Biomedical engineering merges engineering principles with biological sciences to innovate diagnostics, therapeutic devices, and regenerative solutions. The discipline supports scaffold design, imaging systems, and microfluidic platforms that mimic in vivo conditions for tissue development. Biomedical engineers are now integrating biosensors with cellular constructs to monitor healing in real time. Tools such as lab-on-a-chip and organ-on-chip are reshaping how researchers model disease and test regenerative therapies. In the context of clinical applications, Biomedical Engineering contributes to designing biocompatible implants, enhancing rehabilitation technologies, and streamlining regenerative workflows. Its impact spans across tissue mechanics, cellular responses, and translational efficacy, making it indispensable to modern regenerative medicine.
Title : Eliminating implants infections with nanomedicine: Human results
Thomas J Webster, Interstellar Therapeutics, United States
Title : Biodistribution and gene targeting in regenerative medicine
Nagy Habib, Imperial College London, United Kingdom
Title : Graphene, butterfly structures, and stem cells: A revolution in surgical implants
Alexander Seifalian, Nanotechnology & Regenerative Medicine Commercialisation Centre, London NW1 0NH, United Kingdom
Title : Precision in cartilage repair: Breakthroughs in biofabrication process optimization
Pedro Morouco, Polytechnic of Leiria, Portugal
Title : Keratin-TMAO wound dressing promote tissue recovery in diabetic rats via activation of M2 macrophages
Marek Konop, Medical University of Warsaw, Poland
Title : Assessing geometric simplifications in vertebral modeling for reliable numerical analysis of intervertebral discs
Oleg Ardatov, Vilnius University, Lithuania