Enhanced neurite outgrowth on electrically conductive carbon aerogel substrates in the presence of an external electric field

Influence of aerogel mechanical properties on collagen micromorphology and its architecture

Previously, we demonstrated the promise of aerogels for the repair of nerve injuries as neural cells extend longer processes (neurites) when grown on aerogels compared to a control surface. We also reported that the aerogel surface topography influenced neurite length. Neurite extension may be boosted by depositing collagen on the aerogel prior to plating the cells. Indeed, collagen has many applications in biomaterials for nerve repair because it profoundly influences cellular properties such as shape and motility. Using collagen to enhance neurite extension requires knowing the effect of collagen deposition on the aerogel surface profile as well as how the aerogel's surface topography influences collagen organization into fibers or films. Herein, we have examined by SEM and profilometry the reciprocal relationship between collagen micromorphology and aerogel surface features including pore diameters, surface roughness, and Young's modulus (Y). Using 5 types of aerogels differing from each other by these parameters, we show that increasing the collagen surface concentration from 4 to 20 μg cm-2 leads to a gradual transition in collagen architecture from discrete fibers to films where individual fibers were not discernible. The collagen surface concentration at which deposited collagen changes from filaments to films (transition point, T.P.) was strongly dependent on aerogel physical properties as it increased with increasing pore diameter and surface roughness, while Y had little effect. These results provide a practical framework to customize the organization of collagen fibers on scaffolds for biomedical applications.

Noninvasive Detection, Tracking, and Characterization of Aerogel Implants Using Diagnostic Ultrasound

Medical implants are routinely tracked and monitored using different techniques, such as MRI, X-ray, and ultrasound. Due to the need for ionizing radiation, the two former methods pose a significant risk to tissue. Ultrasound imaging, however, is non-invasive and presents no known risk to human tissue. Aerogels are an emerging material with great potential in biomedical implants. While qualitative observation of ultrasound images by experts can already provide a lot of information about the implants and the surrounding structures, this paper describes the development and study of two simple B-Mode image analysis techniques based on attenuation measurements and echogenicity comparisons, which can further enhance the study of the biological tissues and implants, especially of different types of biocompatible aerogels.

Effect of concentration of glycidol on the properties of resorcinol-formaldehyde aerogels and carbon aerogels

By using glycidol as a catalyst, high porosity, low-density resorcinol (R) and formaldehyde (F) aerogels and carbon aerogels (CAs) were synthesized via a sol-gel method. The effect of glycidol and water on the color, density, morphology, textual characteristics and adsorption properties of the resultant RF aerogels and CAs were investigated in detail. The results revealed that the properties of RF aerogels and CAs can be controlled by adjusting the amount of glycidol and water. The resultant RF aerogels and CAs were porous materials, the minimum densities of RF aerogels and CAs were 96 and 110 mg cm⁻³ respectively while the maximum specific surface areas of RF aerogels and CAs were 290 and 597 m² g⁻¹. The maximum adsorption capacity of CAs was about 125 mg g⁻¹ on Rhodamine B, which was higher than that of some reported CAs catalyzed by base and acid catalysts. The sol-gel mechanisms of RF aerogels and CAs can be attributed to the opening of the epoxy group of glycidol in the mixture of R and F.

The sol-gel mechanism of glycidol-catalyzed RF aerogels is the opening of the epoxy ring rather than the preservation the of epoxy ring.

Safety and efficacy assessment of aerogels for biomedical applications

The unique physicochemical properties of aerogels have made them an attractive class of materials for biomedical applications such as drug delivery, regenerative medicine, and wound healing. Their low density, high porosity, and ability to regulate the pore structure makes aerogels ideal nano/micro-structures for loading of drugs and active biomolecules. As a result of this, the number of in vitro and in vivo studies on the therapeutic efficacy of these porous materials has increased substantially in recent years and continues to be an area of great interest. However, data about their in vivo performance and safety is limited. Studies have shown that polymer-based, silica-based and some hybrid aerogels are generally regarded as safe but given that studies on the acute, subacute, and chronic toxicity for the majority of aerogel types is missing, more work is still needed. This review presents a comprehensive summary of different biomedical applications of aerogels proposed to date as well as new and innovative applications of aerogels in other areas such as decontamination. We have also reviewed their biological effect on cells and living organisms with a focus on therapeutic efficacy and overall safety (in vivo and in vitro).