Tested,Actual Exam Questions (2026)
WITH Recent Newest Verified And Well
Analyzed Exam Questions (Actual Exam
2026-2027) Correct Detailed & Verified
ANSWERS (100% Accurate Solutions)
ALREADY GRADED A+|| NEWEST
VERSION Of The Exam Guarantee Pass!!
Heme vs Globin - ANSWERS-Heme: Synthesized in mitochondria of reticulocyte
- Carries Oxygen
Globin: Polyribosomes in reticulocytes
- 2 pairs of globin chains on each Hgb molecule
- Combo of pair determines type of globin chain
▪ Most common hgb A: 2 alpha chains and 2 beta chains - hgb F (fetal): 2 alpha, 2
gamma
Hematopoiesis - ANSWERS-Process of blood cell production in adult bone marrow or
the liver and/or spleen of the fetus
Two stages
▪ Mitosis (proliferation)
▪ Maturation (differentiation)
Hemoglobin and its structure - ANSWERS-Oxygen-carrying protein of the erythrocyte --
> may carry up to 300 hgb molecules
,Reversible deformity to be abvle to squeeze through the tiniest of capillaries
Each Hgb molecule has 2 pairs of different globin chains and 4 complexes of iron +
heme
▪ Heme: large, flat, iron-protoporphyrin disk that is synthesized in the mitochondria and
can carry one molecule of oxygen
▪ Each Hgb can carry 4 molecules of oxygen
Red blood cell structure - ANSWERS-Sac of Hgb, no nucleus or mitochondria, only
hemoglobin & enzymes surrounded by membrane
-Lack mitochondria, rely on glycolysis for energy --> "aerobic metabolism"
▪ Deficiencies of 2 enzymes result in anemia
• Pyruvate kinase - necessary for glycolysis - no glycolysis results in RBC damage and
death
• G6PD - involved in protecting the RBC against oxidative stress
Anisocytosis
Poikilocytosis - ANSWERS-Variation in RBC size
Variation in RBC shape
Hereditary vs Acquired Hemolysis - ANSWERS-Hereditary hemolysis: sickle cell
disease
Acquired hemolysis: immune mechanisms (transfusion reaction), infection (malaria),
drugs (penicillin), liver or kidney disease, toxins (chemicals, venoms)
Normal Labs (RBCs, Hgb, Hct, MCV, MCH) - ANSWERS-RBCs 4.2-6.1
Hgb 12-18
Hct 35-50%
MCV: 78-100 (related to size)
MCH: 27-34 (related to hgb content)
Reticulocytes: new RBC formation - low suggest issues in production
,Primary site of hematopoietic stem cells - ANSWERS-Bone marrow ("myeloid tissue")
Difference between red and yellow bone marrow - ANSWERS-Red marrow produces
RBCs, yellow marrow does not produce RBCs
Active bone marrow sites - ANSWERS-pelvic bones
vertebrae
cranium
mandible
sternum
ribs
humerus
femur
Factors that increase hematopoiesis - ANSWERS-(1) conversion of yellow bone
marrow, which does not produce blood cells, to hematopoietic red marrow by the
actions of erythropoietin (a hormone that stimulates erythrocyte production)
(2) faster differentiation of progenitor cells
(3) faster proliferation of stem cells into progenitor cells
Erythropoiesis - ANSWERS-production of RBCs
Sequence of erythropoiesis - ANSWERS-Pluripotent hematopoietic stem cell -->
committed Proerythroblast/Pronormoblast --> Erythroblast/Normoblast (Hgb synthesis
begins) --> Reticulocyte (nucleus is lost; 3 days spent in bone marrow, about 1 day in
blood) --> Erythrocyte
aprox. 1% of RBCs are reticulocytes
In each step the quantity of hemoglobin increases and the nucleus decreases in size
, Erythropoietin - ANSWERS-A hormone produced and released by the kidney that
stimulates the production of red blood cells by the bone marrow
Always present in plasma
Released in response to low renal oxygenation
- NOT the # of RBCs but rather oxygen delivery
- e RBC production increases within 24 hours; life span 4-12 hours; increased RBC # in
5 days
- Given to dialysis and chemo patients
Reticulocytes - ANSWERS-▪ Last immature form of erythroblast
▪ Contains polyribosomes (globin synthesis) and mitochondria (heme synthesis)
▪ 24-48 hours after leaving bone marrow for circulation, matures into erythrocyte
- Loses polyribosomes and mitochondria
-Make up 1-2% of RBCs
- Last about 2 days in bone marrow and 1 day in blood continuing to mature
- During time of low HCT time in marrow decreased to as little as 1 day
▪ Reticulocyte count -- Indicates whether new RBCs are being produced; good indicator
of erythropoiesis
Microcytic-Hypochromic Anemias - ANSWERS-Characterized by red cells that are
abnormally small and contain reduced amounts of hemoglobin
Iron Deficiency Anemia (IDA)
Sideroblastic
Thalassemia
Iron Deficiency Anemia (IDA) - ANSWERS-Type of Microcytic-Hypochromic Anemia
- Most common type of anemia
- Highest risk: older adults, women, infants, poverty
- Associated with cognitive impairment in children