Automated Assessment of Aortic and Main Pulmonary Arterial Diameters using Model-Based Blood Vessel Segmentation for Predicting Chronic Thromboembolic Pulmonary Hypertension in Low-Dose CT Lung Screening

Chronic thromboembolic pulmonary hypertension (CTEPH) is characterized by obstruction of the pulmonary vasculature by residual organized thrombi. A morphological abnormality inside mediastinum of CTEPH patient is enlargement of pulmonary artery. This paper presents an automated assessment of aortic and main pulmonary arterial diameters for predicting CTEPH in low-dose CT lung screening. The distinctive feature of our method is to segment aorta and main pulmonary artery using both of prior probability and vascular direction which were estimated from mediastinal vascular region using principal curvatures of four-dimensional hyper surface. The method was applied to two datasets, 64 low-dose CT scans of lung cancer screening and 19 normal-dose CT scans of CTEPH patients through the training phase with 121 low-dose CT scans. This paper demonstrates effectiveness of our method for predicting CTEPH in low-dose CT screening

Effect of Ball Milling on the Electrochemical Performance of Activated Carbon with a Very High Specific Surface Area

Activated carbon (AC) with a very high specific surface area of >3000 m(2)g(-1) and a number of course particles (average size: 75 mu m) was pulverized by means of planetary ball milling under different conditions to find its greatest performances as the active material of an electric double-layer capacitor (EDLC) using a nonaqueous electrolyte. The variations in textural properties and particle morphology of the AC during the ball milling were investigated. The electrochemical performance (specific capacitance, rate and cyclic stabilities, and Ragone plot, both from gravimetric and volumetric viewpoints) was also evaluated for the ACs milled with different particle size distributions. A trade-off relation between the pulverization and the porosity maintenance of the AC was observed within the limited milling time. However, prolonged milling led to a degeneration of pores within the AC and a saturation of pulverization degree. The appropriate milling time provided the AC a high volumetric specific capacitance, as well as the greatest maintenance of both the gravimetric and volumetric specific capacitance. A high volumetric energy density of 6.6 Wh L-1 was attained at the high-power density of 1 kW L-1, which was a 35% increment compared with the nonmilled AC. The electrode densification (decreased interparticle gap) and the enhanced ion-transportation within the AC pores, which were attributed to the pulverization, were responsible for those excellent performances. It was also shown that excessive milling could degrade the EDLC performances because of the lowered micro- and meso-porosity and the excessive electrode densification to restrict the ion-transportation within the pores

Impact of Full Prelithiation of Si-Based Anodes on the Rate and Cycle Performance of Li-Ion Capacitors

The impact of full prelithiation on the rate and cycle performance of a Si-based Li-ion capacitor (LIC) was investigated. Full prelithiation of the anode was achieved by assembling a half cell with a 2 mu m-sized Si anode (0 V vs. Li/Li+) and Li metal. A three-electrode full cell (100% prelithiation) was assembled using an activated carbon (AC) cathode with a high specific surface area (3041 m(2)/g), fully prelithiated Si anode, and Li metal reference electrode. A three-electrode full cell (87% prelithiation) using a Si anode prelithiated with 87% Li ions was also assembled. Both cells displayed similar energy density levels at a lower power density (200 Wh/kg at <= 100 W/kg; based on the total mass of AC and Si). However, at a higher power density (1 kW/kg), the 100% prelithiation cell maintained a high energy density (180 Wh/kg), whereas that of the 87% prelithiation cell was significantly reduced (80 Wh/kg). During charge/discharge cycling at similar to 1 kW/kg, the energy density retention of the 100% prelithiation cell was higher than that of the 87% prelithiation cell. The larger irreversibility of the Si anode during the initial Li-ion uptake/release cycles confirmed that the simple full prelithiation process is essential for Si-based LIC cells

Efect of Ball Milling on the Electrochemical Performance of Activated Carbon with a Very High Specific Surface Area

Activated carbon (AC) with a very high specific surface area of >3000 m2 g-1 and a number　of course particles (average size: 75 μm) was pulverized by means of planetary ball milling under　di erent conditions to find its greatest performances as the active material of an electric double-layer　capacitor (EDLC) using a nonaqueous electrolyte. The variations in textural properties and particle　morphology of the AC during the ball milling were investigated. The electrochemical performance　(specific capacitance, rate and cyclic stabilities, and Ragone plot, both from gravimetric and volumetric　viewpoints) was also evaluated for the ACs milled with di erent particle size distributions. A trade-o 　relation between the pulverization and the porosity maintenance of the AC was observed within the　limited milling time. However, prolonged milling led to a degeneration of pores within the AC and a　saturation of pulverization degree. The appropriate milling time provided the AC a high volumetric　specific capacitance, as well as the greatest maintenance of both the gravimetric and volumetric　specific capacitance. A high volumetric energy density of 6.6 Wh L-1 was attained at the high-power　density of 1 kW L-1, which was a 35% increment compared with the nonmilled AC. The electrode　densification (decreased interparticle gap) and the enhanced ion-transportation within the AC pores,　which were attributed to the pulverization, were responsible for those excellent performances. It was　also shown that excessive milling could degrade the EDLC performances because of the lowered　micro- and meso-porosity and the excessive electrode densification to restrict the ion-transportation　within the pores

Induction of cyclooxygenase-2 in human synovial cells by β2-microglobulin

Induction of cyclooxygenase-2 in human synovial cells by β2-microglobulin.BackgroundProstaglandins (PGs) are important mediators of inflammation in arthritis. We evaluated the role of the cyclooxygenase-2 (COX-2) enzyme, which regulates PG biosynthesis, in osteoarthropathy associated with hemodialysis-associated amyloidosis (HAA) by characterizing COX-2 expression in β2-microglobulin–treated human synovial cells.MethodsWe examined the effects of β2-microglobulin (β2m), a major constituent protein of amyloid fibrils in HAA, on the COX-2 protein and mRNA expression in human synovial cells using Western blot and reverse transcriptase-polymerase chain reaction.Resultsβ2m selectively increased the biosynthesis of COX-2 protein and induction of COX-2 mRNA in a dose-dependent manner. Immunoabsorption of β2m–containing media by anti-β2m–specific antibody abrogated β2m–mediated COX-2 expression on synovial cells. On the other hand, dexamethasone markedly suppressed the induction of COX-2 protein and mRNA in β2m–stimulated synovial cells.ConclusionsOur results suggest that induction of COX-2 expression by β2m may be an important component of the inflammatory process in hemodialysis-associated osteoarthropathy

Studies on Expression of Aldehyde Dehydrogenase in Normal and Cancerous Tissues of Thyroids

Recently published articles have reported the controversial data regarding expression of aldehyde dehydrogenase isozyme 1A1 (ALDH1A1), a potential candidate marker for normal and cancer stem cells (CSCs), in thyroid tissues. These data prompted us to re-evaluate expression of ALDH1A1 in normal and cancerous thyroid tissues by 2 different means. The first method was immunohistochemistry with 2 different anti-ALDH1A1 antibodies from distinct companies. Following validating the integrity of these 2 antibodies by Western blotting with ALDH-expressing and nonexpressing cancer cell lines and immunohistochemistry with breast and colon tissues, we report here significant and comparable expression of ALDH1A1 in both normal and cancerous thyroid tissues with both antibodies. Next, relative expression levels of ALDH isozymes were evaluated by reverse transcription-polymerase chain reaction (RT-PCR), revealing that ALDH1A1 was the most highly expressed isozyme followed by ALDH9A1 and relative expression patterns of isozymes were very similar in normal and cancerous tissues. All these data demonstrate that thyroid cells of normal and cancer origins do express ALDH1A1 and to a lesser extent 9A1. Further study will be necessary to study functional significance of ALDH1A1 in the function and behaviors of thyroid normal and cancer stem cells