AbstractTransitioning towards a circular economy requires holistic consideration encompassing environmental, economic, and social dimensions. This perspective paper explores circular makerspaces as innovative platforms for fostering social integration and creating employment opportunities within the circular economy, as makerspaces can offer a more inclusive alternative to traditional employment platforms. They have the potential to unveil unrecognised talents, bridge access to under-utilised human capital, and act as pivotal conduits to a decent and inclusive circular labour force. Drawing insights from the European Horizon 2020 project: Pop-Machina, this perspective paper emphasizes the importance of collaborative efforts among policymakers, practitioners, and researchers to unlock the full transformative potential of circular makerspaces. By prioritizing the social aspect of sustainability and leveraging the network of circular makerspaces, circular makerspaces can unlock unexplored human capital, provide employment opportunities and cultivate inclusive, sustainable communities, while highlighting their potential for societal empowerment and innovation. Finally, this perspective paper underscores the need for ongoing research and collaboration to comprehensively understand and evaluate the role of circular makerspaces in the inclusive circular labour market, ensuring that the social dimension remains central to sustainable development endeavours and informing effective policy making.This project focused on the gene PFKFB3, a pivotal regulator of the Warburg effect, which facilitates enhanced glycolysis in cancer cells, including MCF7 human breast cancer lines. The objective was to investigate the effects of PFKFB3 knockout on the metabolic profile and proliferative capacity of MCF7 cells, hypothesizing that disruption of this gene would significantly impair cellular energy production and, consequently, cell growth. Through the application of CRISPR/Cas9 technology, PFKFB3 was specifically targeted and knocked out, followed by a meticulous process of selection to enrich for cells bearing the knockout. Growth assays, particularly MTT, were conducted to evaluate the impact of PFKFB3 deletion on cell proliferation. Contrary to expectations preliminary results indicated no significant difference in the growth rates between PFKFB3-knockout and control groups. This outcome suggests possible metabolic flexibility within MCF7 cells, allowing them to bypass the blockade of one glycolytic pathway—a concept supported by current understandings of cancer metabolism. Despite the lack of expected growth inhibition, this study provides critical insights into the adaptability of cancer cells to metabolic interventions and highlights the importance of targeting multiple metabolic pathways. Future directions will consider exploring the combined knockout of PFKFB3 and other glycolytic genes to overcome the metabolic resilience of cancer cells, thereby offering a more effective strategy for crippling cancer cell energy supplies.