Progress on HL-LHC Nb3Sn Magnets

The high-luminosity Large Hadron Collider (HL-LHC) project aims at allowing to increase the collisions in the LHC by a factor of ten in the decade 2025-2035. One essential element is the superconducting magnet around the interaction region points, where the large aperture magnets will be installed to allow to further reduce the beam size in the interaction point. The core of this upgrade is the Nb Sn triplet, made up of 150-mm aperture quadrupoles in the range of 7-8 m. The project is being shared between the European Organization for Nuclear Research and the US Accelerator Upgrade Program, based on the same design, and on the two strand technologies. The project is ending the short model phase, and entering the prototype construction. We will report on the main results of the short model program, including the quench performance and field quality. A second important element is the 11 T dipole that replaces a standard dipole making space for additional collimators. The magnet is also ending the model development and entering the prototype phase. A critical point in the design of this magnet is the large current density, allowing increase of the field from 8 to 11 T with the same coil cross section as in the LHC dipoles. This is also the first two-in-one Nb Sn magnet developed so far. We will report the main results on the test and the critical aspects. 3

Standardizing Handoff: From Operating Room to Intensive Care Unit

The transfer of patient information that is shared among health care providers during transitions of care is an integral component of the handoff process that ensures patient safety and continuity of care. The postoperative period is one of high acuity. Communication failures during the acute phase of transfer from operating room to intensive care unit leave critically ill patients vulnerable to devastating adverse outcomes. The problem identified in the Surgical Intensive Care Unit (SICU) of a North Philadelphia hospital is a lack of standardization with postoperative patient handoffs. The purpose of this project is to assess the impact of utilizing a standardized postoperative handoff tool and to evaluate the satisfaction of SICU nurses through a Plan Do Study Act (PDSA) methodology of quality improvement (QI)

Developmental expression of Sp1 in the mouse.

The expression of the trans-acting transcription factor Sp1 in mice was defined by a combination of RNA analysis and immunohistochemical localization of the Sp1 protein. Although ubiquitously expressed, there was an unexpected difference of at least 100-fold in the amount of Sp1 message in different cell types. Sp1 protein levels showed corresponding marked differences. Substantial variations in Sp1 expression were also found in some cell types at different stages of development. Sp1 levels appeared to be highest in developing hematopoietic cells, fetal cells, and spermatids, suggesting that an elevated Sp1 level is associated with the differentiation process. These results indicate that Sp1 has a regulatory function in addition to its general role in the transcription of housekeeping genes

Localization of the gene for the trans-acting transcription factor Sp1 to the distal end of mouse chromosome 15.

The mouse chromosomal location for the gene (Sp1-1) encoding the trans-acting transcription factor Sp1 has been determined. Analysis of restriction fragment length polymorphisms in recombinant inbred, congenic, and interspecific backcross mice using human and mouse cDNA probes demonstrated that Sp1-1 is a single gene closely linked to the mammary tumor virus integration site-1 (Int-1) on the distal end of chromosome 15. Sp1 is a zinc finger protein, but Sp1-1 is not closely linked to any of the other zinc finger protein genes that have been mapped in mouse. Int-1 and other markers flanking the Sp1-1 locus are part of a conserved linkage group represented on human chromosome 12q

Progress on high luminosity LHC Nb3_{3}Sn magnets

The HL-LHC project aims at allowing to increase the collisions in the Large Hadron Collider by a factor ten in the decade 2025 - 2035. One essential element are the superconducting magnets around the interaction region points, where large aperture magnets will be installed to allow to further reduce the beam size in the interaction point. The core of this upgrade is the Nb$_{3}$Sn triplet, made of 150 mm aperture quadrupoles of in the range of 7 - 8 m. The project is being shared between CERN and US Accelerator Upgrade Program, based on the same design, and on two strand technologies. The project is ending the short model phase, and entering the prototype construction. We will report on the main results of the short model program, including quench performance and field quality. A second important element is the 11 T dipole that replacing a standard dipole makes space for additional collimators. The magnet is also ending the model development and entering the prototype phase. A critical point in the design of this magnet is the large current density, allowing increasing the field from 8 to 11 T with the same coil cross - section as in the LHC dipoles. This is also the first two - in - one Nb$_{3}$Sn magnet developed so far. We will report the main results on the test and the critical aspects