Porous hydroxyapatite (HA) bioceramics are widely studied for their potential use in bone regeneration. These materials are biocompatible and have a structure that contains many connected pores. This allows fluid to flow through the material and provides nucleation points for bone growth. The best results are obtained when the the pores are smaller than 1 μm and therefore synthetic methods that give good control over the pore size and material structure are highly desirable.
Prof. Molly Stevens and her team have now demonstrated a way of making an HA bioceramic with a 3D ordered (DOM) macroporous structure. They used an ordered macroporous carbon template (OMC) in combination with a sol-gel method to form the desired bioceramic. They found that the DOM HA, when compared with HA material made without the OMC template, allowed the nucleation of calcium phosphate on the surface of the pores, thus demonstrating that the template method used affects the crystallisation of material.
The team hopes that these materials will find applications not only in the generation of bone but also in the generation of other materials. Want to find out more? Then download the ChemComm article for free today and leave a comment below to let us know what you think.
The luminescent probe features an azaxanthone moiety, which is linked to a europium complex by an amide bond. The azaxanthone allows the probe’s uptake into cells and localisation within the mitochondria, and the europium complex has an affinity for bicarbonate ions. The ability to probe bicarbonate levels ‘can offer an unprecedented insight into signalling mechanisms’, says Parker.
A probe that can cross the blood-brain barrier to allow high sensitivity brain tumour imaging has been made by Chinese scientists. The probe could be used to pinpoint the location and extent of a tumour before an operation and be used for image-guided tumour removal. 
Despite being a useful supplement to support the healthy growth of hair, nails and teeth and the strengthening of bones, an excessive intake of fluorine can lead to adverse effects on development. It can cause mottling of teeth and skeletal fluorosis (causing joint pain and abnormalities in the skeletal structure). Other effects have only been studied in animal models and at concentrations unlikely to be encountered by humans.
