Sample records for saibo baiyo shisutemu

  1. DomeGene Sample Removal from Cell Biology Experiment Facility (CBEF)

    NASA Image and Video Library

    2009-03-28

    ISS018-E-044268 (28 March 2009) --- Japan Aerospace Exploration Agency (JAXA) astronaut Koichi Wakata, Expedition 18/19 flight engineer, works on an experiment at the Saibo biological experiment rack in the Kibo laboratory of the International Space Station.

  2. 77 FR 65578 - Certain Hydroxyprogesterone Caproate and Products Containing the Same; Notice of Receipt of...

    Federal Register 2010, 2011, 2012, 2013, 2014

    2012-10-29

    ...; Bellevue Pharmacy of MO; Betapharma (Shanghai) Co., Ltd. of China; Boudreaux's Specialty Compounding of LA... Center of NJ; Hubei Gedian Humanwell Pharmaceutical Co., Ltd. of China; Hubei Saibo Chemical Co., Ltd. of China; Jinan Haohua Industry Co., Ltd. of China; Kelley-Ross & Associates, Inc. of WA; Lacey Drug...

  3. Wakata in JPM

    NASA Image and Video Library

    2009-06-01

    ISS020-E-005881 (1 June 2009) --- Japan Aerospace Exploration Agency (JAXA) astronaut Koichi Wakata, Expedition 20 flight engineer, conducts the current periodic humidity check on the Cell Biology Experiment Facility (CBEF) in the Saibo Rack in the Kibo laboratory of the International Space Station. Wakata opened the facility’s door for wiping up any condensation inside the micro-G & 1G section, if present, and also secured floating fan mesh with Kapton tape.

  4. Chamitoff works on the SAIBO Rack in the JEM during Expedition 17

    NASA Image and Video Library

    2008-07-30

    ISS017-E-012001 (30 July 2008) --- NASA astronaut Greg Chamitoff, Expedition 17 flight engineer, uses a computer while working with an experiment in the Kibo laboratory of the International Space Station.

  5. Assessing Pearl Quality Using Reflectance UV-Vis Spectroscopy: Does the Same Donor Produce Consistent Pearl Quality?

    PubMed Central

    Mamangkey, Noldy Gustaf F.; Agatonovic, Snezana; Southgate, Paul C.

    2010-01-01

    Two groups of commercial quality (“acceptable”) pearls produced using two donors, and a group of “acceptable” pearls from other donors were analyzed using reflectance UV-Vis spectrophotometry. Three pearls with different colors produced by the same donor showed different absorption spectra. Cream and gold colored pearls showed a wide absorption from 320 to about 460 nm, while there was just slight reflectance around 400 nm by the white pearl with a pink overtone. Cream and gold pearls reached a reflectance peak at 560 to 590 nm, while the white pearl with pink overtone showed slightly wider absorption in this region. Both cream and gold pearls showed an absorption peak after the reflectance peak, at about 700 nm for the cream pearl and 750 nm for the gold pearl. Two other pearls produced by the same donor (white with cream overtone and cream with various overtones) showed similar spectra, which differed in their intensity. One of these pearls had very high lustre and its spectrum showed a much higher percentage reflectance than the second pearl with inferior lustre. This result may indicate that reflectance is a useful quantitative indicator of pearl lustre. The spectra of two white pearls resulting from different donors with the same color nacre (silver) showed a reflectance at 260 nm, followed by absorption at 280 nm and another reflectance peak at 340 nm. After this peak the spectra for these pearls remained flat until a slight absorption peak around 700 nm. Throughout the visible region, all white pearls used in this study showed similar reflectance spectra although there were differences in reflectance intensity. Unlike the spectral results from white pearls, the results from yellow and gold pearls varied according to color saturation of the pearl. The results of this study show that similarities between absorption and reflectance spectra of cultured pearls resulting from the same saibo donor are negligible and could not be detected with UV

  6. Assessing pearl quality using reflectance UV-Vis spectroscopy: does the same donor produce consistent pearl quality?

    PubMed

    Mamangkey, Noldy Gustaf F; Agatonovic, Snezana; Southgate, Paul C

    2010-09-20

    Two groups of commercial quality ("acceptable") pearls produced using two donors, and a group of "acceptable" pearls from other donors were analyzed using reflectance UV-Vis spectrophotometry. Three pearls with different colors produced by the same donor showed different absorption spectra. Cream and gold colored pearls showed a wide absorption from 320 to about 460 nm, while there was just slight reflectance around 400 nm by the white pearl with a pink overtone. Cream and gold pearls reached a reflectance peak at 560 to 590 nm, while the white pearl with pink overtone showed slightly wider absorption in this region. Both cream and gold pearls showed an absorption peak after the reflectance peak, at about 700 nm for the cream pearl and 750 nm for the gold pearl. Two other pearls produced by the same donor (white with cream overtone and cream with various overtones) showed similar spectra, which differed in their intensity. One of these pearls had very high lustre and its spectrum showed a much higher percentage reflectance than the second pearl with inferior lustre. This result may indicate that reflectance is a useful quantitative indicator of pearl lustre. The spectra of two white pearls resulting from different donors with the same color nacre (silver) showed a reflectance at 260 nm, followed by absorption at 280 nm and another reflectance peak at 340 nm. After this peak the spectra for these pearls remained flat until a slight absorption peak around 700 nm. Throughout the visible region, all white pearls used in this study showed similar reflectance spectra although there were differences in reflectance intensity. Unlike the spectral results from white pearls, the results from yellow and gold pearls varied according to color saturation of the pearl. The results of this study show that similarities between absorption and reflectance spectra of cultured pearls resulting from the same saibo donor are negligible and could not be detected with UV

  7. The International Space Station as a Research Laboratory: A View to 2010 and Beyond

    NASA Technical Reports Server (NTRS)

    Uri, John J.; Sotomayor, Jorge L.

    2007-01-01

    Assembly of International Space Station (ISS) is expected to be complete in 2010, with operations planned to continue through at least 2016. As we move nearer to assembly complete, replanning activities by NASA and ISS International Partners have been completed and the final complement of research facilities on ISS is becoming more certain. This paper will review pans for facilities in the US On-orbit Segment of ISS, including contributions from International Partners, to provide a vision of the research capabilities that will be available starting in 2010. At present, in addition to research capabilities in the Russian segment, the United States Destiny research module houses nine research facilities or racks. These facilities include five multi-purpose EXPRESS racks, two Human Research Facility (HRF) racks, the Microgravity Science Glovebox (MSG), and the Minus Eighty-degree Laboratory Freezer for ISS (MELFI), enabling a wide range of exploration-related applied as well as basic research. In the coming years, additional racks will be launched to augment this robust capability: Combustion Integrated Rack (CIR), Fluids Integrated Rack (FIR), Window Observation Rack Facility (WORF), Microgravity Science Research Rack (MSRR), Muscle Atrophy Research Exercise System (MARES), additional EXPRESS racks and possibly a second MELFI. In addition, EXPRESS Logistics Carriers (ELC) will provide attach points for external payloads. The European Space Agency s Columbus module will contain five research racks and provide four external attach sites. The research racks are Biolab, European Physiology Module (EPM), Fluid Science Lab (FSL), European Drawer System (EDS) and European Transport Carrier (ETC). The Japanese Kibo elements will initially support three research racks, Ryutai for fluid science, Saibo for cell science, and Kobairo for materials research, as well as 10 attachment sites for external payloads. As we look ahead to assembly complete, these new facilities represent