L2 RBCs Structure Development PDF

Summary

This document, L2 RBCs Structure Development, details the structure and function of red blood cells (RBCs). It covers the normal shape, size, and structure of RBCs, including the role of the cell membrane and cytoskeleton in flexibility and ease of passing through capillaries. It also discusses abnormalities in RBC shape (e.g., spherocytosis, crenation), and the presence of RBCs in different situations. Also discusses the life span of RBCs and the mechanism of removal by the spleen, liver, and bone marrow. The document also includes information about hemopoiesis (the process of blood cell production) and erythropoiesis (specifically RBC production).

Full Transcript

Dr. Shehab Hafez

Semester (3): Blood & Lymphatic
System Module (BMS201)

Histology of
RBCs & Erythropoiesis

Prof. Dr. Shehab Hafez
Professor & Head of Histology Department
Faculty of Medicine. Mansoura University

2024-2025
 Dr. Shehab Hafez

1. To determine normal shape, number, size and structure
of RBCs.
2. Correlate between structure and function of RBC.
3. To demonstrate knowledge of hemopoiesis, Its sites &
Hemopoietic stem cells.
4. To determine steps of erythropoiesis.
 Dr. Shehab Hafez

Blood is a specialized connective tissue in which cells (RBCs,
WBCs) are suspended in a fluid extracellular material called
plasma. Also it contains fibers (fibrin) that forms blood clot).

Contents of blood

Formed elements Blood plasma
(Blood cells)

1. RBCs (Erythrocytes).
2. WBCs (Leucocytes).
3. Blood platelets (Thrombocytes).
 Dr. Shehab Hafez
Preparing a blood smear

▪ Blood cells can be studied histologically in smears prepared by spreading a
drop of blood on a microscope slide.

Staining
1. Neutral stains: example: Leishman’s stain: a mixture of acidic (eosin)
& basic (methylene blue) dyes.
2. Romanowsky stains: polychromatic stains: examples: Giemsa and
Wright stains
 Dr. Shehab Hafez
RBCs (Erythrocytes)
Normal shape of RBCs
▪ In stained blood smear: RBCs are Biconcave discs. With a pale center.
▪ This shape provides a 20% to 30% greater surface area & facilitates gas exchange.

With scanning EM (SEM) biconcave discs are better seen.

With Transmission EM (TEM) RBCs
inside a capillary have a classic
dumbbell shape (DB).
 Dr. Shehab Hafez
Abnormal shape of RBCs

1.Spherocytosis (biconvex)
The center of RBC appears dark.

2.Crenation
Shrinkage and notching of RBC when
exposed to hypertonic solution.

3. Swelling & rupture
When exposed to hypotonic solution.
Marked hypotonic solution may
cause rupture of the cell membrane
and hemolysis. Only remnants of
RBCs (cell ghosts) appear.
 Dr. Shehab Hafez
Abnormal shape of RBCs

In Sickle cell anaemia Inherited disease (Sickle cell disease)
The RBCS appear either: The sickled RBC is less flexible and
Sickle-shape. more fragile and has a short life
Teardrop-shape. span → anemia.
It increases blood viscosity
promoting blood coagulation.
 Dr. Shehab Hafez
Size (diameter) of RBCs

▪ Normal diameter: 6-9 µm (average 7.5 µm).
▪ In macrocytic anemia: RBC size˃ 9 µm.
▪ In microcytic anemia: RBC size ˂ 6 µm.
▪ Thickness: 2.6 μm thick at the rim, but only
0.75 μm thick in the center (→ biconcave
shape).

Normal concentration of RBCs in blood

▪ In males: 4.1- 6.0 million/ µL (microliter) or mm³
▪ In females: 3.9- 5.5 million/ µL (microliter) or mm³
 Dr. Shehab Hafez
Structure of RBCs
The erythrocyte is highly adapted for its principal
function of oxygen and carbon dioxide transport
How?

1. Highly flexible cell membrane with a supporting cytoskeleton
▪ The cell membrane of RBC is formed of:
40% phospholipids in the form of a
bilayer, 10% carbohydrates, and 50%
protein.

▪ Cytoskeleton: A network of proteins
(spectrin, ankyrin and actin) supports the
cell membrane & provides a great degree
of flexibility of RBC
This flexibility → Easy change in shape
of RBCs→ easy passage through small
capillaries.
 Dr. Shehab Hafez
2. No nucleus…No cell organelles.
3. The RBC are filled with:
▪ Haemoglobin molecules.
▪ Enzymes of anaerobic glycolysis
(source of energy), as the RBC has
no mitochondria.

Life span of RBCs

▪ 120 days.
▪ Dead or worn-out RBCs are
removed from the circulation by
macrophages of the spleen, liver,
and bone marrow.
Splenic macrophages
phagocytosing dead RBCs
 Dr. Shehab Hafez

Hemopoiesis
 Dr. Shehab Hafez

Hemopoiesis
Definition: blood cells have a limited life span. They are continuously
replaced by differentiation and maturation of stem cells in
the hematopoietic organs.

Sites of hemopoiesis
Age Site
Fetus: 0-2 months Yolk sac
2-5 months Liver, spleen
5-9 months Bone marrow
Infants Bone marrow, particularly all bones.
Adults Bone marrow in: Vertebrae, ribs, sternum,
sacrum, pelvic bones, proximal ends of femur.
All blood cells are derived from Pluripotential
Hemopoietic stem cell (HSC)
 Dr. Shehab Hafez
Pluripotential Hemopoietic stem cell (HSC)

Active proliferation to Proliferate and differentiate to produce more
maintain their own mature and differentiated cells called:
population (self-renewing). Progenitors
▪ Definition of Progenitor cells: they are
committed to produce specific blood cells.
▪ Types of progenitor cells:

Myeloid stem cell Lymphoid stem cell
 Dr. Shehab Hafez
Pluripotential Hemopoietic stem
cell (HSC)

Myeloid stem cell Lymphoid stem cell

▪ Colony forming unit Granulocytes-monocytes ▪ Colony forming unit
(CFU-GM): Lymphocytes (CFU-L):
1. Neutrophils. 1. B- lymphocytes.
2. Eosinophils. Granulocytes 2. T-lymphocytes.
3. Basophils. 3. Natural killer cells.
4. Monocytes.
▪ Colony forming unit Erythrocytes (CFU-E).
▪ CFU Megakaryocytes (CFU-Meg)→ platelets.

HSC → Progenitor cell →CFU →Precursor (blast) cells for each type
of blood cells.
 Dr. Shehab Hafez
Hematopoietic stem cell
(HSC)

Progenitor cells
(myeloid or Lymphoid stem cells)

Colony forming unit cells
(CFU)

Precursor (blast) cells

Mature cells
 Dr. Shehab Hafez

Hemopoiesis
 Dr. Shehab Hafez

Erythropoiesis
Hematopoietic stem cell
(HSC) The first precursor (blast cell) of RBCs is
Proerythroblast
Progenitor cells
(myeloid stem cells)

Colony forming unit cells
(CFU erythrocytes)

Precursor (blast) cells Mature erythrocyte
(Proerythroblasts) Proerythroblast

Erythrocytes (RBCs)
 Dr. Shehab Hafez
Erythropoiesis

Size Nucleus Cytoplasm
Proerythroblast Active Basophilic

Basophilic Erythroblast Less active Basophilic
(early normoblast)

Polychromatophilic Condensed Basophilia and acidophilia
erythroblast (intermediate Gradual
normoblast) reduction in
Orthochromatophilic size More condensed Acidophilic and little
Erythroblast (late normoblast) and eccentric basophilia

Reticulocyte Extruded (No Acidophilic with a reticulum
nucleus) of ribosomal RNA

Mature erythrocyte No nucleus Acidophilic with a pale
center
 Dr. Shehab Hafez
Erythropoiesis

Proerythroblast Orthochromatophilic
Reticulocyte
erythroblast

Basophilic Polychromatophilic Mature erythrocyte
erythroblast erythroblast
 Dr. Shehab Hafez

▪ 1% of total RBCs in the peripheral blood.
Reticulocytes ▪ Have mitochondria and a reticulum of ribosomal
RNA in the center.

▪ When severe erythrocyte loss occurs, such as after
haemorrhage or haemolysis, the rate of erythrocyte
Reticulocytosis
production in the bone marrow increases and the
proportion of reticulocytes in circulating blood rises
 Dr. Shehab Hafez
Resources
▪ Junqueira LC, Carneiro J: Junqueira’s Basic Histology. Text and
Atlas, thirteenth edition (2013), LANGE Mc Graw Hill.

▪ Gartner LP and Hiatt JL: Color Textbook of Histology. Third edition
(2007). Saunders Elsevier.

Prof. Dr. Shehab Hafez