Factors affecting the structure and properties of bioactive foam scaffolds for tissue engineering

## Abstract In this work, the conditions to obtain concentrated and fluid suspensions from a bioactive glass (55‐SiO~2~; 41‐CaO; 4‐P~2~O~5~; mol %) were investigated. The influence of the heat treatment of the glass on the specific surface area, solubility, bioactivity, and finally on their dispers

## Abstract One of the main challenges in the investigation on calcium phosphate cements (CPC) lies in the introduction of macroporosity, without loosing the self‐setting ability and injectability, characteristic of the cement‐type materials. The benefits of macroporosity are related to the enhance

Cell transplantation using biocompatible, biodegradable scaffolds offers the possibility of creating or regenerating tissue to replace organ function when deficiency arises. The role of these temporary substrates is to support and guide the expanding cell culture until it becomes structurally integr

## Abstract Highly porous poly(DL‐lactic acid) (PDLLA) foams and Bioglass®‐filled PDLLA composite foams were characterized and evaluated __in vitro__ as bone tissue engineering scaffolds. The hypothesis was that the combination of PDLLA with Bioglass® in a porous structure would result in a bioreso

## Abstract Well‐defined structural characteristics are some of the exigencies that have to be attended when scaffolds for bone tissue cell culture are designed. A high porosity (70–90%) and a high specific surface area and an average pore size > 150 μm will contribute to allow cell migration throu

## Abstract Porous polyester thermoset xerogels have been produced via sol–gel chemistry as a first step in the development of sol–gel derived tissue engineering scaffolds templated by replica molding and/or salt leaching. The pore structure of these untemplated thermosets is tunable and can be alt