"You're doing great. Keep doing what you're doing": socially supportive communication during first-generation college students' socialization

The experiences of first-generation college students (FGCS) are marked by high levels of stress and uncertainty as they navigate the transition to college. This study uses the organizational assimilation model to explore FGCS’ transition to college by temporally analyzing multiple sources and types of socially supportive communication found in interviews with 28 FGCS in their first semester at a four-year university. Findings suggest that during anticipatory socialization, FGCS primarily engaged in informational and instrumental social support interactions; in the encounter phase of socialization, FGCS (while still engaging in informational and instrumental support interactions) also engaged in appraisal and emotional support interactions. Findings also illuminate the ways in which FGCS embodied the role of pioneers, even early in the socialization process, suggesting important implications for their role not only as receivers of social support, but as agents of social support

Systematic Analysis of the Epidermal Growth Factor Receptor by Mass Spectrometry Reveals Stimulation-dependent Multisite Phosphorylation

Multisite phosphorylation of proteins is a general mechanism for modulation of protein function and molecular interactions. Definition of phosphorylation sites and elucidation of the functional interplay between multiple phosphorylated residues in proteins are, however, a major analytical challenge in current molecular cell biology and proteomic research. In the present study, we used mass spectrometry to determine the major phosphorylated residues of the human epidermal growth factor (EGF) receptor at various well defined cellular conditions. Activation of EGF receptor was achieved by several types of stimulation, i.e. by sodium pervanadate, EGF, and integrin-dependent adhesion. The contribution of cell-matrix adhesion was also determined by activating the EGF receptor by EGF in cells kept in suspension. We developed an analytical strategy that combined miniaturized sample preparation techniques and MALDI tandem mass spectrometry and determined a total of nine phosphorylation sites in the EGF receptor. We discovered one novel phosphorylation site (Ser967) and revealed constitutive phosphorylation of Thr669, Ser967, Ser1002, and Tyr1045 and stimulation-dependent differential phosphorylation of Tyr1068, Tyr1086, Ser1142, Tyr1148, and Tyr1173. The EGF receptor was purified from HeLa cells or ECV304 cells by immunoprecipitation and SDS-PAGE and then digested with trypsin. Phosphopeptides in the range of 0.8-3.7 kDa were recovered by combinations of IMAC, perfusion chromatography, and graphite powder chromatography and subsequently detected and sequenced by MALDI quadrupole time-of-flight tandem mass spectrometry. Two phosphorylation sites were detected in the peptide 1137GSHQISLDNPDYQQDFFPK1155; however, only Tyr1148 was phosphorylated upon EGF treatment; in contrast Ser1142 was only phosphorylated by integrin-dependent adhesion in the absence of EGF treatment, suggesting differential phosphorylation of this region by distinct stimuli. This MALDI MS/MS-based analytical approach demonstrates the feasibility of systematic analysis of signaling molecules by mass spectrometry and provides new insights into the dynamics of receptor signaling processes

Listeria abdominal endograft infection miming pseudoaneurysm treated with in-situ aortic reconstruction: a case report

We report the case of a 72-year old man previously treated with an aortic endograft for an abdominal aortic aneurysm. After 3 years the patient developed a sepsis. Imaging and blood exams detected an endograft infection related to Listeria monocytogenes. Patients underwent endograft removal and in-situ aortic reconstruction with a cryopreserved allograft. A continuous antibacterial therapy has been established. One-month follow-up revealed the absence of clinically relevant infection with patency of the graft and absence of biochemical inflammatory markers

Infrared and Raman spectroscopic features of the self-interstitial defect in diamond from exact-exchange hybrid DFT calculations

International audienceQuantum-mechanical calculations are performed to investigate the structural, electronic, and infrared (IR) and Raman spectroscopic features of one of the most common radiation-induced defects in diamond: the “dumb-bell” 〈100〉 split self-interstitial. A periodic super-cell approach is used in combination with all-electron basis sets and hybrid functionals of density-functional-theory (DFT), which include a fraction of exact non-local exchange and are known to provide a correct description of the electronic spin localization at the defect, at variance with simpler formulations of the DFT. The effects of both defect concentration and spin state are explicitly addressed. Geometrical constraints are found to prevent the formation of a double bond between the two three-fold coordinated carbon atoms. In contrast, two unpaired electrons are fully localized on each of the carbon atoms involved in the defect. The open-shell singlet state is slightly more stable than the triplet (the energy difference being just 30 meV, as the unpaired electrons occupy orthogonal orbitals) while the closed-shell solution is less stable by about 1.55 eV. The formation energy of the defect from pristine diamond is about 12 eV. The Raman spectrum presents only two peaks of low intensity at wave-numbers higher than the pristine diamond peak (characterized by normal modes extremely localized on the defect), whose positions strongly depend on defect concentration as they blue shift up to 1550 and 1927 cm−1 at infinite defect dilution. The first of these peaks, also IR active, is characterized by a very high IR intensity, and might then be related to the strong experimental feature of the IR spectrum occurring at 1570 cm−1. A second very intense IR peak appears at about 500 cm−1, which, despite being originated from a “wagging” motion of the self-interstitial defect, exhibits a more collective, less localized character

Modeling Variable Linear Polarization Produced by Co-Rotating Interaction Regions (CIRs) Across Optical Recombination Lines of Wolf-Rayet Stars

Massive star winds are structured both stochastically ("clumps") and often coherently (Co-rotation Interaction Regions, or CIRs). Evidence for CIRs threading the winds of Wolf-Rayet (WR) stars arises from multiple diagnostics including linear polarimetry. Some observations indicate changes in polarization position angle across optical recombination emission lines from a WR star wind but limited to blueshifted Doppler velocities. We explore a model involving a spherical wind with a single conical CIR stemming from a rotating star as qualitative proof-of-concept. To obtain a realistic distribution of limb polarization and limb darkening across the pseudo-photosphere formed in the optically thick wind of a WR star, we used Monte Carlo radiative transfer (MCRT). Results are shown for a parameter study. For line properties similar to WR 6 (EZ CMa; HD 50896), the combination of the MCRT results, a simple model for the CIR, and the Sobolev approximation for the line formation, we were able to reproduce variations in both polarization amplitude and position angle commensurate with observations. Characterizing CIRs in WR~winds has added importance for providing stellar rotation periods since the v sin i values are unobtainable because the pseudo-photosphere forms in the wind itself.Comment: This is a pre-copyedited, author-produced PDF of an article accepted for publication in MNRAS following peer revie

Comment on: "Diagnosis of Periprosthetic Joint Infection: The Role of Nuclear Medicine May Be Overestimated" by Claudio Diaz-Ledezma, Courtney Lamberton, Paul Lichtstein and Javad Parvizi

We read with interest the article by Diaz-Ledezma et al entitled“Diagnosis of Periprosthetic Joint Infection: The Role of NuclearMedicine May Be Overestimated”recently published in The Journal ofArthroplast