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The route to tenure is often clear and well-defined, while the path to full professor is notoriously described as ambiguous and elusive, which raises questions and uncertainty on how to be promoted. In order to explore institutional concerns expressed by associate professor women in science, technology, engineering, and mathematics (STEM) and social and behavioral sciences (SBS) regarding the pathway to full professor, interviews were conducted with members of the Belayers Network at the University of Colorado Colorado Springs (UCCS). The Belayers Network consists of STEM and SBS associate professor women and is designed to support their promotion to full professor through opportunities to come together for informational, tangible, and emotional resources. An instrumental case study with a pragmatic theoretical lens was employed for this study. Interviews were analyzed inductively and resulted in five themes: (1) Full professor promotion criteria are ambiguous; (2) Teaching and service expectations are too high; (3) Lack of research collaborators inhibits scholarly output; (4) Scarce research-related resources are a persistent struggle; and (5) Mentoring and support are absent. The academy may find it instructive to understand better associate professor women’s institutional concerns about the pathway to full professor and possible ways to offset the obstacles toward achievement. Additionally, pragmatic solutions and implications are offered to mitigate these concerns in the context of UCCS. This research is sponsored by a National Science Foundation ADVANCE Adaptation Award. 

Synthetic polymers have contributed significantly to the development of advanced scaffolds for load bearing tissue engineering applications. Despite this, there is still a need to create scaffolds that can simultaneously present multiple biophysical and biochemical properties to better mimic native cellular environments. Polyglycidol has been shown to be a biocompatible polyether polyol, that forms different, sometimes complex, polymeric architectures. Furthermore, it has multiple hydroxyl groups that are capable of numerous chemical modifications. However, little is known about the biocompatibility of modified polyglycidols and their resulting 3-D network. The overarching hypothesis for this project is that changes in the mechanical, structural, and compositional cues within a polyglycidol-based network can be tailored to influence cell responses. Therefore, as a crucial first step, we investigated the biocompatibility of functionalized polyglycidols, and the swelling, degradation, and mechanical properties of polyglycidol based hydrogels. Ongoing studies aim to show that a defined subset of biophysical and biochemical cues can be incorporated simultaneously within the polyglycidol hydrogel. Such an advanced scaffold would allow us to study the synergistic effects of various chemical and physical cues on cellular behavior.