sepharose and xylenol-orange

sepharose has been researched along with xylenol-orange* in 2 studies

Other Studies

2 other study(ies) available for sepharose and xylenol-orange

Article	Year
Investigation and analysis of ferrous sulfate polyvinyl alcohol (PVA) gel dosimeter. Physics in medicine and biology, 2002, Dec-07, Volume: 47, Issue:23 Ferrous sulfate (Fe(SO4)2) PVA gels were investigated for a range of absorbed doses up to 20 Gy using both magnetic resonance imaging (MRI) and spectrophotometry to determine R1 and optical density (OD) dose responses and G values. It was found that R1- and OD-dose sensitivities increased with O2 saturation or by the introduction of a freeze-thaw cycle during preparation of the PVA gel. The storage temperature of the Fe(SO4)2 PVA gel at -18 degrees C increased R1-dose sensitivity above that of gels stored at 5 degrees C. The addition of sucrose to the formulation was found to result in the largest increase in both R1- and OD-dose sensitivities. Fe(SO4)2 PVA gel with and without the addition of xylenol orange was demonstrated to have a G value of approximately 20 ions/100 eV and with sucrose approximately 24 ions/100 eV. Topics: Calibration; Dose-Response Relationship, Drug; Electrophoresis, Agar Gel; Ferrous Compounds; Gelatin; Gels; Iron; Magnetic Resonance Imaging; Oxygen; Phenols; Polyvinyl Alcohol; Radiometry; Sepharose; Spectrophotometry; Sucrose; Sulfoxides; Temperature; Ultraviolet Rays; Xylenes	2002
Fast T1 imaging of dual gel samples for diffusion measurements in NMR dosimetry gels. Magnetic resonance imaging, 1997, Volume: 15, Issue:2 Diffusion of iron is one of the major problems limiting the usefulness of NMR gel dosimetry. This was studied in dual gel samples using a 4.7T micro-imaging MR scanner and a fast T1 imaging sequence which allowed the acquisition of a 64 x 128 x 8 data sets (phase encoding x frequency encoding x number of inversion times) in less than 15 min. The procedure enabled us to obtain relative relaxation times for any region of interest within the sample. After the two differently doped gels were brought into contact in the dual gel samples (diameter 12 mm), the diffusion could be observed on subsequent images as a function of time. An inverse square root function was used to fit the change of 1/T1 across the junction between the two gel phases. A diffusion constant of 0.014 +/- 0.003 cm2/h was determined for Fe3+ in a typical dosimetry gel (1.5% agarose, 50 mM H2SO4). This could be lowered by adding a chelating agent such as xylenol orange to the gel. It was also found that diffusion was slower in gelatine gels, however these gels tended not to set properly when H2SO4 was added as required for NMR dosimetry. From the present results we propose that a gel consisting of 1.5% agarose (for stability), 3% gelatine and 0.1 mM xylenol orange (to combat diffusion and allow a visual evaluation) is a suitable base for NMR dosimetry gels. The use of a fast T1 imaging sequence reduces acquisition times and therefore the potential impact of diffusion. Topics: Chelating Agents; Diffusion; Gels; Iron; Magnetic Resonance Spectroscopy; Models, Theoretical; Phenols; Radiometry; Sepharose; Sulfoxides; Xylenes	1997

Article

Year

Investigation and analysis of ferrous sulfate polyvinyl alcohol (PVA) gel dosimeter.

Physics in medicine and biology, 2002, Dec-07, Volume: 47, Issue:23

Ferrous sulfate (Fe(SO4)2) PVA gels were investigated for a range of absorbed doses up to 20 Gy using both magnetic resonance imaging (MRI) and spectrophotometry to determine R1 and optical density (OD) dose responses and G values. It was found that R1- and OD-dose sensitivities increased with O2 saturation or by the introduction of a freeze-thaw cycle during preparation of the PVA gel. The storage temperature of the Fe(SO4)2 PVA gel at -18 degrees C increased R1-dose sensitivity above that of gels stored at 5 degrees C. The addition of sucrose to the formulation was found to result in the largest increase in both R1- and OD-dose sensitivities. Fe(SO4)2 PVA gel with and without the addition of xylenol orange was demonstrated to have a G value of approximately 20 ions/100 eV and with sucrose approximately 24 ions/100 eV.

Topics: Calibration; Dose-Response Relationship, Drug; Electrophoresis, Agar Gel; Ferrous Compounds; Gelatin; Gels; Iron; Magnetic Resonance Imaging; Oxygen; Phenols; Polyvinyl Alcohol; Radiometry; Sepharose; Spectrophotometry; Sucrose; Sulfoxides; Temperature; Ultraviolet Rays; Xylenes

2002

Fast T1 imaging of dual gel samples for diffusion measurements in NMR dosimetry gels.

Magnetic resonance imaging, 1997, Volume: 15, Issue:2

Diffusion of iron is one of the major problems limiting the usefulness of NMR gel dosimetry. This was studied in dual gel samples using a 4.7T micro-imaging MR scanner and a fast T1 imaging sequence which allowed the acquisition of a 64 x 128 x 8 data sets (phase encoding x frequency encoding x number of inversion times) in less than 15 min. The procedure enabled us to obtain relative relaxation times for any region of interest within the sample. After the two differently doped gels were brought into contact in the dual gel samples (diameter 12 mm), the diffusion could be observed on subsequent images as a function of time. An inverse square root function was used to fit the change of 1/T1 across the junction between the two gel phases. A diffusion constant of 0.014 +/- 0.003 cm2/h was determined for Fe3+ in a typical dosimetry gel (1.5% agarose, 50 mM H2SO4). This could be lowered by adding a chelating agent such as xylenol orange to the gel. It was also found that diffusion was slower in gelatine gels, however these gels tended not to set properly when H2SO4 was added as required for NMR dosimetry. From the present results we propose that a gel consisting of 1.5% agarose (for stability), 3% gelatine and 0.1 mM xylenol orange (to combat diffusion and allow a visual evaluation) is a suitable base for NMR dosimetry gels. The use of a fast T1 imaging sequence reduces acquisition times and therefore the potential impact of diffusion.

Topics: Chelating Agents; Diffusion; Gels; Iron; Magnetic Resonance Spectroscopy; Models, Theoretical; Phenols; Radiometry; Sepharose; Sulfoxides; Xylenes

1997