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Leadership, governance, and management are frequently conceptualized as conflictory institutional logics. The recent shift to a ‘new managerialism’ in universities, for example, clearly favors business-like leadership and management styles over collegial governance practices. This article provides a micro foundation of leadership, governance, and management in universities based on the underlying communication of strategic issues among governing bodies. Reporting on a longitudinal case study of a comprehensive reorganization of a German university, it illustrates how institutional logics translate into micro patterns of communication. The findings suggest that leadership, governance, and management are not necessarily conflictory but reflect in four complementary micro patterns. Rather than ‘managerialism’ replacing ‘collegialism,’ organizational change unfolds in oscillating sequences of these four micro patterns. The findings furthermore indicate that the strategic issues of research and teaching at the university’s core remain largely autonomous, despite their increasing managerial regulation. 相似文献
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Linfeng Xu Hun Lee Mariana Vanderlei Brasil Pinheiro Phil Schneider Deekshitha Jetta Kwang W. Oh 《Biomicrofluidics》2015,9(1)
We propose a blood separation microfluidic device suitable for point-of-care (POC) applications. By utilizing the high gas permeability of polydimethylsiloxane (PDMS) and phaseguide structures, a simple blood separation device is presented. The device consists of two main parts. A separation chamber with the phaseguide structures, where a sample inlet, a tape-sealed outlet, and a dead-end ring channel are connected, and pneumatic chambers, in which manually operating syringes are plugged. The separation chamber and pneumatic chambers are isolated by a thin PDMS wall. By manually pulling out the plunger of the syringe, a negative pressure is instantaneously generated inside the pneumatic chamber. Due to the gas diffusion from the separation chamber to the neighboring pneumatic chamber through the thin permeable PDMS wall, low pressure can be generated, and then the whole blood at the sample inlets starts to be drawn into the separation chamber and separated through the phaseguide structures. Reversely, after removing the tape at the outlet and manually pushing in the plunger of the syringe, a positive pressure will be created which will cause the air to diffuse back into the ring channel, and therefore allow the separated plasma to be recovered at the outlet on demand. In this paper, we focused on the study of the plasma separation and associated design parameters, such as the PDMS wall thickness, the air permeable overlap area between the separation and pneumatic chambers, and the geometry of the phaseguides. The device required only 2 μl of whole blood but yielding approximately 0.38 μl of separated plasma within 12 min. Without any of the requirements of sophisticated equipment or dilution techniques, we can not only separate the plasma from the whole blood for on-chip analysis but also can push out only the separated plasma to the outlet for off-chip analysis. 相似文献
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