RESUMO
We present a vacuum window mechanism that is useful for applications requiring two different vacuum windows in series, with one of them movable and resealable. Such applications include space borne instruments that can benefit from a thin vacuum window at low ambient pressures but must also have an optically open aperture at atmospheric pressures. We describe the implementation and successful operation with the E and B experiment balloon-borne payload, a millimeter-wave instrument designed to measure the polarization of the cosmic microwave background radiation.
RESUMO
Selective elimination of alloreactive cells was carried out in the set-up of T-cell-mediated immunotherapy in an effort to gain the benefits of hematopoietic allogeneic transplantation while reducing the risk of GVHD. Low MW chemical compounds were screened for their effect on T-cell-mediated immune responses of murine- and human-derived lymphocytes. Selected compounds were further tested in secondary MLR assays in which sensitization to alloantigens was carried out in vitro, in the presence or absence of a given compound, followed by exposure to related and unrelated alloantigens or T-cell mitogenic stimulation. At a low concentration of <1 µM, a quinazoline derivative named AO#349 [2-(3,4,5-trimethoxyphenyl)-N-p-tolylquinazolin-4-amine], was able to induce 78-90% inhibition of a selective allogeneic response while retaining >92% immune reactivity to unrelated alloantigens and mitogenic stimuli in vitro. Following allogeneic sensitization in the presence of AO#349, elimination of alloreactivity to the priming alloantigens was also proved in a murine model of GVHD: 10 out of 15 sub-lethally irradiated mice inoculated with these sensitized cells were GVHD-free for >200 days. AO#349 was efficient in induction of a selective elimination of alloreactivity and should be considered for clinical application in allogeneic cell-mediated immunotherapy.