Immunology and Genetics for Blood Bank

Question 1

Objective

IgG properties that promote serological reactivity of agglutination or hemolysis

Answer 1

• Monomer
• Reacts at 37°C body temp
• Secondary response
• Small size means it can escape venous space to cause extravascular hemolysis
• Only IgG3 activates complement

Question 2

Objective

IgM properties that promote serological reactivity of agglutination or hemolysis

Answer 2

• Pentamer
• Reacts at 20°C room temp provides easy testing
• Primary response
• Activates complement
• Large size means it stays stuck inside venous space

Question 3

Objective

Which protein in the complement system is ID’d on the RBC after complement activation?

Answer 3

C3b
It attaches to the RBC antigen before destruction

Question 4

Objective

Compare and contrast properties of the RBC component that make them an ideal product for transfusion

Answer 4

• Designed to carry oxygen efficiently
• Non-toxic to human body
• Naturally sourced

Question 5

Objective

Compare and contrast properties of the RBC component that make them an less than ideal product for transfusion

Answer 5

• Transplant rejection due to immune stimulation
• Infectious
• Limited shelf life
• Volunteer collection only

Question 6

Objective

Use the Punnett square to predict phenotypic expression of given genes in offspring

Answer 6

:)

Question 7

LObjective

Which RBC chemical properties are increased during storage and why?

Answer 7

• Lactic acid bc metabolic byproduct
• Plasma K and Hgb due to hemolysis

Question 8

Objective

Which RBC chemical properties are decreased during storage?

Answer 8

• % viable cells bc hemolysis
• Glucose bc used for glycolysis
• ATP bc cells use them up
• pH bc more acidic lactate made
• 2,3 DPG bc it degrades over time

Question 9

Objective

How do anticoagulant preservatives mitigate storage changes?

Answer 9

• Citrate chelates calcium to prevent clotting
• Monobasic Sodium Phosphate maintains pH and 2,3 DPG levels
• Dextrose is an ATP substrate
• Adenine makes ATP

Question 10

Objective

cis and trans in genetics

Answer 10

• cis: two genes inherited together on the same chromosomes (e.g, AB blood antigens)
• trans: two genes inherited together from opposite chromosomes

Question 11

Word of the day

Haplotype

Answer 11

• 2 genes inherited together on the same chromosome but code for different Ag
• Genes are linked
• Do not follow Hardy-Weinberg equilibrium equation (don’t add up to 1)

Question 12

Is the complement system innate or acquired immunity?

Answer 12

Innate immunity

Question 13

What does adding plasma do to blood specimen?

Answer 13

Hemolysis

Question 14

What causes agglutination?

Answer 14

IgM latticing (Ag-Ab)

Question 15

Does compatible blood agglutinate? Why or why not?

Answer 15

No agglutination because the Ab does not have the right Ag to bind, which is good for blood tranfusions

Question 16

Does incompatible blood agglutinate? Why or why not?

Answer 16

Yes, agglutination happens because
Ab have Ag to bind, which is bad for blood transfusions

Question 17

Stable Ab-Ag reactions depend on what?

Answer 17

• fit (size/shape)
• charge
• avidity

Question 18

Outside forces that can be controlled

Answer 18

• time
• temp
• pH
• ionic strength
• centrifugation

Question 19

How is blood bank like algebra?

Answer 19

• Figure out which Ag is on pt RBCs
• Figure out which antibody is coming from pt plasma

Question 20

Why do we transfuse blood?

Answer 20

• When the demand for oxygen exceeds 50% of the oxygen you already have, the compensatory mechanisms fail, and the patient requires transfusion
• To maintain hemostasis (such as coagulation cascade vs clot formation)

Question 21

How does the body compensate for anemia?

Answer 21

Increase plasma volume, heart rate, respiratory rate, and RBC oxygen extraction

Question 22

Explain oxygen binding and unloading in context of 2,3-DPG

Answer 22

• During oxygen unloading, 2,3-DPG takes O2’s place and creates a tight binding structure. More O2 released to tissues
• During oxygen binding, 2,3-DPG leaves to create a relaxed binding structure. Less O2 delivered to tissues

Question 23

Explain why 2,3-DPG levels decrease over time in blood product

Answer 23

• It degrades over time, leading to O2 too tightly bound to Hgb -> hypoxia potential
• Can’t pick up or release O2

Question 24

Left shift in oxygen-dissociation curve

Answer 24

Less oxygen delivered to tissues
Increased pH and abnormal Hgb
Decreased temp, P50, 2,3-DPG

Question 25

Right shift oxygen-dissociation curve

Answer 25

More oxygen delivered to tissues
Increased temp, P50, 2,3-DPG
Decreased pH

Question 26

Criteria for viable blood product

Answer 26

• RBC survival >75% post transfusion
• Free Hgb (hemolyzed RBC) < 1%

Question 27

Criteria for non-viable blood product

Answer 27

• Increased cardiac output (transfusion tends to decrease it)
• Decreased pO2 tension (can’t carry O2)

Question 28

What percent of RBCs are cleared from daily circulation?

Answer 28

1%

Question 29

Why does ATP loss reduce deformability and permeability of RBC?

Answer 29

• Deformability impacted because no ATP available to phosphorylate spectrin
• Permeability is reduced because calcium and sodium ions accumulate inside the RBCS, potassium and water are lost, which leads to a rigid and dehydrated cell that gets sequestered by spleen

Question 30

Phenotype

Answer 30

• Physical gene expression
• Detected by serologic testing
• Antigen

Question 31

Genotype

Answer 31

• Actual inherited genes
• Detected by molecular testing
• Allele (individual expression of Ag)

Question 32

Locus

Answer 32

Location on chromosome where gene can be found

Question 33

Allele

Answer 33

Variety within gene
Ag produced by allele

Question 34

Dosage

Answer 34

When Ag expression is less because of heterozygous allele inheritance and more expressed due to homozygous allele inheritance

Question 35

How is gene frequency calculated?

Answer 35

Hardy-Weinberg
p^2 + 2pq + q^2 = 1 (independent inheritance of p and q if equal 1)

Question 36

Hardy-Weinberg assumptions

Answer 36

• Genotypes distributed in proportion to frequency in population
• Genotypes remain constant across generations