Wet Slip Resistance of Plastic Based Material Flooring (PBM Flooring)

Tile Council of North America Product Performance Testing Laboratory, under the direction of Dr. John Sanders of the Bishop Materials Laboratory at Clemson University, measured the wet Dynamic Coefficient of Friction (DCOF) of 22 plastic based material (PBM1) flooring products that manufacturers2 advertise or claim to be waterproof, water resistant, or depict being used in areas where flooring gets wet.3 The claims suggest that such PBM products can be used where exposed to water. However, product literature for only five products tested in this report cautioned the products can be potentially slippery when wet, and no measurements of wet DCOF are provided by the product manufacturers for any of the PBM flooring products studied.4 This research examines whether the tested products are suitable for wet use, or instead should carry a dry use-only caution. ANSI A326.3, American National Standard Test Method for Measuring Dynamic Coefficient of Friction of Hard Surface Materials, was used to measure the wet DCOF of each PBM product. The ANSI A326.3 test method was developed through a broad consensus of stakeholders across the flooring industry and is widely used in the ceramic tile, polished concrete, and stone industries.5 The ANSI A326.3 testing showed 16 out of the 22 product specimens tested in this report had an average wet DCOF value below 0.42. Per ANSI A326.3, those 16 specimens are not suitable for wet use,6 although each tested product was advertised as waterproof, water resistant, or was depicted being used in areas where flooring gets wet. In addition, two out of 22 product specimens’ DCOF measured below 0.42 when tested parallel to the plank length, but above 0.42 when tested perpendicular to the plank length. These two products exhibited a potentially dangerous level of directionality (See Section 3.6.3) with a significant change in DCOF occurring depending on the direction of measurement. Further, four other products exhibited directionality. In total, 20 of the 22 products tested for this report exhibited either a low level of wet DCOF for products that are advertised for wet applications (18 of 22) or directionality when wet (6 of 22)7, and should be considered for a dry use-only cautionary statement

On the He II Emission In Eta Carinae and the Origin of Its Spectroscopic Events

We describe and analyze Hubble Space Telescope (HST) observations of transient emission near 4680 {\AA} in Eta Car, reported earlier by Steiner & Damineli (2004). If, as seems probable, this is He II $\lambda$4687, then it is a unique clue to Eta Car's 5.5-year cycle. According to our analysis, several aspects of this feature support a mass-ejection model of the observed spectroscopic events, and not an eclipse model. The He II emission appeared in early 2003, grew to a brief maximum during the 2003.5 spectroscopic event, and then abruptly disappeared. It did not appear in any other HST spectra before or after the event. The peak brightness was larger than previously reported, and is difficult to explain even if one allows for an uncertainty factor of order 3. The stellar wind must provide a temporary larger-than-normal energy supply, and we describe a special form of radiative amplification that may also be needed. These characteristics are consistent with a class of mass-ejection or wind-disturbance scenarios, which have implications for the physical structure and stability of Eta Car.Comment: 47 pages (including all appendices, tabs, & figs), 9 figures, 3 tables; submitted to Astrophysical Journal (2005 March 29), accepted for publication in Ap

Ku70 Is Required for Late B Cell Development and Immunoglobulin Heavy Chain Class Switching

Immunoglobulin (Ig) heavy chain (HC) class switch recombination (CSR) is a late B cell process that involves intrachromosomal DNA rearrangement. Ku70 and Ku80 form a DNA end-binding complex required for DNA double strand break repair and V(D)J recombination. Ku70^(−/−) (K70T) mice, like recombination activating gene (RAG)-1– or RAG-2–deficient (R1T or R2T) mice, have impaired B and T cell development at an early progenitor stage, which is thought to result at least in part from defective V(D)J recombination (Gu, Y., K.J. Seidl, G.A. Rathbun, C. Zhu, J.P. Manis, N. van der Stoep, L. Davidson, H.L. Cheng, J.M. Sekiguchi, K. Frank, et al. 1997. Immunity. 7:653–665; Ouyang, H., A. Nussenzweig, A. Kurimasa, V.C. Soares, X. Li, C. Cordon-Cardo, W. Li, N. Cheong, M. Nussenzweig, G. Iliakis, et al. 1997. J. Exp. Med. 186:921–929). Therefore, to examine the potential role of Ku70 in CSR, we generated K70T mice that carry a germline Ig HC locus in which the JH region was replaced with a functionally rearranged VH(D)JH and Ig λ light chain transgene (referred to as K70T/HL mice). Previously, we have shown that B cells from R1T or R2T mice carrying these rearranged Ig genes (R1T/HL or R2T/HL mice) can undergo CSR to IgG isotypes (Lansford, R., J. Manis, E. Sonoda, K. Rajewsky, and F. Alt. 1998. Int. Immunol. 10:325–332). K70T/HL mice had significant numbers of peripheral surface IgM^+ B cells, which generated serum IgM levels similar to those of R2T/HL mice. However, in contrast to R2T/HL mice, K70T/HL mice had no detectable serum IgG isotypes. In vitro culture of K70T/HL B cells with agents that induce CSR in normal or R2T/HL B cells did lead to the induction of germline CH transcripts, indicating that initial signaling pathways for CSR were intact in K70T/HL cells. However, treatment with such agents did not lead to detectable CSR by K70T/HL B cells, and instead, led to cell death within 72 h. We conclude that Ku70 is required for the generation of B cells that have undergone Ig HC class switching. Potential roles for Ku70 in the CSR process are discusse

Ca channels induced in Xenopus oocytes by rat brain mRNA

RNA was isolated from brains of 16-d-old rats and poly(A) samples were injected into stage V and VI oocytes. After allowing 2–5 d for expression, most oocytes were exposed to medium in which the K had been replaced by Cs for 24 hr prior to recording. Ba currents were usually measured in Cl-free Ba-methanesulfonate saline. I_(Ba) in noninjected oocytes was often undetectable, but ranged up to 50 nA (22 ± 4 nA, n = 21). In contrast, injected oocytes showed a peak I_(Ba) of 339 ± 42 nA (n = 33). The threshold for activation of I_(Ba) was -40 mV, with peak currents at +10 to +20 mV. After a peak, currents decayed to a nearly steady level along a single-exponential time course (τ = 650 ± 50 msec at +20 mV). The maintained current was 67 ± 6% (n = 9) of the early peak amplitude. A prepulse duration of 5 sec was needed to examine the inactivation of barium currents in injected oocytes. The inward I_(Ba) could be observed in BaCl₂ solutions at potentials positive to E_(Cl) and also in Na-free salines, indicating that neither Cl⁻ nor Na⁺ was carrying the inward current. Although I_(Ba) displayed voltage- independent blockade by Cd (50% inhibition at 6 µM), the peptide Ca channel antagonist, ω-CgTX (1 µM), and the organic Ca channel-blocking agents (verapamil, compound W-7, and nifedipine) were uniformly ineffective. No effects were observed with the dihydropyridine antagonist nifedipine (even at 10 µM, or when cells were held at -40 mV) or agonist Bay K-8644. However, I_(Ba) was enhanced via activation of protein kinase C with 4-beta-phorbol dibutyrate (PBT₂). In contrast, use of forskolin to activate protein kinase A did not alter I_(Ba). However, experiments in the presence of Cd revealed that forskolin decreased I_K. Ca channels produced by rat brain mRNA were thus in contrast to the nifedipine-sensitive, Bay K-8644- and forskolin-enhanced Ca channels observed after injection of rat heart mRNA (Dascal et al., 1986)

Ca channels induced in Xenopus oocytes by rat brain mRNA

RNA was isolated from brains of 16-d-old rats and poly(A) samples were injected into stage V and VI oocytes. After allowing 2–5 d for expression, most oocytes were exposed to medium in which the K had been replaced by Cs for 24 hr prior to recording. Ba currents were usually measured in Cl-free Ba-methanesulfonate saline. I_(Ba) in noninjected oocytes was often undetectable, but ranged up to 50 nA (22 ± 4 nA, n = 21). In contrast, injected oocytes showed a peak I_(Ba) of 339 ± 42 nA (n = 33). The threshold for activation of I_(Ba) was -40 mV, with peak currents at +10 to +20 mV. After a peak, currents decayed to a nearly steady level along a single-exponential time course (τ = 650 ± 50 msec at +20 mV). The maintained current was 67 ± 6% (n = 9) of the early peak amplitude. A prepulse duration of 5 sec was needed to examine the inactivation of barium currents in injected oocytes. The inward I_(Ba) could be observed in BaCl₂ solutions at potentials positive to E_(Cl) and also in Na-free salines, indicating that neither Cl⁻ nor Na⁺ was carrying the inward current. Although I_(Ba) displayed voltage- independent blockade by Cd (50% inhibition at 6 µM), the peptide Ca channel antagonist, ω-CgTX (1 µM), and the organic Ca channel-blocking agents (verapamil, compound W-7, and nifedipine) were uniformly ineffective. No effects were observed with the dihydropyridine antagonist nifedipine (even at 10 µM, or when cells were held at -40 mV) or agonist Bay K-8644. However, I_(Ba) was enhanced via activation of protein kinase C with 4-beta-phorbol dibutyrate (PBT₂). In contrast, use of forskolin to activate protein kinase A did not alter I_(Ba). However, experiments in the presence of Cd revealed that forskolin decreased I_K. Ca channels produced by rat brain mRNA were thus in contrast to the nifedipine-sensitive, Bay K-8644- and forskolin-enhanced Ca channels observed after injection of rat heart mRNA (Dascal et al., 1986)

Evidence for the involvement of more than one mRNA species in controlling the inactivation process of rat and rabbit brain Na channels expressed in Xenopus oocytes

The properties of rat and rabbit brain sodium (Na) channels expressed in Xenopus oocytes following either unfractionated or high-molecular- weight mRNA injections were compared to assess the relative contribution of different size messages to channel function. RNA was size-fractionated on a sucrose gradient and a high-molecular-weight fraction (7–10 kilobase) encoding the α-subunit gave rise to functional voltage-dependent Na channels in the oocyte membrane. Single- channel conductance, mean open time, and time to first opening were all similar to the values for channels following injection of unfractionated RNA. In contrast, inactivation properties were markedly different; Na currents from high-molecular-weight RNA inactivated with a several-fold smaller macroscopic inactivation rate and showed a steady-state voltage dependence that was shifted in the depolarizing direction by at least 10 mV relative to that for unfractionated RNA. Single-channel recording revealed that the kinetic difference arose from a greater probability for high-molecular-weight RNA induced channels to reopen during a depolarizing voltage step. Pooling all gradient fractions and injecting this RNA into oocytes led to the appearance of Na channels with inactivation properties indistinguishable from those following injection of unfractionated RNA. These results suggest that mRNA species not present in the high- molecular-weight fraction can influence the inactivation process of rat brain Na channels expressed in Xenopus oocytes. This mRNA may encode β-subunits or other proteins that are involved in posttranslational processing of voltage-dependent Na channels