Marco A. Velasco

TL;DR: Issues related to scaffold biomaterials and manufacturing processes are discussed, and mechanobiology of bone tissue and computational models developed for simulating how bone healing occurs inside a scaffold are described.

TL;DR: A geometric generation scheme from a reaction-diffusion model and its manufacturing via a material jetting system is proposed, showing its potential to generate structures that allow to control the basic scaffold properties for bone tissue engineering such as the width of the channels and porosity.

TL;DR: A novel hypothesis that a reaction-diffusion system can be used to design the geometrical specifications of the bone matrix is proposed and the results show the possibility that a Reaction-Diffusions system can control features such as the percentage of porosity, trabecular size, orientation, and interconnectivity of pores.

TL;DR: A novel hypothesis that a reaction–diffusion (RD) system can be used for designing the geometrical specifications of the bone matrix is presented and results showed the methodology's effectiveness in controlling features such as the percentage of porosity, size, orientation, and interconnectivity of pores in an injectable bone matrix produced by the proposed hypothesis.

TL;DR: In this article, a transradial prosthetic hand motion control system using myoelectric signals processing, for a series of preset gestures that are detected in real-time, is presented.