Ex. 6 Myeloid Tissue.pdf

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Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

Exercise 6. MYELOID TISSUE (Bone Marrow)

Myeloid tissue is a gelatinous, vascular, cell-rich connective tissue. It occupies the cavities of
long bones and intertrabecular spaces of spongy bones as bone marrow. It provides the
microenvironment for the formation of blood cells and platelets (hematopoiesis). In infants and
younger individuals, the bone marrow is actively producing blood cell precursors, blood cells in
various stages of development but predominantly red blood cells, thus called red bone marrow. As
the individual reaches about 20 years of age, much of the bone marrow in long bones accumulates
so much fat and it becomes haematopoietically inactive, and called yellow bone marrow.

The red bone marrow is composed of two compartments. The vascular compartment comprising
of reticular tissue, blood vessels and sinusoids for nutrient supply and transport of newly formed
blood cells. The other compartment is the hematopoietic islands (hematopoietic cords), each
composed of progenitor cells, precursor cells and developing or maturing blood cells of specific
lineage. Both compartments also contain macrophages, reticular cells, and fine mesh of reticular
fibers.

Activity 1. Red Bone Marrow

The red bone marrow is haematopoietically active that fills the cavity of a long bone or the cavities
of spongy bone.
A. Examine the cross-section of the bone marrow (Plate 1) at high power objective.
B. Distinguish the following:

hematopoietic (hemopoietic) islands – clusters of hematopoietic cells
stroma – the framework that is composed of all tissues that are indirectly involve in
hematopoiesis. It consists of reticular connective tissues, and blood vessels
(sinusoids). Stromal cells include macrophages, adipocytes, reticulocytes,
osteoblasts, osteoclasts, and endothelial cells.
bone trabeculae – eosinophilic struts projecting into hemopoietic islands
C. Photograph a section of the red bone marrow and paste in appropriate section of Worksheet 5.
D. Label the photomicrograph.

Plate 1. Red bone marrow

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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

Activity 2. Cells of Hematopoietic Islands

Identification of the cells in hematopoietic islands is quite complicated due to the large number
and kinds of cells at different stages of development. These cells are randomly mixed during
the preparation of the tissue. To identify each cell, one must consider both the cytoplasmic and
nuclear features, and its color.

A. Examine closely the cells in a bone marrow smear using the oil immersion objective.
B. Look for each cell described below. (Warning: Cells may not be all intact and cannot be all found in a
single bone marrow smear. You may use another slide of bone marrow smear)
C. Choose one intact cell of each developing stage.
D. Photograph one cell and paste it on the labeled boxes in Worksheet 6. (No need to label the parts
of each cell.

The cells of the hematopoietic compartment are the following:

I. Hemocytoblast or Stem Cell (Plate 2)
Nucleus is round to oval with fine chromatin arranged in a sieve-like reticulum. Nucleoli are
prominent. Cytoplasm is with basophilic to azurophilic (aniline blue) granules. It differentiates
into progenitor cell which in turn become precursor cell of both red and white blood cell series.

Plate 2. Hemocytoblast

II. ERYTHROCYTE SERIES
The developing stages of red blood cells are numbered here according to the order of the stages
of development:

1. Proerythroblast (Plate 3)
Nucleus is large, ovoid and centrally located with a regular checker board-like distribution of
chromatin material. Two nucleoli are generally present. Cytoplasm is intensely basophilic
(dark blue) due to ribosomes, and with white rim around the nucleus.

Plate 3 Proerythroblast
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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

2. Basophilic erythroblast (Plate 4)
Smaller than proerythroblast. Nucleus is rounded and centrally located, but chromatin material
is coarser and clumped. Cytoplasm is deeper blue (basophilic) due to more free ribosomes and
initiation of hemoglobin synthesis.

Plate 4. Basophilic erythroblast

3. Polychromatophilic erythroblast(Plate 5)
Nucleus is smaller than in basophilic erythroblast. Chromatin is even more condensed and has
a “cart-wheel” appearance. Nucleoli are absent. Cytoplasm has varying shades of grayish-blue,
lilac, reddish or pink.

Plate 5. Polychromatophilic erythroblast

4. Orthochromatic erythroblast or Normoblasts (Plate 6)
Small, nucleus is compact an intensely heterochromatic (dark blue) due to highly condensed.
chromatin. The cytoplasm is lilac but may contain traces of basophilia to ribosomes and
slightly acidophilic due to increased hemoglobin. The last stage that divides.

Plate 6. Orthochromatic erythroblast or Normoblasts

5. Polychromatophilic erythrocyte or Reticulocyte (Plate 7)
The once normoblast without nucleus , or with a nucleus ready to be expelled. Cytoplasm is
reticulated and reddish pink due hemoglobin and with slightly diffused basophilia due to
residual ribosomes. It is an immature red blood cell ready to exit from the bone marrow.

Plate. 7. Polychromatophilic erythrocyte or Reticulocyte

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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

C. GRANULOCYTES SERIES
Cells are characterized by lobed nucleus and specific cytoplasmic granules. The following
developing stages of granulocytes are numbered according to sequence.

1. Myeloblast or Leucoblast (Plate 8)
Stem cell that differentiates into the granulocyte series. Large cell with ovoid nucleus
containing delicate chromatin in threadlike arrangement. Two to five nucleoli are present.
Cytoplasm slightly basophilic due to scattering of ribosomes, and with a few azurophilic
granules.

Plate 8. Myeloblast or Leucoblast

2. Promyelocyte (Plate 9)
Nucleus is somewhat elongated and contains nucleoli and clumped chromatin. Cytoplasm is
greater than that myeloblast and with more azurophilic (primary) granules.

Plate 9. Promyelocyte

3. Myelocyte (Plate 10)
Nucleus is ovoid and usually eccentric and with coarse chromatin and no nucleoli. Cytoplasm
may have azurophilic granules but there are more specific (secondary) granules. The cell can
be distinguished by the color of the cytoplasm as neutrophilic myelocyte (pale blue)
eosinophilic (pinkish) myelocyte and basophilic myelocyte (lilac).

Plate 10. Myelocyte
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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

4. Metamyelocyte
Nucleus has deep indentation or bean-shaped. Cytoplasm is pink or lilac with numerous
specific granules. The cell is further classified as:

Basophilic metamyelocyte (Plate 11)
Nucleus indented, cytoplasm pale blue with dark purple granules. Rare or scarce in
most bone marrow smear.

Plate 11. Basophilic metamyelocyte

Eosinophilic metamyelocyte. (Plate 12)
Nucleus deeply indented (about half of the nucleus). Cytoplasm has orange specific
granules

Plate 12. Eosinophilic metamyelocyte

Neutrophilic metamyelocyte (Plate 13)
Nucleus is slightly indented (less than half of the nucleus). Cytoplasm contains
abundant specific and azurophilic granules.

Plate 13. Neutrophilic metamyelocyte

5. Band form or Stab form
Nucleus indentation is more than one third of the nucleus, or appears C, U or S shaped. Can
be distinguished as:

Basophil band form (Plate 14)
Cytoplasm is pale blue with dark purple and black granules

Plate 14. Basophilic band form
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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

Eosinophil band form (Plate 15)
Cytoplasm is colorless or cream-colored with pale to dark pink specific granules

Plate 15. Eosinophilic band form

Neutrophil band form (Plate 16)
Cytoplasm is pinkish with bluish or purple azurophilic granules

Plate 16. Neutrophil band form

6. Segmented form or Mature granulocyte
Nucleus is centrally or eccentrically located and separated into lobes or segments.
Chromatin is dark purple, coarse, and clumpy.

Basophil (Plate17)
Nucleus is usually of two lobes and obscured by numerous granules. Cytoplasm with
basophilic or dark purple granules

Plate 17. Basophil
Eosinophil (Plate 18)
Nucleus is of 2 -3 lobes and cytoplasm. Cytoplasm is cream-colored to colorless with pale
to dark pink specific granules

Plate 18. Eosinophil
Neutrophil (Plate 19)
Nucleus is of 2 -5 lobes with reddish purple azurophilic granules

Plate 19. Neutrophil

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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
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 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

C. PLATELET SERIES

1. Megakaryoblast (Plate 20)
Nucleus is large, oval, or kidney-shaped or lobed with several nucleoli. Has very high
nucleus to cytoplasm ratio. Cytoplasm is deeply basophilic and agranular.

Plate 20. Megakaryoblast
2. Promegakaryocyte (Plate 21)
Nucleus have overlapping nuclear lobes with coarse chromatin but evenly distributed and
has lower nucleus to cytoplasm ratio. Cytoplasm is less basophilic or pinkish and contain
azurophilic granules. It is larger than megakaryoblast.

Plate 21. Promegakaryocyte
3. Megakaryocyte (Plate 22)
Nucleus has multiple lobes tightly packed together but extend through much of the cell,
and has coarsely granular clumped chromatin. Cytoplasm is pale- staining and contains
numerous azurophilic granules. The fragmentation of its cytoplasm produce platelets.

Plate 22. Megakaryocyte

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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
University.
 Biology Department
College of Arts & Sciences
BIOL 113 L – Animal Histology
Prepared by L. Saab and P. Fudalan

Activity 3. Answer the following questions:

1. Give the committed (mature) cell or product on each series of blood cell formation by filling-
in Table 1.
Table 1. The committed cell of blood cell series

Series of Cell Maturation Cells or Product
A. Erythrocyte Series

B. Granulocyte Series

C. Platelet Series

2. What caused the cytoplasmic staining affinities of the basophilic
erythroblast, polychromatophilic erythroblast, normoblast and erythrocyte? Fill in Table 2.

Table 2. Functional significance of the cytoplasmic staining affinities.

Cell Cause of Staining Affinity
A. Basophilic erythroblast

B. Polychromatophilic erythroblast

C. Orthochromatic
erythroblast/Normoblast
D. Erythrocyte

Reflection/Realization:

3.Why are patients with blood cancer may be treated with bone marrow transplant?

End

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reproduced in any form or by any electronic or mechanical means (including photocopying, recording, CD reproduction
or any information storage and retrieval system) without written permission from the Biology Department of Xavier
University.