Normal Stem Cells (normal + stem_cell)

Distribution by Scientific Domains


Selected Abstracts


Successful correction of murine sickle cell disease with reduced stem cell requirements reinforced by fractionated marrow infusions

BRITISH JOURNAL OF HAEMATOLOGY, Issue 4 2010
Hady Felfly
Summary Minimal criteria requirements of stem cell replacement, conditioning regimen and modalities of infusion essential for cure of sickle cell disease (SCD) by bone marrow(BM)/stem cell transplantation or gene therapy must be established prior to clinical trials. The threshold of normal BM/stem cells for therapeutic correction of this red blood cell disorder was evaluated in the SAD murine SCD model from peripheral donor white blood cells. From 11 groups of stable chimeric SAD mice (5,92%) analyzed over ,2 years, mice with ,16% normal donor stem cells showed improvement of haematological and erythroid responses. Mice in the 26% chimeric group and above demonstrated substantial amelioration of organ pathologies with generalized decreased iron deposits, fibrosis and reached normal lifespan. Subsequently, the minimal myelosuppression concurrently with number and timing of infusions and number of BM cells was determined to reach therapeutic threshold in SAD mice. Higher myelosuppression (2 Gy vs. 1 Gy) and cell number in single infusion led to increased chimerism. Importantly, administration of three-equivalent cell subdoses within 28 h of mild myelosuppression resulted in 100% recipient engraftment at therapeutic levels. These studies established the long-term therapeutic chimeric threshold of normal white blood cells at ,26% and determined the minimal fractionated BM/stem cell doses concomitant with mild myelosuppression for significant correction of SCD in SAD mice. [source]


Liver stem cells and hepatocellular carcinoma,

HEPATOLOGY, Issue 1 2009
Lopa Mishra
Although the existence of cancer stem cells (CSCs) was first proposed over 40 years ago, only in the past decade have these cells been identified in hematological malignancies, and more recently in solid tumors that include liver, breast, prostate, brain, and colon. Constant proliferation of stem cells is a vital component in liver tissues. In these renewing tissues, mutations will most likely result in expansion of the altered stem cells, perpetuating and increasing the chances of additional mutations and tumor progression. However, many details about hepatocellular cancer stem cells that are important for early detection remain poorly understood, including the precise cell(s) of origin, molecular genetics, and the mechanisms responsible for the highly aggressive clinical picture of hepatocellular carcinoma (HCC). Exploration of the difference between CSCs from normal stem cells is crucial not only for the understanding of tumor biology but also for the development of specific therapies that effectively target these cells in patients. These ideas have drawn attention to control of stem cell proliferation by the transforming growth factor beta (TGF-,), Notch, Wnt, and Hedgehog pathways. Recent evidence also suggests a key role for the TGF-, signaling pathway in both hepatocellular cancer suppression and endoderm formation, suggesting a dual role for this pathway in tumor suppression as well as progression of differentiation from a stem or progenitor stage. This review provides a rationale for detecting and analyzing tumor stem cells as one of the most effective ways to treat cancers such as HCC. (HEPATOLOGY 2009;49:318,329.) [source]


Characterisation of normal and cancer stem cells: One experimental paradigm for two kinds of stem cells

BIOESSAYS, Issue 9 2009
Jean-François Mayol
Abstract The characterisation of normal stem cells and cancer stem cells uses the same paradigm. These cells are isolated by a fluorescence-activated cell sorting step and their stemness is assayed following implantation into animals. However, differences exist between these two kinds of stem cells. Therefore, the translation of the experimental procedures used for normal stem cell isolation into the research field of cancer stem cells is a potential source of artefacts. In addition, normal stem cell therapy has the objective of regenerating a tissue, while cancer stem cell-centred therapy seeks the destruction of the cancer tissue. Taking these differences into account is critical for anticipating problems that might arise in cancer stem cell-centred therapy and for upgrading the cancer stem cell paradigm accordingly. [source]


Combined bezafibrate and medroxyprogesterone acetate have efficacy without haematological toxicity in elderly and relapsed acute myeloid leukaemia (AML)

BRITISH JOURNAL OF HAEMATOLOGY, Issue 1 2010
Jim A. Murray
Summary Acute myeloid leukaemia (AML) causes life-threatening deficits of functional blood cells that require management using red cell and platelet transfusion and aggressive treatment of neutropenic infections. Current cytotoxic chemotherapy further worsens the problem of reduced haemopoiesis and two-thirds of patients are too frail to tolerate intensive chemotherapy at all. Median survival amongst these patients remains at <3 months emphasizing the urgent need for anti-AML therapies that do not suppress haemopoiesis. Our laboratory studies showed combined Bezafibrate and Medroxyprogesterone acetate (BaP) had activity against AML without toxicity to normal stem cells. Here we report the safety and efficacy of BaP in 20 patients (19 AML, 1 high-risk myelodysplasia) for whom intensive chemotherapy was not an option. No patient exhibited haematological toxicity from BaP. Eleven patients took BaP alone for >4 weeks. One reverted from high risk myelodysplasia and remains transfusion independent after 201 weeks of therapy. Three AML patients gained major haematological improvements for 22,30 weeks; in one, marrow was available to document a partial AML response. Thus, this trial indicates that BaP therapy has potential for treatment of elderly and relapsed AML. [source]


Mathematical model for the cancer stem cell hypothesis

CELL PROLIFERATION, Issue 1 2006
R. Ganguly
Various genes that regulate self-renewal in normal stem cells are also found in cancer stem cells. This implies that cancers can occur because of mutations in normal stem cells and early progenitor cells. A predictive mathematical model based on the cell compartment method is presented here to pose and validate non-intuitive scenarios proposed through the neural cancer stem cell hypothesis. The growths of abnormal (stem and early progenitor) cells from their normal counterparts are ascribed with separate mutation probabilities. Stem cell mutations are found to be more significant for the development of cancer than a similar mutation in the early progenitor cells. The model also predicts that, as previously hypothesized, repeated insult to mature cells increases the formation of abnormal progeny, and hence the risk of cancer. [source]