Myelocyte Information and Courses from MediaLab, Inc.
These are the MediaLab courses that cover Myelocyte and links to relevant pages within the course.
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| Identify the cell in this illustration indicated by the arrow: | View Page |
| Identify the cell in this illustration indicated by the arrow: | View Page |
| Identify the cell in this illustration indicated by the arrow: | View Page |
| Identify the cell in this illustration indicated by the arrow: | View Page |
| Which is arranged from least mature to most mature: | View Page |
| The M:E ratio represent the ratio of nucleated bone marrow cells with respect to: | View Page |
| The nucleated red blood cell and myelocyte photographed here were found on scanning of a peripheral blood smear. In context they are suggestive of metastatic carcinoma to the bone marrow. | View Page |
| Leukoerythroblastosis Illustrated in this field is a normoblast and a myelocyte, representing leukoerythroblastosis, a term associated with the release of immature cells from a disrupted marrow. Metastatic disease in the bone marrow, particularly in patients with primary breast or prostate cancer, is usually the culprit. Leukoerythroblastosis in the absence of anemia or thrombocytopenia is a signal to search for cancer metastic to the marrow. Nucleated RBCs were not identified on the blood smear seen here but were detected by an automated analyzer.The mortality rate of elderly patients with increased NRBCs, especially following accidents or general surgery, is greater. | View Page |
| Chediak-Higashi Chediak-Higashi syndrome is a rare autosomal recessive disorder. It results from a mutation of the gene LYST which encodes a protein with multiple phosphorylation sites. This defect causes a cellular abnormality involving the fusion of cytoplasmic granules. Early in neutrophil maturation normal azurophilic granules form, but they fuse together to form megagranules. Later during the myelocyte stage, normal specific granules form. The mature neutrophils contain both normal specific granules and abnormal azurophilic granules.
These large abnormal granules can be seen in the cytoplasm of neutrophils, eosinophils, basophils, monocytes and lymphocytes.
These abnormal granules are able to kill bacteria in neutrophils and monocytes; however, the process is much less effective than in normal cells in part, because these neutrophils have impaired locomotion. For these reasons, individuals with Chediak-Higashi have recurrent infections.
An accelerated lymphoma-like phase occurs, with lymphadenopathy, hepatosplenomegaly, and pancytopenia. Death often occurs at an early age.
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| The cells included in the composite image were found in a peripheral blood smear with a total WBC of 24,500/mm3. The differential count was:
myelocytes 1
metamyelocytes 4
band neutrophils 15
segmented neutrophils 40
monocytes 8
eosinophils 2
basophils 1
lymphocytes 29.
This hematologic picture is most consistent with: | View Page |
| A peripheral blood smear illustrated by this photograph is highly suggestive of metastatic carcinoma. | View Page |
| Normal Bone Marrow Cells A normal bone marrow smear stained with Wright/Giemsa stain is captured in this photograph.Note the normal maturation sequence beginning with myelocytes (the two large cells in the left upper corner)through metamyelocytes, band neutrophils,and multi-lobed segmented neutrophils.The small cells with darkly staining, centrally placed nuclei are normoblasts (three are clustered in the left lower field).Absent in this field are eosinophils, basophils and megakaryocytes.A normal M:E ratio of 2.4:1 is calculated from the twelve myeloid cells and five normoblasts. Two lymphocytes are identified, one left center, the other left upper. | View Page |
| Additional comments on this exercise The following pages in this presentation includes a series of white blood cell abnormalities that may be identified in a peripheral blood smear. Many of the cases will simulate the practice of a peripheral smear review by a hematology morphologist. He/she must asses what responses in patient care may be triggered by the clinician attempting to interpret the reported findings on a peripheral smearObservations of white blood cell abnormalities in the peripheral blood smear should be reported so as to direct the physician to an immediate specific diagnosis, such as: (1) atypical lymphocytes suggesting infectious mononucleosis rather than leukemia, (2) toxic granules in neutrophils as in acute infections, or atypical granules suggesting a genetic disorder, (3) an unusual mix of cells, such as too many or too few neutrophils, monocytes, or other myeloid cells, and (4) the presence of giant platelets, myelocytes, or other cells suggesting a myelodysplastic syndrome.In summary, laboratory data should be presented to clinicians in a user friendly way to promote effective decision making. The design of the data base of information must be directed toward providing clinically helpful information clearly and quickly in order to facilitate appropriate action in terms of optimizing patient care outcomes.d | View Page |
| Typical cells on a peripheral blood smear as photographed here were repeatedly encountered as the smear was reviewed. The peripheral white blood cell count was 51,000/ml with an orderly maturation sequence. The comment "leukemoid reaction" may properly be appended to the report. | View Page |
| Leukemoid reaction revisited The term leukemoid reaction is used to describe peripheral white blood cells that on the stained blood smear may have some resemblances to leukemia cells. Quantatively in a leukemoid reaction, the neutrophil count is >50,000 cumm with more immature cells, particularly myelocytes, than are usually present in toxic left shift syndromes. The presence of immature cells in a leukemoid reaction awakens thoughts of leukemia. Great care must be taken to make a distinct differentiation between aberrant white blood cell proliferations and a benign but exaggerated granulocytic proliferative response. Our material is from a 1-month-old girl with Down's syndrome. Her total white blood count was 37,000/mm3 interpreted as leukocytosis with left shift. Leukocytosis with a left shift, and leukemoid reactions with high alkaline phosphatase are conditions to be mindful of in patients with Down's syndrome. The alkaline phosphatase score is high in leukemoid reactions, low in granulocytic leukemia. | View Page |