Author:
Johnston Iain G.,Slater Mark,Cazier Jean-Baptiste
Abstract
Bioinformatics is a highly interdisciplinary subject, with substantial and growing influence in health, environmental science and society, and is utilised by scientists from many diverse academic backgrounds. Education in bioinformatics therefore necessitates effective development of skills in interdisciplinary collaboration, communication, ethics, and critical analysis of research, in addition to practical and technical skills. Insights from bioinformatics training can additionally inform developing education in the tightly aligned and emerging disciplines of data science and artificial intelligence. Here, we describe the design, implementation, and review of a module in a UK MSc-level bioinformatics programme attempting to address these goals for diverse student cohorts. Reflecting the philosophy of the field and programme, the module content was designed either as “diversity-addressing”—working toward a common foundation of knowledge—or “diversity-exploiting”—where different student viewpoints and skills were harnessed to facilitate student research projects “greater than the sum of their parts.” For a universal introduction to technical concepts, we combined a mixed lecture/immediate computational practical approach, facilitated by virtual machines, creating an efficient technical learning environment praised in student feedback for building confidence among cohorts with diverse backgrounds. Interdisciplinary group research projects where diverse students worked on real research questions were supervised in tandem with interactive contact time covering transferable skills in collaboration and communication in diverse teams, research presentation, and ethics. Multi-faceted feedback and assessment provided a constructive alignment with real peer-reviewed bioinformatics research. We believe that the inclusion of these transferable, interdisciplinary, and critical concepts in a bioinformatics course can help produce rounded, experienced graduates, ready for the real world and with many future options in science and society. In addition, we hope to provide some ideas and resources to facilitate such inclusion.
Reference69 articles.
1. The comparative immunology of wild and laboratory mice, mus musculus domesticus;Abolins;Nat. Commun.,2017
2. Genomics virtual laboratory: a practical bioinformatics workbench for the cloud;Afgan;PLoS ONE,2015
3. Teaching bioinformatics: a student-centred and problem based approach;Ai;Int. J. Innov. Sci. Math. Educ. (formerly CAL-Laborate Int.),2012
4. How to give a good talk;Alon;Mol. Cell,2009
5. A curriculum for bioinformatics: the time is ripe;Altman;Bioinformatics (Oxford, England),1998
Cited by
2 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献
1. Role of Bioinformatics in Sustainable Development;Role of Science and Technology for Sustainable Future;2024
2. Data literacy in genome research;Journal of Integrative Bioinformatics;2023-12-01