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New laboratory parameters in the diagnosis of iron-restricted erythropoiesis許自豪, Hui, Chi-ho, Geo. January 2008 (has links)
published_or_final_version / Medical Sciences / Master / Master of Medical Sciences
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The biochemistry of avian erythropoiesisWilliams, Alan Frederick January 1970 (has links)
xi, 150 leaves : ill. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.1971) from the Dept. of Biochemistry and General Physiology, University of Adelaide
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The biochemistry of avian erythropoiesis.Williams, Alan Frederick. January 1970 (has links) (PDF)
Thesis (Ph.D. 1971) from the Dept. of Biochemistry and General Physiology, University of Adelaide.
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New laboratory parameters in the diagnosis of iron-restricted erythropoiesisHui, Chi-ho, Geo. January 2008 (has links)
Thesis (M. Med. Sc.)--University of Hong Kong, 2008. / Includes bibliographical references (p. 53-60)
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An examination of in vitro erythropoiesis by utilizing agents that mimic the in vitro activity of erythropoietinMurthy, Sudish C. January 1987 (has links)
The major in vivo hormonal regulator of terminal erythropoiesis is erythropoietin (Ep). This 38,000 dalton acidic glycoprotein has been shown to stimulate the formation of hemoglobinizing erythroblasts. Two in vitro assays designed to measure Ep bioactivity were utilized to determine if other agents could mimic Ep activity in vitro. It was hoped that this approach might yield insights into the mechanism of action of Ep. Several agents have now been identified, and two, dimethyl sulfoxide (DMSO) and sodium orthovanadate had previously been shown (in other systems) to stimulate membrane phosphorylation changes. Accordingly, Ep, DMSO and sodium orthovanadate were assayed with Ƴ-³²P-ATP and plasma membranes purified from Ep-responsive cells to determine if each could induce significant phosphorylation changes as assessed by sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. It was found that while both sodium orthovanadate and DMSO effected profound phosphorylation alterations, Ep did not elicit any detectable phosphorylation changes. Specifically, vanadate caused a generalized increase in membrane base-stable phosphoproteins, and DMSO reproducibly stimulated the base resistant phosphorylation of a 35 Kd membrane-associated protein. It is reasonable to postulate that the latter phosphorylation event might be responsible for the stimulatory activity of DMSO on terminally differentiating erythroid cells.
To understand whether Ep and Ep-mimicking agents were operative on the same target cell population, homogeneous, virally-infected, erythroblasts were cultured in vitro and assayed for ³H-thymidine incorporation in the presence of each agent at various intervals during erythroid cell differentiation. It was found that Ep greatly stimulated very early, as well as differentiated, erythroblasts to proliferate, while four different Ep-mimicking agents could only effect thymidine incorporation into a more mature erythroid population. From this work it is conceivable that Ep-mimicking agents stimulate in vitro erythropoiesis through specific membrane phosphorylation changes and function primarily on late erythroblasts, while the mechanism of action of Ep on primitive and late erythroblasts remains unresolved. / Medicine, Faculty of / Pathology and Laboratory Medicine, Department of / Graduate
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The role of reactive oxygen species during erythropoiesis: an in vitro model using TF-1 cells.January 2009 (has links)
Ge, Tianfang. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2009. / Includes bibliographical references (leaves 87-93). / Abstract also in Chinese. / EXAMINATION COMMITTEE LIST --- p.ii / DECLARATION --- p.iii / ACKNOWLEDGEMENTS --- p.iv / ABSTRACT --- p.v / ABSTRACT IN CHINESE --- p.vii / ABBREVIATIONS --- p.ix / TABLE OF CONTENTS --- p.xiii / Chapter 1 --- INTRODUCTION --- p.1 / Chapter 1.1 --- Erythropoiesis --- p.2 / Chapter 1.2 --- The TF-1 model --- p.3 / Chapter 1.3 --- The erythroid marker glycophorin A (GPA) --- p.4 / Chapter 1.4 --- Reactive oxygen species (ROS) --- p.4 / Chapter 1.5 --- Oxidative stress in human erythrocytes --- p.6 / Chapter 1.6 --- Antioxidant defense systems --- p.6 / Chapter 1.7 --- Glucose provides the majority of reducing equivalents in human erythrocytes --- p.9 / Chapter 1.8 --- Glucose transporter type 1 (Glut l) transports glucose and vitamin C into human erythrocytes --- p.10 / Chapter 1.9 --- Hypothesis and objectives --- p.11 / Chapter 1.10 --- Long-term significance --- p.12 / Figure 1.1 Stages of mammalian erythropoiesis. Adapted from (Koury et al.,2002) --- p.13 / "Figure 1.2 Conversion of major ROS. Adapted from (Ghaffari," --- p.14 / Figure 1.3 Major oxidative defense in human erythrocytes --- p.15 / "Figure 1.4 Peroxide scavenging systems. Adapted from (Day," --- p.16 / Chapter 2 --- MATERIALS AND METHODS --- p.17 / Chapter 2.1 --- Cell culture --- p.18 / Chapter 2.1.1 --- Culture media --- p.18 / Chapter 2.1.2 --- Cell maintenance --- p.19 / Chapter 2.1.3 --- Cell cryopreservation --- p.19 / Chapter 2.1.4 --- Cell differentiation --- p.20 / Chapter 2.1.5 --- Cell treatments --- p.20 / Chapter 2.1.5.1 --- Antioxidant treatments --- p.21 / Chapter 2.1.5.2 --- H2O2 challenging --- p.22 / Chapter 2.1.5.3 --- Antibiotic treatment --- p.22 / Chapter 2.2 --- Flow cytometry --- p.23 / Chapter 2.2.1 --- Flow cytometers --- p.23 / Chapter 2.2.2 --- Analysis of erythroid differentiation --- p.23 / Chapter 2.2.3 --- Analysis of cell lineage --- p.24 / Chapter 2.2.4 --- Analysis of intracellular ROS --- p.24 / Chapter 2.2.5 --- Analysis of mitochondrial transmembrane potential (Δψm) --- p.25 / Chapter 2.2.6 --- Analysis of mitochondrial mass --- p.25 / Chapter 2.2.7 --- Analysis of cell death --- p.26 / Chapter 2.2.8 --- Analysis of caspase-3 activity --- p.27 / Chapter 2.2.9 --- FACS cell sorting --- p.27 / Chapter 2.2.10 --- Two-variant flow cytometric experiments --- p.28 / Chapter 2.2.11 --- Analysis of flow cytometry data --- p.28 / Chapter 2.2.12 --- Compensation --- p.29 / Chapter 2.2.12.1 --- Compensation matrix for Annexin V-PI double-staining --- p.29 / Chapter 2.2.12.2 --- Compensation matrix for Annexin V-TMRM double-staining --- p.30 / Chapter 2.2.12.3 --- Compensation matrix for CFSE- GPA double-staining --- p.31 / Chapter 2.2.12.4 --- Compensation matrix for CFSE- TMRM double-staining --- p.31 / Chapter 2.2.12.5 --- Compensation matrix for CM- H2DCFDA-GPA double-staining --- p.32 / Chapter 2.2.12.6 --- Compensation matrix for GPA- TMRM double-staining --- p.33 / Chapter 2.3 --- Western blot --- p.35 / Chapter 2.4 --- Statistical analysis --- p.37 / Chapter 3 --- RESULTS AND DISCUSSION --- p.38 / Chapter 3.1 --- The cells with high GPA staining were younger in cell lineage --- p.39 / Chapter 3.2 --- ROS was produced during TF-1 erythropoiesis --- p.40 / Chapter 3.3 --- ROS production was not essential for TF-1 erythropoiesis --- p.41 / Chapter 3.4 --- ROS production was not the cause of cell proliferation during TF-1 erythropoiesis --- p.41 / Chapter 3.5 --- ROS production was not the cause of sub-lethal mitochondrial depolarization in TF-1 erythropoiesis --- p.42 / Chapter 3.6 --- The cells showing mitochondrial depolarization were mother cells that gave rise to differentiating cells --- p.44 / Chapter 3.7 --- ROS production was not the cause of cell death in TF-1 erythropoiesis --- p.45 / Chapter 3.8 --- ROS production confers oxidative defense during TF-1 erythropoiesis --- p.47 / Chapter 3.8.1 --- Glut l inhibition partially blocked TF-1 erythropoiesis without affecting cell viability --- p.47 / Chapter 3.8.2 --- Antioxidant defense systems were established during TF-1 erythropoiesis --- p.48 / Chapter 3.8.3 --- Antioxidant treatments blocked the establishment of antioxidant defense systems during TF-1 erythropoiesis --- p.51 / Chapter 3.9 --- Conclusion --- p.55 / Chapter 3.10 --- Future work --- p.56 / Figure 3.1 Cell lineage versus erythroid marker during erythropoiesis under vitamin E treatment --- p.59 / Figure 3.2 ROS production during erythropoiesis --- p.60 / Figure 3.3 ROS production versus erythroid marker during erythropoiesis under vitamin E treatment --- p.61 / Figure 3.4 Percentage of ROS+ cells in vitamin E-treated TF-1 erythropoiesis as compared to control --- p.63 / Figure 3.5 Percentage of GPA+ cells in vitamin E-treated TF-1 erythropoiesis as compared to control --- p.64 / Figure 3.6 Cell death versus mitochondrial transmembrane potential (Δψm) during erythropoiesis under vitamin E treatment --- p.65 / Figure 3.7 Erythroid marker versus mitochondrial transmembrane potential (Δψm) during erythropoiesis under vitamin E treatment --- p.67 / Figure 3.8 Cell lineage versus mitochondrial transmembrane potential (Δψm) during erythropoiesis under vitamin E treatment --- p.69 / Figure 3.9 Change of mitochondrial mass during erythropoiesis --- p.71 / Figure 3.10 ROS production versus erythroid marker during erythropoiesis under levofloxacin treatment --- p.72 / Figure 3.11 Percentage of GPA+ cells in levofloxacin-treated TF-1 erythropoiesis as compared to control --- p.73 / Figure 3.12 Cell death versus mitochondrial transmembrane potential (Δψm) during erythropoiesis under levofloxac in treatment --- p.74 / Figure 3.13 Expression level of antioxidant enzymes during erythropoiesis --- p.75 / Figure 3.14 Expression level of Glut l during erythropoiesis --- p.76 / Figure 3.15 Expression level of Glut l in GPA positive and GPA negative populations --- p.77 / Figure 3.16 Cell death under oxidative stress challenging during erythropoiesis --- p.78 / Figure 3.17 Expression level of antioxidant enzymes and Glutl during erythropoiesis under EUK-134 treatment --- p.79 / Figure 3.18 Expression level of antioxidant enzymes and Glutl during erythropoiesis under vitamin E treatment --- p.80 / Figure 3.19 Cell death under oxidative stress challenging during erythropoiesis under vitamin E treatment --- p.82 / Figure 3.20 Expression level of antioxidant enzymes during erythropoiesis under vitamin C treatment --- p.83 / Figure 3.21 Cell death under oxidative stress challenging during erythropoiesis under vitamin C treatment --- p.84 / Figure 3.22 Cell death under oxidative stress challenging during erythropoiesis under NAC treatment --- p.85 / Figure 3.23 Summary of oxidative stress challenging during erythropoiesis --- p.86 / REFERENCES --- p.87
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The regulation of globin gene expression during developmentStanworth, Simon J. January 1994 (has links)
No description available.
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Regulation of erythroid-specific 5-aminolevulinate synthase (ALAS2) by hypoxia /Abu-Farha, Mohamed, January 1900 (has links)
Thesis (M.Sc.) - Carleton University, 2005. / Includes bibliographical references (p. 92-100). Also available in electronic format on the Internet.
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The effects of intermittent hypoxic exposure on hematological markers and exercise performanceAustin, Krista G. Haymes, Emily M., January 2005 (has links)
Thesis (Ph. D.)--Florida State University, 2005. / Advisor: Emily M. Haymes, Florida State University, College of Human Sciences, Dept. of Nutrition, Food and Exercise Science. Title and description from dissertation home page (viewed Mar. 16, 2006). Document formatted into pages; contains xiii, 237 pages. Includes bibliographical references.
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The biogenesis of erythropoietin during inflammationLeng, Henry Martin John January 1995 (has links)
Anaemia frequently accompanies chronic inflammatory diseases like rheumatoid arthritis and cancer. It is postulated to result primarily from the suppression of erythropoiesis by inflammatory cytokines. A contributing factor could be the inhibition of erythropoietin synthesis which may also be mediated by cytokines. Erythropoietin is the hormone which regulates erythropoiesis. The aims of this project were to investigate whether cytokines can indeed suppress erythropoietin production, and to determine whether the erythropoietin response in experimental models of acute and chronic inflammation was appropriate for the associated anaemia. Macrophage-conditioned medium, interleukin-1β, interleukin-6, tumour necrosis factor-α, and neopterin were assayed for inhibition of erythropoietin synthesis by HepG2 cells in culture. All, except neopterin, effected dose-dependent reductions in the secretion of the hormone. Interleukin-1β and tumour necrosis factor-α down-regulated erythropoietin gene transcription, whereas interleukin-6 inhibited a post-transcriptional process. Rats with acute inflammation developed a mild anaemia which evoked an increase in their serum levels of erythropoietin. The serum erythropoietin levels were optimal, since rats with acute inflammation and severe phenylhydrazine-induced anaemia did not have lower levels of the hormone than controls with a similar degree of anaemia, but without acute inflammation. Erythropoietin is, therefore, not an acute phase reactant. Mice with cancer developed a progressive anaemia which was not due to bone marrow invasion by tumour cells. During the first fourteen days after inoculating them with cancer cells, the mice responded by increasing their serum levels of erythropoietin as the anaemia worsened. The erythropoietin response was appropriate when compared to mice with the same degree of phenylhydrazine-induced anaemia. Erythropoietin levels measured in mice with tumours older than fourteen days were significantly lower than those of control mice with the same degree of experimental anaemia. These animals were very cachectic, suggesting that a blunted erythropoietin response may depend on disease activity.
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