Implementation of a visual raise hand function in PowerPoint®.

Objective: Replacing face-to-face lessons by remote teaching due to COVID-19 led to a markedly reduced interaction between students and lecturers. In our opinion, one of the main reasons for this is the raise hand function of the respective web conference systems, which (independent of the system used) results in an unobtrusive signal that can easily be missed by the lecturer. Given the necessary focus on one's own presentation, questions can therefore only be perceived with a considerable time delay and can only be integrated into the lessons to a limited extent. Thus, the idea arose to display question requests of the auditorium by a clear visual signal in PowerPoint® itself. Methodology: With Visual Basic for Applications (VBA), Microsoft PowerPoint® holds an integrated programming language that extends its functionality. Accordingly, VBA was used to program a routine running in the background of the presentation, which periodically retrieves the contents of a web-based "signal file" in a cycle of a few seconds. The content of this signal file, in turn, can be modified by the students by calling up an URL (i.e. from any Internet-capable device) - this results in a (customizable) visual signal in PowerPoint® that is temporarily visible and does not further interfere with the presentation. Conclusion: With the concept presented here, a raise hand function was realized in PowerPoint®, which manifests itself as a clear visual signal independent of the web conferencing system used. This enables the lecturers to respond instantly to questions from the audience during live transmission of lectures.

Distance teaching of experimental scientific methodology and scientific thinking.

Objective: The aim of this project was to convert a traditional face-to-face seminar for the teaching of experimental scientific methodology to remote teaching in a timely manner due to the COVID-19 related restrictions to teaching in presence. Methodology: The main focus of the course was on flow cytometry. Basics were developed in a virtual presence phase. Specific teaching contents were taught by an interactive presentation, which came very close to the user experience of a flow cytometer and interactively illustrated the influence of different experimental conditions on the obtained results. Video sequences of authentic sample acquisitions were integrated into Adobe Captivate®. These "virtual acquisitions" were not distinguishable from the original procedure. For interpretation of the resulting diagrams, interactions were inserted, which allowed direct comparison of the obtained results. Implementation: A presentation with interactive elements and video sequences was created and used for the virtual presence phases. After publishing on a web server in HTML 5, contents were made available to the students for post-processing of learning contents by self-paced learning with full (interactive) functionality. Conclusion: Contributions elaborated by the students during the course demonstrate a learning outcome comparable to that archieved in the last years in presence mode. While implementation of this solution represented a highly time-consuming process, narrative feedback was consistently positive. Due to the short time available for implementation, no systematic evaluation could be conducted, which represents a clear limitation of this work.