Low-dimensional materials especially graphene-based are of high interest to a broad community. One of the most fundamental aspects in the biomedical field is material characterization, which helps understand their property and tune for application. Though the existing teaching curricula are well standardized to include basic principles and…

Launching biomedical innovations based on clinical demands instead of translating basic research findings to practice reduces the risk that the results will not fit the clinical routine. To realize this type of innovation, a meta-analysis of the body of research is necessary to reveal demand-matching concepts. However, both the data deluge and the…

American universities are purported to excel at technology transfer. This assumption, however, masks important features of American innovation. Attempts to emulate the US example must recognize the heterogeneity of its industries and institutions of higher education. Stanford University and the biomedical cluster in Boston, Massachusetts,…

This chapter describes a model for continuous development of adaptive expertise, including growth along the dimensions of innovation and knowledge, examined in the context of a biotransport course in biomedical engineering. Students improved on both knowledge and innovation, moving along a continuum toward adaptive expertise. (Contains 5 figures.)

An analysis of research and development (R&D) funding in New England is presented in four sections: (1) total federal obligations for R&D to the region (e.g., New England received 8.8% of all federal obligations for R&D that were made nationally in 1986, and of the 1986 funds obligated nationally to colleges and universities, over 11%…