Enhancing students´ engagement, learning and knowledge generation: The RISE case study

The present case study illustrates an example of how universities can develop initiatives that enhance the learning effectiveness of their students and, at the same time, help them become more innovative and generate knowledge that improves research outcomes and contributes to scientific advancement. Research & Innovation in Science and Engineering (RISE) constitutes an initiative implemented by an Indian comprehensive university, through which multidisciplinary teams of students present their project ideas and, if selected, they get the institutional support to develop them: some funds, the university facilities and equipment and, more than anything, the guidance of a dedicated faculty mentor, and the involvement of the industry. The students´ learning experience is totally collaborative, interdisciplinary, applied and experiential, in good alignment with the needs of the present and future labor market. Additionally, the outcomes of the program include research papers, patents and industry partnerships that clearly benefit the institution and all its stakeholders

ANTICANCER ACTIVITIES OF THIOSEMICARBAZIDES/THIOSEMICARBAZONES: A REVIEW

There have been tremendous development in the chemotherapy of cancer and researches are still developing new and more effective drugs to combat this disease. Thiosemicarbazides and thiosemicarbazone possess a wide range of biological applications. This key biological role is often related with their capability to inhibit the enzyme ribonucleotide reductase, similar to what is observed with potent anticancer drugs such as triapine and methisazone. Recent studies have revealed that thiosemicarbazones can inhibit topoisomerase II enzyme. This review discusses current advances of an emerging ‘new wave' of thiosemicarbazide/thiosemicarbazone and their metal complexes as potent anticancer agents, mode of action and toxicity caused by them

Sugarcane Bagasse-Derived Activated Carbon- (AC-) Epoxy Vitrimer Biocomposite: Thermomechanical and Self-Healing Performance

Vitrimeric materials have emerged as fascinating and sustainable materials owing to their malleability, reprocessability, and recyclability. Sustainable vitrimeric materials can be prepared by reinforcing polymeric matrix with bioderived fillers. In the current work, a sustainable vitrimer is prepared by incorporating biomass-derived activated carbon (AC) filler into the epoxy matrix to achieve enhanced thermal and mechanical properties. Thus, prepared biocomposite vitrimers demonstrate a lower-temperature self-healing (70°C for 5 min) via disulfide exchanges, compared to the pristine epoxy vitrimers (80°C for 5 min). Significantly, the self-healing performances have been studied extensively with the flexural studies; and changes in material healing efficiency have been demonstrated based on the observed changes in modulus