. Finally, it reaches the Purkinje fibers which are in the ventricular walls. It
allows the ventricular muscles to strongly contract in unison. A pacemaker can replace the SA
node because it starts the electrical current throughout your heart.

The electrical system and your pulse can be tracked
through an Electrocardiogram (EKG). During each stage of
the electrocardiogram, a change occurs. The P phase on the
EKG is the time when the atrium contracts and the heart
becomes electro-polarized. Then, during the QRS stage,
the ventricles are contracting. Finally, during the T stage,
the ventricles become repolarized. All of this can occur
from 0.5-0.7 seconds. Also, the length between the R-R is
the length of your heart beat, and from that cardiologists
can determine your pulse. Cardiology is the study of the
heart and its actions, so a cardiologist is a person that
studies the heart. A cardiologist can use an EKG for many purposes. They can use the EKG to
determine their pulse, their likelihood of a heart attack and they can determine if they need
a pacemaker.
 4.3 One Page Wonder – Heart Dysfunction
Josh Jones

4.3.1. HDL vs LDL
HDL – High Density Lipoprotein LDL – Low Density Lipoprotein
HDL carries
cholesterol
away from
your heart and
other organs.
It delivers the
cholesterol to
the liver. HDL
is considered
good cholesterol because it takes the
cholesterol from your arteries and delivers
them to your liver, which can prevent LDL brings cholesterol to the cells and can
atherosclerosis (hardening/narrowing of the build up in your arteries. This is considered
arteries). Structurally, HDL has more proteins the bad cholesterol because it can cause
and less cholesterol than LDL has. cholesterol to buildup in your arteries and
can cause atherosclerosis.
Triglycerides
Triglycerides are a type of fat that store extra energy from your food. High levels of
triglycerides can cause atherosclerosis.
Triglycerides are lipids. A normal amount of
triglycerides are
below 150 mg/dL.
High levels of
triglycerides are
200-499 mg/dL.

4.3.2 Familial Hypercholesterolemia
Familial Hypercholesterolemia is a genetic disorder, caused by a mutation on chromosome 19,
which causes LDL receptors on the cell surfaces to be defective or nonexistent. This allows
the buildup of LDL in the arteries. It is an autosomal dominant trait.
Genotypes for FH: AA, Aa. Because it is an autosomal dominant trait, it must have at least one
dominant allele. AA means that it is homozygous dominant and they have a 100% chance of
passing to their offspring. Aa is heterozygous for the trait and is a 50% chance of passing
the trait to their offspring. The phenotype for either genotypes is that you have Familial
Hypercholesterolemia, which means you have high cholesterol due to genetics.
4.3.2 Familial Hypercholesterolemia
Genotype that protects from FH: aa. In order FH is
to be protected from FH, you must have 2 passed on
recessive alleles from one
Hypercholesterolemia has many risks. If you person to
have FH you are at risk for: heart disease, their
atherosclerosis, aortic aneurysm, stroke, offspring.
peripheral artery disease, etc. Because it
Hypercholesterolemia mainly harms the is
cardiovascular system because it is means that autosomal dominant, it is very common for a
you have too much cholesterol in your blood. parent to pass it to their child. If a person
is homozygous dominant, their offspring is
guaranteed to receive the trait.
Familial Hypercholesterolemia causes high levels of LDL because of the genetic mutation. On
chromosome 19, the instructions for making LDL receptors is missing or badly mutated. The
low amount of LDL receptors, causes a high amount of LDL in the bloodstream, which can
cause hypercholesterolemia and atherosclerosis.
To see if you have Familial Hypercholesterolemia,
doctors can take DNA samples and use Polymerase
Chain Reaction (PCR) to multiply your DNA. Then,
they can see the DNA samples on Gel
Electrophoresis, to determine whether the RFLPs
show that you have FH. The Restriction Enzymes on
the Gel Electrophoresis cuts the DNA so that you can tell whether you have FH.

4.3.3 Atherosclerosis and the Heart
Hypercholesterolemia is a high amount of cholesterol in
the bloodstream. Atherosclerosis is the build-up of plaque
in the arteries, which causes it to narrow and harden. If
you have Hypercholesterolemia, there is a higher risk of
you getting atherosclerosis. Hypercholesterolemia can
increase you blood pressure. The narrowing of your
arteries causes the same of blood to travel through a
smaller area. This puts more pressure on your arteries.
There are very high risks for high cholesterol and atherosclerosis. Fat, cholesterol, and
calcium is considered the plaque in your arteries. When these components build-up,
atherosclerosis can create many problems. Risks of having hypercholesterolemia and
atherosclerosis includes: hypertension, heart disease, heart failure, stroke, kidney disease,
liver dysfunction (from lack of blood), and peripheral artery disease. You could die from a
heart attack or stroke, if you have hypercholesterolemia and/or atherosclerosis.
 4.4 One Page Wonder – Heart Intervention
Josh Jones

4.4.1 Unblocking the Vessels
Myocardial Angiograms allow
Infarctions are cardiologists to find
blockages of blood where a blockage is in
flow in the coronary your heart. From this
artery to the heart. they can determine
If you have whether you have
atherosclerosis, blocked arteries that
then you are at a higher risk of getting a need a stenting,
myocardial infarction. Because Coronary Artery Bypass Graft (CABG) or
atherosclerosis is the hardening and balloon angioplasty. Cardiologists insert a
narrowing of the arteries, less blood can pass catheter into your elbow and inject dye, so
through your arteries, which eventually will that when they perform the angiogram, they
cause a blockage. Eventually, if untreated, can determine where the dye does not go. If
myocardial infarctions and atherosclerosis the dye flows to a certain artery less, then
will cause a heart attack. this means you have a blockage.
Atherosclerosis can also relate to many other health problems,
including a stroke. Just like in the heart, if you have a build-up of
plaque, blood will not be able to flow as well. A stroke occurs because of
a blood clot, which can be linked to atherosclerosis. If you have
atherosclerosis, you are at a higher risk for a blood clot because there
is a smaller amount of space for the same amount of blood to flow.

Methods of Unblocking Vessels
Balloon Angioplasty Stenting Coronary Artery Bypass Graft
(CABG)

In balloon angioplasty, In stenting, a cardiologist will If the blockage is severe
cardiologists insert a catheter insert a catheter with a balloon enough, cardiothoracic surgeons
with a balloon on the end into and a stent. Once the catheter will remove part of your
the blocked artery/vein. Then, reaches the blockage, saphenous vein in your leg, and
they blow the balloon up, so that cardiologists will blow up the insert it into your heart to
it pushes the plaque back. They balloon and the stent. They then bypass the blockage.
then remove the catheter and remove the balloon so that only
balloon. the stent remains.
 4.4.2 Heart Disease Risk
According to the CDC, heart disease is the
leading cause of death in the US, killing more
than 614,000 people per year. Many people
can be at risk for heart disease, but may not
know it. 6 major risk factors for heart
disease include:
 Family History (non-modifiable)
 Smoking (modifiable)
 Age and Gender (non-modifiable)
 Exercise/Physical Inactivity
(modifiable)
 Diet with lots of sugars, fats, salt, and cholesterol (modifiable)
 Obesity (modifiable)

Metabolic Syndrome
Metabolic Syndrome is a group a factors
that can cause an increased risk of
cardiovascular diseases and Type 2
diabetes. If you have three or more of
the following, you are considered to have
metabolic syndrome: high blood pressure,
high triglyceride levels, low HDL levels,
high fasting levels of blood sugar, and are
obese.
If you have metabolic syndrome, then you
are at risk for many other health problems.
From metabolic syndrome, you could get
heart disease, lipid problems, hypertension,
type 2 diabetes, cancer, dementia,
polycystic ovarian syndrome, and non-
alcoholic fatty liver disease.
 5.1 One Page Wonder – Infection
Josh Jones

5.1.1. Patient Zero
Patient Zero refers to the person who started an outbreak of an infectious agent.
They are the first carrier of a contagious disease and may never show signs of
the infection. An example of a patient zero would be Typhoid Mary. Mary Mallon
was the first asymptomatic carrier of the pathogen, Typhoid Fever. Because she
was a cook, she spread the pathogen through food, after not washing her hands.

5.1.2 Infectious Disease Agents
Bacteria Virus Helminths
 Superbugs-antibiotic resistant  Attaches to a cell and  Parasites (generally worms
 Single-celled microbes- few injects DNA into the cell and are multicellular)
cause disease, mostly helpful  Vaccines prevent  Treatment: Anthelmintic
 Treatment: Antibiotics  Antivirals treat drugs
 Transmission: Direct Contact,  Transmission: Direct/  Transmission: Contaminated
Airborne, Touching Indirect Contact, Bodily food/water, Feces
Contaminated Objects Fluids, Airborne  Examples: Tapeworms,
 Examples: MRSA, C. Difficile,  Examples: Zika, HIV, Guinea Worms, Pin worms
Streptococcus pneumonia, etc. Influenza, Rhinovirus, etc.
Protozoa Prions Fungus
 Single celled organisms-  Not an organism, not made  Related to mushrooms, but
parasitic meaning first animal of cells – protein that feed on human tissue
 Treatment: Antibiotics folded wrong  Treatment: Antifungal,
 Transmission: “fecal-oral  Destroys the brain antibiotics
route”, contaminated  Treatment: None  Transmission: Airborne,
food/water, direct contact  Transmission: None Direct contact
 Examples: Giardia lamblia  Examples: Kuru Disease,  Examples: Ringworm,
parasite, plasmodium parasite, Bovine Spongiform Candiaditis, Dermatophytes
Brain-eating amoeba, etc. Encephalopathy, etc.

5.1.3 Bacterial Structure
Nucleoid: DNA of bacteria – holds genetic information
Plasmid: Round piece of DNA for passing genetic information
between bacteria
Ribosomes: made of rRNA, help create proteins
Cell Wall (peptidoglycan): Keeps the shape of the cell
Plasma Membrane: selectively permeable
Capsule: Protects the cell and makes more virulent
Flagella: movement- spin around
Pili: hollow tubes that allow plasmid to go through
Cytoplasm: holds everything in place
5.1.3 Aseptic Technique
Aseptic literally means “without infection”, so aseptic technique is the technique used to ensure that
you do not spread germs to a specimen and that the specimen does not introduce infectious agents to
you. 5 ways we ensure aseptic techniques are: PPE is worn, hair is properly tied back, inoculating loops
are never placed in the same sample twice, no food or drink in the lab, and hands are washed before
and after the lab. A person who studies microbiology, a microbiologist will use these aseptic techniques
 5.1.3 Plate Streaking
The quadrant method is a way of streaking and culturing
bacteria. First, you obtain a Petri dish, bacteria, and an
inoculating loop. Then, you split the Petri dish into 4
quadrants. Take the bacteria and start in the top left
quadrant. Then, you get a new inoculating loop (or you burn
it if it’s metal), and you streak across the top half, from
left to right. You repeat this with the right side. Finally, you streak the
bottom, this time from right to left. The purpose of the quadrant method is to
separate individual colonies to identify the morphology and identify the type of infectious agent.

5.1.4 Gram Staining
The purpose of gram staining is to see the bacteria sample and to identify the cell morphology and the
type of infectious agent. Under the microscope, if the bacteria is rod-shaped, it is bacillus; if the
bacteria is spherical, it is coccus; if the bacteria is spiral-shaped, then it is spirillum.
Gram Positive Gram Negative
 Blue/purple color  Pink/Red color
 Less pathogenic  More pathogenic
 Less endotoxins (“worse”)
 Less capsule  More endotoxins
 More peptidoglycan  More capsule
 Less cell peptidoglycan

5.1.5 Bacterial Identification
Chemical testing can be used to identify bacteria by finding out specific thing about them. For
example, you can narrow it down based on their morphology, but sometimes that does not totally
eliminate all the possibilities. The lactose fermentation test determines whether the bacterium
ferments lactose as a food source. The Lysine Decarboxylase Test determines whether the bacterium
can use lysine as a food source. Finally, the oxidase test determines whether an infectious agent
contains cytochrome oxidase.

5.1.6 Lines of Defense – the immune system helps protect the human body against infectious diseases.
The specific defenses (antigens, antibodies, T-cells, and B-cells) and non-specific defenses (skin, nose
hair, mucus, phagocytes) rid your body of unnecessary infectious agents. The specific and non-specific
defenses of the immune system, especially B-cells, can provide immunity to specific pathogens.
Antibodies are B Lymphocytes T-Cells Phagocytes
what our B-cells T-
immune are a cells
systems kind are
produce to of the
attack the pathogen. WBC last
that makes the
Antigens are on the cell antibodies to resort option. When an Phagocytes are
surfaces to alert the immune attack and stop infection has infected cells, a kind of WBC
cells of an invader. the pathogen. Killer T-cells inject poison that eat yeast
into that cell so it will die.
and other cells.