Formation
and Significance of Keratocytes in Peripheral Blood Smears
Eve M. Boggs, DVM;
Kenneth S. Latimer, DVM, PhD; Heather L. Tarpley, DVM; Bruce E. LeRoy,
DVM, PhD
Class of 2003 (Boggs)
and Department of Pathology (Latimer, Tarpley, LeRoy), College of Veterinary
Medicine, The University of Georgia, Athens, GA 30602-7388
Introduction
Healthy, mature erythrocytes
of humans and most domestic animals normally circulate as biconcave
disks. This special shape allows for gas exchange as well as deformation
and return to a preexisting shape without permanent damage as these
cells pass through microvasculature.9
Microscopic examination
of Romanowsky-stained blood smears is performed routinely as a portion
of the complete blood cell count. In sick patients, erythrocyte abnormalities
may indicate the presence of disease. Abnormally shaped red blood cells
generally can be classified as poikilocytes (misshapen erythrocytes),
some of which are spiculated or have surface projections. These latter
cells may be classified more specifically as keratocytes, echinocytes, schistocytes,
or acanthocytes.1 Keratocytes
are abnormally shaped erythrocytes that appear to have horns (kerat
in Latin means horn; Fig. 1).2 Another synonym for keratocyte
is "helmet cell" because the cell may resemble a helmet with
chinstraps.
 |
| Figure
1. Keratocytes (arrows) are present in a Wright stained
blood smear of a dog. |
Mechanism
of Formation and Diseases Associated with Keratocytes
Keratocyte formation
may be associated with trauma, especially cellular damage from contact
with fibrin strands within the microvasculature. Other processes that
can contribute to microvascular injury include endotoxemia and antigen-antibody
reactions. These forms of microangiopathy subsequently may lead to
platelet aggregation, fibrin formation, and, ultimately, intravascular
coagulation.10 As normal erythrocytes encounter a mesh of
fibrin strands, they can become entrapped. Sometimes these cells are
impaled on fibrin strands. Blood flow then pushes the cell against
the strand of fibrin and the cell may bisect. Alternatively, the opposing
sides of the cell may adhere to one another around the fibrin strand.
When blood flow frees the cell, the opposing sides rejoin forming a
pseudovacuole. Cells with pseudovacuoles are called "blister" cells
or pre-keratocytes (Fig. 2). When the vacuole ruptures (usually within
minutes), the remaining cell resembles a helmet with straps or a horned
cell that is designated a keratocyte (Figs. 2, 3, and 4).2 Prekeratocytes
also can form via fusion of injured cell membranes (e.g.,
administration of doxorubicin6 and some iron deficiency
anemias7,5). These new cells are more fragile than the original
parent cell and may rupture, forming a keratocyte.2
 |
| Figure
2. Prekeratocytes or blister cells in a Wright stained
blood smear of a dog. |
 |
 |
 |
| Figure
3. Phase contrast photomicrographs demonstrating successive
stages of formation of keratocytes in the blood (from Bessis
M: Blood Smears Reinterpreted, Springer-Verlag, 1977, p. 85). |
 |
 |
 |
| Figure
4. Scanning electron micrographs of keratocytes showing
the formation of irregular spicules that resemble horns (modified
from Bessis M: Blood Smears Reinterpreted, Springer-Verlag, 1977,
p. 85). |
As previously mentioned,
many seemingly unrelated disease processes that can result in keratocyte
formation. Various diseases and mechanisms of keratocyte formation
are listed in Table 1.
Table
1. Diseases associated with and mechanisms of formation
of keratocytes.
Disease
Proposed Mechanism of Keratocyte Formation
| DIC2,9,10 |
Microvascular
injury and resultant fibrin deposition |
| Neoplasia
Hemangiosarcoma often with DIC7,9Lymphosarcoma9
Other neoplasms, especially with concominant DIC10 |
Probable
changes in microvasculature with subsequent deposition of fibrin |
Glomerulonephritis2,9 |
Excessive
coagulation and fibrin deposition |
Hemolytic
anemia2,7 |
RBC destruction
(often with antigen antibody complexes) leading to deposition of
fibrin |
Iron deficiency
anemia7,5 |
Oxidative
damage of membrane proteins with fusion of membranes and increased
fragility of cells |
Hepatic Disease9,3 |
Microvascular injury and subsequent deposition of fibrin |
Doxorubicin
administration6 |
Mechanism
not fully understood; may involve oxidative damage of cell membranes |
This list
is not all inclusive; the disease processes listed are excerpted
from the published literature. Understanding the mechanism of cellular
injury in the formation of keratocytes is important in interpreting
the significance of these cells in the stained blood smear.
Other
Facts Concerning Keratocytes
Formation of keratocytes
is not commonly associated with a decreased hematocrit or packed cell
volume. However, if keratocytes are formed PCV, these abnormal cells
will be removed from the circulation by the spleen. The feline spleen
is less efficient in removing abnormal cells from circulation, so it
is not uncommon to see more keratocytes in peripheral blood smears
of cats.6
Keratocytes usually
have a normal concentration of hemoglobin; therefore, they may retain
an area of central pallor.2 Keratocytes, blister cells,
and schistocytes may be observed commonly in the same blood smear because
they may be formed by a common mechanism (e.g., fragmentation
in circulation).
It has been reported
that blood collected with EDTA had a greater potential for keratocyte
formation.4 Furthermore, morphological artifacts of erythrocytes
may be associated with cellular damage when the blood specimen is obtained
or the blood smear is prepared. When possible apply the blood immediately
to a clean, debris free slide and use proper technique when preparing
the smear.
References
1. Andreasen CB,
Brockus CW: Erythrocytes. In: Latimer KS, Mahaffey EA, Prasse
KW (eds): Duncan and Prasse's Veterinary Laboratory Medicine: Clinical
Pathology, 4th ed. Iowa State Press, Ames, IA, 2003.
2. Bessis M: Blood
Smears Reinterpreted (translated by G. Brecker). Springer International,
New York, NY, 1977.
3. Christopher MM,
Lee SE: Red cell morphologic alterations in cats with hepatic disease.
Vet Clin Pathol 23:7-12 1994.
4. Harvey JW: Erythrocytes. In:
Atlas of Veterinary Hematology: Blood and Bone Marrow of Domestic Animals.
W.B. Saunders Company, Philadelphia, PA, 2001, pp. 21-44.
5. Harvey JW: Microcytic
Anemias. In: Feldman BF, Zinkl JG, Jain NC (eds): Schalm’s
Veterinary Hematology, 5th ed. Lippincott Williams & Wilkins,
Philadelphia, PA, 2000, pp 200-204.
6. O’Keefe DA,
Schaeffer DJ: Hematologic toxicosis associated with doxorubicin adminis-tration
in cats. J Vet Intern Med 6:276-283, 1992.
7. Weiser G: Erythrocyte
responses and disorders. In: Ettinger SW, Feldman EC (eds):
Textbook of Veterinary Internal Medicine Diseases of the Dog and Cat,
vol. 2, 4th ed. WB Saunders, Philadelphia, PA, 1989, pp
1864-1891.
8. Weiss DJ, Kristensen
A, Papenfuss N: Quantitatitve evaluation of irregularly spiculated
red blood cells in the dog. Vet Clin Pathol 22:117-121,1993.
9. Weiss DJ, Kristensen
A, Papenfuss N, McClay CB: Quantitative evaluation of echinocytes in
the dog. Vet Clin Pathol 19:114-118,1990.
10. Rebar AH, Lewis
HB, DeNicolo DB, et al: Red cell fragmentation in the dog:
An editorial review. Vet Pathol 18:415-426, 1981.
Acknowledgement
Photograph of the
Holy Cult Horns, Palace of King Minos, Knossos, Crete from the page Impressions
of Crete on the web site Sights and Cultural Features Around the
World is used with permission. |