Performance of the EPD-N2 dosemeter for monitoring aircrew doses.

United States Air Force (USAF) aircrew fly at altitudes and for durations where doses from cosmic radiation are significant enough to warrant monitoring. This study evaluated a candidate radiological monitoring system for USAF aircrew, the Thermo Scientific electronic personnel dosemeter (EPD-N2). The evaluation consisted of characterising the device in a well-characterised radiation field at a European Organization for Nuclear Research (CERN) accelerator, and aboard an USAF aircraft. The performance of the EPDs was evaluated by comparison with accepted values for dose at the CERN facility, comparison with the value calculated by flight dose software and comparison with the value estimated by a tissue-equivalent proportional counter aboard the aircraft. This study recommends that a correction factor of 1/CF = 1/3.9 be applied to EPD-N2 measurements aboard aircraft flights. The uncertainty in this correction factor is 11.8 %.

Radiological assessment of petroleum pipe scale from pipe-rattling operations.

Petroleum pipe scale, consisting of concentrated inorganic solids such as barium sulfate, can deposit on the inside of down-hole pipes during the normal course of oil field pumping operations. A portion of this scale has been shown to contain naturally occurring radioactive materials (NORM), predominantly compounds of radium. When these pipes are removed from the well, there is a potential for radiation doses to the oil field workers handling the pipes, especially as the pipes are cleaned for reuse. A thorough sampling and measurement protocol was applied under a variety of weather conditions in an outdoor laboratory to obtain an accurate indication of the radiological and aerodynamic characteristics of scale release and dust dispersion during petroleum pipe scale removal from out-of-service pipes with a restored, historically relevant outdoor pipe-cleaning machine. Exposure rate data were also obtained for both the pre-cleaned pipes, and the general area inhabited by workers during the descaling operation. Four radiation exposure pathways were investigated: inhalation of pipe scale dust generated during pipe rattling, incidental ingestion of the pipe scale dust, external exposure from uncleaned pipes, and external exposure from pipe scale dispersed on the ground. Pipes from three oil fields were rattled to collect as much industry-representative data as possible. The Ra specific activity of the pipe scale ranged from 33.6 +/- 0.4 to 65.5 +/- 0.7 Bq g, depending on the formation. A median atmospheric dust loading of 0.13 mg m was measured in the operator breathing zone. The respirable fraction was observed to be about 42% to 46%. Based on cleaning 20 pipes per day,250 d per year on average, annual committed effective doses for the operator and helper ranged from 0.11 mSv (11 mrem) to 0.45 mSv(45 mrem) for inhalation and from 19 microSv (1.9 mrem) to 97 microSv (9.7 mrem) for incidental ingestion. Worker annual external dose from the pipe racks ranged from 0 to 0.28 mSv (28 mrem). In the deposition experiment, more than 99% by weight of the deposited scale fell within 2 m of the machine centerline, the vast majority of which was in the downwind direction. The dose from this deposited material dominated the worker dose estimates. The annual external dose from dispersed material was estimated to be 2.8 mSv (280 mrem) for the operator and 4.1 mSv (410 mrem) for the helper.

Mechanical characteristics of lyophilized human saphenous vein valves.

PURPOSE: We investigated the mechanical characteristics of lyophilized human saphenous vein valves to determine their suitability for use as allogeneic transplants to treat chronic venous insufficiency. METHODS: Fresh cadaveric veins were lyophilized in vacuum bottles within 24 hours of harvest and were stored at room temperature. The veins were reconstituted in saline solution and then were placed in an in vitro flow circuit for evaluation. At varied flow rates, pressures proximal and distal to valves during prograde and retrograde flow were measured. Valve closure times were determined with Doppler examination and spectral analysis. The valves were also stressed to 350 mm Hg on a separate apparatus. RESULTS: All pressures proximal and distal to the valves remained less than 10 mm Hg during prograde flow. A pressure gradient developed immediately on the reversal of flow. Pressure as high as 200 mm Hg applied against the closed valves was not transmitted beyond the valve. Valve closure times had a mean of 0.31 +/- 0.03 seconds and 0.21 +/- 0.01 seconds for the Doppler examination and spectral analysis, respectively. All valves withstood stress pressures to 350 mm Hg. CONCLUSIONS: The in vitro mechanical characteristics of the valves of lyophilized veins are similar to known values for normal in vivo valves.

Accuracy of the inverse Womersley method for the calculation of hemodynamic variables.

We have studied the accuracy of the inverse Womersley method, a linear theory for the calculation of hemodynamic variables from measured volumetric flow rate or centerline velocity, for two canine arteries with different degrees of arterial wall motion and taper. The results from the linear theory are compared with the estimates from the nonlinear theory of Ling and Atabek for a canine thoracic aorta and femoral artery. For the thoracic aorta, the linear theory underestimates the mean wall shear stress by as much as 77%, when compared with the nonlinear theory. For the femoral artery, on the other hand, the mean wall shear stress value is underestimated by as much as 23%. Estimates of other hemodynamic variables show similar discrepancies between the nonlinear and linear theories. Thus, the inverse Womersley method does not give accurate estimates of hemodynamic quantities. This failure results from the neglect of convective accelerations due to arterial wall motion and taper, with the neglect of arterial taper leading to the largest errors.

Evaluation of the effect of retroviral gene transduction on vascular endothelial cell adhesion.

Genetically modified endothelial cells (ECs) seeded on synthetic vascular grafts offer the potential to improve small diameter vascular graft patency. Despite encouraging results with naive ECs, cells transduced with retroviral vectors appear impaired in their ability to adhere to and stably colonize vascular grafts in vivo. This study addresses changes in retrovirally transduced EC adhesion as the cause of cell loss. Endothelial cells were retrovirally transduced with the bacterial neoR gene or "mock" transduced with empty viral particles. Cells were allowed to adhere to collagen IV (CIV) or fibronectin (FN) prior to exposure to 20 or 90 dyn/cm(2) using a parallel plate apparatus. Cell detachment was evaluated using time lapse videomicroscopy. Fibronectin was a significantly better adhesive protein for naive EC than CIV at both shear stresses. NeoR-transduced EC had significantly greater detachment from FN than either naive or "mock"-transduced EC. Transduced EC attachment to FN was no greater than to CIV. Flow cytometric analysis of the fibronectin receptor (FNR) showed that transduced cells have reduced receptor expression compared to naive and "mock"-transduced EC. These results indicate retrovirally transduced EC have altered FNR and adhesion to FN and that these changes may account for transduced EC loss in vivo.

In vitro studies of deformation and adhesion properties of transformed cells.

The micropipet aspiration technique and the parallel-plate flow chamber were used to investigate the deformation and detachment properties, respectively, of normal and transformed rat fibroblasts. The normal Cloned Rat Embryo Fibroblasts (CREF) cell line was transfected with the T24 ras oncogene to produce the transformed cell line CREF T24. The CREF T24 cell line was transfected with a Kirsten ras revertant gene (K-rev 1a suppressor) to produce the CT24HKB1 cells, which have the same morphological characteristics as the cells in the CREF line. The cells utilized in this investigation were derived from the parent cell line CREF, the only differences being the presence or absence of the T24 ras oncogene and the Kirsten ras revertant gene. The detachment and deformation properties, therefore, could be related to the metastatic phenotype of the cell rather than inherent differences between disparate cell lines. Results indicated that transfecting the CREF cell line with the ras oncogene greatly modified the detachment and deformation properties. The CREF T24 cells were more easily detached from normal cells and were 50% more deformable. Both CREF and CT24HKB1 showed similar detachment properties. Based on these results, it is speculated that K-rev 1a reversed ras-induced membrane alterations in these cells. Preliminary investigations have demonstrated that both CREF and CREF T24 cells in different phases of the cell cycle differed in morphological characteristics. However, the majority of the cells within a given cell line showed similar deformation characteristics. Current investigations are focusing on characterization of both detachment and deformation properties of these cells as a function of the cell cycle using synchronization techniques.

The effects of shear stress and metastatic phenotype on the detachment of transformed cells.

A parallel-plate flow chamber was used to quantify the detachment of normal, transformed, and reverted rat fibroblasts from a confluent monolayer of normal fibroblasts. In this method, known shear stresses were applied to the adherent cells and the percent of cells detached from the monolayer was determined. Results indicate that the detachment of all cell types increased with increasing shear stress and detachment of highly metastatic ras-transformed cells was significantly higher than that of either nonmetastatic normal cells or transformed cells reverted with the Kirsten ras revertant (K-rev 1a) gene, which are lowly metastatic. From these results, it is concluded that a correlation exists between the metastatic phenotype of the cell and its ability to detach from normal cells.

Flow/velocity characteristics of arterial bypass stenoses.

In the carotid system with relatively constant blood flow, peak systolic velocity within a stenosis (PSVST) can characterize the degree of hemodynamic stenosis. We have studied flow/velocity characteristics in an in vitro model of stenosis within conduits of varying diameters in an attempt to quantify the degree of stenosis from flow/velocity profiles in peripheral vein bypasses. A Harvard pulsatile flow pump (70 BPM) pumped human blood (HCT, 35-45%) through thin-walled polytetrafluoroethylene (3-6 mm in i.d.) into a variable peripheral resistance maintaining a constant mean blood pressure of 80 mm Hg over a flow range of 0-500 ml/min. A Diasonics DRF400 duplex scanner with a 10-MHz imager and 4.5-MHz Doppler probe was used to image and Doppler the conduits and measure flow through them. Validation of Doppler flow measurements (DF) was performed comparing them with flow measured (MF) by timed collection. PSVST within and pressure drop across a 50% stenosis was measured for each of the conduit's sizes over a range of 0-500 ml/min MF. The results show a good correlation between DF and MF (r = 0.99, P less than 0.001) for the whole range of internal diameters. In each 50% stenosed conduit, PSVST correlated well with MF (r = 0.95, P less than 0.001). Curves were constructed of MF vs PSVST for each 50% stenosed conduit. We conclude that measurement of volumetric flow, conduit diameter, and peak systolic velocity within a vein bypass can objectively predict bypass stenoses of 50% or greater.