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Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices (2024)
Journal Article
Yong, L. X., Sefton, J., Vallières, C., Rance, G. A., Hill, J., Cuzzucoli Crucitti, V., Dundas, A. A., Rose, F. R., Alexander, M. R., Wildman, R., He, Y., Avery, S. V., & Irvine, D. J. (2024). Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices. ACS Applied Materials and Interfaces, 16(40), 54508–54519. https://doi.org/10.1021/acsami.4c04833

This study reports the development of the first copolymer material that (i) is resistant to fungal attachment and hence biofilm formation, (ii) operates via a nonkilling mechanism, i.e., avoids the use of antifungal actives and the emergence of funga... Read More about Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices.

Enabling High-fidelity Personalized Pharmaceutical Tablets through Multimaterial Inkjet 3D Printing with a Water-soluble Excipient (2024)
Journal Article
Rivers, G., Lion, A., Rofiqoh Eviana Putri, N., Rance, G., Moloney, C., Taresco, V., Crucitti, V. C., Constantin, H., Inê Evangelista Barreiros, M., Cantu, L. R., Tuck, C., Rose, F. R. A. J., Hague, R. J. M., Roberts, C. J., Turyanska, L., Wildman, R. D., & He, Y. (2024). Enabling High-fidelity Personalized Pharmaceutical Tablets through Multimaterial Inkjet 3D Printing with a Water-soluble Excipient. Materials Today Advances, 22, Article 100493. https://doi.org/10.1016/j.mtadv.2024.100493

Additive manufacturing offers manufacture of personalised pharmaceutical tablets through design freedoms and material deposition control at an individual voxel level. This control goes beyond geometry and materials choices: inkjet based 3D printing e... Read More about Enabling High-fidelity Personalized Pharmaceutical Tablets through Multimaterial Inkjet 3D Printing with a Water-soluble Excipient.

Enabling high-fidelity personalised pharmaceutical tablets through multimaterial inkjet 3D printing with a water-soluble excipient (2024)
Journal Article
Rivers, G., Lion, A., Putri, N. R. E., Rance, G. A., Moloney, C., Taresco, V., Crucitti, V. C., Constantin, H., Evangelista Barreiros, M. I., Cantu, L. R., Tuck, C. J., Rose, F. R., Hague, R. J., Roberts, C. J., Turyanska, L., Wildman, R. D., & He, Y. (2024). Enabling high-fidelity personalised pharmaceutical tablets through multimaterial inkjet 3D printing with a water-soluble excipient. Materials Today Advances, 22, Article 100493. https://doi.org/10.1016/j.mtadv.2024.100493

Additive manufacturing offers manufacture of personalised pharmaceutical tablets through design freedoms and material deposition control at an individual voxel level. This control goes beyond geometry and materials choices: inkjet based 3D printing e... Read More about Enabling high-fidelity personalised pharmaceutical tablets through multimaterial inkjet 3D printing with a water-soluble excipient.

Exploiting Generative Design for Multi-Material Inkjet 3D Printed Cell Instructive, Bacterial Biofilm Resistant Composites (2022)
Preprint / Working Paper
he, Y., Begines, B., Trindade, G., Abdi, M., dubern, J.-F., Prina, E., Hook, A., Choong, G., Ledesma, J., Tuck, C., R. A. J. Rose, F., Hague, R., Roberts, C., De Focatiis, D., Ashcroft, I., Williams, P., Irvine, D., alexander, M., & Wildman, R. Exploiting Generative Design for Multi-Material Inkjet 3D Printed Cell Instructive, Bacterial Biofilm Resistant Composites

As our understanding of disease grows, it is becoming established that treatment needs to be personalized and targeted to the needs of the individual. In this paper we show that multi-material inkjet-based 3D printing, when backed with generative des... Read More about Exploiting Generative Design for Multi-Material Inkjet 3D Printed Cell Instructive, Bacterial Biofilm Resistant Composites.

Mineralizing Coating on 3D Printed Scaffolds for the Promotion of Osseointegration (2022)
Journal Article
Hasan, A., Bagnol, R., Owen, R., Latif, A., Rostam, H. M., Elsharkawy, S., Rose, F. R., Rodríguez-Cabello, J. C., Ghaemmaghami, A. M., Eglin, D., & Mata, A. (2022). Mineralizing Coating on 3D Printed Scaffolds for the Promotion of Osseointegration. Frontiers in Bioengineering and Biotechnology, 10, Article 836386. https://doi.org/10.3389/fbioe.2022.836386

Design and fabrication of implants that can perform better than autologous bone grafts remain an unmet challenge for the hard tissue regeneration in craniomaxillofacial applications. Here, we report an integrated approach combining additive manufactu... Read More about Mineralizing Coating on 3D Printed Scaffolds for the Promotion of Osseointegration.

Ink-jet 3D printing as a strategy for developing bespoke non-eluting biofilm resistant medical devices (2021)
Journal Article
He, Y., Luckett, J., Begines, B., Dubern, J. F., Hook, A. L., Prina, E., Rose, F. R., Tuck, C. J., Hague, R. J., Irvine, D. J., Williams, P., Alexander, M. R., & Wildman, R. D. (2022). Ink-jet 3D printing as a strategy for developing bespoke non-eluting biofilm resistant medical devices. Biomaterials, 281, Article 121350. https://doi.org/10.1016/j.biomaterials.2021.121350

Chronic infection as a result of bacterial biofilm formation on implanted medical devices is a major global healthcare problem requiring new biocompatible, biofilm-resistant materials. Here we demonstrate how bespoke devices can be manufactured throu... Read More about Ink-jet 3D printing as a strategy for developing bespoke non-eluting biofilm resistant medical devices.

Mixed polymer and bioconjugate core/shell electrospun fibres for biphasic protein release (2021)
Journal Article
Adala, I., Ramis, J., Ntone Moussinga, C., Janowski, I., Amer, M. H., Bennett, A. J., Alexander, C., & Rose, F. R. (2021). Mixed polymer and bioconjugate core/shell electrospun fibres for biphasic protein release. Journal of Materials Chemistry B, 9(20), 4120-4133. https://doi.org/10.1039/d1tb00129a

Effective regenerative medicine requires delivery systems which can release multiple components at appropriate levels and at different phases of tissue growth and repair. However, there are few biomaterials and encapsulation techniques that are fully... Read More about Mixed polymer and bioconjugate core/shell electrospun fibres for biphasic protein release.

Discovery of synergistic material-topography combinations to achieve immunomodulatory osteoinductive biomaterials using a novel in vitro screening method: The ChemoTopoChip (2021)
Journal Article
Burroughs, L., Amer, M., Vassey, M., Koch, B., Figueredo, G., Mukonoweshuro, B., Mikulskis, P., Vasilevich, A., Vermeulen, S., Dryden, I. L., Winkler, D. A., Ghaemmaghami, A. M., Rose, F. R. A. J., de Boer, J., & Alexander, M. R. (2021). Discovery of synergistic material-topography combinations to achieve immunomodulatory osteoinductive biomaterials using a novel in vitro screening method: The ChemoTopoChip. Biomaterials, 271, Article 120740. https://doi.org/10.1016/j.biomaterials.2021.120740

© 2021 The Authors Human mesenchymal stem cells (hMSCs) are widely represented in regenerative medicine clinical strategies due to their compatibility with autologous implantation. Effective bone regeneration involves crosstalk between macrophages an... Read More about Discovery of synergistic material-topography combinations to achieve immunomodulatory osteoinductive biomaterials using a novel in vitro screening method: The ChemoTopoChip.

Inkjet based 3D Printing of bespoke medical devices that resist bacterial biofilm formation (2020)
Preprint / Working Paper
He, Y., Begines, B., Luckett, J., Dubern, J.-F., Hook, A., Prina, E., Rose, F. R., Tuck, C., Hague, R., Irvine, D., Williams, P., Alexander, M. R., & Wildman, R. D. Inkjet based 3D Printing of bespoke medical devices that resist bacterial biofilm formation

We demonstrate the formulation of advanced functional 3D printing inks that prevent the formation of bacterial biofilms in vivo. Starting from polymer libraries, we show that a biofilm resistant object can be 3D printed with the potential for shape a... Read More about Inkjet based 3D Printing of bespoke medical devices that resist bacterial biofilm formation.

Nanofibrous scaffolds support a 3D in vitro permeability model of the human intestinal epitheleum (2019)
Journal Article
Patient, J. D., Hajiali, H., Harris, K., Abrahamsson, B., Tannergreen, C., White, L. J., Ghaemmaghami, A. M., Williams, P. M., Roberts, C. J., & Rose, F. R. (2019). Nanofibrous scaffolds support a 3D in vitro permeability model of the human intestinal epitheleum. Frontiers in Pharmacology, 10, Article 456. https://doi.org/10.3389/fphar.2019.00456

Advances in drug research not only depend on high throughput screening to evaluate large numbers of lead compounds but also on the development of in vitro models which can simulate human tissues in terms of drug permeability and functions. Potential... Read More about Nanofibrous scaffolds support a 3D in vitro permeability model of the human intestinal epitheleum.