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The COVID-19 pandemic and the recent increased interest in generative artificial intelligence (GenAI) highlight the need for interprofessional communities’ collaboration to find solutions to complex problems. A personal narrative experience of one of the authors compels us to reflect on current approaches to learning and knowledge acquisition and use solutions to the challenges posed by GenAI through social learning contexts using connectivism. We recognize the need for constructivism and experiential learning for knowledge acquisition to establish foundational understanding. We explore how connectivist approaches can enhance traditional constructivist paradigms amid rapidly changing learning environments and online communities. Learning in connectivism includes interacting with experts from other disciplines and creating nodes of accurate and accessible information while distinguishing between misinformation and accurate facts. Autonomy, connectedness, diversity, and openness are foundational for learners to thrive in this learning environment. Learning in this environment is not just acquiring new knowledge as individuals but being connected to networks of knowledge, enabling health professionals to stay current and up-to-date. Existing online communities with accessible GenAI solutions allow for the application of connectivist principles for learning and knowledge acquisition.
The COVID-19 pandemic was unprecedented in exposing the importance of staying current as health professional educators, the dangers of misinformation, and the need for a new approach to learning. In our commentary, we aim to highlight these 3 different aspects.
The first case of COVID-19 in the United States was confirmed in January 2020, and stay-at-home orders were not issued till March 2020 [
In March 2020, just before the COVID-19 pandemic became a reality in the United States, this author was precepting a student in an ambulatory clinic. After some discussion on the topic, the physician and the student both wore masks at the clinic. Coincidentally, another member of the team who was a member of the hospital’s COVID-19 task force walked by, commenting, “You know masks don’t work for COVID-19, right? You will more likely get infected by transferring droplets to your face as you repeatedly adjust the mask.” Due to the information in the preprint articles, the physician and student continued masking, and the physician shared the reasoning behind masking and why several respected health care organizations and experts were advocating against it.
At this hospital, the emphasis was still on droplet precaution with hand washing, thereby aligning with health organizations’ statements prioritizing the need for handwashing for droplet precautions [
The confusion of airborne versus droplet transmission of infection existed several decades prior with other infections, such as tuberculosis, when it was mistakenly believed that infections spread primarily as droplets, with reluctance to accept the airborne route as the cause of transmission [
Questions to be considered at this stage are: What convinced this physician about the mode of transmission and to practice masking contrary to recommendations by their hospital or public health organizations during the initial days of the pandemic? How can a health care provider stay informed when traditional peer-reviewed literature is not yet available and recommendations from health care organizations differ from expert opinions?
As physicians, we are expected to be fully informed of the latest advances in medicine, stay connected with accurate sources of information, and, thus, make the best clinical care decisions. While the challenges posed by the pandemic may be behind us, our aim is to reflect and learn from this experience and derive solutions when there are differing opinions. Overall, the question to address is: How can one use critical appraisal to decipher signals from noise when bombarded with information?
While peer-reviewed evidence is still being generated, people often fall back on institutional guidance and policies, and one needs to recognize the need to explore differing opinions with a critical approach. With this personal experience as our background, we pivot our attention to addressing the realistic challenge of today: the role of GenAI in education. We propose the need for a different approach to learning and knowledge building to solve challenges facing health professionals with GenAI, using connectivism as a complementary approach to the tried and tested methods of constructivism. In doing this, we apply the foundational principles of learning from this personal experience to derive solutions to challenges posed by GenAI and provide concrete examples and suggestions to implement this new framework of learning.
Let us consider this physician’s approach to knowledge generation.
As the news broke of a serious respiratory illness in China, the physician created their personalized stream of information from firsthand observers, including journalists and reporters from reputable newspapers and websites, opinions of a diverse group of experts in infectious disease, virology, immunology, epidemiology, and environmental engineering by creating a list on Twitter (subsequently rebranded X). They checked the profile of experts in each field by their institutional affiliations and qualifications, ignoring follower counts and, instead, focusing on previous work using PubMed, Google Scholar, and organic web searches. Intentionally seeking diverse viewpoints, they expanded their network by adding experts in their field of interest or followed by their existing contacts. They also created an RSS feed of newly published preprint articles on the topic. By regularly perusing the knowledge network and the latest studies on the feed, they stayed current on the latest evidence-based knowledge and multidisciplinary expert opinions by being connected to new knowledge and information in real-time, thus overcoming traditional health care siloes. Their knowledge network expanded by adding authors of key studies from the RSS feed to the Twitter list. Their expanding knowledge allowed them to openly discuss evidence-based facts and highlight scientific knowledge about transmission by airborne spread in earlier studies [
Traditionally, the dissemination of evidence-based knowledge is through information taught at medical schools, academic conferences, and peer-reviewed literature, including systematic reviews. Experts from other fields rarely teach in medical schools, and we seldom venture beyond health care literature for evidence-based information. There are few opportunities for the exchange of ideas between basic scientists and clinical researchers, which further delays the application of translational research to clinical practice. Medical training relies on years of education and learning from clinical experience. This process of building upon previous knowledge while constructing new knowledge is known as “constructivism.” Constructivism works well for established paradigms of knowledge generation at a controlled pace. However, in settings such as the pandemic and currently with GenAI, evidence is generated rapidly and often sourced from disciplines outside health care. In the example above, it was the interdisciplinary work of aerosol scientists that helped us acknowledge airborne transmission [
Constructivism takes time and is a gradual process. As individuals, we are unable to process numerous sources of information simultaneously, and technology can help address this challenge by personalizing the information we receive. When faced with new ideas that do not align with previous knowledge, we either ignore new information or work harder to reframe our understanding. Our psychological drive for consensus suppresses disagreement, sometimes even in the face of evidence-based facts [
Differentiation between constructivism and connectivism.
|
|
Constructivism | Connectivism |
| Learning focus |
Focuses on an individual building internal understanding |
Distributed within a network through connections between information sources |
| Factors |
Influenced by engagement, participation, and social and cultural factors |
Influenced by the diversity of the network, strength of ties, reliability, and accuracy in becoming “nodes” |
| Process of learning |
Learner builds schema based on previous understanding |
Learner builds knowledge by connecting to nodes and growing network |
| Knowledge |
Exists within an individual Connecting new information to existing knowledge |
Exists outside the individual Network’s collective intelligence |
| Information flow |
Sequential builds from a foundational understanding of simple to complex concepts |
Nonlinear, influenced by strength and diversity of connections |
| Knowledge dissemination |
Source of new information: systematic reviews and conferences, slower pace of new information |
Source of new information: preprints; rapidly changing, diverse pool of resources |
| Technology |
Supportive, enhances learning experience |
Integral to learning for connections and to access information |
| Educator’s role |
Experiential learning, helps learners construct knowledge |
Learner-driven, facilitates connections, guides learners to reliable sources |
Public health institutions’ announcements from the World Health Organization and the Centers for Disease Control and Prevention reach billions of people who trust and follow their recommendations as they are based on well-founded evidence. Until fully verified, informing the public of aerosolized spread could cause panic and chaos, leading to a shortage of personal protective equipment with a huge socioeconomic impact [
Connectivism was first proposed by Siemens [
We consider the following implications for using connectivism as clinicians: First, the starting point of connectivism are “nodes” of accurate information; these can be individual experts, devices, or communities. Knowledge is created through interaction between the nodes and due to the diversity of opinions [
Second, autonomy allows learners to choose their learning communities through self-directed learning in massive online open courses. Individuals have the freedom to express their ideas and explore the knowledge network to identify experts and acquire knowledge based on their level of motivation and not be restricted by a hierarchical approach to learning. Exploring the diversity of opinions allows the learner to experience the breadth of opinions. A physician with the skills to identify reliable and accurate sources of information with a diversity of opinions has a better understanding of the challenges faced by patients and can provide practical advice by directly addressing misinformation. These dialogues allow for interactivity and problem-solving [
Connectedness enables collaboration, and learning occurs through new connections between nodes and being connected to the right sources allows knowledge propagation in networks [
Learning in connectivism is based on the production of knowledge rather than the consumption of knowledge by prioritizing relevant data while filtering out irrelevant information. In the digital environment, learning is enhanced by engagement with virtual communities of practice through blogs, posts on X, podcasts, and meaningful dialogue [
If academia fails to embrace a connectivist framework, it risks losing its position as an arbiter of information while becoming less relevant.
The application of connectivism helps expand our approach to constructing scientific knowledge. It can move us from traditional classrooms to virtual communities by implementing solutions that are responsive, agile, networked, and dynamic [
A limitation of connectivism is the overwhelming amount of information and diversity of opinions. Educators should address this by organizing the content by highlighting the common themes through coherence [
Learning activities for teaching connectivism and its application.
| Course objectives | Learning objectives | Learning activities | How can it be incorporated into the curriculum? |
| Connectivism framework |
Summarize principles of connectivism Compare the relevance of connectivism to other frameworks for learning about GenAIa Identify valid resources from misinformation |
Create a session on GenAI; as prework, provide the seminal paper by Siemens (Connectivism: A Learning Theory for the Digital Age) [ At the session, review the paper in a large group discussion Small group discussion on how connectivism is relevant for learning about and staying up to date on GenAI |
Identify a learning community Identify experts on social media platforms Discuss a preprint article on GenAI [ Describe the cognitive authority of communities or experts |
| GenAI concerns, limitations, and potential benefits. |
List limitations, concerns, and benefits of GenAI Recognize settings when it is most applicable |
Discussion board on the dangers of misinformation and how to avoid it Small group discussion on the dangers of not exploring diverse opinions |
Provide an article on droplet transmission [ Provide resources on scientific community sites that show |
| Practicing connectivism |
Review a strategy for building, curating, and navigating a knowledge network Practice tools for implementing this strategy Discuss bias in GenAI |
Provide tasks for identifying reliable sources of information. Identify tools for knowledge curation |
Identify a list of reputable experts and reliable media articles [ Identify expertise by looking at their track record for accuracy: explore institutional affiliations Track Google Scholar and PubMed citations of experts; explore other experts they follow Populate the list with people of multiple perspectives and disciplines Identify resources to address misinformation [ |
aGenAI: generative artificial intelligence.
In this commentary, we use a personal narrative to make the case for rethinking our approach to learning and acquiring knowledge in a connected world. We recognize the challenges posed by GenAI and the need for innovative solutions using connectivist approaches. Some of the challenges with GenAI are the concerns about biases, inaccuracies with hallucinations, and the accessibility of these tools. Being connected to learning communities, subscribing to credible and accurate sources of information, and being able to critically analyze information are potential solutions. Using freemium GenAI tools addresses some of the problems with accessibility and unfamiliarity with these tools. Embracing digital technologies and internet tools as health professional educators enables us to direct our learners through cohesive approaches to trainees to build, curate, and navigate knowledge networks that will help them address challenges with misinformation. As the amount of information and misinformation grows, one of the essential skills for health care practitioners will be the need to decipher accurate information from misinformation, which is possible by belonging to learning communities that amplify accurate information and expose the dangers of misinformation. GenAI poses an exciting opportunity to democratize resources through open-source collaborative efforts.
GenAI can be used across different learning paradigms, enabling learner-directed learning and empowering the teacher in a connectivist learning environment [
First, creating a dynamic learning network encourages health care professionals and students to build and maintain professional networks through platforms like LinkedIn, X, and specialty-specific forums. Individuals can access real-time updates and exchange information. Use the feed generators from online communities and interested studies to build a knowledge network. Demonstrate the use of desired feed from journals on topics of interest. Identify experts from various disciplines.
Second, integrate technology into learning and practice; demonstrate the use of available resources such as podcasts, online webinars, blogs, and community forums to help with knowledge-building.
Third, develop critical information literacy skills, including training on how to critically assess the reliability and credibility of information sources, especially those found online. It is essential for learners to be able to distinguish between valid and misleading information and address misinformation.
Fourth, by leveraging artificial intelligence capabilities, clinicians can filter out unnecessary information, and GenAI tools can identify relevant scientific articles through feeds from reliable sources of information and amplify their search using freemium tools such as Research Rabbit. In addition, these tools allow for adaptive personalized instruction to the learner.
Fifth, the clinician can incorporate these tools as part of a synchronous classroom activity and model critical inquiry skills when using GenAI. By analyzing the accuracy of outputs, clinicians can model iterative prompting to refine GenAI outputs, refine learning, and expose the gaps in outputs.
generative artificial intelligence
The authors acknowledge the Huffington Department of Education Innovation and Technology at Baylor College of Medicine and the Lerner College of Medicine Cleveland Clinic for their support. The open access publication fee was funded in part by a nonrestrictive donor gift through the Hennick Bridgepoint Foundation.
HM declares a paid role as interim assistant dean of clinical faculty development at Toronto Metropolitan University School of Medicine, paid honorariums for invited academic talks for various organizations and conferences on academic technologies., and a nonrestricted educational grant from Novo Nordisk for online faculty development on teaching social determinants of health.