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Your search keyword '"Nome, Ragnhild V."' showing total 12 results
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12 results on '"Nome, Ragnhild V."'

1. Managing hemolysis in serum neuron-specific enolase measurements – an automated algorithm for routine practice.

Author

Nome, Ragnhild V., Paus, Elisabeth, Gehin, Johanna E., Bolstad, Nils, and Bjøro, Trine

Subjects
*NEUROENDOCRINE cells, *NEUROENDOCRINE tumors, *CARDIAC arrest, *ENOLASE, *HEMOLYSIS & hemolysins
Abstract

Neuron-specific enolase (NSE) derived from neurons and peripheral neuroendocrine cells is a biomarker for neuroendocrine tumors and for prognostication in comatose cardiac arrest survivors. However, as platelets and erythrocytes contain NSE, hemolysis causes falsely elevated NSE. We used native serum and hemolysate derived from the same patients to make serial dilutions, and subsequently measured NSE (mNSE) and hemolytic index (HI) in each dilution. An algorithm suitable for the laboratory information system was developed based on the mNSE, HI and the estimated gradient of hemolytic interference from 30 patients. We estimated the associated uncertainty of the corrected NSE (cNSE) results based on the observed range of the gradient and derived an equation for cNSE for samples with limited hemolysis (i.e. 5 < HI ≤ 30): cNSE = mNSE − HI × (0.34 ± 0.23) µg/L. By semi-quantitatively grading the contribution from limited hemolysis, a texted result noting the hemolysis-associated degree of uncertainty can accompany the cNSE result. The major challenge of hemolysis when using serum NSE as a biomarker can be managed using an automated algorithm for correction of NSE results based on degree of hemolysis. However, laboratorians and clinicians should be aware of the limitations associated with in vivo hemolysis. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Radiosensitization of colorectal carcinoma cell lines by histone deacetylase inhibition

Author

Rasmussen Heidi, Bratland Åse, Folkvord Sigurd, Nome Ragnhild V, Flatmark Kjersti, Ellefsen Mali, Fodstad Øystein, and Ree Anne

Subjects
Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background The tumor response to preoperative radiotherapy of locally advanced rectal cancer varies greatly, warranting the use of experimental models to assay the efficacy of molecular targeting agents in rectal cancer radiosensitization. Histone deacetylase (HDAC) inhibitors, agents that cause hyperacetylation of histone proteins and thereby remodeling of chromatin structure, may override cell cycle checkpoint responses to DNA damage and amplify radiation-induced tumor cell death. Methods Human colorectal carcinoma cell lines were exposed to ionizing radiation and HDAC inhibitors, and cell cycle profiles and regulatory factors, as well as clonogenicity, were analyzed. Results In addition to G2/M phase arrest following irradiation, the cell lines displayed cell cycle responses typical for either intact or defective p53 function (the presence or absence, respectively, of radiation-induced expression of the cell cycle inhibitor p21 and subsequent accumulation of G1 phase cells). In contrast, histone acetylation was associated with complete depletion of the G1 population of cells with functional p53 but accumulation of both G1 and G2/M populations of cells with defective p53. The cellular phenotypes upon HDAC inhibition were consistent with the observed repression of Polo-like kinase-1, a regulatory G2/M phase kinase. Following pre-treatment with HDAC inhibitors currently undergoing clinical investigation, the inhibitory effect of ionizing radiation on clonogenicity was significantly amplified. Conclusion In these experimental models, HDAC inhibition sensitized the tumor cells to ionizing radiation, which is in accordance with the concept of increased probability of tumor cell death when chromatin structure is modified.

Published
2006
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12. DNA damage responses in cell cycle G2 phase and mitosis--tracking and targeting.

Author

Ree AH, Stokke T, Bratland A, Patzke S, Nome RV, Folkvord S, Meza-Zepeda LA, Flatmark K, Fodstad O, and Andersson Y

Subjects
Cell Division genetics, Cell Division radiation effects, Cell Growth Processes genetics, Cell Growth Processes radiation effects, Flow Cytometry, G2 Phase radiation effects, Gene Targeting, HeLa Cells, Humans, Mitosis radiation effects, DNA Damage physiology, G2 Phase genetics, Mitosis genetics
Abstract

Background: In order to determine temporal responses of cell cycle populations to DNA damage, a rational combination of cell cycle analyses is critical. Moreover, the targeting of cell cycle checkpoint responses may modify the cytotoxic effect of DNA damage., Materials and Methods: The characteristics of cell cycle populations (DNA content, cell cycle transitioning of S phase cells and size of mitotic cell fraction within the total G2/M phase population) in HeLa cells exposed to ionizing radiation were analyzed using three individual flow cytometry-based assays. The potential radiosensitization from inhibiting DNA damage responses was assessed by the colony formation assay., Results: Irradiation resulted in an initial accumulation of S phase cells in G2 phase, from which the arrested cells were subsequently released to enter mitosis. Upon drug inhibition of G2 checkpoint signaling or mitotic progression, the cytotoxic effect of ionizing radiation on the HeLa cells was amplified., Conclusion: DNA damage-induced cell cycle responses, analyzed by selected cytometry assays and modified by specific targeting, might contribute to an understanding of how to improve radiotherapy outcome.

Published
2006

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